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• N£KTON STATION 5 0 Fig. 2.6. Environmental Technical Specifications nekton station locations and environmental surveillance zones, San Onofre Nuclear Generating Station Unit 1. Source:

Lockheed Center for Marine Research, San Onofre Nuclear Generating Station Unit 1-,------

Envil'onmental Technical Specifications, Annual Operating Report, Vol. IV, B1:ologiaal Data Analysis- 1976, June 1977.

2-18 surfperch, black croaker (Chilotrema saturnum), spotfin croaker, and half moon (Medialuna californiensis) were captured in both zones.21 As a group, these seven species accounted for 81.3% of the total catch for the year. 27 .The first five of these species were tested for significant differences between zones and among surveys. Only the queenfish and white croaker showed a significant difference between zones, being significantly more abundant in zone OA than in zone 6. The remaining three species did not differ significantly between zones.

In contrast, six predominant species in 1975 {bottom nets) contributed 82.3% of the individuals collected. 25 Of the predominant species netted in both years, only the queenfish and white croaker were significantly more abundant in zone OA than in zone 6 during both years of the survey.

The spatial distribution of the queenfish, white croaker, and white surfperch differed significantly among the 1976 surveys. Temporally, the queenfish was found to be most abundant during the December survey and least abundant during the March survey. The white croaker was significantly more abundant during the December and March surveys than during the September and June surveys, and the white surfperch was significantly more abundant in the December catch than during all of the other 1976 surveys.

Significant differences were observed in the number of species between zones, with the number in zone OA being significantly greater than the number in zone 6. Four species best discriminated between zones OA and 6: white seabass, white croaker, yellowfin croaker (Umbrina roncador); and white surfperch.

There was also a significant difference among survey periods, with the number of species taken in March being significantly less than the number taken during all of the other surveys, which were not significantly different from each other.

The significant difference found in both number of individuals and number of species among surveys in 1976 was also found in.l975 although no obvious trend in species diversity was revealed (Fig. 2.7). On the other hand, a high similarity within zones existed during 1976; the 1975 data indicated similar but less distinct patterns.

The data suggest that the areas sampled in the two zones m~ support somewhat different nekton communities. Physical differences between the zones which may also affect the nekton results include the presence of the intake and discharge structures at SONGS 1 and riprap material in zone OA, general differences in substrate type and composition between the zones, turbidity, and the presence of a dense stand of the phaeophyte Cystoseria spp. in the area of the zone OA nekton stations. Temperature data collected during bimonthly cruises and nekton surveys revealed no obvious differences between zones, which indicates that temperature is not an important factor.

Fisheries statistics Commercial and sport fisheries catch data for 1974 from the California Department of Fish and Game statistical blocks in the vicinity of SONGS 1 (Fig. 2.8) revealed that the number of fish per block ranged from 16,601 in block 737 to 123,246 in block 756. 27 With the exception of block 801, all of the blocks examined measured an increase in catch per unit effort between 1973 and 1974. However, the magnitude of the increase was small in comparison to the decrease shown by all of the blocks over the past 13 years.

The 1974 commercial catch reported a total of 46 taxa from the five blocks surrounding San Onofre. 27 The only taxon comaon to all five blocks was the Pacific bonito (~

chiliensis). Each of the five blocks yielded catches at about the expected level, based on the s1ze of the blocks and the amount of coastline encompassed. 27 2.5.2.3 Benthos 1975 Data Three surveys conducted in 1975 at 11 benthic stations (Fig. 2.9) revealed a total of 160 species or higher taxa of epibenthic macrobiota (Tables X-1 to X-11, pp. X-12 to X-43 of ref. 22). The taxa represented members of 11 major taxonomic groups. Within zones not associated with kelp beds (zones OA and 6), the flora was dominated by rhodophyte taxa throughout the year. Mollusks were the dominant fauna during April and October, whereas molluscan and chordate taxa occurred in similar numbers during the July sampling period. Rhodophytes were also the dominant floral component and mollusks were the dominant faunal component of the kelp bed biota at all kelp bed stations during all survey periods.

2-19 22or---------------------------------------------~E~S~-~41~9~1 NUMBER OF INDIVIDUALS I

I I

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0.5 Fig. 2.7. The mean number of individuals and species per net by zone and species diversity of zones OA and 6 by survey du.ring 1975 and 1976. Source: Lockheed Center for Marine Research, San Onof:r>e Nuclear Gene:r>ating Station Unit 1., Envi:r>onmental Teahniaal Speaifiaations, Annual Operoting Report, Vol. IV, Biological Data Analysis - 1976, June 1977.

2-20 The species whose distribution best discriminated between zones OA and 6 were the anthozoan Muricea californica, which occurred mostly in zone 6; the rhodophyte Prionitis spp.,

which was absent from zone 6; the holothuroid Parastichopus carvimenSlS, whlch occurred only in zone 6; and the gastropod Astrea undosa, which was o served only in zone OA.

The trophic composition based on the number of taxa of the two zones not associated with kelp beds (zones OA and 6) was similar among these zones and was dominated by suspension feeders and by primary producers during all surveys (Table 2.6).

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.5 0 Fig. 2.9. Environmental Technical Specifications environmental surveillance zones, benthic station locations, San Onofre Nuclear Generating Station Unit 1. Source: lockheed Center for Marine Research, San Onofre NUclear Generating Station Unit 1, Environmental Teahniaal Speai~aations, Annual Operating Report, Vol. IV, Biological Data Analysis - 19?6, June 1977.

2-22 Table 2.6. Trophic composition (percent) of benthic taxa at discharge (zone OAI and control (zone 6) based on the number of taxa of each trophic type present during 1975 April10-18 Jul~ 15-18 October 13-17 Trophic types Zone OA ZoneS ZoneOA ZoneS Zone OA ZoneS Primary producers 23 18 35 40 30 29 Suspension feeders 34 43 35 42 33 37 Grazers 10 3 12 12 5 Scavengers 13 13 7 10 12 11 Predators 20 22 12 7 13 18 Source: Lockheed Marine Biological Laboratory, San Onofre Nuclear Generating Station Unit 1.

Annual Analysis Report, Environmental Technical Specifications, January - December 1975, 197S.

Kelp bed stations were best distinguished by four taxa: the gastropod Gypraea epadiaea, which occurred only at San Onofre Kelp Bed; the anthozoan Corynaatis spp., which occurred predomi-nately at San Mateo and Barn kelp beds; the annelid spioahaetopterus costarum, which did not occur at San Onofre Kelp Bed; and the white abalone, HaZiotis sorenseni, which occurred only at San Onofre Kelp Bed. Twelve taxa were considered predominant at kelp bed stations: CheZyoeoma produatum, Conus aaZiforniaus, CoraZZina/HaZiptyZon, Corynaatis spp., Crustose corallines (unident.), Dioptra spp., LeuaiZZa nuttingi, Lyteahinus piatus, MitreZZa aarinata, Muriaea aaZiforniaa, Pagurids (unident.), and Rhodymenia spp.

Trophic composition based on the number of taxa at the kelp bed stations was similar among stations and was dominated by suspension feeders (e.g., barnacles, which feed by filtering out suspended material) and primary producers (algae) during all surveys {Table 2.7).

Table 2.7. ::rrophic composition (percent) of benthic taxa at San Matao (SMK),

San Onofre {SOKI, and Barn (BKI kelp beds based on the number of taxa of each trophic type present during 1975 April10-18 Jul~ 15-18 October 13-17 Trophic types SMK SOK BK SMK SOK BK SMK SOK BK Primary producers 22 19 24 26 21 25 30 18 26

• Suspension feeders 49 36 41 38 36 59 43 38 45 Grazers 2 17 9 8 12 7 10 4 Scavengers 12 12 9 12 12 9 7 12 10 Predators 15 17 17 16 18 6 12 22 16 Source: Lockheed Marine Biological Laboratory, San Onofra Nuclear GenertJting Station Unit 1, Annual Analysis Report, Environmental Technical Specifications, JB{Iuary - Dacamber 1975,1976.

1976 Data Diving surveys of the epibenthic macrobiota were conducted quart~rly during 1976 at the same 11 benthic stations. A total of 159 species or higher taxa, which were members of 11 major taxo-nomic groups, were identified during the four surveys. 27 A taxonomic summary of these data by station and by survey is presented in Tables IV-1 and IV-2, pp. 21-28 of ref. 26. Zones OA and 6 contained twelve predominant taxa whose combined abundance accounted for 84.3% of the total percent cover and 65.1% of the total enumerated individuals.27 Seven of the twelve predominant taxa consisted of large taxonomic categories that were not field identifiable to a lower taxon.

These seven taxa included parvosilvosa, unidentified ectoprocts, unidentified crustose coralline algae, and unidentified hydroids, rhodophytes, pelecypod siphons, and pagurids. These large taxonomic groups totaled 72% of the total percent cover and 20% of the total enumerated indivi-duals for the entire year*s data. 27 The magnitude of the abundances of these large taxonomic groups may be somewhat misleading, however, because each of these categories can contain members of several different species. 27

2-23 The predominant taxa identified to at least the generic level consisted of Rhodymenia spp.,

Bryopsis hypnoides, Diopatra ornata, Murioea oalifornica, and Patiria miniata. The distribution of these taxa among zones and stations is presented in Table V-12, p. 68 of ref. 27. The abund-ance of all of these taxa differed significantly between zones; Rhodymenia spp. and Patiria miniata were significantly more abundant in zone OA, whereas Bryopsis hypnoides, Diopatra ornata, and MUrioea californioa were significantly more abundant in zone 6. None of these taxa differed significantly among surveys.

A greater degree of similarity in both species composition and abundance was found within zones than between zones. Distribution of the anthozoan Murioa oalifornioa and the rhodophyte Prio-nitis spp. contributed the greatest to the differences between zones OA and 6 in both years.

Also in both 1975 and 1976, M. oaZifornioa and the polychaete Diopatra ornata were significantly more abundant in zone 6. Species composition of the San Onofre Kelp Station was generally more similar to zone OA stations than to the other kelp bed stations; this is much the same as the 1975 survey data.

No significant differences existed between zones or kelp bed stations in the distribution of taxa among trophic levels during 1975 or 1976.

Aerial infrared kelp survey An aerial infrared kelp survey revealed that both Barn and San Onofre kelp beds showed a slight increase in total area during 1975 (Fig. 2.10). All of the kelp beds increased in size between February and May 1976 (Fig. 2.10). During the period May to September 1976, Barn and San Onofre kelp beds underwent an 80 and 92% decrease respectively. 27 At the time of the November 1976 survey, Barn Kelp Bed had increased to 77% of the area it had covered during the May survey, whereas San Onofre Kelp Bed again underwent a slight decrease.27 San Mateo Kelp Bed remained essentially the same. The same general trends were encountered during mapping of the kelp beds by electronic positioning during 1975 and 1976 as part of the construction surveillance program for SONGS 2 &3.

ES-4194 360 330 300 270 240

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Source: Lockheed Center for Marine Research, San Onofre Nuclear Generating Station Unit 1, Environmental Teohnioal Speoifioations, Annual Operating Report, VoZ. IV, Biological Data Analysis- 1976, June 1977.

2-24 Historical accounts of changes in kelp bed canopy areas throughout southern California have shown changes in magnitude e~ual to or much ~reater than those observed during this study, often over a short period of time. 2 2.5.2.4 Intertidal community 1975 Data During four intertidal surveys in 1975, 106 species or higher taxa representing 12 major taxo-nomic groups were observed at the five intertidal stations (Fig. 2.11). 2 5 These taxa are listed in Appendix XII, Tables 1 and 2, p. 246-52 of ref. 25. A comparison of the data collected in 1975 with historical data indicates that the fauna and flora encountered are typical inhabitants of this geographical area. 2 5 Phaeophytes, rhodophytes, and mollusks consistently exhibited the greatest number of taxa throughout the year at all stations. The distribution of five taxa were found to contribute significantly to the variability among stations: the rhodophytes CoraZZina/

HaLiptyZon~ PteroaZadia/GeZidium~ Laurenaia spp.; the spermatophyte PhyZZospadix spp.; and the anthozoan AnthophZeura spp. Seventeen taxa, the majority of which were algae, were both common and abundant. The most abundant of these seventeen taxa were CoraZLina/HaLiptyLon~ UZva spp.,

and Zonaria farol:wii.

Six predominant taxa exhibited distributions that varied significantly among stations, but no patterns that interrelated these differences were obvious. These six taxa were the anemone AnthopZe~ spp.; the rhodophytes CoraZZina/HaZiptyZon~ Lithot~ aspergiZZum~ PteroaZadia/

GeZidium; and the phaeophytes Sargassum spp. and Zonaria farZowii.

1976 Data Quarterly intertidal sampling was also conducted in 1976. A taxonomic summary of these data by survey and station is presented in Table VI-1, pp. 35-38 of ref. 26.

Predominant taxa identified to at least the generic level were Sargassum spp., ~treZZa aarinata, Maaron Zividu.s~ AnthopZeura eZegantissima~ CoraZZina/HaZiptyZon~ Zonaria farZowii, and Diatyota/

Paahydiatyon. The distribution of the abundance of these organisms for each station and for each survey is presented in Table VII-11, p. 104 of ref. 27. No significant differences were found in the abundance of Diatyota/Paahydiatyon~ Maaron Zividu.s, and MitreZZa aarinata among stations.

The distribution of four taxa -CoraZZina/HaZiptyZon, Zonaria farZowii, Sargassum spp., and AnthopZeura eZegantissima -displayed statistically significant differences in abundance among stations. CoraZZina/HaZiptyZon was most abundant at station 5, Zonaria farZowii at stations 2 and 4, and Sargassum spp. was at station 3. The greatest number of A. eZegantissima was observed at stations 1, 4, and 5.

The rhodophyte CoraZZina/HaZiptyZon contributed the most to the differences among stations during both 1975 and 1976 and was also predominant both years. During both years this taxon was more abundant at the station farthest downcoast of the SONGS 1 discharge and least abundant at the two stations upcoast of the discharge. Three other predominant taxa, Sargassum spp., Zonaria farZowii, and AnthopZeura eZegantissima exhibited statistically significant differences in abundance among stations during both 1975 and 1976. Diatyota/Paahydiatyon exhibited no statisti-cally significant differences in abundance among stations during either year.

No statistically significant difference in the distribution of taxa among trophic types existed among intertidal stations during either year. During both years, the intertidal communities of all stations were dominated by primary producers (algae).

The study area is accessible to considerable human intervention in the form of organism collecting in the tide pools, clam digging, surfing, and walking through intertidal cobble beds. Because of their accessibility via public roads, the stations nearest and upcoast of the generating station receive the heaviest use; the other stations receive less use because they are accessible only via hiking trail or the beach. Overall beach use in the study area is indicated by the San Onofre Beach State Park (which includes the study area) estimates of park use for 1976, which indicate that 378,483 people used the beach in the study area. The study area is also used heavily by clam diggers collecting littleneck clams, because this area is probably one of the most extensive and productive in the state. The large excavations and overturned cobble that result from clam digging may have considerable effect on the intertidal biota by disturbing habitats and inter-fering with mating activities.

Aerial infrared survey data on three occasions in 1976 revealed possible shore impingement of the 0.6°C (1°F) elevated temperature field at the four stations nearest the generating station. The zoe (4°F) elevated field appeared to contact the shore immediately upcoast of the generating station but did not impinge on any intertidal cobble stations. Shore impingement of the elevated temperature field was not indicated in 1975.

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Ol A USCGS BENCH MhRK MIUI 8 tNfERTIOAl STATION

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.5 0 Fig. 2.11. Environmental Technical Specifications intertidal station locations and environmental surveillance zones, San Onofre Nuclear Generating Station Unit 1. Source: lockheed Center for Marine Research, San Onofre Nualear Generating Station Unit 1, Environmental TeahniaaZ Speaifiaations, Annual Operating Report, Vol. IV, BioZogiaal Data Analysis- 19?6, June 1977.

2-26 Based on a comparison of the abundance of predominant taxa among stations and the similarity of stations during the study, the intertidal communities under study did not display a great deal of temporal variation during either 1975 or 1976. Minimal differences were detected among surveys with respect to the abundance of predominant taxa. These differences did not appear related to the offline condition of the generating station which occurred during two of four surveys.

2.6 BACKGROUND

RADIOLOGICAL CHARACTERISTICS The Environmental Protection Agency 29 has reported average background radiation dose equivalents for California as 96.6 millirems per person per year. The average background for San Diego is 104.6 millirems per person per year. (This is higher than the state average because of natural radioactivity in granitic rocks in the area.* ) Of the total for California, 42.2 millirems per person per year was attributed to cosmic radiation. Of this total external gamma radiation (primarily from K-40 and the decay products of the uranium and thorium series) was estimated at 36.4 millirems per person per year. The remainder of the whole body dose is due to internal radiation (mostly H-3, C-14, K-40, Ra-225, and Ra-228 and their decay products), which was esti-mated to average 18 millirems per person per year.

2-27 REFERENCES Except as specifically noted, the documents referenced below are available in public technical libraries.

1. R. L. Bernstein, L. Breaker, and R. Whri tner, "Ca 1iforni a Current Eddy Formation:

Ship, Air, and Satellite Results," Science 195: 353-359 (1977).

2. Intersea Research Corporation, "Current Meter Observations and Statistics San Onofre Nuclear Generating Station, 5 January-22 November, 1972," January 1973.*

3. R. C. Y. Koh and E. J. List, "Report to Southern California Edison Company on Further Analysis Related to Thermal Discharges at San Onofre Nuclear Generating Station,"

Sept. 30, 1974.*

4. S. M. Adams, P. A. Cunningham, D. D. Gray, and K. D. Kumar, "A Critical Evaluation of the Nonradiological Environmental Technical Specifications, Vol. 4, San Onofre Nuclear Generating Station Unit 1," Report ORNL/NUREG/TM-72, Oak Ridge National Laboratory, Oak Ridge, Tenn., June 1977.**

5. Southern California Edison Company, "San Onofre Nuclear Generating Station Units 2 and 3, Environmental Report- Operating license Phase," Docket No. 50-361/362, 1977.*

6. Southern California Edison Company, "San Onofre Generating Station Units 2 & 3, Final Safety Analysis Repor*t," Docket No. 50-361/362, 1977.

7. J. L. Baldwin, "Climates of the United States," U.S. Department of Commerce, Environ-mental Data Service, Washington, D.C., 1973.

8. U.S. Department of Commerce, Environmental Data Service, "Local Climatological Data, Annual Summary with Comparative Data," National Climatic Center, Asheville, N.C.,

1976.

9. U.S. Department of Commerce, Environmental Data Service, "Local Climatological Data, Annual Summary with Comparative Data- San Diego, California," National Climatic Center, Asheville, N.C., 1976.

10. H. C. S. Thorn, "Tornado Probabilities," Mon. Weather Rev. October-December 1963, pp. 730-737.

11. H. L. Crutcher and R. G. Quayle, "Mariners Worldwide Climatic Guide to Tropical Storms at Sea- NAVAIR 50-1C-61," Naval Weather Service Environmental Detachment, Asheville, N.C., 1974.***

12. M. M. Orgill and G. A. Sehmel, "Frequency and Diurnal Variation of Dust Storms in Contiguous U.S.A.," Atmos. Environ. 10: 813-825 (1976).

13. G. C. Holzworth, "Mixing Heights, Wind Speeds and Potential for Urban Air Pollution Throughout the Contiguous United States," Report AP-101, U.S. Environmental Protection Agency, Research Triangle Park, N.C., 1.972.

14. U.S. Nuclear Regulatory Commission, Regulatory Guide 1.111; "Methods for Estimating Atmospheric Transport and Dispersion of Gaseous Effluents in Routine Releases from Light-Water-Cooled Reactors," U.S. NRC Office of Standards Development, Washington, D.C., 1976.**

15. J. F. Sagendorf and J. T. Goll, "Program for the Meteorological Evaluation of Routine Effluent Releases at Nuclear Power Stations (Draft)," Report NUREG-0324, XOQDOQ, U.S. NRC Office of Nuclear Reactor Regulation, Washington, D.C., 1976.**

16. U.S. Department of the Interior, "Endangered and Threatened Wildlife and Plants,"

41 F.R. 47180-47198.

2-28

17. P. A. Munz, "A Flora of Southern California," University of California Press, Berkeley, Calif., 1974.

18. W. R. Powell, ed., "Inventory of Rare and Endangered Vascular Plants of California, 11 Special Publication No. 1, Berkeley, Calif., 1974.

19. U.S. Department of the Interior, "Endangered and Threatened Species, Plants," 41 F.R. 24524-24572.

20. Attachment 1, Biological Study of the San Onofre-Santiago Transmission Line Route Extracted from the Report Environmental Data Statement San Onofre to Santiago Substation 220 kV Transmission Line by VTN Consolidated as per letter of K. P.

Baskin, Southern California Edison Company to B. J. Youngblood, U.S. Nuclear Regulatory Commission, Mar. 23, 1977.*

21. Environmental Quality Analysts, Inc., and Marine Biological Consultants, Inc.,

"Thermal Effect Study, Final Summary Report, San Onofre Nuclear Generating Station Units 2 & 3," September 1973.*

22. Lockheed Aircraft Service Co., Department of Marine Biology, "San Onofre Nuclear Generating Station Unit 1, Semiannual Operating Report, Environmental Technical Specifications, November 1974-July 1975."*

23. Lockheed Marine Biological Laboratory, "San Onofre Nuclear Generating Station Unit 1, Semiannual Operating Report, Environmental Technical Specifications, January-June 1975."*

24. Lockheed Marine Biological Laboratory, "San Onofre Nuclear Generating Station Unit 1, Semiannual Operating Report, Environmental Technical Specifications, July-December 1975."*

25. Lockheed Marine Biological Laboratory, "San Onofre Nuclear Generating Station Unit 1, Annual Analysis Report; Environmental Technical Specifications, January-December 1975, 11 1976.*

26. Lockheed Center for Marine Research, "San Onofre Nuclear Generating Station Unit 1, Environmental Technical Specifications, Annual Operating Report, Vol. II, Biological Data Summary - 1976, 11 March 1977. *

27. Lockheed Center for Marine Research, "San Onofre Nuclear Generating Station Unit 1, Environmental Technical Specifications, Annual Operating Report, Vol. IV; Biological Data Analysis - 1976," June 1977.*

28. California Coastal Commission Marine Review Committee, "Annual Report to the California Coastal Commission, August 1976August 1977, Summary of Estimated Effects on Marine Life of Unit 1 San Onofre Nuclear Generating Station," MRC Document 7709 no. 1, September 1977.*

29. D. T. Oakley, "Natural Radiation Exposure in the United States," Report ORP/SID 72-1, Office of Radiation Programs, Environmental Protection Agency, Washington, D.C.,

June 1972.

• Available per inspection and copying for a fee in the NRC Public .Document Room, 1717 H St. N.W., Washington D.C. 20555.

• • Available from NRC/GPO Sales Program, Washington, DC 20555 and the National Technical Information Service, Spingfield, VA 22161.

• • • Available from NTIS only.

3. THE PLANT

3. l RESUME The domestic water supply and service water system will now be supplied by the Tri-Cities Municipal Water District rather than obtained from flash boilers as previously contemplated (Sect. 3.2. 1). The major design changes that have environmental effects relate to the heat dissipation system. The revised heat dissipation system is described in Sect. 3.2.2. These revisions and others result in a change in the chemical effluents and are discussed in Sect.

3.2.4. 1. Changes in the radioactive waste treatment systems are described in Sect. 3.2.3.

Significant changes have occurred in the transmission lines; the revised transmission line system is described in Sect. 3.2.5.

3.2 DESIGN AND OTHER SIGNIFICANT CHANGES 3.2. 1 Plant water use Both fresh water and seawater will be used at SONGS 2 & 3. About 0.05 m3 /sec (1.65 cfs) of fresh water will be supplied by the Tri-Cities Municipal Water District for the domestic water supply system and service water system. The major portion of the domestic water requirement will be used for landscaping and associated functions. The service water system will provide water to miscellaneous systems and equipment throughout the operating areas. A large amount of this fresh water will be used at the intake screenwell area for cooling of pump bearings.

The source of seawater is the Pacific Ocean. Cooling water will be withdrawn from the ocean at a rate of 53.5 m3 /sec (1887 cfs). This water will be used for turbine plant cooling, component cooling, main condenser cooling, and for the fish handling system. The turbine plant and component cooling water systems are closed-cycle systems. Heat is transferred to the seawater by heat exchangers.

Further details of the plant water use are given in Fig. 3. 1.

3.2.2 Heat dissipation system Plant waste heat will be dissipated by means of a separate once-through cooling system for each unit. About 53.5 m3 /sec (1887 cfs) of seawater per unit is withdrawn from the ocean through a velocity-cap-type submerged intake, located about 975 m (3200 ft) from shore. The velocity cap is circular with a 15-m (50-ft) diameter. The lower lip of the cap is 2.7 m (9 ft) from the ocean bottom, and the interior separation of the upper and lower lip is 2.1 m (7ft). The intake velocity will be about 0.5 m/sec (1.7 fps). The total water depth at the intake region is 9.1 m (30ft). The intake structure is illustrated in Fig. 3.2.

Each unit has a Seismic Category 1 auxiliary intake structure to provide emergency core cooling.

These structures are located approximately 32 m (100 ft) shoreward of the primary intake structures. Each structure has a 3.66 m (4-ft) ID vertical riser that extends upward from the intake conduit and is equipped with a velocity cap that is similar in design to that of the primary system. During normal operating conditions, water is estimated to enter the structure at 0.38 m/sec (1.3 fps). Details of these structures are shown in Fig. 3.2.

After passing through the intake, the cooling water for each unit will travel to the plant via a 5.5-m (18-ft) ID pipe that becomes a 4.9-m (16-ft) square box conduit at the shoreline.

Here, water is delivered to a forebay leading to the intake structure screenwell. The water will then pass through a series of baffles as the channel widens to about 12.5 m (41 ft). At this point, the channel narrows and the main volume of water turns through an angle of 70°,

where it passes through six adjacent sets of traveling bars and screens. A small volume of water does not turn towards these bars and screens but continues along the narrowing channel and enters the fish collection chamber.

Each screenwell is outfitted with traveling bar racks behind which are 1-cm (3/8-in.) mesh travel-ing screens. In the forebay behind the traveling screens are four 1/4-capacity vertical, wet pit, 3-1

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-[ SYSTEM COMMON,

.,. SYSTEM COMMON, NOTE (1) NOTE (2)

INTAKE STRUCTURE SUMP 1371lOOGPD UNIT 3 MISCI USERS AND SEA I 7.000GPO SANITARY WASTE SYST£M COMMON, 1-WATER PUMPS NOTE (2) 277,000GPD 277,000GPD 223,600GPO ~42.,000GPD 3!i.OOOGPD

-,

STORM DRAINS SEA WATER PUMPS MISC. USERS:

BEARING FLUSH FIREWATER UTIUTY STATIONS WATER PUMP SEALS 242 OOOGPO 69600GPO TO UNIT l UNIT 3 7,000 GPO CONDENSER I

TURBINE PLANT MAKEUP DEMNERAL-22.0MGPO 12 400GPD COOLING WATER r--- ISER SYSTEM I SYSTEM 69,600GPD COMMON, NOTE (I )

72,000GPD VENT LOSS l !i,IIOOGPD NUCLEAR SERVICES 3!i,OOOGPD COMPONENT MAKEUP DEMINEfiAL.

24.5MGPD AND RADWASTE .JIL

~ COOLIMi WATER ISER SYSTEM SUMPS SYSTEMS COMMON, SYSTEM COMMON, NOTE (I) NOTE (I) l2MGPD VENT 72 OOOGPD LOSS WASTE TO 1,172 MGPD, TRUCK FISH HANDLING MAIN CONDENSER I STEAM SYSTEM GENERATORS 6,800GPD

, 86,400GPD 24.!1MGPD SLOWDOWN BUILDING SUMPS 85800 GPO PROCESSING TURBINE PLANT 22.0MGPO CONTROl. NilS AND SYSTEM SUMP DIESEL GEN. BLDG.

1.2MGPD 600GPD UNIT 3 3!i,OOOGPD BLDG. SUMP BLOWOOWN OIL REMOVAL' IT~

1.2 PROCESSI¥l SYSTEM COMMON, UNIU ~~

FISH HANDLING SYSTEM SUMP 3!1JG~ NOTE II)

SYSTEM 600GPD I 70,000GPO 72 OODGPD TRUCK 2.4MGPD 3.30DGPD .................

70000GPD I UNIT 2&3

~,218MGPO t TO UNIT 3 FISH HANDLING UNIT 2 COMMON DISCHARGE DISCHARGE LINE TO OCEAN LINE lO OCEAN NOTE{4)

Notes:(l)Common system. serves Units 2&3 (4)Unit 3 flows are same as Unit 2 (2)Common system, serves Units 2&3, AWS bldg (5)To convert GPO to 1iters per day, (3)MGPD, millions of gallons per day multiply by 3.7854 Fig. 3.1. Plant water use. Source: ER. Fig. 3.3-1.

3-3 ES*4110B AUXILIARY INLET STRUCTURE INTAKE STRUCTURE TYPICAL DIFFUSER PORT BLOCK DIFFUSERS ARE MOUNTED ALTERNATELY 20° EACii SIDE OF CENTERLINE OF CONDUIT Fig. 3.2. Design details of the velocity-cap intake structure and typical diffuser port.

Source: ER, Fig. 3.4-2.

{To convert ft tom, multiply by 0.3048.)

circulating water pumps. These pumps provide 50.3 m3fsec (1775 cfs) of water to a two-shelled condenser. This water experiences an ll.l°C (20°F) temperature rise across the condenser. About 2.1 m3 /sec (75.8 cfs) of water is withdrawn prior to reaching the condenser for use in the turbine plant cooling loop and the fish return systems. Details of the intake screenwell structure are shown in Fig. 3.3.

After passing through the condenser, the heated water will pass through the Amertap strainer, which collects the Amertap balls used for cleaning the condenser tubes. Subsequently, this heated water is supplemented by 1.1 m3 /sec {37.9 cfs) of water from the turbine plant cooling system and screenwashing. The water then passes into a seal well weir chamber designed to ensure proper siphon flow through the condenser. This chamber terminates into* a 4.9-m (16-ft) square box conduit to which 1.1 m3 /sec (37.9 cfs) of nuclear component cooling water flow is added. At the shoreline, this square conduit joins a 5.5-m (18-ft) IO buried pipe that conveys the heated water to the diffuser.

The diffuser for each unit is about 762 m (2500 ft) in length, and each diffuser has 63 ports spaced 12m (40ft) apart. Each port extends 1.8 m (6ft) from the bottom and is oriented from the horizontal at an angle of 20°. The ports are alternately aligned at angles of +/-25° from the offshore direction. The port throat diameter will vary from 56 em (22 in.) to 61 em (24 in.),

and the maximum discharge velocity from any port will be 4 m/sec (13 fps). The Unit 3 diffuser begins about 1150 m (3800 ft) from shore, and the Unit 2 diffuser begins about 1950 m (6400 ft) from shore. The Unit 2 diffuser is located about 220 m (722 ft) upcoast of the Unit 3 diffuser.

ES-4111 Circulating Water Pump (Typ.) .

Recirculation Gate

-ro I

Traveling Scrcen-ro

~

wI

.

• <~>. i.:*id .:. ~.4: -:.*~*-: *.:*

,o- Intake

""'

• -<.0

, I I --

Traveling Bar Racks fish Removal Area 78'-7 11 25'-11 11 Fig. 3.3. Design details of the intake screenwell area. Source: ER, Fig. 3.4-3.

(To convert ft tom, multiply to 0.3048; to convert.in. to mm, multiply by 25.4,)

3-5 To control biofouling, the circulating water system is designed to allow heated water to reach all portions of the system. To accomplish this, an intake/discharge crossover gate allows seawater to be drawn into the plant through the diffusers and the heated water to be discharged via the intake. To achieve the temperature required to control biofouling, each unit has a recirculation and crossover gate. This system allows the cooling water requirement to be reduced by recircul-ating a portion of the heated water through the condenser. The temperature rise will be propor-tional to the degree of recirculation. During diffuser heat treatment, the circulating water follows the normal path but with recirculation. Intake heat treatment is performed by opening the intake/discharge crossover gate to reverse the flow direction, as well as to allow recirculation.

Circulating water flov1 paths for the various plant operations are shown in Fig. 3.4.

A fish return system minimizes the mortality of fish that have reached the intake screenwell area.

The louvered bar racks are designed and oriented in such a way that the fish are encouraged to follow a narrowing channel terminating at a fish holding chamber. This chamber is equipped with a vertical elevator basket that periodically rises slowly from the bottom to capture the fish in the chamber. Subsequently, tne fish are flushed from the basket with seawater into a 1.2-m (48-in.) diameter pipe, which returns them to the ocean via an offshore submarine outfall.

3.2.3 Radioactive waste systems During the operation of SONGS 2 & 3 radioactive material will be produced by fission and by neutron activation of corrosion products in the reactor coolant system. From the radioactive material produced, small amounts of gaseous and liquid radioactive wastes will enter the waste streams. These streams will be processed and monitored within the station to minimize the quantity of radioactive nuclides ultimately released to the atmosphere and to the Pacific Ocean.

The waste handling and treatment systems to be installed at the station are discussed in the applicant's Final Safety Analysis Report (FSAR) and in the ER. Information submitted to meet the requirements of Appendix I to 10 CFR Part 50 is contained in both the FSAR and ER. In these documents, the applicant has presented an analysis of the radioactive waste treatment systems and has estimated the annual release of radioactive waste materials in liquid and gaseous effluents resulting from normal operation.

In the following paragraphs, the radioactive waste treatment systems are described, and an analysis is given based on the staff's model of the applicant's proposed radioactive waste treatment systems. The staff's model has been developed from a review of available data from operating nuclear power plants, adjusted to apply over a 30-year operating life. The reactor coolant activities and flow rates used in the staff's analyses are based on experience and data from operating reactors. As a result, the parameters used in the model and the calculated re-leases vary somewhat from those used in the applicant's evaluation.

On April 30, 1975, the NRC announced its decision in the rulemaking proceeding (RM 50-2) con-cerning numerical guides for design objectives and limiting conditions for operation to meet the criterion "as low as is reasonably achievable" for radioactive material in light-water-cooled nuclear power reactor effluents. This decision is implemented in the form of Appendix I to 10 CFR 50.1 To effectively implement the requirements of Appendix I, the NRC staff has reassessed the parameters and mathematical models used in calculating releases of radioactive materials in liquid and gaseous effluents in order to comply with the Commission's guidance.

This guidance directed that current operating data, applicable to proposed radwaste treatment and effluent control systems for a facility, be considered in the assessment of the input parameters.

These parameters, models, and their bases are given in NUREG-0017. 2 By letter of February 25, 1976, the applicant was requested to submit additional information concerning the means proposed to keep levels of radioactive materials in effluents from SONGS 2 & 3 to unrestricted areas "as low as is reasonably achievable," in conformance with the re-quirements of Appendix I to 10 CFR 50. The applicant was also given the option of providing either a detailed cost benefit analysis or demonstrating conformance to the guidelines given in the September 4, 1975, Annex to Appendix I. The applicant chose to perform the cost-benefit analysis required by Sect. II.D of Appendix I to 10 CFR Part 50.

The staff performed an independent evaluation of the applicant's proposed methods to meet the requirements of Appendix I. The evaluation consisted of (1) a review of the information provided by the applicant, (2) a review of the applicant's proposed radwaste treatment and effluent con-trol systems, (3) the calculation of new source terms based on models and parameters as given in NUREG-0017, 2 and (4) a cost-benefit analysis to determine the cost-effectiveness of proposed augments to the liquid and gaseous radwaste treatment systems.

ES-4078 CIRCULATING CIRCULATING CIRCULATING WATER PUMPS WATER PUMPS WATER PUMPS

• • --~!

I

~~~-~.1

,-

[__ __ _

wI a-KEY

, , . GATE CLOSED

iii ~~~ ~~~~lAllY OPEN!;

+ FLOW PATTERN INTAKE CONDUIT DISCHARGE CONDUIT NORMAL OPERATION HEAT TREATMENT HEAT TREATMENT Fig. 3.4. Circulating water flow paths for normal plant operation, intake heat treatment, and discharge heat treatment. Source: Fig. 2-9 of Thermal Effects Study Final Summary Repo~t3 San Onof~e Gene~ting Station Units 2 & 3 Volume 1; Environmental Quality Analysts and Marine Biological Consultants, September 1973.

3-7 On the basis of the following evaluation, the staff concludes that the liquid and gaseous radio-active waste treatment systems for SONGS 2 & 3 are capable of maintaining releases of radioactive materials in liquid and gaseous effluents to "as low as is reasonably achievable" levels in accordance with 10 CFR Part 50.34a, and meet the requirements of Sect. II.A, II.B, II.C, and Il.D of Appendix I to 10 CFR Part 50. 1 3.2.3. l Liquid radioactive waste treatment system The liquid radioactive waste treatment system, which is shared by Units 2 and 3, will consist of equipment and instrumentation necessary to collect, process, monitor, recycle, or dispose of potentially radioactive liquid wastes generated during normal operation including anticipated operational occurrences. Liquid radioactive waste will be processed on a batch basis to permit optimum control of releases. Prior to release, samples will be analyzed to determine the types and amounts of radioactivity present; on the basis of the results, the waste will be recycled for reuse in the plant, retained for further processing, or discharged under controlled conditions to the Pacific Ocean via the circulating water outfall. A radiation monitor will automatically terminate liquid waste discharge if radiation measurements exceed a predetermined level in the discharge line. A schematic diagram of the liquid radioactive waste treatment system is given in Fig. 3.5.

The liquid radioactive waste treatment system will consist* of the coolant radwaste (boron recovery) system, the miscellaneous (aerated) waste system, and the chemical waste system.

The plant does not have a separate laundry and hot shower system; this function is combined in the aerated waste system.

The coolant radwaste system is shared by Units 2 and 3 and will process shim bleed and equipment drain wastes collected inside the reactor containment. The principal system components will be a gas stripper, four primary coolant radwaste holdup tanks, two preholdup demineralizers, two intermediate holdup tanks, two evaporator feed demineralizers, one evaporator, two polishing demineralizers, and two makeup storage tanks.

The miscellaneous liquid waste system will process non-reactor-grade liquid wastes, including floor drains, equipment drains containing non-reactor-grade water, and building sumps. After treatment these wastes will be transferred to the waste monitor tanks for reuse in the plant or for discharge to the Pacific Ocean via the circulating water outfall. The principal miscella-neous liquid waste system components will consist of one collection tank, four demineralizers, an optional evaporator, and two recycle monitor tanks. The liquid process stream may be routed through the optional evaporator if additional treatment is indicated.

The chemical waste system will process non-reactor-grade liquid wastes with high chemical con-tent, including demineralizer regenerant solutions and laboratory drains. After treatment, these wastes will be transferred to the waste monitor tanks for reuse in the plant or for discharge to the Pacific Ocean via the circulating water outfall. The principal chemical waste system components will consist of one collection tank, an evaporator, two demineralizers, and two recycle monitor tanks.

The steam generator blowdown will be processed continually through a flash tank, with the liquid being cooled in a heat exchanger before passing through a filter and two demineralizers in series. The processed liquid is piped to the main condenser. The flashed steam is routed to the third point heater. The processed water will be reused in the plant, but may be discharged to the circulating water outfall under certain circumstances provided that radioactivity concentrations are below predetermined values.

Coolant radwaste system Primary coolant will be withdrawn from the reactor coolant system at about 151 liters/min (40 gpm) and processed through the chemical and volume control system (CVCS). The letdown stream will be cooled, reduced in pressure, filtered, and processed through one of two mixed bed demineralizers. At the end of core cycle life this letdown stream will be passed through an anion demineralizer to remove boron when the feed and bleed mode of operation is not practicable.

Radionuclide removal by the CVCS was evaluated by assuming 151-liters/min (40-gpm) letdown flow at primary coolant activity (PCA) through one mixed bed demineralizer (Li 3 B0 3 form), and a continuous 30-liters/min (8-gpm) flow through one mixed bed demineralizer (H 3 B03 form) for lithium control. The CVSC will be used to control the primary coolant boron concentration by diverting a side stream of about 3,785 liters/day (1000 gpd) per reactor of the treated letdown stream to the shared coolant radwaste system as shim bleed.

The shim bleed from the letdown stream will be processed through two mixed bed demineralizers (Li 3 B0 3 form) in series, through a gas stripper, and routed to one of four 227,124-liter (60,000-gal) radwaste primary holdup tanks. Valve leakoffs and equipment drain wastes in the

ES-4301 Secondary Loop Turbine Condenser Flashed BLOWOOWN SYSTEM Steam From Unlt3 COOLANT RAO WASTE SYSTEM

~

low Actlvtty Discharges Only COOLANT AND BORIC ACID RECYCLE SUBSYSTEM Unit2 Primary Coolant wI Makeup Storage Tank I,. I co Unit3 Bottoms To Boric Acid Storage Tanke MISCELLANEOUS LIQUID WASTE SYSTEM !UNIT NOS. 2 AND 3}

Floor Drains Miscellaneous Liquids Miscellaneous Liquid Waste Collection Tank I .. , Filter I ., I I Regenarent Solutions, Chemical Waste.

laboratory Wastes Filter Collection Tank Pacific Ocean Fig. 3.5. SONGS 2 &3 radioactive liquid waste treatment systems.

3-9 reactor containment, as well as excess spent fuel pit water, will be processed as above and will be transferred to the radwaste primary holdup tanks where it will be combined with the shim bleed. These streams will form the inputs to the coolant radwaste system and will be processed batchwise*from the four radwaste primary holdup tanks. The combined streams are next processed batchwise through two mixed bed demineralizers (H 3 B0 3 form) and routed to one of two 454,248-liter (120,000-gal) radwaste secondary holdup tanks. From the radwaste secondary holdup tanks, the processed liquid can be recycled to the reactor coolant makeup tank, can be discharged to the circulating water outfall if radioactivity concentrations are within estab-lished limits, or can be processed further through a boric acid evaporator and mixed bed deborating and polishing demineralizers.

In the latter mode of operation, the boric acid recovered in the evaporator bottoms can be re-cycled. Because the system is capable of continuously operating in the boron recovery mode with inputs from both Units 2 and 3, and because the staff's source term calculation assumes a failed fuel rate of 0. 12%, the staff's evaluation was made on the basis of the system being operated in the boron recycle mode. The staff calculated the collection time in a radwaste secondary holdup tank to be about 38 days, based on a combined input flow rate of 9463 liters/day (2500 gpd) from Units 2 and 3. Based on an assumption of 80% tank capacity and process flow rate of 189 liter/min (50 gpm), the staff calculated the decay time during processing to be about 1.3 days. If the radioactivity is below predetermined value, the treated stream may be pumped to the waste monitor release tank and discharged. The staff assumed that 10% of the treated stream will be discharged to the circulating water outfall and to the Pacific Ocean because of anticipated operational occurrences and for tritium inventory control. The decon-tamination factors listed in Table 3.1 were applied for radionuclide removal in the coolant radwaste system. The concentrated bottoms from the evaporator and the spent resins from the demineralizers will be transferred to the radioactive solid waste system for disposal by burial offsite.

Miscellaneous liquid waste system The miscellaneous liquid waste system of the liquid radioactive waste treatment system is designed to collect ana treat non-reactor-grade water for reuse within the plant from auxiliary building sumps, the containment sumps, and other miscellaneous sources. These wastes will be collected in a shared 22,712-liters (6000-gal) waste holdup tank at an input flow rate of about 5300 liters/day (1400 gpd) per unit. The staff calculated the collection time to be about 1.7 days. The wastes will be processed through four series connected mixed bed demineralizers and collected in a 94,635-liter (25,000-gal) test tank. The staff calculated the decay time during processing to be about 0.03 days. If necessary, the stream can be diverted to the evaporator in the chemical waste system for additional treatment.

The decontamination factors listed in Table 3. l were applied for radionuclide removal in the miscellaneous liquid waste system of the liquid waste treatment system. The contents of the treated stream will be sampled periodically, recycled for further treatment, recycled for in-plant use, or discharged. The staff assumed that 100% of the treated stream will be released to the Pacific Ocean.

Evaporator bottoms and spent resins will be transferred to the radioactive solid waste system for disposal by burial offsite.

Chemical waste system The chemical waste system of the liquid radioactive waste treatment system is designed to collect and treat non-reactor-grade liquid wastes from laboratory drains and from the regener-ation of demineralizers. These wastes will be collected in a shared 94,635-liter (25,000-gal) chemical waste tank and sampled and analyzed. The wastes will be treated through the chemical waste system evaporator and two series connected mixed bed demineralizers prior to entering the waste monitor tanks. The staff calculated the collection time to be about 25 days, based on an input flow of about 1514 liters/day {400 gpd) per unit, and a decay time during processing of about 0. l day.

Turbine building drain The turbine building drains will be released through a radiation monitor to the Pacific Ocean via the circulating water outfall without treatment. The monitor will automatically terminate liquid discharge if radioactivity exceeds a predetermined level. The staff assumed a release of 27,255 liters/day (7200 gpd) per reactor and that the wastes will be discharged without processing.

3-10 Table 3.1. Principal parameters and conditions used in calculating releases of radioactive material in liquid and gaseous effluents from SONGS 2 & 3 Reactor power level, MWt 3600 Plant capacity factor 0.80 Failed fuel, percent 0.12" Primary system:

Mass of coolant, lb 5.6 X 105 Letdown rate, gpm 40 Shim bleed rate, gpd 1 X 103 Leakage to secondary system, lb/day 100 Leakage to containment building b Leakage to auxiliary building, lb/day 160 Frequency of degassing for cold 2 shutdowns, per year Secondary system Steam flow rate, lb/hr 1.5 X 107 Mass of liquid steam generator, lb 1.7 X 105 Mass of steam/steam generator, lb 1.2 X 104 Secondary coolant mass, lb 2.2 X 106 Rate of steam leakage to turbine 1.7 X 103 building, lb/hr Containment building volume, ft 3 2 X 106 Annual frequency of containment purges, shutdown 4 Containment low volume purge rate (cfm) 2000 Iodine partition factors, gas/liquid Leakage to auxiliary building 0.0075 Leakage to turbine building 1.0 Main condenser/air ejector, volatile species 0.15 Liquid radwaste system decontamination factors (OF)

Coolant radwaste Miscellaneous Chemical*

system (CRS) liquid-waste system waste system 1 X 105 1 X 103 1 X 104 Cs, Rb 2 X 105 2 X 10 1 1 X 105 Others 1 X 106 1 X 103 1 X 105 All nuclides Iodine except iodine Radwaste evaporator OF 104 103 Coolant radwaste system 103 102 evaporator OF Anions Cs, Rb Other nuclides Boron recycle feed demineralizer 10 2 10 OF,H3B03 Primary coolant letdown demineralizer 10 2 10 OF, Li 3 B0 3 Evaporator condensate polishing 10 10 10 demineralizer, H+oH-Mixed*bed radwaste demineralizer 102 (10) 2(10) 102 (10)

Steam generator blowdown demineralizer 102 (10) 10(10) 102 (10)

Containment building internal 10 recirculation system charcoal filter OF, iodine removal Main condenser air*removal system 10 charcoal bed OF, iodine removal 8

This value is constant and corresponds to 0.12% of the operating power fission product source term as given in NUREG*0017 (April 1976).

bone percent per day of the primary coolant noble gas inventory and 0.001%

per day of the primary coolant iodine inventory.

(To convert lb to kg, multiply by 0.4536; to convert gals to liters, multiply by 3.7854; to convert ft 3 to m3, multiply by 0.0283.)

3-11 Steam generator blowdown The steam generator blowdown system for Units 2 and 3 will continuously process steam generator blowdown at an average flow rate of 325,545 liters/day (86,000 gpd) per reactor (design flow rate is 1136 liters/min (300 gpm)). The blowdown from the two steam generators for each unit will be directed to a common flash tank. The liquid will be cooled, filtered, and treated through two series connected demineralizers before being returned to the main condenser. The flashed steam will be condensed in the main condenser hotwell. The staff did not consider any direct releases from this system to the environment.

Liquid waste summary Based on the staff's evaluation of the radioactive liquid waste treatment systems and the parameters listed in Table 3. l, the staff calculated the release of radioactive materials in liquid waste effluent to be about l. l Ci per year per reactor, excluding tritium and dissolved gases. The staff estimates that about 300 Ci per year per reactor of tritium will be released to the Pacific Ocean. In comparison, the applicant estimated a release of radioactive material in liquid effluent, exclusive of tritium, to be about 0.67 Ci per year per reactor and a tritium release of 710 Ci per year per reactor. The differences between the staff's values and those of the applicant lie principally in assumptions as to the parameters used for each radwaste system component and the distribution of tritium between gaseous and liquid releases.

The staff's calculations of the radionuclides expected to be released annually from SONGS 2 &

3 are given in Table 3.2.

On the basis of the calculated releases of radioactive materials in liquid effluents given in Table 3.2, the staff calculated the annual dose or dose commitment to the total body or to any organ of an individual in an unrestricted area, as shown in Table 5.3, to be less than 3 millirem per reactor and 10 millirem per reactor, respectively, in conformance with Sect. II.A of Appendix I to 10 CFR Part 50.

Cost-benefit analysis of liquid radwaste system augments The staff evaluated potential liquid radwaste system augments based on a study of the appli-cant's system designs, the population dose information provided in Table 5.3 of this statement, a value of $1000 per total body man-rem and $1000 per man-thyroid-rem for reductions in dose by the application of augments, and the methodology presented in Regulatory Guide 1.110. 3 The principal parameters used in this cost-benefit analysis are: (1) labor cost correction factor, FPC Region VIII, 1.2 (Regulatory Guide 1. 1103 ); (2) indirect cost factor, 1.75 (Regula-tory Guide 1. 110 3 ); (3) cost of money, 15%; and (4) capital recovery factor, 0.0806 (Regulatory Guide 1. 1103).

The calculated total body and thyroid doses from liquid releases to the projected population within a 80 km (50-mile) radius of the station, when multiplied by $1000 per total body man-rem and $1000 per man-thyroid-rem, resulted in cost-assessment values of $170 per year per unit and $140 per year per unit respectively. Potential radwaste system augments were selected from the list given in Regulatory Guide l. 110. 3 The most effective augment was the optional use of an existing 0.189 liters/min (50-gpm) evaporator in the miscellaneous liquid waste system; however, the calculated total annualized cost of $80,000 for operation and maintenance of the augment exceeded the cost-assessment values of $170 per unit for the total body man-rem dose and $140 per unit for the man-thyroid-rem dose. The staff concludes, therefore, that there are no cost-effective augments to reduce the cumulative population dose at a favorable cost-benefit ratio, and that the proposed liquid waste management system meets the requirements of Sect. II.D of Appendix I to 10 CFR Part 50.

3.2.3.2 Gaseous radioactive waste treatment system The gaseous radioactive waste treatement and building ventilation exhaust systems will be designed to collect, store, process, monitor, recycle, and/or discharge potentially radioactive gaseous wastes that will be generated during normal operation including anticipated operational occurrences. The system will consist of equipment and instrumentation necessary to reduce releases of radioactive gases and particulates to the environment.

The principal source of radioactive gaseous wastes are the gaseous waste processing system, condenser vacuum pump, and ventilation exhausts from the auxiliary, radwaste, fuel handling, containment, and turbine buildings. The principal system for treating gaseous wastes stripped from the primary coolant will be the gaseous waste processing system (GWPS). The GWPS will be a once-through nitrogen system containing a surge tank, two compressors, and six pressurized storage tanks. The off-gas from the main condenser air ejector will be processed through HEPA

3-12 Table 3.2. Calculated relell$8s of radioactive materials in liquid effluents from SONGS 2 & 3 Curies per year Nuclide per unit Corrosion and activation products Cr-51 5.6(-4)

Mn*54 9(-5)

Fe-55 4.9(-4)

Fe-59 3(-4)

Co-58 4.8(-3)

Co-60 6.1(-4)

Np-239 2.5(-5)

Fission products Br-83 7(-5)

Ab-86 1.1(-3)

Ab*BB 1.4(-2)

Sr-89 1(-4)

Sr-91 4(-5)

Y-91m 3(-5)

Y-91 2(-5)

Zr*95 2(-5)

Nb-95 1(-5)

Mo-~ 1.9(-21 Tc*99m 1.5(-21 Ru-103 1(-5)

Ah*103m 1(-51 Te-127m 8(-5)

Te-127 1.1(-4)

Te*129m 4.1(-4)

Te-129 2.8(-41 1*130 1.9(-4)

Te-131m 4(-41 Te-131 7(-51 1-131 8.1(-2)

Te-132 6.2(-3) 1-132 7.8(-31 1*133 5.3(-2) 1-134 2.3(-4)

Cs-134 3.5(-1) 1*135 9.5(-3)

Cs-136 1.7(-1)

Cs*137 2.5(-1)

Ba*137m 1.6(-1)

Ba-140 6(-5)

La-140 4(-5)

Ce-141 2(-5)

Pr-143 1(-5)

All others 5(-5)

Total, except H-3 1.1 H-3 300 filters and charcoal absorbers prior to release to the environment. The containment building atmosphere will be recirculated* through HEPA filters and charcoal absorbers prior to release to the environment. Ventilation exhaust air from the auxiliary building and the fuel handling area will not be processed prior to re'lease to the environment. The turbine building ventilation exhaust air will be released to the environment without treatment. The gaseous waste and

• ventilation treatment systems are shown schematically in Fig. 3.6.

Gaseous waste processing system (GWPS)

The GWPS will be designed to collect and process gases stripped from the primary coolant in the eves, coolant radwaste system, and miscellaneous tank cover gases. The GWPS is shared between Units 2 and 3. The GWPS will contain an inventory of nitrogen and hydrogen which will act as a carrier gas to transport radioactive gases removed from the primary coolant. Hydrogen and nitrogen cover gases from the volume control and reactor coolant drain tanks, and gases stripped in the coolant radwaste system degasifier will be collected, compressed, and stored in one of six pressurized storage tanks. The storage tanks will collect and store gases to allow short-lived radionuclide decay. After holdup, the gases will be discharged to the environment.

3-13 ES-4300 UNIT N0.2 UNIT N0.3 VENT VENT

/CONTAINMENT)

\PURGE ONLY (No Treatment)

Containment Building Unit No.2 Condenser Offgas System r-----------------------~.------Unh3 Auxiliary Building Ventilation Exhaust ----------------------~-r.------Unh3 Fuel Building Ventilation Exhaust - - - - - - - - - - - - - - - - - - *....- - - U n i t 3 Turbine Building (Open Structure, No Oucted Release}

UNIT2 - - - - - - - - - - -.....

Compressor Primary System Degassing Gas Surge And Tank Cover Gases Tank UNIT3 - - - - - - - - - - -....

Gas Decay Tanks lSI Fig. 3.6. SONGS 2 & 3 radioactive gaseous waste treatment systems.

In its evaluation, the staff assumed three tanks for storage, with two tanks held in reserve for back-to-back shutdowns, and one tank in the process of filling. Each tank has a volume of 14.16 m3 (500 ft 3 ) and operates at 300 psig. On this basis, the staff calculated a holdup time of 90 days prior to discharge of gases to the environment.

Containment ventilation system Radioactive material will be released inside the containment when primary system leakage occurs. The staff assumed on the basis of system parameters that the containment will be purged continuously during power operations at 56.6 m3 /min (2000 cfm) and in addition will have four high volume shutdown purges per year at 1132 m2 /min (40,000 cfm). Prior to purging, the containment atmosphere will be recirculated through HEPA filters and charcoal absorbers.

The staff assumed radionuclide removal during the recirculation phase to be based on a flow rate of 453m3 /min (16,000 cfm), system operation for 16 hr, a mixing efficiency*of 70%, a particulate decontamination factor of 100 for HEPA filters, and an iodine decontamination factor of 10 for charcoal absorbers. The purge exhaust gases are released without filtration or other treatment.

Ventilation releases from other buildings Radioactive materials will be released into the plant atmosphere due to leakage from equipment transporting or handling radioactive materials. Ventilation air from the auxiliary building and fuel building is not processed prior to release. The staff estimated that 72.58 kg (160 lb) of primary coolant per day will leak to the auxiliary building with an iodine partition factor of 0.0075. Small quantities of radionuclides will be released to the open turbine building, based on an estimated 771 kg/hr (1700 lb/hr) of steam leakage. The open turbine building releases will be released directly to the environment.

' .

3-14 Main condenser air ejector Off-gas from the main condenser air ejectors will contain radioactive gases as a result of primary to secondary leakage. In its evaluation, the staff assumed a primary to secondary leak rate of 45 kg/day (100 lb/day). Noble gases and iodine will be contained in steam generator leakage and released to the environment through the main condenser air ejectors in accordance with the partition factors listed in Table 3. 1. The air ejector exhaust will b.e released to the environ-ment through HEPA filters and charocal absorbers.

Gaseous waste summary Based on the staff's evaluation of the gaseous radioactive waste treatment and building ventila-tion systems and the parameters listed in Table 3. l, the staff calculated the release of radio-active materials in gaseous effluents to be about 15,000 Ci per year per unit for noble gases and 0.44 Ci per year per unit for iodine-131. In comparison, the applicant estimated a release of 8600 Ci per year per unit for noble gases and 0.096 Ci per year per unit for iodine-131. The staff estimated a release of 0.39 Ci per year per unit of particulates and 1100 Ci per year per unit of tritium. The applicant estimated a release of 0.2 Ci per year per unit of particulates and 710 Ci per year per unit of tritium.

The staff's calculated annual releases of radioactive materials in gaseous effluents from radio-nuclides expected to be released annually from SONGS 2 & 3 are given in Table 3.3. Based on the calculated releases of radioactive materials in gaseous effluents given in Table 3.3, the staff calculated the annual air in an unrestricted area, as shown in Table 5.3. to be less than 10 millirads per reactor for gamma radiation or 20 millrads per reactor for beta radiation and the annual external doses to the total body and skin of an individual in an unrestricted area to be less than 5 millirems and lS millirems, respectively, and an organ dose of less than lS milli-rems per reactor for radioiodine and radioactive particulates in conformance with Sect. II.B and II.C of Appendix I to 10 CFR 50.

Table 3.3. Calculated releases of radioac:tiva materials in gasaous effluents from SONGS 2 & 3 (Curies per year per unitl Decay Reactor Auxiliary Turbine Air Nuclide Total tanks building building building ejector Kr*83m a 2 a a a 2 Kr-85m a 24 2 a 2 28 Kr*85 430 170 5 a 3 610 Kr*87 a 5 1 a a 6 Kr-88 a 30 4 a 3 37 Kr-89 a a a a a a Xe-131m a 90 3 a 2 95 Xe*133m a 140 5 a 3 150 Xe-133 a 13,000 410 a 260 14,000 Xe*135m a a a a a a Xe-135 a 120 8 a 5 130 Xe-137 a a a a a a Xe-138 a a a a a a Total noble gases 15,000 1*131 a 0.35 0.08 0.0042 0.005 0.44 1*133 a 0.27 0.09 0.0033 0.0056 0.37 Mn*54 4.5(-3)b 2.2{-2) 1.8{-2) c c 4.4(-2)

Fe-59 1.5(-3) 7.4(-3) 6(-3) c c 1.5(-31 Co-58 1.5(-2) 7.4(-2) 6(-2) c c 1.5(-2)

Co-60 7(-3) 3.3(-2) 2.7(-2) c c 6.7(-2)

Sr-89 3.3(-4) 1.7(-3) 1.3(-3). c c 3.3(-3)

Sr-90 6(-5) 2.9(-4) 2.4(-4) c c 5.9(-4)

Cs-134 4.5(-3) 2.2(-2) 1.8(-2) c c 4.4(-2)

Cs-137 7.5(-3) 3.7(-2) 3(-2) c c 7.4(-2)

Total particulates 1.2 H*3 1,100 C-14 7 1 a a a 8 Ar-41 a 25 a a a 25 a Less than 1 Ci/year for noble gases and carbon-14, less than 10- 4 Ci/year for iodine.

bExponential notation: 4.5(-3) = 4.5 X 10-3, cLess than 1% of total for this nuclide.

3-15 Cost-benefit analysis of gaseous radwaste system augments The staff has evaluated potential gaseous radwaste system augments based on a study of the applicant's system designs, the population dose information provided in Table 5.3 of this statement, a value of $1000 per total body man-rem and $1000 per man-thyroid-rem for reductions in dose by the application of augments, and the methodology presented in Regulatory Guide 1.110. 3 The calculated total body and thyroid doses from gaseous releases to the population within a 80 km (50-mile) radius of the station, when multiplied by $1000 per total body man-rem and

$1000 per man-thyroid-rem, resulted in cost-assessment values of $21,000 per year per unit and

$46,000 per year per unit respectively. Potential radwaste system augments were selected from the list given in Regulatory Guide 1. 110. The most effective augment considered was the installation of charcoal adsorbers and HEPA filters on the containment mini-purge ventilation exhaust. The addition of this augment would result in a dose reduction of approximately 6.3 total-body man-rem and 23.8 thyroid man-rem with corresponding cost assessment values of

$6,300 and $23,800, respectively. The calculated total annualized cost of $26,500 for the augment is more than the annual cost assessment values of $6,300 and $23,800 given above. The staff concludes, therefore, that there are no cost-effective augments to reduce the cumulative population dose at a favorable cost-benefit ratio, and the proposed gaseous waste treatment and ventilation systems meet the requirements of Sect II.D of Appendix I to 10 CFR Part 50. 1 The staff concludes that the gaseous radwaste system for Units 2 and 3 is capable of maintaining releases of radioactive materials in gaseous effluents to "as low as is reasonably achievable" levels in accordance with 10 CFR Part 50.34a and meets the requirements of Appendix I to 10 CFR Part 50. The staff, therefore, concludes that the proposed system is acceptable.

3.2.3.3 Solid wastes The solid waste system will be designed to process two general types of solid wastes: "wet" solid wastes which require solidification prior to shipment, and "dry" solid wastes which require packaging and, in some cases, compaction prior to shipment to a licensed burial facil-ity. "Wet" solid wastes will consist mainly of spent filter cartridges, demineralizer resins, and evaporator bottoms which contain radioactive materials removed from liquid streams during processing. "Dry" solid wastes will consist mainly of low-activity ventilation air filters, contaminated clothing, paper, and miscellaneous items such as laboratory glassware and tools.

Spent resins from the demineralizers will be collected in the spent resin storage tank. When the resin is to be packaged, it will be sluiced to a disposable liner and dewatered before solidification. The resin beads are solidified by filling the void spaces with urea formalde-hyde and catalyst. A disposable paddle is used to agitate the mixture in the liner during the solidification process. Concentrated evaporator wastes will be collected in an evaporator bottoms tank, and then pumped batchwise through an inline mixer where they are blended with a urea formaldehyde solution. From the inline mixer, the mixture is sprayed into a disposal liner while a liquid catalyst is simultaneously sprayed into the liner by a separate nozzle to assure intimate mixing of the waste-urea formaldehyde solution and the catalyst.

On the basis of its evaluation and on recent data from operating plants, the staff has deter-mined that about 425 m3 (15,000 ft 3 ) per unit of "wet" solid wastes, containing about 1060 Ci of activity, will be shipped offsite annually. The principal radionuclides in the solid wastes will be long-lived fission and corrosion products, mainly Cs-134, Cs-137, Co-58, Co-60 and Fe-55. The applicant estimated the combined production of solid wastes from Units 2 and 3 to be 283 m3 /yr -(10,000 ft 3 / year) of solidified wastes. The applicant calculated the total curie content of these solid wastes to be about 6500 Ci. The waste containers will be stored in a shielded area, as required, to reduce contact radiation levels.

Dry solid wastes will be packaged in cardboard boxes, wooden boxes, and special DOT-approved containers. Compressible wastes such as clothing and rags will be compressed prior to packag-ing. The staff estimates the dry solid wastes to total 283 m3 (10,000 ft 3 ) per unit per year with a total activity content of less than 5 Ci. The applicant estimates the combined produc-tion of dry wastes from Units 2 and 3 to be 207 m3 /yr (7300 ft 3 /year) with a calculated total curie content of about 21 Ci.

3.2.4 Chemical, sanitary, and other waste effluents 3.2.4. 1 Chemical effluents Several design changes have had significant impacts on chemical discharges. The condenser tubes are made of titanium (ER, Table 3.4-1) rather than of a copper-nickel alloy; this should eliminate the small amounts of copper and nickel in the discharge as described previously

3-16 (FES-CP, Sect. 3.5. 1). An Amertap condenser tube cleaning system has been installed (ER; Sect. 3.4.4). In this system, sponge rubber balls are injected into the inlet piping of the condenser and are forced through the condenser tubes to scrape them clean. The balls are collected in the circulating water discharge conduit and are recirculated. This *change helps to control fouling within the circulating water system and should reduce the frequency of chlorination necessary to maintain a clean condenser system. A makeup demineralizer system will replace the flash evaporators. Chemicals originally indicated as being discharged from the flash evaporators (FES-CP, Table 3.9) will not be discharged. A cellulose sealant for the circulating water system (FES-CP, Sect. 3.5. 1) will not be used. Steam generator blowdown will be treated by filtration and demineralization and will be recycled to the condenser.

Phosphates will not be added to the blowdown (FES-CP, Sect. 3.5.2), and the discharge of salts and heavy metal ions will be eliminated.

The only significant chemical discharge results from the use of sodium hypochlorite as a biocide. The chlorination system is common to both Units 2 and 3. The two units will not be treated at the same time. Hypochlorite solution will be injected into the circulating water pump discharge headers three times each day. Each injection will last about 15 min but will not exceed 90 min per unit per day. The chlorine residual in the circulating water discharge line is monitored by amperometric titration, and the addition of hypochlorite is adjusted to maintain a 0.5-mg/liter (1.89 grains/gal) maximum concentration of free available chlorine.

The applicant estimates that this will result in a maximum free available chlorine concentra-tion of 0.1 mg/liter (0.38 grains/gal) in the immediate vicinity of the discharge.

Other chemicals may be discharged at certain times. These chemicals generally will be discharged at low concentrations and, when mixed with the circulating water flow, represent a negligible concentration at the discharge to the ocean. During restarts the discharge of condensate from the hotwell may contain concentrations of several milligrams per liter of iron and copper.

These substances will be reduced to negligible concentrations in the circulating water discharge.

The discharge from the regeneration of demineralizers will contain sodium and sulfate ions; the concentrations at the discharge to the ocean will be less than 10 mg/liter (38 grains/gal)

- negligible concentrations as compared to the natural concentrations in seawater. Small amounts of oil, not to exceed 5 mg/liter (19 grains/gal), will be discharged from the oil removal system and diluted to negligible concentration in the circulating water discharge.

Various closed-loop cooling systems will be treated with potassium chromate to inhibit corrosion.

Offsite rainfall runoff from the coastal hills and from Interstate Highway 5 (I-5) is collected by the storm runoff drainage system for the highway. Part of this drainage is discharged directly to the ocean and part is discharged with the onsite plant drainage. Onsite plant drainage is collected in catch basins and is discharged with the circulating water discharge.

Drainage collected in areas in which significant quantities of oil or grease might be present are routed through the oil removal system.

A National Pollutant Discharge Elimination System (NPDES) permit for SONGS 2 & 3 was issued on June 14, 1976, by the California Regional Water Quality Control Board, San Diego Region. The chemical effluent limitations for the combined discharges (cooling water, low-volume wastes, and storm drains) are: (1) the monthly average free available chlorine discharged shall not exceed 0.2 mg/liter (0.757 grains/gal), and the daily maximum shall not exceed 0.5 mg/liter (1.89 grains/gal); (2) discharge of free available chlorine or total residual chlorine from any plant unit for more than 2 hr in any one day or for more than one unit in the plant at any one time is prohibited; (3) the pH of the effluent shall be within the range of 6.0 to 9.0; and (4) after July 1, 1976, the discharge shall not exceed the limits given in Table 3.4. The permit prohibits the discharge of any chemicals or pollutants from the fish handling system.

The low-volume waste discharge shall not exceed the following limits: (l) a monthly average of 30 mg/liter (113.6 grains/gal) and a daily maximum of 100 mg/liter (378.6 grains/gal) for total suspended solids and (2) a monthly average of 15 mg/liter (56.78 grains/gal) and a daily maximum of 20 mg/liter (75.7 grains/gal) for oil and grease. The discharge from the storm drains shall not exceed a monthly average of 10 mg/liter (38 grains/gal) and a daily maximum of 15 mg/liter (56.78 grains/gal) for oil and grease.

3.2.4.2 Sanitary and other waste effluents Sanitary wastes from Units 2 and 3 will receive secondary level treatment in the sewage treat-ment plant located at Unit 1, which will serve all three units. The treated wastes will have the following water quality characteristics (average daily concentration): suspended solids, 30 mg/liter (113.6 grains/gal); biological oxygen demand, 30 mg/liter(413.6 grains/gal);

coliform, mean probable number of 200 per 100 ml (59 per ounce); pH, 7.0 to 8.5; and total residual chlorine, 2.0 mg/liter (7.57 grains/gal) (ER, Table 5.4-1). The treated wastes will be discharged into the Unit 1 circulating water discharge at an average rate of about 0.02 m3 /min (5 gpm). Because the circulating water discharge at Unit 1 is about 1200 m3 /min (320,000 gpm),

the sanitary waste effluents will be reduced to negligible concentrations at the point of discharge to the ocean. The sanitary waste effluents for all three units will be within the

3-17 Table 3.4. NPDES chemical effluent limitations Concentration (mg/liter) not to Constituent be exceeded more than 50% of time 10% of time Arsenic 0.01 0.02 Cadmium 0.02 0.03 Total chromium 0.005 0.01 Copper 0.2 0.3 Lead 0.1 0.2 Mercury 0.001 0.002 Nickel 0.1 0.2 Silver 0.02 0.04 Zinc 0.3 0.5 Cyanide 0.1 0.2 Phenolic compounds 0.5 1.0 Total chlorine residual 1.0 2.0 Ammonia (as N) 40 60 Total identifiable chlorinated 0.002 0.004 hydrocarbons Toxicity concentration 1.5. 2.o" "Toxicity units.

Source: ER, Appendix 12C.

(To convert mg/liter to grains/gal, multiply by 3.785.)

limitations established for Unit 1 by the California Regional Water Quality Board and the Environmental Protection Agency.

Some gaseous wastes from the operation of diesel generators and the auxiliary boiler will be discharged intermittently. Four diesel generators will serve Units 2 and 3, and it is antici-pated that these will operate for about 2 hr once per month. The estimated hourly full-load emission in kilograms (pounds) from each generator is nitrogen oxides, 84 (185); sulfur dioxide, 11 (25); particulates, 0.9 (2); hydrocarbons, 3.9 (8.5); and carbon monoxide, 9.5 (21) (ER, Sect. 3.7.4. 1). A single auxiliary boiler will be used for both Units 2 and 3. This boiler will be operated for varying time periods throughout the life of the plant (ER, Sect. 3.7.4.2).

The maximum annual use is expected to be 1250 hr at full load and 3130 hr at half load. Under these conditions, the anticipated annual emissions in tonnes (tons) are nitrogen oxides, 44 (49); sulfur dioxide, 98 (108); and particulates, 34 (38),

Trash from screens for the circulating water system for Units 2 and 3 will be taken to the Bonsall Sanitary Landfill near the city of Vista, California. This landfill is used for the disposal of trash from Unit 1.

3.2.5 Transmission lines Much of the description of the transmission lines presented in Sect. 3.7 of the FES-CP is no longer valid. Construction of SCE's transmission line from SONGS to Santiago Substation will be completed only up to Santiago Tap, thereby deleting that portion between Santiago Tap and Santiago Substation. SOG&E's line from Telega Substation to Escondido Substation has also been deleted. SCE will retrofit transmission lines from SONGS to Santiago Tap, Santiago Tap to Santiago Substation, and Santiago Tap to Black Star Canyon Tap. SOG&E will add a line from SONGS to Mission Substation. SOG&E's lines from SONGS to Telega Substation and SONGS to Encina Substation will still be constructed but the staff has received ~dditional information with regard to these lines since issuance of the FES-CP. Therefore, these lines will be further discussed in Sect. 3.2.5.2. All transmission lines for operation of SONGS Units 2 and 3 are illustrated in Figs. 3.7 and 3.8. Generally, the lines are coastal, using existing rights-of-way traversing northward from SONGS to Talega Substation, Santiago Tap, Santiago Substation, and Black Star Canyon Tap, and southeast to Encina and Mission Substations. A total of about 159.1 krn (98.9 miles) will be crossed by the transmission lines. No new rights-of-way, however, will be required.

The SCE and SOG&E transmission lines will each be supported by two steel horizontal portal structures (Fig. 3.9) for the initial 0.6 krn (0.4 mile) of right-of-way northeast of the SONGS switchyard. These structures will replace the steel lattice towers now supporting the exist-ing circuits in this area. No additional land for tower bases or access roads will be required.

3-18 ES-4080

--EXISTING TRANSMISSION LINES RETROFITTED FOR 220 kV

MILES 0 5 I

I I 0 5 KILOMETER Fig. 3.7. Schematic diagram of proposed Southern California Edison Company transmission lines for SONGS 2 &3.

3.2.5.1 SCE transmission lines A double circuit 220-kV transmission line will be constructed between SONGS and Santiago Tap, an approximate distance of 24.3 km (15.1 miles) (Fig. 3.7). About 73 steel lattice towers

{Fig. 3.10) will be required for this line, with an average span of about 335m {1100 ft) between towers. The average tower height is estimated to be 39.6 m (130ft). The new tower bases will require 2.44 ha (6.03 acres), and access road extensions are expected to require 1.32 ha (3.25 acres) of land (ER, Suppl. 2, Item 36). Additional transmission lines required by SCE that were not discussed in the FES-CP are those from SONGS to Santiago Tap, Santiago Tap to Santiago Substation, and Santiago Tap to Black Star Canyon Tap. These lines, totaling

3-19 ES-4079R TALEGA

> I

-'1 SUBSTATION

', SAN ONOFRE NUCLEAR

\ GENERATING STATION (SONGS)

- EXISTING TRANSMISSION LINES RETROFITTED FOR 230 kV

./If *.**:.;::::::::;: ("') ::'.::::*\' ENCINA *::. I SHOWN.

NEW STEEL TOWER MILES 0

X MIRAMAR 0 10 ~-NAVAL X

KILOMETERS '\.:R STATION MISSION SUBSTATION Fig. 3.8. Schematic diagram of proposed San Diego G~s and Electric Company transmission lines for SONGS 2 &3.

71.7 km (44.2 miles) will be retrofitted to operate at 220 kV. Retrofitting will involve the replacement of existing conductors with larger ones {on existing towers) and the construction of four additional towers between Santiago Tap and Black Star Canyon Tap. 4 These towers are required to provide adequate ground clearance in some spans where the wire tension will have to be reduced from its present value (ER, Sect. 3.9.1.1). This additional construction is expected to require 0.13 ha (0.33 acres) of land for new tower bases and 0.52 ha (1.3 acres) for access road extensions (ER, Suppl. 2, Item 36).

The material storage yard for SCE transmission lines will be located about 1.6 km (l mile) north of the San Onofre Nuclear Generating Station within Camp Pendleton Marine Base. The area involved will be about 2.2 ha (5.5 acres) and will not require any clearing or opening of new roads (ER, Suppl. 2, Item 30).

3-20 ES-4112 1

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Fig. 3.9. Four-circuit steel horizontal portal structures used by Southern California Edison

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Company; San Diego Gas and Electric Company will use a similar structure with five circuits.

Source: ER, Fig. 3.9-2.

(To convert ft tom, multiply by 0.3048.)

• 3.2.5.2 SDG&E transmission lines The only transmission line required by SDG&E that was not discussed in the FES-CP will run between SONGS and Mission Substation, a distance of 85 km (53 miles) (Fig. 3.8). This line will be installed by adding a 230 kV circuit to the vacant position on existing double circuit towers; 1 some of the existing towers will be replaced. A total of about 36 wooden H-frame towers (Fig. 3.11) will be constructed along a 1.6-km (1-mile.) segment east of Oceanside Airport and a 6.8-km .

(4.2-mile) segment opposite Miramar Naval Air Station to accommodate FAA regulations. 1 About 9 km (5.6 miles) of existing 138 kV wood structures south of the Oceanside Airport will be replaced by approximately 32 double circuit steel lattice towers (Fig. 3.12). The construction of the new towers for this line will not require any additional land for tower bases or access roads (ER, Suppl. 2, Item 36). Subsequent to issuance to the FES~CP, additional information was supplied by the applicant regarding the line from SONGS to Encina Substation and SONGS to Talega Substation.

The line from SONGS to Encina Substation, 40 km (25 miles), will be formed by adding a 230 kV circuit to the vacant position on existing double circuit towers.l In addition, approximately four wooden H-frame towers (Fig. 3.11) will be constructed along a 1-km (0.6 mile) segment east of Oceanside Airport to accommodate FAA regulations. To facilitate arrangement of the new conductors, a single steel tower will also be installed east of Encina.Substation. All new structures will be constructed within existing rights-of-way and will not require any additional land for tower bases or access roads (ER, Suppl. 2, Item 36). The line from SONGS to Talega Substation traverses about 11.3 km (7 miles) and will require construction of about 32 steel lattice towers (Fig. 3.12). The new tower bases will. require about 0.23 ha (0.58 acre), and access road extensions are expected to require 0.53 ha (1.3 acres) of land (ER, Suppl. 2, Item 36). Because SDG&E's original plan assumed that the Talega Substation would be constructed and in operation prior to completion of SONGS 2 &

3 (ER, Suppl. 2, Item 25), this facility was discussed in the FES-CP as if it were already in existence. Construction, however, was delayed. The proposed Talega Substation is expected to cover 2 ha (5 acres) of land; an additional 2 ha (5 acres) around the substation will also require grading.

The material storage yard for SDG&E transmission lines will be located in existing substations with the following exceptions: (1) fencing a level area of about 0.09 ha (0.23 acre) adjacent

3-21 ES-4113 Fig. 3.10. Typical steel lattice tower design used*by Southern California Edison Company.

Source: ER, Fig. 3.9-3 ..

to the existing Pulgas Substation and (2) fencing a level area of about 0.09 ha (0.23 acre) adja-cent to the Japanese Mesa Substation. No grading, clearing, or additional access roads are anticipated for this project (ER, Suppl. 2, Item 30).

3-22 4a'-e"

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3.2.6 Probable maximum flood berm 3.2.6.1 Description of structure and existing environment Subsequent to issuance of the FES-CP the applicant was required to construct an earthern berm to protect the Station form the probable maximum flood (PMF). Construction of this structure

3-23 ES-4114 1

I 18 (VARIES) 1 Gl5 (VARtEil Fig. 3.12. Typical steel lattice tower design used by San Diego Gas and Electric Company.

Source: ER, Fig. 3.9-B.(To change ft tom, multiply by 0.3048.)

and associated environmental impacts are presented by the applicant in a letter to the NRcs and in the applicant's final safety analysis report (FSAR).

3-24 The San Onofre site is located on a coastal plain at the base of the western foothills of the Santa Margarita Mountain Range. Elevation in this area rises sharply from sea level to a fairly level terrace formation 30 to 61 m (100 to 200 feet) above sea level. About 450 m' (1500 feet) inland the foothills begin, rising with moderate slopes to an elevation of about 900 m (3000 ft) above sea level. Natural plant cover in the coastal plain typically consists of coastal chaparral and grassland, while in the foothills it is composed primarily of chaparral and open woodland.

There are no perennial streams in the general vicinity of the plant site. However, ephemeral streams and water courses do exist. The major streams are San Mateo Creek, located about 3.2 km (2 miles) to the northwest and San Onofre Creek located approximately 1.6 km (1 mile) to the northwest. The drainage divide separating San Mateo and San Onofre Creeks precludes the plant site from being influenced by San Mateo Creek. The applicant's results of the probable maximum flood (PMF) analysis concluded that the San Onofre Creek Basin exhibits no flooding potential to the site (FSAR, Sect. 2.4.2.2). Topographical features of the basin would contain the maximum flood stage and thereby preclude flooding of the site by this source.

The foothill .drainage basin, however, does contribute to the hydrologic factors influencing the plant site. The basin totals 2.2 km 2 (0.86 mi 2 ). There are no gaging stations located within the*basin and, consequently, stream flow records are not available.

The entire watershed of the foothill drainage basin lies within the boundaries of the Marine Corps Base, Camp Pendleton. Elevation of the basin varies between 30 to 365 m (100 to 1200 feet) above sea level. Ground slope varies from 8 to 22%. Ground cover is moderate, consisting mainly of chaparral and grassland.

Water control structures at the foot of this basin consist of the 107- and 183-cm (42- and 72-in.) diameter concrete culverts under I-5. The capacity of these culverts is 5. l and 14.7 m3 /sec (180 and 520 ft 3 /sec), respectively. In addition to the two culverts, an earthern channel traverses the basin along the east side of I-5 diverting runoff to San Onofre Creek.

The capacity of the channel is 52.4 m3/sec (1850 ft 3/sec). .

The applicant's analysis of the flooding potential of the foothill drainage area indicated that the plant site could be subjected to flooding during the occurrence of the PMF. In order to preclude flooding of the site by this source a diversion structure routes the surface runoff from the foothill drainage area to the San Onofre Creek Basin. This PMF structure will be an earthern berm, having an isoceles trapezoid cross section that is 2.4 m (8 feet) high and 12.8 m (42 feet) wide at its base, with 2:1 side slopes. The berm will parallel I-5 and will be 2.7 km (1.68 miles) long. The existing channel which parallels the proposed berm will be widened where necessary and will vary from 7.6 to 30.5 m (25 to 100 ft) in width. The berm will cover a portion of an existing road, El Camino Real Road, requiring the construction of a new road. The relocated road will run approximately parallel to and east of the proposed PMF berm.

Relocation of the road will require about 1.4 ha (3.5 acres) of land, the berm will cover .

approximately 3.5 ha (8.6 acres), and the channel (assuming a 30 m (96 ft) width) will require about 8.3 ha (20.6 acres) for a total land area requirement of 13.2 ha (32.7 acres). The existing channel and El Camino Real Road are included in this acreage.

A terrestrial biological survey of the site was conducted on October 25 and 31, 1977. Vegetation on the site is basically a southern coastal sage scrub community, being influenced by the .

coastal marine climatic conditions. However, nearly half of the site (northern portion) has been previously disturbed as evidenced by the presence of many non-native "weedy" species including saltbush (Atri lex semibaccata), Russian thistle (Salsola kali), mustard (Brassica geniculata) tree tobacco N1cot1ana glauca), and sow thistle (Sonchus oleraceus). Nat1ve species on this area include California sagebrush (Artemesia californica), California buckwheat (Eriogonum fascilculatum), and coyote brush (Baccharis pilularis). The southern half of the site is primarily vegetated with native species of the coastal sage scrub plant community including the native species listed above. The land on which the El Camino Real Road will be relocated contains many of the same species that occur at the berm site, but with a higher degree of cover.

Fauna surveys of the site and vicinity demonstrated that the majority of the species present were birds (24 species). Red-tailed hawks (Buteo jamaicensis) were prevalent in the vicinity using wooden posts, telephone and power poles as perches and a SCE lattice transmission tower for nesting. Although only 2 species of reptiles and 2 species of mammals were observed, others are likely to occur in the vicinity.

No threatened or endangered flora or fauna were observed on the proposed PMF Berm site, the area to be cut, or on the area where the El Camino Real Road is to be relocated.s On November 14, 1977, an onsite inspection of the alignments of both the proposed berm and access road was conducted* to determine the presence or absence of surficial paleontologic

3-25 values. 5 Although the survey did not result in locating any fossils, a review of the literature revealed that all sedimentary formations in the vicinity contain fossils. No localities in the immediate area have been placed on the National Registry of Natural Landmarks.

The site was surveyed for archaeological resources on December 8, 15, and 16, 1977 (ref. 5).

The northern third of the berm was not surveyed because it had previously been studied; some portions of the berm also were not adequately surveyed because of dense vegetation. 5 In one area, eight pieces of marine shell were observed. The shells, however, were weathered and worn and gave the appearance of paleontological specimens, rather than archaeological remains. 5 An archaeological map and literature search revealed four recorded archaeological sites within 1.6 km (1 mile) of the proposed project, but none were located within the project area. 5 3.2.6.2 Impacts of PMF berm The berm will be built on top of an existing asphalt road. Consequently disruption of this area will have no significant biological impact. Widening the existing channel which parallels the proposed berm will require loss of about 8.5 ha (21 acres), and an additional 1.4 ha (3.5 acres) of habitat will be lost due to relocation of El Camino Real Road. Because these habitats do not represent unique communities, loss of this relatively small acreage should have no significant impact to biological resources of the area. To minimize the impact to raptors nesting in the vicinity the a~plicants will attempt to avoid construction activity during the period of March and April.

The construction of the PMF berm might physically destroy fossils and/or relationships between fossils, or the environmental context of original deposition, that could provide significant paleontological data. In addition, the berm and new road may cover deposits containing signifi-cant paleontological data thereby making such data unreachable. To mitigate these potential impacts the applicants will conduct a paleontological survey prior to construction and monitor the excavation as it proceeds. 5 This will allow fossils to be salvaged as they are unearthed.

Construction should be phased so that equipment could be shifted to other areas if fossils were located. Sufficient time should be allowed to uncover, record, and remove the fossils.

If excavation were initiated in areas of highest paleontological potential, equipment could be moved to areas of low potential if paleontological values were encountered. This would provide a maximum amount of construction time and a maximum amount of time for paleontologic resource recovery.

Construction of the proposed PMF berm should not cause any direct or indirect adverse impact to known archaeological resources. However, the site would have been a favorable area for aboriginal habitation; i.e., an area of relatively flat topography with abundant fresh water and food resources. 5 The probability exists that buried resources may be in the area, espe-cially where dense vegetation obscures the surface. Consequently, a trained archaeologist will monitor the construction activity and take appropriate conservation measures if necessary. 5 No significant commitments of resources will result from construction and maintenance of the PMF Berm. The possibility exists that potential archaeological or paleontological resources would be destroyed during the excavation activity required for construction of the berm.

However, if the proper mitigation measures are performed (monitoring, analysing, interpretat-ing, preserving, and reporting), then these resources would not be irretrievable.

3.2.6.3 Floodplain management The objective of Executive Order 11988, "Floodplain Management," is" . . . to avoid to the extent possible, the long- and short-term adverse impacts associated with the occupancy and modification of floodplains and to avoid direct and indirect support of floodplain development whenever there is a practicable alternative." The Construction Permit was issued and the majority of construction completed prior to issuance of the Executive Order. Thus we conclude that no practicable alternative locations exist. The following is a discussion of floodplain conditions prior to construction of the plant and alterations made to these floodplains as a result of construction of San Onofre Units 2 and 3.

The San Onofre Units 2 and 3 are bounded on the east by Interstate Highway 5, the Atchison Topeka and Santa Fe Railroad and Highway 101. Interstate Highway 5 was constructed in 1968 prior to San Onofre Units 2 and 3. As part of the I-5 construction, a drainage channel designed for 100-year storm runoff was constructed parallel to and east of I-5. This channel intercepted tributary rainfall runoff from the foothills east of I-5 and transported it to the north away from the plant. The channel then merged with San Onofre Creek which in turn flowed to the Pacific Ocean.

The plant site which is bounded on the west by the Pacific Ocean was originally on a high coastal bench approximately 100 feet above sea level. Located at this elevation, the site was protected from severe flooding events and thus was not in the 100-year ocean floodplain.

3-26 The existing drainage channel which is west of and parallel to I-5, is being enlarged to contain floods and debris. The design capacity of the channel enlargement and extension is the Probable Maximum Flood, an event which is greater than the one-percent chance flood. The improvement will not induce higher flood stages.

The San Onofre plant grade is lower than the original coastal bench. However, construction of a seawall on the* seaward side of the plant and east of the original bluff line provides protec-tion from events larger than the one percent chance flood.

The plant, including the intake structure and seawall, is not built in the 100-year floodplain and will not be flooded by any 100-year flood levels. The intake crib and intake and discharge conduits are submerged on the ocean floor. The channel improvement east of Interstate Highway 5 will not increase flood levels. Therefore, the construction and operation of the San Onofre Unit 2 and 3 Nuclear Generating Station will comply with the intent of Executive Order 11988.

3.2.7 Emergency facilities Emergency plans for San Onofre Units 2 and 3 call for an onsite Technical Support Center adjacent to the control room and an interim onsite Operational Support Center in the lunch room of the administration, warehouse, and shop building. Neither requires changes in the structural design or layout of the facility, An offsite Emergency Operations Facility is tentatively planned to be constructed on Japanese Mesa, east of Interstate 5, within the Camp Pendleton Reservation. This area was used for disposal of excavated material during construction. The structures must be designed to accommodate a minimum of 35 people.

3-27 REFERENCES

1. U.S. Nuclear Regulatory Commission, "Numerical Guides for Design Objectives and Limiting Conditions for Operation to Meet the Criterion 'As Low as Practicable' for Radioactive Material in Light-Water-Cooled Nuclear Power Reactor Effluents," May 5, 1975, and as amended Sept. 4, 1975, and Dec. 17, 1975, in Title 10, "Code of Federal Regulations," Part 50,

. Appendix I.

2. U.S. Nuclear Regulatory Commission, "Calculation of Releases of Radioactive Materials in Gaseous and Liquid Effluents from Pressurized Water Reactors (PWR-GALE Code)," NUREG-0017, April 1976.**

3. U.S. Nuclear Regulatory Commission, "Cost-Benefit Analysis for Radwaste Systems for Light-Water-Cooled Nuclear Power Reactors," in Regulatory Guide 1. 110, March 1976.**

4. letter from Ira Thierer, Southern California Edison Co., to Dr. Knox Mellon, State Historic Preservation Officer, June 2, 1978.*

5. letter from J. G. Haynes, Southern California Edis6n Co., to W. H. Regan, Jr., USNRC, undated, docketed on February 18, 1978.*

• Available for inspection and copying for a fee in the NRC Public Document Room, 1717 H St.,

N.W. Washington, DC 20555.

• • Available from the NRC/GPO Sales Programs, Washington, DC 20555 and from the National Technical Information Service, Springfield, VA 22161.

4. STATUS OF SITE PREPAQATION AND CONSTRUCTION 4.1 RESUME AND STATUS OF CONSTRUCTION As of December 1980, the construction of SONGS Unit 2 was 97% complete, and SONGS Unit 3 was 68% complete. Figure 4. l is a recent photograph of the site.

Impacts of construction have been identified in the FES-CP. The major terrestrial impact has been the excavation of about 16.4 ha (40.5 acres) of the San Onofre Bluffs, which resulted in the loss of a small amount of wildlife habitat. No rare or endangered animal species in the vicinity of the site have been or are expected to be adversely affected by construction activities.

The environmental impacts associated with changes in the routing of transmission lines subsequent to issuance of the FES-CP have been evaluated by the staff in its environmental impact appraisal regarding extension of the earliest and latest construction completion dates.

4.2 Offsite Emergency Operations Facility An offsite Emergency Operations Facility is tentatively planned to be constructed on Japanese Mesa, east of Interstate 5. within the Camp Pendleton Reservation.

This area was used for disposal of excavated material during construction. The structure must be designed to accommodate a minimum of 35 people. Construction of the Emergency Operations Facility on Japanese Mesa will not significantly disturb the* area relative to previous disturbances.

4-1

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Fig. 4. 1. Photograph of San Onofre Nuclear Generating Station taken in October 1980.

5. ENVIRONMENTAL EFFECTS OF STATION OPERATION 5.1 RESUME The major design changes that have environmental effects involve the heat dissipation system. A more thorough analysis by the staff of the thermal plume is described in Sect.

5.3. 1.2. The effects of the revised thermal-plume analysis on aquatic biota are discussed in Sect. 5.4.2. 1. Changes in the effects of chemical effluents are discussed in Sects.

5.3.2 and 5.4.2.2. A revised discussion of radiological impacts is given in Sect. 5.5.

Sect. 5.6 contains a revised assessment of the socioeconomic impacts.

5.2 IMPACTS ON LAND USE Although the transmission line routes have been modified since the issuance of the construc-tion permit (Sect. 3.2.5), the analysis of projected impacts as set forth in the FES-CP (Sect. 5. 1) remains valid. All new transmission lines will be constructed on existing rights-of-way; a total of 5.2 ha (12.8 acres) of land will be required for access road extensions and for new tower bases.

The operation of SONGS 2 &3 .is not expected to affect any existing or proposed areas of the National Park System nor any existing or known potential sites to be listed as national landmarks. 1 In 1980, the applicant conducted a National Register assessment program of the 230 kV transmission right-of-way from San Onofre Nuclear Station to Black Star Canyon and Santiago Substation and to Encina and Mission Valley Substation and evaluated 41 previously identified archaeological sites. As a result of this effort, the NRC, in consul-tation with the State Historic Preservation officer, is seeking a determination of eligi-bility for inclusion in the National Register of Historic Places for 23 sites (see Appendix 0, letter from Dr. Knox Mellon, State Historic Preservation officer, to D. C.

Scaletti, USNRC, dated December 18, 1980). The staff agrees with the conclusions of the December 18, 1980, letter and will seek concurrence of determinations of effect from the Advisory Council on Historic Preservation.

5.3 IMPACTS ON WATER USE 5.3.1 Thermal discharges 5.3.1.1 Applicant's thermal analysis The applicant retained the California Institute of Technology to perform a thermal analysis for the purpose of modifying the diffuser design in order to ensure compliance with state thermal standards. To accomplish this, a physical hydraulic model study was carried out at theW. M. Keck Laboratory of Hydraulics and Water Resources. The culmination of this effort was the diffuser design and configuration described in Section 3.2.2.

The physical model simulation was performed in a basin having horizontal dimensions of ll m (36 ft) by 6 m (20 ft) which represents a prototype modeled region of about 8500 m (28,000 ft) by 4900 m (16,000 ft). The location and orientation of the Units 2 and 3 model intakes and diffusers within the basin are illustrated in Fig. 5. 1. The bottom of the basin was filled with sand which was shaped to produce a simplified representation of the San Onofre bathymetry. The resulting bottom geometry was uniform in the longshore direction and varied as a composite of linear slopes in the offshore direction, as shown in Fig. 5.2. In order to satisfy scaling laws, the number of ports per laboratory diffuser was 16.

To perform simulations, the basin was filled with water at a constant temperature, then water at a temperature 16.67°C (30°F) higher was discharged through the diffusers. This excess temperature was required to maintain proper similitude and represents a ll.l°C (20°F) prototype excess temperature. Water was withdrawn from the basin through the intakes; however, this water was not recirculated. The model basin had the capability to simulate a variety of longshore current regimes, and among those investigated were no crossflow, crossflows of various amplitudes, reversing flows of various amplitudes, and special currents. The results of the simulations are summarized in the ER, Table 5. 1-1. Among 5-1

5-2 BASIN WALL

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Fig. 5.1. Layout of basin used for the physical model study. Source: R. C. Y. Koh, N. H. Brooks, E. J. List, and E. J. Wolanski, HydrauZi~ ModeZing of ThermaZ OutfaZZ Diffusers f~ the san Ono~ NucZear Power PZant, W. M. Keck Laboratory of Hy~raulics and Water Resources, California Institute of Technology, Report KH-R-30, January 1974, F1g. 6.1.

(To change ft tom, multiply by 0,3048.)

these simulations, the worst case was that of zero crossflow. A plot of surface isotherms produced by the model for this case is given in Fig. 5.3. Further details of the

• physical-model study can be found in ref. 2. There are, however, certain physical condi-tions and mechanisms that could not be properly modeled in the laboratory. In an effort to account for this limitation on modeling, the modelers associated a probable temperature excess with each uncertainty. The total of these individual uncertainties was 0.. 83°C (l.5°F). It was therefore reasoned that state thermal standards should be met if the laboratory results satisfied these standards for 1.39°C (2.5°F), with the 0.83°C (l.5°F) margin of error, rather than 2.2°C (4.0°F).

It is evident from Fig. 5.3 that this case satisfies the state thermal standards. The applicant suggests that this is the worst case and, therefore, concludes that SONGS 2 and 3 will, under all conditions, comply with California State thermal standards.

The staff has reviewed the applicant's thermal analysis and believes that the physical model does not adequately represent certain hydrodynamic mechanisms and certain physical features of the prototype. The most* significant of these is the duration of the physical model simulation. The staff believes that the physical model simulation, which *yielded the result given in Fig. 5.3, has not reached thermal equilibrium. This is apparent in the applicant's results for surface excess temperature versus time given in Fig. 5.4. The upper curve represents the maximum surface temperature as a function of time anywhere in the basin, while the lower curve represents the maximum surface temperature as a function of time beyond 305 m (1000 ft) from the discharge point. The time scale for thermal equilibrium in the upper curve is a function of the time required for the heated*water from the discharge to reach the surface and, therefore, should be relatively short. The staff has substantiated this by performing a least-squares curve fit on the data shown in the upper curve. The results show that the maximum surface excess temperature anywhere in the basin is increasing less than 0.028°C (0.05°F) per day. This is small compared with*

the standard deviation of the curve fit and, therefore, thermal equilibrium can justi-fiably be assumed. Beyond 305 m (1000 ft) from the discharge, the thermal equilibrium time scale will be a function of the rate of transport of heated water by densimetric effects and diffuser momentum away from the discharge point. This time scale should be longer than that for thermal equilibrium near the discharge. A similar curve fit performed on the lower plot reveals that the excess surface temperature beyond 305 m (1000 ft) from the discharge is increasing by approximately O.l6°C (0.29°F) per day. The staff believes that such a time-.rate-of-change of temperature does not represent thermal equilibrium. Using a mathematic model, the staff has qualitatively reproduced the applicant*s results. However, this mathematical simulation demonstrates that for increased

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6.2. (To change ft tom, multiply by 0.3048) duration of the simulation, there is a substantial increase in the predicted excess temperatures. In fact, for the conditions represented in Fig. 5.3, an increase in simula-tion time would likely have resulted in predicted excess temperatures that violate state thermal standards. However, such a prediction is unimportant because the particular simulation then represents conditions so unrealistic that the results become irrelevant.

Although the problem of underprediction is inherent in all the applicant's results, it is less significant for the realistic cases. For conditions more realistic than those in Fig. 5.3, the predicted excess temperatures are sufficiently low so that no violations of thermal standards would be expected as a result of increases of simulation duration in the physical model. This expectation is confirmed by the staff's mathematical model study.

5.3.1.2 Staff's thermal analysis The staff has performed an independent thermal analysis for the proposed operation of the once-through cooling system. Depth-averaged numerical models from the Unified Transport Approach 3 were used to simulate plant-induced flows, natural flow, and water temperatures.

Predictions have been made for conditions typical of mid-July, since this is the time of year when thermal impacts should be the most severe. The modeled region is a rectangle measuring approximately 24,000 m (80,000 ft) in the longshore direction and approximately 12,000 m {40,000 ft) in the offshore direction. This region with the numerical grid system superimposed is shown in Fig. 5.5.

5-4 EB-4570 SAN ONOFRE IIUCL~AR G!NERATIII$ STATION UNITS I, 213 0 00

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.,,8CAU! II mT Fig. 5.3 Excess temperature at the surface predicted in the physical model study, for the case of no ambient flow. Source: ER Fig. 5. 1-1. (To change ft to m, multiply by 0.3048; to change F0 to C0 , divide by 1.8.)

One numerical model was used to generate the induced flow from intakes and discharges from all three units. In this model., the intakes are represented as point sinks and the Unit 1 discharge is represented as a point source. The diffusers for Units 2 and 3 are each represented as a superposition of five jets. The hydrodynamics of each jet is modeled using a uniformly valid singular-perturbation theory, numerically corrected for bathymetry. The

• individual flows from the three intakes and discharges were summed to generate a total plant-induced flow field, as shown in Fig. 5.6.

A quasi-potential hydrodynamic model was used to generate the magnitude and direction of the natural currents and free surface displacement resulting from two tidal components and a net downcoast drift, at each grid element. The open-water boundary conditions were adjusted to produce flows which are consistent with observed data 4 - 7 from current meters and drogues. Three individual runs were executed, one for each of the two tidal harmonics (a 12.4 hr period and a 24.8 hr period), and a third to generate the drift current. These three flow components were combined, with the appropriate phase relationships, to produce a simulation of the natural flow field during mid-July conditions.

5-5 ES-4816 RUN C-11 U=O TR=21.~ TH=35.9 0

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Water temperatures were computed using a depth-averaged thermal model. Inputs to this model were the calculated natural and plant-induced flows, along with meteorological parameters used for surface heat transfer calculations. The required meteorological variables are incoming solar radiation, cloud cover, air temperature, wind speed, and relative humidity.

The incoming solar radiation is the mid-day value, which the code automatically adjusts for the time of day, from sunrise to sunset. The remaining parameters are taken to vary sinusoidally over one day and, therefore, require as input the daily average, the amplitude of the daily variation, and the time of maximum value. Typical values for these parameters during mid-July were used and are shown plotted as a function of time in Fig. 5.7.

This thermal model was first run without thermal output or flow from any of the units to produce a five-day simulation of ambient ocean temperatures. Subsequently, the calculation was repeated, with all three units operating at full capacity, to predict the total temperature field. These two results were then subtracted to generate excess temperature plots. Figures 5.8 through 5.15 show ambient flow and excess temperature plots at 6 hr intervals during the fifth day of the simulation at 2:00 am, 8:00am; 2:00pm, and 8:00pm respectively. Isotherms are plotted in increments of 0.28°C (0.5°F) from 0.28°C (0.5°F) to 2.8°C (5.0°F). In general, the hottest spots occur directly above the discharge for each unit, with Unit 1 being consistently hotter than Unit 2 or 3. In addition, during the part of the tidal cycle when the natural flow is downcoast, there is a secondary warm spot approximately 3000 m (10,000 ft) downcoast of the discharges. This apparently is a result of the influence of the shape of the shoreline on the flow which, in turn, causes the plume from Units 2 and 3 to intersect the plume from Unit 1 at this point downcoast.

California thermal standards require that the 2.2°C (4°F) excess temperature isotherm never reach the shoreline or bottom, and that the 2.2°C (4°F) surface isotherm must be within 305 m (1000 ft) of the discharge point during at least one-half of the tidal cycle. Although the thermal model is depth averaged, it is still possible to address the state standards with the model results because the ambient crossflow has a destabilizing effect upon the discharge buoyancy. During portions of the tidal cycle, the ambient crossflow is of sufficient magnitude to dominate the stable stratification, resulting in mixing of the plume to the ocean bottom in the neighborhood of the diffuser. Recent work by Almquist 8 provides the basis for determination of conditions for vertical mixing. According to Almquist, the warm plume will mix to the bottom when the ratio of the ambient crossflow velocity to the cube root of the buoyancy flux per unit length of diffuser is greater than one. Figure 5. 16 (a) is a plot of this stability parameter versus time for one tidal cycle based on the staff's ambient flow predictions. The shaded area shows the period during the tidal cycle when instability will occur and the water column will be vertically homogeneous.

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Figure 5.16 (b) is *a plot of the maximum excess temperature in the vicinity of the diffuser as a function of time for one tidal cycle. The shaded portion of this curve represents the period during the tidal cycle when the excess temperature is greater than or equal to 2.2°C (4.0°F) and the plume is vertically well mixed. In other words, the shaded area in this figure reflects the portion of the tidal cycle that will violate state thermal standards as applied to excess bottom temperature. It is clear from this figure that bottom excess temperatures greater than 2.2°C (4.0°F) are predicted to occur. for two hours during the tidal cycle. Because, however, this prediction,-based on a low ambient drift current, is conservative, excessive incremental bottom temperatures should not occur during each tidal cycle but rather during periods of worst case conditions.

Wi~h an assumed persistent drift, the data shown in Figs. 5.8 through 5.15 indicate that the constraints on the surface and shoreline excess temperature will be satisfied. The model is inadequate for addressing the issue of bottom temperature. However, at worst, the 2.2°C (4°F) excess temperature should only touch the bottom over a very limited area in the vicinity of the Unit 2 and 3 diffusers. On the basis of these results, the staff believes that violations of the state thermal standards are unlikely.

Heat treatment Heat treatment will be necessary to control biological growth in the discharge conduits, intake conduits, and screenwells. Heat treatment consists of decreasing the flow rate through the heat-dissipation system while maintaining a constant waste-heat rejection rate.

The result is an increased temperature rise across the condensers.

Fig. 5.9. Predicted excess temperatures in the San Onofre region at 2:00a.m. on the fifth day. Isotherms are plotted in increments of 0.28°C (0.5°F) beginning with the 0.2°C

,(0.5°F) isotherm. (To change F0 to C0 , divide by 1.8.)

Discharge.heat treatment will be required only when none of the following conditions are met:

1. discharge temperatures exceed 26.7°C (80°F) for a minimum of 1000 hrs,

2. discharge temperatures exceed 29.4°C (85°F) for 150 hrs, or

3. discharge temperatures exceed 32.2°C (90°F) for 31 hrs.

On the basis of these conditions it is expected that discharge heat treatment will be required only infrequently and usually during the winter. When discharge heat treatment is required, it will be performed at a discharge temperature of 40.6°C (105°F) for a dura-tion of l. 1 hrs for Unit 2 and 0.9 hrs for Unit 3. During discharge heat treatment, discharge flow rates will be reduced and discharge temperatures wi 11 ,be increased. The discharge excess temperature will be the difference between the ambient water temperature and 40.6°C (l05°F.) The reduction in the discharge flow rate will be proportional to the increase in the discharge excess temperature.

Although the exact nature of the thermal plume resulting from discharge heat treatment will be dependent upon the ambient conditions at the time of heat treatment, the thermal plume will be qualitatively similar to the plume resulting from normal operation as shown in Figs. 5.9, 5. 11, 5. 13, and 5. 15. However, the flow is reduced and the temperature increased, so that the plume will be somewhat warmer and smaller in spatial extent than that from normal operation. The greatest plume temperatures will occur if Units 2 and 3 are heat treated simultaneously. A warmer plume will persist the longest when the heat treatment for these units are sequenced.

During the summer months, discharge heat treatment should increase far-field plume tempera-tures by no more than 25% if both units are heat treated simultaneously (an unlikely event due to the increased probability of a reactor scram) and by no more than 15% if the units are heat treated sequentially. Plume temperatures at this extreme would persist for several hours, and plume temperatures would return to normal within several tidal cycles.

During the winter, the thermal plume should exhibit temperature distributions no greater that those predicted during the summer {Figs. 5.9, 5. 11, 5. 13, and 5: 15). Excess tempera-tures during winter heat treatment will be greater than during the summer since a greater condenser temperature rise will be required to meet the design discharge temperature of 40.6°C (105°F). For an ambient water temperature of l0°C (50°F) (typical of winter) excess temperature at the San Onofre kelp bed would be approximately 4°C (7.2°F) if the Units 2 and 3 discharges are heat treated simultaneously and 2 to 3°C (3.6 to 4.8°F) if the discharges are heat treated sequentially.

Intake conduit and screenwell heat treatment will be performed by reducing the flow rate through the heat-dissipation system, thereby increasing the temperature rise across the condensers, and by reversing the flow direction so that ambient water is withdrawn through the diffuser and heated water is discharged from the velocity cap intake. The duration of this heat treatment will be 2. l hr at an anticipated maximum temperature of 37.8°C (100°F).

The plume produced by discharge through the velocity caps will resemble the thermal plume from Unit 1. Since this discharge does not induce the dilution produced by diffusers, the heat-treatment plume will be considerably hotter, though much smaller, than the plume resulting from normal plant operation. Plume temperatures will decrease approximately as the square of the distance from the intakes. Heat treatment on either the Unit 2 or the Unit 3 intake will have an indirect impact on the thermal pluine of the unit operating normally. If, for example, the Unit 2 intake is heat treated while Unit 3 is operating normally, the Unit 2 heat treatment plume could be advected during certain ti~es in the

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on the fifth day. Iostherms are plotted in increments of 0.5°F beginning with the 0.5°F isotherm. (To change F0 to C0 , divide by 1.8.)

tidal cycle towards the Unit 3 intake. As a result, water at temperaures above the ambient could be drawn into the Unit 3 intake, resulting in a temperature rise in the Unit 3 discharge plume. Similarly, Unit 3 intake heat treatment could affect the plume from Unit 2.

This recirculation phenomenon will be offset by virtue of the fact that only one unit will be discharging through the diffuser. Therefore, far-field diffuser plume temperatures will likely be less during intake heat treatment than during normal plant operations.

Both discharge and intake heat treatment will produce plumes showing temperatures greater

.than plume temperatures expected during normal operations. These increased temperatures will be greatest near the point of discharge, and will be of short duration returning to normal within several tidal cycles after completion of heat treatment.

Should it be determined that heat treatment results in significant excess temperatures at biologically sensitive areas, impacts could be mitigated by scheduling heat treatments during phases of the tidal cycle (such as periods when the tidal flow will transport the thermal plume away from areas of concern) that will minimize excess temperatures occurring in such areas.

5.3.2 Chemical discharges The assessment of the effect of chemical discharges on water use contained in the FES-CP (5.2) is still, for the most part, valid. The discussion of the impacts of copper and nickel discharges has been altered by the change to titanium condenser tubes (3.2.4. 1),

and these discharges should not affect water use since the tubes no longer contain copper or nickel.

5-12 ES-4547 4.5 3

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A National Pollutant Discharge Elimination System Permit for SONGS 2 & 3 was issued on June 4, 1976, by the California Regional Water Quality Control Board; San Diego Region.

The chemical effluent limitations imposed by this per111it are given in Sect. 3.2.4.1.

5.4 ENVIRONMENTAl IMPACTS 5.4. 1 Terrestrial environment Generally, operation of SONGS 2 and 3 and associated transmission lines should have no significant impact on the terrestrial ecological characteristics of the area. Although the transmission line routes have been modified since the issuance of the construction permit (3.2.5), the analysis of projected impacts as set forth in the FES-CP (5.3. 1) remains

• the same. All new transmission lines will be constructed on exfsting rights-of-way; a total of 5.2 ha (12.8 acres) of land will be required for access road extensions and for new tower bases. The fire break which was bulldozed adjacent to the transmission line on Camp Pendleton Marine Base is expected to be maintained by periodic blading. Impacts associated with this operation should be minimal.

Other potential terrestrial impacts associated with operation of SONGS 2 and 3 which were not addressed in FES-CP are as follows. Some audible noise will be generated from the operation of the transmission lines. Noise levels, however, will be well within the urban evening levels accepted by the public (ER, Section 5.5. 1). The transmission lines will be designed to minimize any affects on radio and television reception (ER, Section 5.5. 1).

Maintenance of the transmission lines (washing and repair work) requires that the access

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(To change F0 to co, divide by 1.8.}

roads be kept in good condition by blading (ER, Suppl. l, Item 21); associated impacts should be minimal. Maximum ground-level field gradients for all transmission lines will not exceed 7.5 kV/m (ER, Suppl. 1, Item 20). Generally, no harmful effects occur from the electrical fields associated with lines operating at 230 kV and below. 9 5.4.2 Impacts on the aquatic environment 5.4.2. l Effects of the heat dissipation system A description of -the heat dissipation system to be employed at SONGS 2 and 3 is found in Sect. 3.3 of the FES-CP. Design changes that have occurred since then are discussed in 3.2.2 of this statement. The only changes of potential significance for the assessment of biological effects involve the final specifications for the fish return system, the biocide use program, and the.composition of the condenser tubing. Assessments of most major potential impacts also have been reevaluated in light of additional data obtained during technical specifications monitoring programs for SONGS 1 and from construction and preoper-ation monitoring programs for SONGS 2 and 3 (Section 2.5.2). Except as noted, the reassessments have resulted in the same conclusions that were reached in the FES-CP.

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Thennal effects The discharges from SONGS 2 & 3 must conform to regulations of the California State Water Resources Control Board, the Environmental Protection Agency (with reQard to thennal discharges), and the California Regional Water Quality Board, San Diego Region, (under the auspices of the EPA) with regard to NPDES pennit considerations (primarily chemical effluent limitations). The regulatory restrictions on thermal discharges are found in Sect. 5.1.1 of the ER; the NPDES permit, as amended, is found in Appendix l2C of the ER.

The results of thermal models used to evaluate temperature increases attributable to SONGS 2 &3 (and incremental to SONGS 1) are discussed in Sect. 5.3.1. These data indicate that the thermal plume characteristics will be different from those estimated in the FES-CP and in the ER. Since the area to be affected by thermal discharges is now estimated to be greater than previously thought and since areas of substantial biological importance potentially will be affected (e.g.,

kelp beds), a reassessment is necessary.

Plankton. More planktonic organisms will be affected by thermal discharges than estimated in the FES-CP because the plume will cover greater area. The types of impact will, however, be the same (e.g., species compositon changes, greater respiration rates), and significant changes should be localized. The staff believes that changes which are produced in plankton communities will not threaten the ecological integrity of the near-shore region surrounding the facility (see pp. 5-26 to 5-32 of the FES-CP for a description of the anticipated effects).

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5-16 Fish. The types of impact on fish to be expected as the result of thermal discharges are the same as those discussed in the FES-CP. However, with more area to be influenced by the effluent, more fish potentially will be affected. The most observable change is likely to be shifts in the types of species (and their numbers) which inhabit the area; e.g., species which normally exhibit increased standing crops during naturally warm years will be more prevalent.

Although the area of potential impact will be greater than estimated before, no fish popula-tions are expected to be adversely impacted in the vicinity of the facility. Species compo-sition changes, however, may affect commercial and recreational fishing within the thermal plume (in some cases adversely, and in others, beneficially; see FES-CP for details).

However, because the plume will occupy a relatively small area of the available fishing space nearby, no significant changes in harvest rates for the various species are expected.

As stated in the FES-CP, cold kills of fish are not likely to occur to any large degree.

The principal reasons are the relatively high ambient winter temperatures and the fact that all three units are not likely to be inoperative at any given time.

Benthic fauna. The major component of the ecosystem expected to receive the greatest impact from thermal discharges is the benthic community. Unlike free-swimming organisms, benthic individuals cannot easily avoid undesirable temperatures. And unlike planktonic organisms, they do not regenerate quickly to compensate for losses or experience continual, rapid recruitment from surrounding waters. Two major categories of the benthic community exist:

animals, such as starfish and molluscs, and attached algae, the most conspicuous of which is kelp (discussed in the following section).

Among the benthic fauna recorded in the vicinity of SONGS during surveys conducted in 1977 in compliance with Environmental Technical Specifications criteria for SONGS Unit 1 were the gastropod molluscs Astraea undosa, Kelletia kelletii, and Roperia poulsoni, the asteroid echinoderm Pisaster giganteus, and the ech1no1d ech1noderm Strongylocentrotus franciscanus. 10 Although there have been only a limited number*of detailed studies concerning the effects of temperature on marine species inhabiting the Pacific Coast, some recent laboratory simulation experiments of 12 to 14 weeks duration have examined the effects of thermal effluent on the survival, growth, and state of health of seven motile invertebrates from shallow rocky habi-tats along the southern California coast. 11 The treatment conditions simulated temperatures measured at distances of 84 and 335 m (276 and 1098 ft) from the cooling-water discharge structure of the Redondo Generating Station, located approximately 100 km (62 miles) upcoast of SONGS. Several of the species displayed low survival and impaired growth, especially among large. adults, in response to the simulated thermal plume conditions at 84 m.

Weekly mortality data for S. franciscanus, P. ochraceus, and R. poulsoni showed that indivi-duals of all three species began to d1e when the temperature fluctuated over a range of 19° to 23°C (66° to 73°F), with a mean for the week of 21.4°C (70.5°F). No deaths had occurred the previous week when the same temperature range prevailed and the mean was slightly higher 22.8°C (73°F). The mortality observed during the second of these two weeks may, however, actually have been a delayed response to the higher average temperature of the previous week.

In the test involving R. poulsoni under a different thermal regime, deaths began occurring when the temperature flunctuated between 18° and 24°C (64° and 75°F) during the week, with a mean of 20.3°C (68.5°F). Although mortality began to appear at a lower mean temperature than in the previous experiment with this or~anism, the maximum temperature in this second experiment was l°C (1.8°F) higher (24° vs 23 C) (75°F vs 73°F) and the temperature range was 2°C (3.6°F) wider (6° vs 4°C) (4.28° VS 39.2°F) than in the previpus experiment. These results demonstrate the complicated nature of temperature effects; that is, adverse conditions can result from a critical high temperature of short duration, an extreme temperature fluctua-tion of short duration, or a prolonged period of a high but normally subcritical temperature.

The ambient depth-averaged temperatures predicted for the hottest time of the year (end of July) in the vicinity of SONGS are shown in 5.3. 1. This section also contains data on the temperature expected during the operation of all three units. Temperatures potentially as high as 27.8°C (82°F) may occur naturally, and increases of 0.5° to 1.7°C (0.90° to 3.1°F) brought about by the operation of all three units can occur within an area of several square kilometers.

On the basis of the 1976 study, 11 the staff concludes that several components of the benthic fauna in the vicinity of SONGS would probably be adversely affected in areas where weekly mean temperatures of 22°C (71.6°F) prevail for one month or more or where daily temperatures reach or exceed 24°C (75°F). It is not, however, anticipated that temperatures averaging 22°C will occur for more than 2 to 3 weeks or that the area experiencing temperatures of 24°C or greater as a result of SONGS operation will be considerably larger than the area experiencing these temperatures under natural conditions.

The staff concludes that any impacts to the benthic fauna as a result of thermal discharges will be minimal and of an acceptable nature.

5-17 Kelp. Kelp beds off California occupy roughly 194 sq km (75 sq mi) of ocean bottom in water depths of 6-18 m (20-60 ft). 12 Although management efforts have possibly halted further severe decline, kelp bed coverage has decreased markedly since about 1920. Although this deterioration may have been partially a result of overharvesting, much of it is probably caused by the increased alteration of the near-shore environment by human activities. In particular, increased temperatures and increased turbidity have been shown to be inimical to kelp surviva1.1a Even without the influence of human perterbations, individual kelp beds experience long-term variations in stand density, productivity, areal extent, etc. Natural factors implicated in causing these variations include storm damage (causing detachment of plants), sand move-ment (burying holdfasts and causing detachment or prohibiting regeneration), introduction of turbid water masses, high natural temperatures, influx of grazing urchin masses, and fungal and bacterial diseases. 12 Thus, for example, in 1957-59, unusually warm temperatures off southern California caused an estimated loss of 90% of the regions' beds during this period (ER, pp. 2.2-28 and 2.2-29), as judged by surface examinations. Individual beds also commonly display changes in canopy extent during the year. For example, the three beds near the SONGS site showed marked variation in canopy area during 1975 and 1976 (Fig. 2. 10). Typically, canopy tissue deteriorates during the warmest time of the year, leaving the basal portion of the plant (which is in cooler water) for regeneration when temperature and light conditions permit. 13 Reduced surface nutrients and higher bottom nutrient mixtures may also contribute to canopy deterioration and basal tissue regeneration respectively. 14 Kelp beds represent a very important ecological community in California's near-shore waters.

It has been estimated that kelp beds are at least three times more productive than the autotrophic components of other near-shore communities. Conservative estimates place the total standing crop of kelp in southern California at 1.8 x 10s kg (2 million tons) and new annual growth potential is on the order of 2-3 times this amount. 13 Kelp beds harbor numerous types of animals and plants, adding greatly to the diversity of an area. Inverte-brates commonly found on the plants themselves include ostracods, copepods, amphipods, decapods, polychaetes, nematods, bryozoans, turbellaria and molluscs. Molluscs and echino-derms are kelp grazers prevalent on and around the plants. It is estimated that the larval, juvenile, and adult stages of 25 main sport fish use kelp beds for refuge and food gathering (eating the associated invertebrates, the kelp itself, or other al~ae), and the average standing crop of fish is estimated to be 300 kg/ha (300 lbs/acre). 3 Kelp not only enter the food chain via grazers, but they contribute large quantities of organic matter to the detritus-based food chains. For example, since several detritus feeders are intermediate in the grazing food chain of many of California's commercial fishes, kelp indirectly influ-ences the populations of these fishes through the production of detritus. 13 Kelp is an important commercial commodity as well. Although used extensively in the past for such diverse things as fertilizer, cattle feed, and for the production of potassium, acetone, and iodine, most kelp today is processed for the production of algin, a poly-saccharide. with numerous industrial uses. 12 It is estimated that roughly 15% of the annual kelp production is harvested yearly at a landed value (1964 dollars) of $2 million (market value is roughly 4 times this figure). 13 The kelp beds in the vicinity of SONGS are not now harvested.

Besides the necessity for a favorable physicochemical environment, kelp requires a solid substrate for attachment. Thus, the local distribution of kelp beds in an unperturbed area is largely substrate-dependent. Near the SONGS site, sandy bottoms are prevalent limiting the areas where beds can develop. Natural environmental fluctuations (e.g., higher-than-average temperatures) can virtually denude an area, but, since the casual phenomena are short-lived, kelp beds generally reestablish themselves quickly. However, anthropogenic disturbances frequently completely eliminate kelp beds in their sphere of influence because they generally are of long duration. Even chronic, low-level perturbations which only slightly decrease kelp production often cause the consumption by grazers to outpace new growth. 13 The temperature tolerance of kelp is probably a reflection of a combination of factors, including physiological responses, susceptibility to disease, and susceptibility to grazing.

It has been rather well established that temperatures above 18-20°C (64-68°F) cause deteri-oration of kelp, and the degree of degradation is directly related to the duration of the exposure to these temperatures. Increased surface temperatures caused by SONGS operation (all three units) would have the effect of extending the period of canopy absence. During the hottest time of the year, data in Section 5.3. 1 suggest that the closest kelp bed (San Onofre bed) will experience an average surface temperature increase (over a 24-hr period) of 1.4°C (2.6°F); the range of temperature increase will be 0.6-2.2°C (l-4°F).

Although daily natural temperature variations of l°C (2°F) are not uncommon in the area (ER, p. 2.2-28), they would not be continuous in nature and thus might not affect the bed

5-18 as severely as the continuous SONGS discharges would, where the thermal plume may impinge on the bed for a longer time. Prediction of the degree to which canopy disappearance would be prolonged is impossible. Regeneration would be quicker in years with naturally cooler ocean temperatures, assuming the regenerative tissues remained unaffected (see below).

The greatest threat of SONGS to the long-term survival of the San Onofre kelp bed is the possibility of injury to the basal tissues from which the canopy is regenerated each year as the waters cool. Estimates for bottom temperatures within the bed at the end of July (Section 5.3. 1) indicate that temperatures could reach 23-25°C (74-76°F), with a 24-hr mean of 24°C (75°F). Such temperatures would represent a l-l.5°C (2-3°F) increase above ambient conditions encountered during the hottest portion of the year (conditions which are likely to persist for up to approximately a one-week period) (Section 5.3. 1). Although the ambient temperatures given above would in and of themselves be detrimental to the kelp, exposure to them for up to a week would not likely cause permanent degradation of the entire bed 13 because the mean exposure temperature does not quite exceed a recognized threshold temperature for rapid degradation (24°C) and deeper portions of the bed would be slightly cooler than the average and would have a greater probability of maintaining a viable population. However, adding l-l.5°C to these ambient temperatures could place the bottom kelp tissues in a critical temperature environment subjecting the tissues of most of the plants to tempera-tures greater than their short-term tolerance, and prolonging the period of time in which the plants would experience temperatures greater than 20°C (68°F), which would cause them to be more susceptible to grazing pressure, diseases, etc., leading to their eventual demise. 13 Since ambient bottom temperature in the region from August- early September may typically range up to l9°C (66°F) (Section 5.3. 1), a several week period could exist in which temperatures exceed l9°C.

The information above suggests that the thermal discharges from SONGS 1, 2 and 3 may result in the destruction of at least a portion of the San Onofre Kelp Bed during the summer months.

Under average conditions, the result may not be detectable or it may be manifested in a noticeably earlier decline of the canopy. However, under extreme worst case conditions (e.g., several days with high ambient temperatures and slack currents, and with all three plants operating continuously), destruction of the basal regenerative tissues might result.

~lthough recolonization of the area from outside sources could occur during the cooler months, the community, if destroyed frequently, could never achieve a stable state charac-teristic of other kelp beds in the area. Furthermore, constant temperature increases coupled with added turbidity would be inimical to interim reestablishment since these factors tend to increase the effects of grazing. 13 The perennial occurrence of worst case conditions seems highly unlikely (Section 5.3. 1) and the staff thus concludes that the long-term thermal impacts from normal station operation are not likely to be severe. However, in view of (1) the potential additive of synergistic effects of turbidity and sediment with thermal discharges, (2) the ecological importance of kelp beds and their already diminished stature, and (3) the fact that the Sah Onofre bed represents about one-third of this resource along approximately 16 km (10 mi) of shoreline in the vicinity of SONGS, the staff recommends monitoring to ensure the bed's protection, * * ** -

• Heat treatment In addition to the thermal discharge associated with the normal operation of the facility (see above), the applicant proposes to heat treat portions of the intake and discharge systems to remove biological growth (see Section 5.3. 1.2). This antifouling procedure will result in periodic discharge temperatures higher than those normally encountered. As a result, the state required the applicant to perform a demonstration to determine if signi-ficant impacts will result from the procedure. This demonstration, in part provided for under part 316(a) of the Federal Water Pollution Control Act of 1972, was used to determine if the proposed process is acceptable to these government agencies. To date, approvals have been obtained from the California State Water Resources Control Board (Resolution No. 80-95 adopted December 18, 1980), thus removing any regulatory obstacles from the state for conducting the antifouling process.

As stated in Section 5.3. 1.2, biofouling control will be needed primarily in the winter; ambient summer temperatures will normally be sufficiently high to obviate the need for the procedure at that time. Additionally, the state has imposed a five-week minimum treatment interval for each unit. Hence, the biological effects will be a manifestati~n of short-term intermittent stress. Localized mortality and chronic debilitation are inevitable, particu-larly for sessile organisms. However, only one community of organisms is judged to be significantly vulnerable ecologically- the San Onofre Kelp Bed.

The thermal effects of normal operation on kelp are discussed above along with more detailed information on thermal tolerances, etc. Since intake heat treatment should produce smaller far-field 8T's than that produced by normal operation (Section 5.3. 1.2), the effects on kelp will be less than or equal to the effects induced normally. Discharge heat treatment is

5-19 judged to produce potentially greater far-field thermal effects, however. Without dispersing currents (i.e., during a slack in the tidal cycle), kelp bed temperatures during the summer may increase by ca. 0.4°C (0.72°F) (above normal operations) (Section 5.3.1.2).

This negligible increase would not be likely to affect the kelp, particularly since the canopy will be naturally reduced (see kelp discussion above) and the heated water is not likely to be near the bottom.

Discharge heat treatment during the winter may cause a temperature increase in the kelp bed of up to 4°C (7.2°F). The kelp are ordinarily tolerant of the absolute temperatures this would produce, but the rapid heat-up involved (e.g., 0.5 h) could be deleterious since the kelp would not be "hardened" for such a temperature regime. However, it is not possible to tell from the literature the severity of such an event. The plants could be only tempo-rarily taxed physiologically and rebound without sequelae. Conversely, the stress could initiate an increased vulnerability to other, natural stresses such as predation, sloughing, and encrustation. Overt mortality is unlikely. In the absence of definitive data, it would be wise to (l) ensure continuation of the kelp monitoring program and (2) attempt to avoid heat treatment during unfavorable ocean current conditions. As pointed out in Section 5.3. 1.2, effects can be mitigated by staggering heat treatment at Units 2 and 3 (thus allowing thermal dispersion from the first treated unit before treating the second) and by conducting the antifouling procedures when current and tidal cycles are known to move the adjacent water mass away from the kelp bed.

Turbidity and sediment transport effects The FES-CP discusses the types of effects turbidity increases due to SONGS operation will have on the various biological communities, indicating that it is not possible to predict the areal extent of this impact.

The organisms likely to receive the greatest impact from increased turbidity are those which.

cannot readily avoid adverse conditions or do not regenerate quickly (or experience rapid recruitment from surrounding waters), namely, the benthos. Since the San Onofre Kelp Bed is estimated to be enveloped within the thermal plume, it is likely that it will also experience increased turbidity. The effect on the kelp would potentially be decreased photosynthesis, possibly causing many of the plants to die if the exposure is continuous (a 1% increase in the absorption coefficient has been found to result in a 20% loss in net photysynthesis at 15 m (49.2 ft} 13 and burial of the holdfasts in particles which settle out, inhibiting regeneration and recolonization. Regardless of the magnitude of these effects, their presence would add to the probability that the kelp bed would be adversely affected (see preceding section).

Some of the effects of increased sediment transport on benthic fauna are addressed in the FES-CP. The staff has further addressed the impact of the change in sediment size in areas near the SONGS site which would result from sediment redistribution. A study conducted during SONGS 1 operation, shutdown, and subsequent startup showed a significant reduction in the number of species and the total abundance of individual benthic fauna (primarily molluses and polychaete worms) within 200 m (656 ft) of the intake and discharge structure, probably because of the coarsening of the grain size of the sediments in this area. 15 Sedi-ment coarsening appears to be mainly a result of the discharge of shells and shell fragments of fouling organisms (barnacles, molluscs) sloughed from the insides of the intake and discharge pipes during normal operation and especially during heat treatment.

The sediment-altered area associated with SONGS 1 (following 13 years of operation) is estimated to be approximately 125,600 m2 (.048 mi 2 ), on the assumption of a circular pattern of effect with a radius of 200m (656 ft). 15 Assuming sediment alteration associated with SONGS 2 and 3 forms a rectangular pattern approximately 200 m from the sides and ends of each diffuser, the area affected by SONGS 2 and 3 would be approximately 0.8 kffi2 (0.31 mi 2 ). Adding this to the area affected by SONGS 1 (125,600 m2 (0.48 mi 2 )) plus an estimate of the area affected by heat-treatment backflushing of the SONGS 2 condenser (59,900.m 2 (0.023mi 2 )) gives a total area affected by all three units, from both normal operation and heat treatments, of approximately 1.0 km 2 (.386 mi 2 ).

It is difficult, however, to extrapolate from the effects associated with the point source discharge of SONGS 1 to the 762-m (2500-ft) long dual, staggered diffusers of SONGS 2 and

3. SONGS 2 and 3 jointly are expected to have 5 times the cooling water flow rate, 3.3 times the intake pipe area per intake structure, and 12.5 times the total fouling surface area associated with the two outfall lines that SONGS 1 has. 15 None of these factors has been taken into consideration in calculating the area potentially affected by SONGS 2 and

3. The magnitude of the effect will also increase with duration of operation.

In contrast to the above prediction of benthic impoverishment, the staff concludes that a zone of enhanced species diversity and abundance is to be anticipated beyond the area of

5-20 sediment modification. This conclusion is also based on results of the Marine Review Committee study, 15 which indicates that within a zone of 200 to 800 m (656 to 2424 ft) from the intake and outfall of SONGS 1, diversity and abundance of benthic fauna show a positive correlation with proximity to these structures. It has been estimated that this area contains 2 times the diversity and 8 times the abundance of benthic fauna as the sediment-altered area within the 200-m (656-ft) radius of the outfall. This phenomenon is believed to be a result of organic enrichment from sinking plankton fragments and/or material continually resuspended by the localized turbulence of the discharged cooling water. 15 Assuming an eliptical ring pattern for this area of enhancement, starting from a point 200 m (656 ft) on either side of the intake and outfall structures of SONGS 1, to 1200 m (3936 ft) upshore and downshore (the extent of enhancement appears to diminish between 800-1500 m (2624-4920 ft) downcoast) and extending for a distance of 400 m (1312 ft) beyond the 200-m (656-ft) point in the onshore and offshore directions (offshore/onshore effect is much less than longshore), the area of enhancement is estimated to be approximately 2.1 km 2 (0.81 mi2).

Predicting the magnitude of an enhancement effect associated with SONGS 2 and 3 on the basis of SONGS 1 observations is complicated. The total volume of dead plankton dispersed might be approximately 5 times that of SONGS 1 as a result of the 5-fold increase in cooling water flow rate. However, the volume of discharge for each diffuser port is less than for the single outfall of SONGS 1 so that the distance the en~rained plankton are dispersed would be expected to be Jess. There may also be considerable differences between the shallow current patterns where the SONGS 1 outfall is located and the current patterns in the deeper waters where the SONGS 2 and 3 diffusers will be located.

If it is assumed that the dispersal distances for dead plankton will extend approximately half the distance from the sediment-altered area surrounding the SONGS 2 and 3 diffusers as was found associated with the SONGS 1 discharge, and accounting for overlap, the area of enhancement would be approximately 2.4 kffi2 (0.93 mi 2). Adding to this the area affected similarly by SONGS 1 gives a total of 4.5 km2 (1.74 mi 2 ). This is an area approximately 5 times that estimated to show a reduction in benthic diversity and abundance. The staff concludes that the impacts likely to occur to the benthic fauna as a result of sediment transport effects are acceptable.

Entrainment The staff's analysis of entrainment effects in the FES-CP remains valid (FES-CP, p. 5-7 to 5-12). A program on the mortality experienced by entrained ichthyoplankton is being planned currently at SONGS 1 and is expected to be submitted to the NRC staff in 1981. The results of this program should help to determine the significance of any impacts although the analysis presented in the FES-CP indicates that impacts should not be significant.

The completion date for this study will be approximately one year after it is initiated.

The circulation of water from near-shore areas to offshore areas will cause some redistri-bution of species, particularly zooplankton, since species composition is not exactly the same for both areas (Section 2.5.2). Although this may result in long-term species composi-tion changes, the areas affected shou'ld be small (FES-CP, Section 5.~.2) relative to the coastal areas as a whole around San Onofre. Because no other power plants or industrial facilities that could exert a similar influence exist within several miles, this impact is judged acceptable.

Impingement The basic impingement analysis contained in the FES-CP remains valid. Some additional information is available, however, on the design and efficiency of the fish return system.

The system is described in detail in Section 3.4 of the ER and in Section 3.2.2 of this document. Basically, the fish return system consists of a mechanism for shunting any fish entrained in the intake to a side holding area by means of an angled conduit design to avoid impinging them on the trash removal mechanisms in front of the final intake.

Preliminary experimental results (ER, p. 5.1-20) indicate that perhaps 90% or more of the fish can be returned to the ocean unharmed. However, precise figures on the effectiveness of this system will not be available until the fish return system is in full-scale operation.

The FES-CP analysis assumes a worst-case situation in which the fish return system is not at all effective. Under these conditions, 33 to 91 tonnes (36 to 100 tons) of fish per year would be removed from the San Onofre area. These figures are based on extrapolations from data obtained on SONGS 1 operation; new data do not indicate that these figures should be adjusted significantly. The majority of the fish impinged at SONGS 1 are queenfish, and, for reasons given in the FES-CP, losses from all three units should not have a significant impact on the population. Moreover, of the dominant recreational fish impinged at SONGS 1, losses were less than 0.8% of the amount taken by fishermen. Likewise, the primary

5-21 commercial fish of the area- jack mackerel, Pacific bonito, and white seabass- were seldom entrained at SONGS 1.

Offshore current induction The analysis of the effects of induced circulation as given in the FES-CP (p. 5-16) remains valid, despite the design changes described in Section 3.2.2.

5.4.2.2 Effects of biocides and other chemical discharges The FES-CP expressed concern about the potential long-term effects of copper being released into surrounding water by corrosion of the condenser tubing. Design changes have eliminated the plan to use a copper-nickel alloy for condenser tubing; titanium tubing will be used.

Therefore, copper- or nickel-induced stresses to the receiving water from condenser tubing would not occur.

The FES-CP conclusion that the effects of chlorine will not be significant remains valid.

However, new information is available on this subject. The applicant estimates that the effluent chlorine concentrations will be no greater than 1.5 ppm as total residual before discharge to the ocean (ER, p. 5.3-2). With a 10-to-1 mixing in the immediate vicinity of the diffuser ports (ER, p. 5.3-2), this value would be reduced to 0.15 ppm. The FES-CP required, and the applicant agreed, that the total residual concentration of chlorine and other halogens in the immediate vicinity of the discharge from each unit be limited to less than 0.1 ppm for no more than six 15-min periods each day [FES-CP, p. iv, item 7.a(2)].

Experience at SONGS 1 indicates that total residual chlorine concentrations quickly dissi-pate to undetectable quantities within a hundred or so meters of the outfall and, for any given 15-min dosing period, are only detectable over the outfall for 2 to 18 min (ER,

p. 5.3-2). Even assuming a worst-case condition for SONGS 2 and 3 in which chlorine remains at levels around 0.15 ppm (total residual) in the vicinity of the outfall ports for as long as 30 min, any significant impacts are unlikely. 16 Thus, any chlorine effects are likely to be minimal and of an acceptable nature. Moreover, the difference in effect between discharges of 0.1 and 0.15 ppm are negligible. In view of this and in light of the provi-sions of the Federal Water Pollution Control Act Amendments of 1972, the staff does not believe that a more stringent limitation on chlorine discharges is necessary.

Miscellaneous chemicals will be discharged through the circulating water outfall system and will include laboratory wastes, ion exchange regeneration chemicals, and pH adjusters (Section 3.2.4 of this document and Section 3.5 of the FES-CP). The FES-CP analysis of the impact of these chemicals remains valid; that is, because of the small quantities involved, the great dilution factors present, and the relatively innocuous nature of most of these chemicals, impacts will not be detectable.

5.4.2.3 Effects of sanitary waste discharge The effects of sanitary waste discharge are not discussed specifically in the FES-CP.

However, any effects will be insignificant for the following reasons.

1. On the average, only about 26m3 /day (7000 gpd) of secondary treated sewage will be discharged.

2. The discharge will be made into the circulatory water system at the rate of 0.02 m3 /min (5 gpm). The**cooling water flow is about 1200 m3 /min (320,000 gpm). Thus, a 6400 dilution factor will result.

3. The resulting concentrations of suspended solids, BOD, N, P, coliform bacteria, and chlorine will not result in detectable incremental increases above ambient levels even before discharge into the ocean.

5.5 RADIOLOGICAL IMPACTS 5.5.1 Radiological impact on man The impact on man associated with the routine release of radioactive effluents from SONGS 2 and 3 has been estimated .. The quantities of radioactive material that may be released annually from the plant are estimated based on the description of the radwaste systems given in the applicant's ER and PSAR and using the calculational model and parameters described in NUREG-0017. 17 Using these quantities and site environs information, the dose commitments to individuals are estimated using models and considerations discussed in detail in Regulatory Guide 1.109. Additional assumptions and models described in Appendix B of this environmental statement were used to estimate integrated population doses.

5-22 5.5.1. l Exposure pathways The environmental pathways that were considered in calculating the radiological impact are shown in Fig. 5. 17. Calculations of radiation doses to man at and beyond the site boundary were based on the radioactive material quantities shown in Tables 3.2 and 3.3, on site meteorological and hydrological considerations, and on exposure pathways at SONGS 2 &3.

ES-2510 LIQUID EFFLUENT Fig. 5.17. Exposure pathways to man.

In the analysis of all effluent radionuclides released from the plant, tritium, carbon-14, radiocesium and radiocobalt inhaled with air and ingested with food and water were found to account for essentially all total-body dose commitments to individuals and the population within 80 km {50 miles) of the plant.

5.5.1.2 Dose commitments from radioactive releases to the atmosphere Radioactive effluents released to the atmosphere from SONGS 2 &3 will result in small radiation doses to the public. NRC staff estimates of the expected gaseous and particulate releases listed in Table 3.3 and the site meteorological considerations discussed in Sect. 2.4 of this statement and summarized in Table 5.1 were used to estimate radiation doses to individuals and populations.

5-23 Table 5.1. Summary of atmospheric dispersion factors and deposition values for selected locations near SONGS 2 & 3" Relative Location SourcJ> X/0 (sec/m 3) deposition (m- 2 )

Nearest site land boundary (0.36 mile N NW)c A 5.4 E-0 2.1 E-7 B 2.4 E-0 9.3 E-8 Nearest residence and garden (1.3 mile NNW)c A 4.8 E-6 2.0 E-8 B 1.7E-6 6.9 E-9 0

The doses presented in the following tables are corrected for radioactive decay and cloud de*

pletion from deposition, where appropriate, in accordance with Regulatory Guide 1.111, Rev. 1, "Methods for Estimating Atmospheric Transport and Dispersion of Gaseous Effluents in Routine Releases from Light Water Reactors," July 1977.

bSource A is gas decay tank, 48 purges per year, 12 hr per purge; source 8 is continuous release.

c"Nearest" refers to that type of location where the highest radiation dose is expected to oc*

cur from all appropriate pathways.

dHere E*x is used to indicate the factor 10-x; i.e., 5.4 E-0 = 5.4 X 10- 5 (To change mi to km, multiply by 1.609.)

Dose commitments to individuals and the population can be estimated using different methodologies.

The staff's assessment of dose is based on a 50-year commitment and is described in Regulatory Guide 1. 109. The results of the calculations are discussed below.

Radiation dose commitments to individuals The predicted dose commitments to the "maximum" individual from radioiodine and particulate releases are listed in Tables 5.2 and 5.3. The maximum individual has been estimated to receive the highest dose commitment from SONGS 2 &3 and is assumed to consume well above average quan-tities of the foods considered (see Table A-2 in Regulatory Guide 1.109). The maximum annual air, total body, and skin doses from noble gas releases are presented in Tables 5.3 and 5.4.

Tibia 5.2. Maximum annual dose commitments to an individual near the SONGS 2 & 3 plant caused by particulate and liquid effluants Dose (millirems per year per unit)

Location Pathway Other organs (if greater Total body Thyroid than 10% of dose)

Iodine and particulate dosas Nearest residence and garden (1.3 NNW)8 Ground deposit 0.66 0.66 NA Inhalation 0.07 0.48 Vegetation 0.40 2.5 Totals 1.1 3.7 Uquid effluent dotes Nearest fish Fish ingestion 0.019 O.Q18 . 0.0016 Invertebrate ingestion 0.0058 0.025 0.104 Shoreline use 0.039 0.039 0.039 Totals 0.064 0.082 0.15

""Nearest" refers to the location where the highest radiation dose to an individual from all applicable path*

ways has been estimated.

{To change mi to km, multiply by 1.609,)

5-24 Table 5.3. Maximum calculated dose commitments to an individual and the population from SONGS 2 & 3" Appendix I Calculated Design objectives doses (Annual dose per reactor unit)

Maximum individual doses Liquid effluents Dose to total body from all pathways, millirems 3 0.064 Dose to any organ from all pathways, millirems 10 0.15 Noble gas effluents (at site boundary)

Gamma dose in air, millirads 10 4.6 Beta dose in air, millirads 20 14 Dose to total body of an individual, millirems 5 2.8 Dose to skin of an individual, millirems 15 8.5 Radioiodines and particulate/'

Dose to any organ from all pathways, millirems 15 3.7 Population doses within 80 km (50 miles)

Total body Thyroid (man*rems) (man-rams)

Natural radiation background" 700,000 Liquid effluents 0.17 0.14 Gaseous effluents 21 46 "Appendix I design objectives from Sects. II.A,II.B,II.C, and 11.0 of Appendix I, 10 CFR 50; considers maximum doses to individuals and population per reactor unit.

Source: Federal Regist. 40, 19442, May 5, 1975.

b Carbon*14 and tritium have been added to this category.

c"Natural Radiation Exposure in the United States," U.S. Environmental Protec*

tion Agency, ORP*SID-72*1 (June 1972); using the average State of California back*

ground dose. of 97 millirems per year and year 2000 projected population of 262 million.

Table 5.4. Annual total*body, skin, and air doses at the nearest site boundary of SONGS 2 & 3 caused by gaseous radioactive effluents" Dose (millirem per year per unit)

Location Total body Skin Gamma air dose Beta air dose Nearest site boundary (0.36 mile WNW)8 2.5 8.3 4.2 14

""Nearest" refers to that site boundary location where the highest radiation doses caused by gaseous effluents have been estimated to occur.

(To convert mi to km, multiply by 1.6.)

Radiation dose commitments to populations The calculated annual radiation dose commitments to the population within 80 km (50 mi) of SONGS 2 and 3 from gaseous and particulate releases are presented in Table 5.3. Estimated dose commitments to the U.S. population are presented in Table 5.5. Background radiation doses are provided for comparison.

Within 80 km of the plant site, specific meteorological, populational, and agricultural data for each of 16 compass sectors around the plant were used to evaluate the doses. Beyond 80 km, meteorological models were extrapolated by assuming uniform dispersion of noble gases and continued deposition of radioiodines and particulates until no suspended radionuclides remained. Doses were evaluated using average population densities and food production values discussed in Appendix B. The doses from atmospheric releases during normal operation repre-sent an extremely small increase in the normal population dose from background radiation sources.

5-25 Table 5.5. Annual total*body population dose commitments in the year 2000 Category U.S. population dose commitment for the site Natural background r.adiation, man*rems per year" 27,000,000 SONGS 2 & 3 operation, man-rems per year per site Plant workers 2600 General public Gas and particulates 160 Liquid effluents <I.

Transportation of fuel and waste 14 a using the average U.S. background dose of 102 man*rems per year and year 2000 projected U.S.

population from "Population Estimates and Projections," Series II, U.S. Department of Commerce.

Bureau of the Census, Series P-25, No. 541 (February 1975).

5.5. 1.3 Dose commitments from radioactive liquid releases to the hydrosphere Radioactive effluents released to the hydrosphere from SONGS 2 & 3 during normal operation will result in small radiation doses to individuals and populations. The staff estimates of the expected liquid releases listed in Table 3.2 and the site hydrological considerations discussed in Sect. 2.3 of this statement and summarized in Table 5.6 were used to estimate radiation dose commitments to individuals and populations. The results of the calculations are discussed below.

Table 5.6. Summary of hydrologic transport and dispersion for liquid releases from SONGS 2 & :r' Location Transit time (hr) Dilution factor Nearest sport 0.1 fishing location (plant outfall)b Nearest shoreline (plant boundary) 0.1 4

See Regulatory Guide 1.112, "Analytical Models for Estimating Radioisotope Concentrations in Different Water Bodies," (1976).

h Assumed for purposes of an upper*limit estimate; de*

tailed information not available.

Radiation dose commitments to individuals The estimated dose commitments to individuals at selected offsite locations where exposures are expected to be largest are listed in Tables 5.2 and 5.3. The standard NRC models given in Regulatory Guide 1.109 were used for these analyses.

Radiation dose commitments to populations The estimated population radiation dose commitments to 80 km for SONGS 2 & 3 from liquid releases, based on the use of water and biota from the Pacific Ocean, are shown in Table 5.3. Dose commit-ments beyond 80 km were based on the assumptions discussed in Appendix B.

Background radiation doses are provided for comparison. The dose commitments from liquid releases from SONGS 2 &3 represent small increases in the population dose from background radiation sources.

5.5.1.4 Direct radiation Radiation from the facility Radiation fields are produced in nuclear plant environs as a result of radioactivity contained within the reactor and its associated components. Doses from sources within the plant are

5-26 primarily due to nitrogen-16, a radionuclide produced in the reactor core. Since the primary coolant of pressurized water reactors is contained in a heavily shielded area of the plant, dose rates in the vicinity of PWRs are generally undetectable (less than 5 millirems per year). Low-level radioactivity storage containers outside the plant are estimated to contribute less than 0.01 millirem per year at the site boundary.

Occupational radiation exposure The dose to nuclear plant workers varies from reactor to reactor and can be projected for environmental impact purposes by using the experience to date with modern pressurized water reactors (PWRs). Most of the dose to nuclear plant workers is due to external exposure to radiation from radioactive materials outside of the body rather than from internal exposure from inhaled or ingested radioactive materials. Recently licensed 1000 MWe PWRs are designed and operated in a manner consistent with the new (post-1975) regulatory requirements and guidelines. These new requirements and guidelines place increased emphasis on maintaining occupational exposure at nuclear power plants as low as is reasonably achievable (ALARA),

and are outlined in 10 CFR Part 20, Standard Review Plan Chapter 12, and Regulatory Guide 8.8.

The applicant's proposed implementation of these requirements and guidelines are reviewed by the NRC staff at the construction permit licensing stage, the operating license licensing stage, and during actual operation. Approval of the proposed implementation of these require-ments and guidelines is granted only after the review indicates that an ALARA program can actually be implemented. As a result of our review the staff has determined that the applicant is committed to design features and operating practices that will assure that individual occupational radiation doses can be maintained within the limits of 10 CFR Part 20 and that individual and population doses will be as low as is reasonably achievable.

On the basis of actual operating experience, it has been observed that this occupational dose has varied considerably from plant to plant, and from year to year. Average individual and collective dose information is available from over 190 reactor-years of operation between 1974 and 1979. These data indicate that the average reactor annual dose at PWRs has been about 410 man-rem, with particular plants experiencing an average annual dose as high as 1300 man-rem. These dose averages are based on widely varying yearly doses at PWRs.

For example, annual collective doses for PWRs have ranged from 18 to 5262 man-rem per reactor.

The average annual dose per nuclear plant worker has been about 0.8 rem.

The wide range of annual doses (18 to 5262 man-rems) experienced by U.S. PWRs is dependent on a number of factors, such as the amount of required routine and special maintenance, and the degree of reactor operations and inplant surveillance. Since these factors can vary in an unpredictable manner, it is impossible to determine in advance a specific year-to-year or average annual occupational radiation dose for a particular plant over its operating lifetime. It is necessary to recognize that high doses may occur, even at plants with radiation protection programs that have been developed to assure that occupational radiation doses will be kept at levels that are ALARA. Consequently, the NRC staff's occu-pational dose estimates for environmental impact purposes for SONGS 2 and 3 are based on the conservation assumption that the station may have an higher than average level of special maintenance work. On the basis of the staff's review of the applicant's Safety Analysis Report, as well as occupational dose data from over 190 PWR reactor operating years, the NRC staff projects that the occupational doses at SONGS 2 and 3 could average as much as 1300 man-rem/yr when averaged over the life of the plant. However, actual year to year doses may differ greatly from this average, depending on actual plant operating conditions.

Transportation of radioactive material The transportation of cold fuel to a reactor, of irradiated fuel from the reactor to a fuel reprocessing plant, and of solid radioactive wastes from the reactor to burial grounds is within the scope of the NRC report entitled "Environmental Survey of Transportation of Radioactive Materials to and from Nuclear Power Plants" [10 CFR 51.20(g)]. The estimated population dose commitments associated with transportation of fuels and wastes are listed in Tables 5.5 and 5.7.

5.5.1.5 Comparison of dose assessment models The applicant's site and environmental data provided in the ER and in subsequent answers to staff questions were used extensively in the dose calculations. Any additional data received which could significantly affect the conclusions reached in this draft statement will be used in preparing the final statement.

5-27 Table 5.7. Environmental impact of transportation of fuel and waste to and from one light-water-cooled nuclear power reactor"*b Range of doses Cumulative dose to Estimated to exposed exposed population Exposed population number of individuals (man*rems per reactor persons (millirems per year)d reactor year)c Transportation workers 200 O.Dl to 300 4 General public Onlookers 1,100 0.003 to 1.3 Along Route 600,000 0.001 to 0.06 3 Accidents in transport Radiological effects Small*

Common (nonradiologicatl causes 1 fatal injury in 100 reactor years; 1 nonfatal injury in 10 reactor years;

$475 property damage per reactor year

• Data supporting this table are given i~ the Commission's Environmental Survey of Transportation of Radioactive Materials to and from Nuclear Power Plants, WASH-1238, December 1972, and Suppl. I, NUREG-75/038, April 1975.

b Normal conditions of transport: heat (per irradiated fuel cask in transit}. 250,000 Btu/hr; weight (governed by Federal or State restrictions), 73,000 lb per truck; 100 tons per cask per rail car; traffic density, <1 per day; rail <3 per month.

cThe Federal Radiation Council has recommended that radiation doses from all sources of radiation other than natural background and medical exposures should be limited to 5000 milirems per year for individuals as a result of occupational exposure and should be limited to 500 millirems per year for individuals in the general population. The dose to in*

dividuals as a result of average natural background radiation is about 102 millirems per year.

dMan-rem is an expression for the summation of whole body doses to individuals in a group. Thus, if each member of a population group of 1000 people were to receive a dose of 0.001 rem (1 millirem). or if 2 people were to receive a dose of 0.5 rem (500 millirems) each, the total man-rem in each case would be 1 man-rem.

"Although the environmental risk of radiological effects stemming from transportation accidents is currently incapable of being numerically quantified, the risk remains small re*

gardless of whether it is being applied to a single reactor or a multireactor site.

(To convert lb to kg, multiply by 0.45; to convert tons to tonnes, multiply by 0,907.)

5.5.1.6 Evaluation of radiological impact The actual radiological impact associated with the operation of SONGS 2 &3 will depend, in part, on the manner in which the radioactive waste treatment system is operated. The staff concludes on the basis of their evaluation of the potential performance of the radwaste system that the system as proposed is capable of meeting the dose design objectives of 10 CFR Part 50, Appendix I.

Table 5.3 compares the calculated maximum individual doses to the dose design objectives. How-ever, because the facility's operation will be governed by operating license technical specifica-tions and because the technical specifications will be based on the dose design objectives of 10 CFR Part 50, Appendix I, as shown in the first column of Table 5.3, the actual radiological impact of plant operation may result in doses close to the dose design objectives. Even if this situation exists, however, the individual doses will still be very small when compared to natural background doses (~lao millirems per year) or of the dose limits specified in 10 CFR Part 20. As a result the staff concludes that there will be no measurable radiological impact on man from routine operation of SONGS 2 & 3.

5.5.2 Radiological impacts to biota other than man Depending on the pathway and the radiation source, terrestrial and aquatic biota will receive doses approximately the same or somewhat higher than man receives. Although guidelines have not been established for acceptable limits for radiation exposure to species other than man, it is generally agreed that the limits established for humans are also conservative for other species.

Experience has shown that it is the maintenance of population stability that is crucial to the survival of a species, and species in most ecosystems suffer rather high mortality rates from natural causes. Although the existence of extremely sensitive biota is possible and increased radiosensitivity in organisms may result from environmental interactions with other stresses (e.g., heat, biocides, etc.), no biota have yet been discovered that show a sensitivity (in terms

5-28 of increased morbidity or mortality) to radiation exposures as low as those expected in the area surrounding SONGS 2 & 3. Furthermore, in all the plants for which an analysis of radiation exposure to biota other than man has been made, there have been no cases of exposures that can be considered significant in terms of harm to the species, or that approach the exposure limits to members of the public permitted by 10 CFR Part 20.19 Since the BEIR Report20 concluded that the evidence to date indicates that no other living organisms are very much more radiosensitive than man, no measurable radiological impact on populations of biota is expected as a result of the routine operation of this plant.

5.5.3 Environmental effects of the uranium fuel cycle On March 14, 1977, the Commission presented in the Federal Register (42 FR 13803} an interim rule regarding the environmental considerations of the uranium fuel cycle. It was effective (by Amend-ment of September 12, 1978) through March 14, 1979 and revised Table S-3 of Paragraph (e) of 10 CFR Part 51.20.* In a subsequent announcement on April 14, 1978, (43 FR 15613}, the Commission further amended Table S-3 to delete the numerical entry for the estimate of radon releases and to clarify that the table does not cover health effects. On July 27, 1979, the Commission approved a final rule setting out revised environmental impact values for the uranium fuel cycle to be included in environmental reports and environmental statements for reactors (44 FR 45362). The final rule reflects new and updated information relative to reprocessing of spent fuel and radioactive waste management as discussed in NUREG-0116, Environmenta~ Survey of the Reprocessing and Waste Management Portions of the LWR Fuel Cycle, 21 and NUREG-0216,2 2 which presents staff responses to comments on NUREG-0116. The rule also considers other environmental factors of the uranium fuel cycle, including aspects of mining and milling, isotopic enrichment, fuel fabrication, and management of low-and high-level wastes. These are described in the AEC report WASH-1248, Environmental Survey of the Uranium Fuel Cycle. 23 Specific categories of natural resource use are included in Table S-3 of the final rule, which is reproduced in this statement as Table 5.8.t These categories relate to land use, water con-sumption and thermal effluents, radioactive releases, burial of transuranic and high- and low-level wastes, and radiation doses from transportation and occupational exposures. The contributions in Table 5.8 for reprocessing, waste management, and trans~ortation of wastes are maximized for either of the two fuel cycles (uranium only and no recycle); that is, the cycle that results in the greater impact is used.

The following assessment of the environmental impacts of the fuel cycle as related to the opera-tion of SONGS 2 & 3 is based on the values given in Table 5.8 and the staff's analysis of the radiological impact from radon releases. For the sake of consistency, the analysis of fuel-cycle impacts has been cast in terms of a model 1000 MWe LWR operating at an annual capacity factor of 80%. In the following review and evaluation of the environmental impacts of the fuel cycle, the staff conclusions would not be altered if the analysis were to be based on the net electrical power output of SONGS 2 &3.

The total annual land requirement for the fuel c~cle supporting a model 1000 MWe LWR is about 46 ha (114 acres). Approximately 5 ha (13 acres) per year are permanently committed land, and 40 ha (100 acres) per year are temporarily committed. (A "temporary" land commitment is a com-mitment for the life of the specific fuel-cycle plant, e.g., mill, enrichment plant, or succeeding plants. On abandonment or decommissioning, such land can be used for any purpose. "Permanent

commitments represent land that may not be released for use after plant shutdown and/or decom-missioning.) Of the 40 ha per year of temporarily committed land, 32 ha (79 acres) are undis-turbed and 9 ha (22 acres) are disturbed. Considering common classes of land use in the U.S.,*

fuel-cycle land-use requirements to support the model 1000 MWe LWR do not represent a significant impact.

The principal water-use requirement for the fuel cycle supporting a model 1000 MWe LWR is that required to remove waste heat from the power stations supplying electrical energy to the enrich-ment step of this cycle. Of the total annual requirement of 43 x 106m3 (11,000 x 106 gal),

about 42 x 106 m3 are required for this purpose, assuminQ that these plants use once-through cooling. Other water uses involve the discharge to air (e.g., evaporation losses in process cooling) of about 0.6 x 106m3 per year and water discharged to ground (e.g., mine drainage) of about 0.5 x 106 m3 per year.

• A notice of final rulemaking proceedings was given in the FederaZ Register of May 26, 1977 (42 FR 26987) that calls for additional public comment before adoption or final modification of the interim rule.

tA narrative explanation of Table 5.8 (Table S-3) was published in the Federal Register (46 FR 15154-75) on March 4, 1981.

• A coal-fired power plant of 1000 MWe capacity using strip-mined coal requires the distur-bance of about 81 ha (200 acres) per year for fuel alone.

5-29 Table 5.8. Summary of environmental consideratkml for uflnium fuel cycle" Normalized to model LWR annual fuel requirement {WASH*1248) or reference reactor year (NUREG*0116)

Natural resource use Total Maximum effect per annual fuel requirement or reference reactor year of modei1QOO..MWe LWR Lond,acm Temporarily commi'tte<i' 100 Undisturbed area 79 Disturbed area 22 Equivalent to 110.MWe coal-fired power plant Permanently committed 7.1 Overburden moved, millions of metric tons 2.8 Equivalent to 95-MWe ooal*fired power plant W1ter, millions of gallons =

Discharged to air 160 Equals 2% of mode11()()()..MWe LWR with cooling tower Discharged to water bodies 11,090 Discharged to ground 127 Total 11,377 less than 4% of mode11000-MWe LWR with once*through cooling FossJI fuel Electrical energy. thoutunds of 321 less tMn 5% of modellOOO.MWe LWR output megawatt hours Equivalent coal,. thousands 117 Equivalent to the consumption of a 45-MWe coal-fired of metric tons power plant Natural gas~ millions of standard cubic feet 135 less than 0.3% of model 1000-MWe energy output Effluents- chemical. metric tons GaHS (including entrainm~t1c so. 4,400 NO,.d 1,190 Equivalent to emissions from 45-MWo coaJ*fired power plant for a year Hydrocarbons 14 co 29.6 Particulates 1,154 Other gases F- 0.67 Prindpally from UF 8 production, enrichment, and reproccuing. Concentration within range of state standards-below level that has effects on human health HCI 0.014 Liquid*

so.~? 9.9 From enrictunent. fuel fabrication. and reproceuing steps. Components that constitute a potential for adverse No3- 25.8 environmental effect are present in dilute concentrations and receive additional dilution by receiving bodies Fluoride 12.9 of water to levels below permissible standards. The constituents that require dilution and the flow of dilu*

ea** 5.4 tion water are:

CI- 8.5 NH 3 -600c:fs Na' 12.1 N03 -20cfs NH3 10.0 Fluoride- 70 c:fs Fe 0.4 Tailings. solutions, tholK8nds of metric tons 240 From mills on(y- no significant effluenu to environment Solids 91,000 Prlncipally from mills- no significant etfl~nts to tmvironment EfffUflttJ - radloloqic41. curiti Gnes (Including entrainment)

Rn*222 Presently under reconsideration by the Commission Ra*226 0,02 Th*230 0,02 Uranium 0.034 Tritium, thousands 18.1 C-14 24 Kr..SS, thouunds 400 Ru*106 0.14 Principally from fuel reproceuing plants 1*129 1.3 1*131 0.83 Tc-99 0.203 rresently under consideration by the Commission Fission products and transuranics Liquidt Uranium and daughters 2.1 Principally from milling - included in tailings liquor and returned to ground- no efflu~nu; thQf'efore. no effect on environment Ra*226 0.0034 From UF 0 production Th*230 0.0015 Th-234 O.Dl From fuel fabrication plants- concentration 10% of 10 CFR Part 20 for total proceuing 26 annuat fuel requirements tor model LWR FIUion and activation products Solids (buried on site)

Othor than high level (shallow) 11,300 9100 Ci come from low*level reactor wastes and 1500 Ci come from reactor decontamination and decommission*

ing - buried at land burial facilities. Mills produce 600 Ci - included in tailings returned to ground; about 60 Ci come from conversion and spent-fuel storage. No significant effluent to the environment TAU and HLW (deep) 1.1 X 10 7 Buried at Federal rePOSitory Effluents- thermal, billions of British 4.063 LtiU than 4% of model 1000-MWe LWR thermal unlu Transportation, ~non*rems 2.5 Exporure at work*rs and ~ol public Occupational e)(powre, person*rems 22.6 From reprocessing and wane management

• tn some castJt where no entry appears, it is clear from the backgt"ound documents that the matter was addressed and that, in effect, this table should be read as if a $J)ecific zero entry h.cJ been made. However, there are other areas that are not addressed at al in this table. Table 5*3 of WASH-1248 does not include health effects irom the effluents described in this table or estimates of releases of Radon-222 from the uranium fuel cycle. These issues which are not addrened at ali by this tabte may be the subject of litigation in individual licensing proc:oedings:. Data supporting this table are given in the Environmental Survey ofrhe Uranium Fuel Cycle, WASH-1248, April 1974; the Environrrumtal SUI'\'VY of the Repi'OCftSing ¥Jd Wute Monagomenr Portion* of the LWR Fuel Cycl*. NUREG-0116 (Suppi. 1 to WASH-1248); and the Ditt:U:sion of Comments Regording the Environmental Surwy of the Rf(JrOCt!fSing and Ware Ma~t Portionr of the LWR Fuel Cycle, NUREG~2T6 {Suppl. 2 to WASH*1248J. The contributions from reprocessing, wane management, and transportation of wanes are rnaximited for either of the two fuel cycles (uranium only and no-recyle). The contribution from transportation excludes transportation of coal fuel to a reactor and of irtadiated fuel and radioactiva wastes from a reactor which .are con:idered in Table S-4 of Sect. 51.20fg). The contributions from the other stops of the fuel cvcf~ are given in columns A- of e Table 5-3A of WASH*1248.

bThe contributions to temporarily committed land from reprocessing are not prorated over 30 years, because the complete temporary impact accrues regardless of whether the plant JetVices 1 reactor for 1 year or 57 reactors for 30 years.

, cEstirnated effluenu based on combustion of equivalent coal for power generation.

d 1.2% from natural gas use and process.

5-30 On a thermal effluent basis, annual discharges from the nuclear fuel cycle are about 4% of those from the model 1000 MWe LWR using once-through cooling. The consumptive water use of 0.6 x 106 ms per year is about 2% of that of the model 1000 MWe LWR using cooling towers. The maximum con-sumptive water use (assuming that all plants supplying electrical energy to the nuclear fuel cycle used cooling towers) would be about 6% of that of the model 1000 MWe LWR using cooling towers.

Under this condition, thermal effluents would be negligible. The staff finds that these com-binations of thermal loadings and water consumption are acceptable relative to the water use and thermal discharges of the proposed project.

Electrical energy and process heat are required during various phases of the fuel-cycle process.

The electrical energy is usually produced by the combustion of fossil fuel at conventional power plants. Electrical energy associated with the fuel cycle represents about 5% of the annual electrical power production of the model 1000 MWe LWR. Process heat is primarily generated by the combustion of natural gas. This gas consumption, if used to generate electricity, would be less than 0.3% of the electrical output from a 1000 MWe plant. The staff finds that the direct and indirect consumption of electrical energy for fuel-cycle operations are small and acceptable relative to the net power production of the proposed project.

The quantities of chemical, gaseous, and particulate effluents with fuel-cycle processes are given in Table 5.8. The principal species are SOx, NOx, and particulates. The staff finds, on the basis of data in a Council on Environmental Quality report,2 4 that these emissions constitute an extremely small additional atmospheric loading in comparison with these emissions from the stationary fuel-combustion and transportation sectors in the U.S., i.e., about 0.02% of the annual national releases for each of these species. The staff believes such small increases in releases of these pollutants are acceptable.

Liquid chemical effluents produced in fuel-cycle processes are related to fuel-enrichment,

-fabrication, and -reprocessing operations and may be released to receiving waters. These effluents' are usually present in such dilute concentrations that only small amounts of dilution water are required to reach levels of concentration that are within established standards.

Table 5.8 specifies the flow of dilution water required for specific constituents~ Additionally, all liquid discharges into the navigable waters of the United States from plants associated with the fuel-cycle operations will be subject to requirements and limitations set forth in an NPDES permit issued by an appropriate state or Federal regulatory agency.

Tailings solutions and solids are generated during the milling process. These solutions and solids are not released in quantities sufficient to have a significant impact on the environment.

Radioactive effluents estimated to be released to the environment from reprocessing and waste management activities and certain other phases of the fuel-cycle process are set forth in Table 5.8. Using these data, the staff has calculated the 100-year involuntary environmental dose commitment* to the U.S. population. These calculations estimate that the overall involuntary total body gaseous dose commitment to the U.S. population from the fuel cycle (excluding reactor releases and the dose commitment due to radon-222) would be approximately 400 man-rems per year of operation of the model 1000 MWe LWR. The additional involuntary total body dose commitment to the U.S. population from radioactive liquid effluents due to all fuel-cycle operations other than reactor operation, estimated on the basis of the values given in Table 5.8, would be approximately 100 man-rems per year of operation. Thus, the estimated involuntary 100-year environmental dose commitment to the U.S. population from radioactive ~aseous and liquid releases due to these portions of the fuel cycle is approximately 500 man-rems (whole body) per year of operation of the model 1000 MWe LWR.

At this time Table 5.8 does not address the radiological impacts associated with radon-222 releases. Principal radon releases occur during mining and milling operations and, following completion of mining and milling, as emissions from stabilized mill tailings and from unreclaimed open-pit mines. The staff has determined that releases from these operations for each year of operation of the model 1000 MWe LWR are as follows:

• The environmental dose commitment (EOC) is the integrated population dose for 100 years; i.e., it represents the sum of the annual population doses for a total of 100 years. The population dose varies with time, and it is not practical to calculate this dose for every year.

5-31 Mining: (during active mining)2S 4060 Ci Mining: (unreclaimed open-pit mines)26 30 to 40 Ci/year Milling and Tai1ings:27 (during active milling) 780 Ci Inactive Tailings: 27 (prior to stabilization) 350 Ci Stabilized Tailings:27 (several hundred years) 1 to 10 Ci/year Stabilized Tailings: 27 (after several hundred years) 110 Ci/year The staff has calculated population dose commitments for these sources of radon-222 using the RABGAD computer code described in Section IV.J of Appendix A of NUREG-0002. 28 The results of these calculations for mining and milling activities prior to tailings stabilization are shown in Table 5.9.

Table 5.9. Estimated 10().year environmental dose commitment per year of operation of me model 1000 MWe LWR Dose commitments (man*remsl Radon-222 releases Lung (bronchial Source Amount (Ci) Total body Bone epithelium!

Mining 4100 110 2800 2300 Milling and active 1100 29 750 620 tailings Total 140 3600 2900 When added to the 500 man-rem total body dose commitment for the balance of the fuel cycle, the overall estimated total body involuntary 100-year environmental dose commitment to the U.S.

population from the fuel cycle for the model 1000 MWe LWR is approximately 600 man-rems. Over this period of time, this dose is equivalent to 0.00002% of the natural background dose of about 3,000,000,000 man-rems to the U.S. population.*

The staff has considered health effects associated with the releases of radon-222, including both the short-term effects of mining, milling, and active tailings and the potential long-term effects from unreclaimed open-pit mines and stabilized tailings. After completion of active mining, the staff has assumed that underground mines will be sealed, with the result that releases of radon-222 from them will return to background levels. For purposes of providing an upper-bound impact assessment, the staff has assumed that open-pit mines will be unreclaimed and has calculated that if all ore were produced from open-pit mines, releases from them would be 110 Ci/year of operation of the model 1000 MWe LWR. However, since the distribution of uranium ore reserves available by conventional mining methods is 66.8% underground and 33.2% open pit,29 the staff has further assumed that uranium to fuel LWRs will be produced by conventional ~ining methods in these propor-tions. This means that long-term releases from unreclaimed open-pit mines will be 0.332 x 110 or 37 Ci/year of operation of the model LWR.

On the basis of these assumptions, the radon released from unreclaimed open-pit mines over 100-and 1000-year periods can be calculated to be about 3700 Ci and 37000 Ci/year of operation of the model reactor, respectively. The total dose commitments for a 100-1000-year period would be as follows:

• Based on an annual average natural background individual dose commitment of 100 mrem and a stabilized U.S. population of 300 million.

5-32 Population dose commitments (man-rems)

Time s~an Total release T~~ Lung (brachial body Bone epithelium) 100 years 3,700 g6 2,500 2,000 500 years 19,000 480 13,000 11,000 1,000 years 37,000 960 25,000 20,000 The above dose commitments represent a worst-case situation since no mitigation circumstances are assumed. However, state and Federal laws currently require reclamation of strip and open-pit coal mines, and it is very probable that similar reclamation will be required for uranium open-pit mines. If so, long-term releases from such mines should approach background levels.

For long-term radon releases from stabilized tailings piles, the staff has assumed that these tailings wquld emit, per year of operation of the model 1000 ~e LWR, 1 Ci/year for 100 years, 10 Ci/year for the next 400 years, and 100 Ci/year for periods beyond 500 years. With these assumptions, the cumulative radon-222 release from stabilized tailings piles per operating year of the model reactor will be 100 Ci in 100 years, 4,090 Ci in 500 years, and 53,800 Ci in 1000 years3o, The total body, bone, and bronchial epithelium dose. commitments for these periods are as follows:

Population dose commitments (man-rems)

Time s~an Total release Total Bone Lung (brochial body epithelium) 100 years 100 2.6 68 56 500 years 4,090 110 2,800 2,300 1,000 years 53,800 1,400 37~000 30,000 Using risk estimators of 135, 6.9, and 22.2 cancer deaths per million man-rems for total body, bone, and lung exposures, respectively, the estimated risk of cancer mortality due to mining, milling, and active tailings emissions of radon-222 would be about 0.11 cancer fatalities per operating year of the model 1000 MWe LWR. When the risk due to radon-222 emissions from stabilized tailings over a 100-year release period is added, the estimated risk of cancer mortality over a 100-year period is unchanged. Similarly, a risk of about 1.2 cancer fatalities is estimated over a 1000-year release period per operating year of the model 1000 MWe LWR. When potential radon releases from reclaimed and unreclaimed open-pit mines are included, the overall risks of radon induced cancer fatalities per operating year of the model 1000 MWe LWR would range as follows:

0.11-0.19 fatalities for a 100-year period 0.19-0.57 fatalities for a 500-year period 1.2-2.0 fatalities for a 1000-year period To illustrate: A single model 1000 MWe LWR operating at an 80% capacity factor for 30 years would be predicted to induce between 3.3 and 5.7 cancer fatalities in 100 years, 5.7 and 17 in 500 years, and 36 and 60 in 1000 years as a result of releases of radon-222.

These doses and predicted health effects have been compared with those that can be expected from natural-background emissions of radon-222. Using data from the National Council on Radiation Protection91, the average radon 222 concentration in air in the contiguous United States is about 150 pCi/m3, which the NCRP estimates will result in an annual dose to the bronchial epithelium of 450 mrem. For a stabilized future U.S. population of 300 million, this represents a total lung dose commitment of 135 million man-rems per year. Using the same risk estimator of 22.2 lung cancer fatalities per million man-lung-rems used to predict cancer fatalities for the model 1000 MWe LWR, estimated lung cancer fatalities alone from background radon-222 in the air can be calculated to be about 3000 per year or 300,000 to 3,000,000 lung cancer deaths over periods of 100 and 1,000 yea!S respectively.

Other nuclides produced in the cycle, such as carbon-14, will contribute to population exposures in addition to the radon-related potential health effects from the fuel cycle. It is estimated that 0:08 to 0.12 additional cancer deaths may occur per operating year of the model 1000 MWe LWR (assuming that no cure or prevention of cancer is ever developed) over the next 100 to 1000 years, respectively, from exposures to these other nuclides.

5-33 These latter exposures can also be compared with those from naturally-occurring terrestrial and cosmic-ray sources, which average about 100 mrem. Therefore, for a stable future popu-lation of 300 million persons, the whole-body dose commitment would be about 30 million man-rems per year, or 3 billion man-rems and 30 billion man-rems for periods of 100 and 1000 years respectively. These dose commitments could produce about 400,000 and 4,000,000 cancer deaths during the same time periods. From the above analysis, the staff concludes that both the dose commitments and health effects of the uranium fuel cycle are insignificant when compared to dose commitments and potential health effects to the U.S. population result-

ng fr*om a 11 natura 1 background sources.

5.6 SOCIOECONOMIC IMPACTS 5.6.1 Introduction A 96-km (60-mile) radius of the San Onofre site circumscribes most of the metropolitan areas of Los Angeles and San Diego, the third and fourteenth largest cities, respectively, in the United States. Between 1970 and 1980, San Diego County had a 37.1% increase in popula-tion, reaching a total of 1,861,846 in 1980 and a density of about 170/km2 (438/m2 ).

'

Continued growth within 96 km (60 miles) of the San Onofre site is expected for the next three decades. The central portion of Orange County and the city of San Diego and its immediate environs are projected to be the major growth areas (ER, Sect. 2.1.3.2.2). The population growth rates within 16 km (10 miles) of the site are expected to fluctuate over the operating life of SONGS 2 and 3. The annual growth rate between 1976 and 1980 is expected to be 4.2%, decreasing to 0.3% between 1990 and 2000, and rising to 1.1% between 2010 and 2020 (ER, Sect. 2.1.3.1.1).

5.6.2 Impact of the construction labor force A peak labor force of about 3000 workers was employed at SONGS 2 and 3 in late 1979. Of this number, the applicant has estimated that about 600 workers (20% of the peak labor force) have relocated to the southern California area (Sect. 2.2.3). Although the staff could not determine the exact location of these workers, current growth projections for the area indicate that the addition of 600 workers represents an insignificant impact. Between 1976 and 1980 the population in the area that is 16 to 80 km (10 to 50 miles) from the site was projected to increase 2.2% (ER, Sect. 2.1.3.2.1). The addition of 600 workers accounts for less than 0.1% of the growth expected during that time period.

Staff interviews with local and regional officials indicated that construction of SONGS 2 and 3 has had no impact on cities within 24 km (15 mi) of the site. Representatives of Southern California Association of Governments stated that it was doubtful that any signif-icant impact attributable to plant construction could be identified in Orange County. The facts that (1) the majority of the work force commuted to site, (2) there was widespread busing to and from Orange County, Oceanside, Vista, Escondido, and San Diego, and (3) the region is currently experiencing rapid population growth support the staff's judgment that no significant social impact has occurred or is likely to occur due to in-migration of construction workers.

Cessation of large construction projects can result in varying degrees of economic disloca-tion to an area, especially if a previously underdeveloped commercial and service structure is expanded to meet the requirements of a large, short-term population influx. The southern California area has a well-developed infrastructure; thus, ending the construction phase of SONGS 2 and 3 is not expected to produce significant economic dislocation.

5.6.3 Impact of the operating labor force The operation of SONGS 2 and 3 will employ about 200 workers. Table 5.10 provides an esti-mate for typical operating personnel requirements and types of employment positions at a two-unit pressurized-water reactor (PWR). The operations positions will be filled first by current members of I.B.E.W. Local No. 246. Positions unfilled will be otfered to all Southern California Edison (SCE) employees, and if the position remains unfilled, SCE will advertise in local and regional newspapers (ER, p. S.2-175). Because of the diversified labor markets of Los Angeles and San Diego, the staff believes that at least 75% of these workers can be hired from within a 96-km (60-mile) radius of the site.

The applicant conducted surveys in March 1976 to determine the residential location of SONGS workers. Seventy-five percent of these workers lived within 40 km (25 miles) of the San Onofre site, and 65% resided in Orange County, 30% in San Diego County, and 5% in Los Angeles and Riverside counties (ER, Appendix SA, p. 10). The surveys further indicated that the cities of Carlsbad, Oceanside, San Clemente, San Juan Capistrano, and Vista were the major

5-34 Table 5.10. Operati!lll perSDnnel for a two-unit PWR Plant superintendent Warehouse staff Assistent plant superintendent 1 Superintendent 2 Safety engineers 1 Assistant superintendent 5 Clerks Quality assurance steff 1 Truck driver 1 Superintendent E1111ineering section 4 Engineers 1 Superintendent 6 Engineering aides 3 Instrument engineers 3 Instrument engineering aides Administrative services 2 Senior instrument mechanic foremen 1 Superintendent 20 Mechanics 1 Assistant superintendent 2 Mechanical engineers 3 Payroll clerks 3 Mechanical engineering aides 9 StenograPhers and file clerks 1 Reactor engineer 7 Janitors 1 Reactor engineering aide 2 Nuclear engineers Industrial engineer 1 Chemical engineer Nurse 9 Chemical engineering aides Health Pflysics staff Maintenance staff 1 Superintendent 1 Superintendent 2 Technicians 1 Assistant superintendent (electrical}

1 Clerk 1 Assistant superintendent (mechanical) 2 Mechanical maintenance engineers Security staff 1 Electrical maintenance engineer 1 Superintendent 3 Engineering aides 1 Assistant superintendent 9 Security officers Tr;ldes and labor staff 1 Machinist foreman Operations 11 Machinists Control room steff 1 Boiler*maker foreman 1 Superintendent 5 Boiler makers 1 Assistent superintendent 1 Steam-fitter foreman 1 Training coordinator 12 Steam fitters 5 Clerks 1 Electrician foreman 6 Shift engineers 10 Electricians 10 Assistant shift engineers 1 Labor foreman 15 Unit operators 10 Laborers 18 Assistant unit operators 2 Truck drivers 2 carpenters Communications engineering steff 2 Sheat metal workers 2 Engineers 2 Painters 3 Engineering aides 2 Insulators 1 Structural iron worker Source: Tennessee Valley Authority, Department of Planning, Chattanooga, Tenn.,

1977.

communities of worker residence. The staff estimates that approximately the same pattern of location will occur with SONGS 2 and 3 workers as* occurred with SONGS 1 workers.

Between 1973 and 1980, northern San Diego County was expected to have a population increase of about 22,000. From 1975 to 1980 southern Orange County was projected to grow by about 21,000 persons. Assuming that all operations workers relocated to the area, the staff concludes that the addition of 200 workers and their households represents a negligible effect.

The staff cannot determine precisely the number of workers who will (1) relocate from outside the a~ea or (2) choose to move from within the 96-km (60-mile) radius to a residence closer to the plant. In order to predict the*maximum possible impact on housing in the area, the staff assumes that all of the workers will relocate and thus require housing. A relocating operations force will likely demand permanent housing. From Table 5.11, it appears that housing availability in Orange and San Diego counties is sufficient to provide diversity in location for all operations workers' households. The table further indicates that, based on the number of vacant units in 1976, a surplus of housing exists in each of the communities expected to house workers.

Estimates on the location of SONGS 1 worker indicate SONGS 2 and 3 households will likely contribute to increased enrollments in the school districts of Carlsbad, Capistrano, Oceanside, Saddleback Valley, and Vista. The total additional *enrollment at all five school districts

5-35 Table 5.11. Housing availability in Orange and San Diego counties Number of Residential dis* vacant units as Number of existing Communities t~ibution of house-indicatad by dwelling units holds SONGS 2 & 3 number of idle as of Jan. 1, 1976 electric meters for Jan. 1, 1976 Orange County total 127 592,932 10,080 San Clemente 32 10,636 170 San Juan Capistrano 41 4,561 73 Saddleback (Irvine) 22 11,102 178 Other unincorporated areas 32 76,260 1,220 San Diego County total 61 547,708 8,783 Carlsbad 11 9,111 200 Oceanside 25 20,835 458 Vista 20 12,539 276 Other unincorporated areas 5 108,841 2,395 Source: ER, Suppl. 2, Table 89-A, p. S.2-178.

will be about 105 students (ER, Appendix A, p. 20). The community college districts of Oceanside-Carlsbad, Palomar, and Saddleback will likely increase their enrollments by approx-imately 20 to 25 students (ER, Appendix SA, p. 20). The staff concludes that this estimated increased enrollment represents a negligible impact on the school districts.

Operations employment at SONGS 2 and 3 will be relatively high-paying, stable work. About 87% of the total work force will have gross incomes in excess of $15,000 per year (ER, Appendix 8A, p. 15). The annual average income in 1976 dollars for a SONGS 2 and 3 household will be about $20,800. This compares to a median family income in 1980 for San Diego and Orange counties of $21,500 and $26,200 respectively. SONGS 2 and 3 households are expected to contribute to the economic activity of the area. Total taxable retail expenditures by households of operations employees are estimated to be about $855,000 per year (ER, p. 5.2-176).

In addition, those workers who build homes will contribute further to the economic activity of the area.

5.6.4 Economic impacts The staff believes that the major economic impact associated with the operation of SONGS 2 and 3 will be a result of tax revenues generated by the plant. These taxes include property tax, state income tax, utility users tax, franchise tax payments, and sales and use taxes.

The analysis presented here differs from that presented earlier in the DES by taking into account the impacts of the Jarvis-Gann Amendment (Proposition 13). The following discussion is based on two important assumptions. (1) The method of determining xhe value of state-regulated utility systems, currently before the State Court of Appeals, will be decided in accordance with the decision of the State Board of Equalization. Accordingly, SONGS 2 and 3 will be assessed on current market value, based on historical methods of valuation rather than on the 1975-76 base year as prescribed in Proposition 13. (2) The allocation of tax revenues among the various funds and districts within the county will remain roughly the same as at present. 32 Changes in either of the above conditions in the future may result in significant variation from the situation described here.

Under Proposition 13, neither the assessed value of the SONGS 2 and 3 units nor their annual tax liability differs greatly from the figures presented in the DES. Earlier projections were for an assessed valuation of $348 million in 1976 dollars (ER, Appendix 8-A, p. 4) and an annual property tax payment of $13.1 million (DES, Sect. 5.6.4). Current calculations show an eventual assessed value of $326 million in 1979 dollars and an annual tax of approxi-mately $13 million (Table 5.12). At present, current construction at SONGS 2 and 3 is already assessed at roughly $100 million and is generating $4 million yearly in property tax revenues.

The remaining $9 million in property taxes will be added as construction is completed. 32 While the total tax burden is not significantly different under the terms of Proposition 13, the distribution of the resulting revenues is. Previously, it was projected that nearly all of the

$13 million in property taxes generated by SONGS 2 and 3 would go to the County General Fund, the County Library Fund, and three local school districts in the immediate vicinity of the plant-Fallbrook Union Elementary, Fallbrook Union High, and Palomar Community College (DES,

5-36 Table 5.12. Projected impacts of SONGS 2 & 3 on San Diego County property tax revenues San Diego County SONGS2&3 Total: County plus SONGS2&3as SONGS 2 & 3  % of total Assessed value $7,775.5 million' $326 million* $8,101.5 rpillion 4.0%

Annual taxes $311 millioo2 $13 million* $324 million 4.0%

'For FY 1978-79, not counting $100 million of SONGS 2 ~ 3 construction currently on tax rolls.

2 For FY 1978-79, not counting ~4 millfon currently received for SONGS 2 & 3 construction.

3 As of project completion, in 1979 dollars.

Source: Letter from J. H. Drake, Southern California Edison Co., toW. H. Regan, Jr., U.S. NRC, dated April 17, 1979.

Sect. 5.6.4). Now, however, the ,new revenues will be distributed throughout the county on the basis of the historical property tax revenue relationships between all the various funds and districts. Accordingly, the five entities named above will receive roughly one-fourth of the plant-induced taxes, or $3.4 million, because this is the proportion of all county funds they have traditionally received. The remaining $9.6 million will go to other recipients county-wide. Because of this widespread distribution, the property taxes paid by SONGS 2 and 3 will not bring a large windfall to any single district but, rather, a modest 4.0%

increase to all county funds and districts over pre-construction receipts (2.9% over the present situation where $100 million of plant construction is already on the tax rolls).

The debt service rate of the three previously named school districts will be reduced as a result of plant induced revenues but this represents a very small part of the total property tax. 32 Sales and use taxes payable to the State of California are levied at 6% of the retail or use value of fixtures, equipment, machinery, and materials purchased either in or outside of the State of California and placed in use within the state. For every 6 cents collected, 1.25 cents is allocated to counties and cities. The state tax on nuclear fuel for SONGS 2 and 3 is expected to be about $2.5 million per year. In addition, $415,000 in sales tax for materials will be paid in 1981, the first year of operation (ER, Appendix SA, p. 8).

Over the operating life of SONGS 2 &3, about $66 million in California state corporate income taxes will be paid by the applicant. California also has a City Utility Users Tax that, although it is difficult to determine the proportion for which SONGS 2 & 3 are directly responsible, is estimated to increase by $1.6 million per year (ER, Appendix SA, p. 8).

This tax varies for each city, and the revenues are not earmarked for any particular purposes.

The California Energy Resources Surcharge is included in the retail customer's bill and is collected by the utility. The current surcharge is $0.00015 per kilowatt-hour. The revenues collected are placed in the State Energy Resources Conservation and Development Special Account in the General Fund in the State Treasury by the State Board of Equalization. All funds in the account are to be expended for the purpose of carrying out the provisions of the Warren-Alquist State Energy Resources Conservation and Development Act.

5.6.5 Impact on recreational resources In the early 1960s the applicant secured a leasehold from the U.S. Marine Corps at Camp Pendleton. During construction of SONGS 1, the Marine Corps released about 5.6 km (3.5 miles) of beach front to the State of California to be maintained as San Onofre State Beach. When this park opened in 1971, an additional 2440 m (8000 ft) of beach front had gained public access. Of this, 1370 m (4500 ft) are on the applicant's leasehold and the remaining 1070 m (3500 ft) are immediately north of the plant site, comprising another section of the state beach.

In order to comply with NRC regulations regarding the siting of nu~lear power plants set forth in 10 CFR Part 100, the applicant proposes to control recreational activities on the beach for*a distance of about 1.4 km (0.85 mile) adjacent to the station (ER, Sect. 2. 1.2).

Access to this area will be permitted for the purpose of viewing the barrancas and bluffs south of the station and for pedestrian passage between the public beach areas north and south of the station. Recreational activities, such as sunbathing or picnicking, will not be permitted within the landward portion of this restricted area. To facilitate passage between the beaches, a walkway will be constructed through the restricted area adjacent to the seawall. This walkway will be 4.6 m (15 ft) wide, will be bounded by a 2.4-m (8-ft) chain link fence, and will be used only for passage through the restricted area. It is the judgment of the staff that the fence proposed by the applicant is inappropriate in light of the scenic nature of the area and that a less aesthetically objectionable way should be

5-37 sought to restrict access to the beach. Therefore, it is recommended that the applicant consider alternate methods of beach enclosure that will safely restrict access in a manner compatible with the scenic nature of this area.

In the Final Environmental Statement required for the construction permit of SONGS 2 and 3, the staff stated, "Use of the beach will not be restricted after construction is complete" (FES-CP, p. 2-11). The current plan to restrict use of approximately 1.4 km (0.85 mile) of the beach front for the 30-year operating life of the plant is a significant loss of valuable recreational and scenic space and represents a substantial change in action between issuance of the FES-CP and application for an operating license. The staff further stated, "The beach in the vicinity of the Station (5639 m (18,500 ft) south and 1036 m (3400 ft) north) is considered to be a unique and scarce recreational resource,"

(FES-CP, p. 2-11) and "Closure for even a brief period is objectionable" (FES-CP,

p. 8-1). The loss of this resource precludes recreational benefits to significant numbers of beach users in the vicinity of San Onofre Beach. The staff reiterates those judgments and concludes that the current plan to restrict the public's use of this beach is a signif-icant cost of the project, unanticipated at issuance of the construction permit. This impact is not sufficiently adverse, however, to warrant denying an operating license.

While all state beaches in the Pendleton coast area experienced increased usage in recent years, the attendance at San Onofre State Beach has risen significantly faster than at the other facilities. Between 1972 and 1978, the annual number of visits to the San Onofre State Beach rose by 98% while San Clemente and Doheny State Beaches showed increases of 46% and 25%, respectively (ER, Appendix SA, Table 24, and Reference 32). As demand on available recreational resources increases, the significance of removing the beach in front of SONGS 2 & 3 from unrestricted public use will increase.

5.6.6 Emergency planning impacts The applicants are currently revising the Emergency Plan, San Onofre Nuclear Generating Station Units 2 and 3 in accordance with 10 CFR Part 50, as amended July 23, 1980, as well as the recommended criteria contained in NUREG-0654. The staff believes the only noteworthy potential source of impact on the public from emergency planning would be associated with the siren alert system. The system will be designed to provide a minimum lOdb dissonant differential from the ambient noise levels. The maximum sound level received by any member of the public should be lower than 123db. A complete cycle test will be required annually. The test requirements and alarm noise levels are consistant with those used for existing alert systems; therefore the staff concludes that the noise impacts associated with the siren alert system will be infrequent and insignificant.

5.6.7 Summary and conclusion The staff concludes that, with the significant exception of restricting public use of 1.4 km (0.85 mi) of the San Onofre beach, the social and economic impact of operating SONGS 2 & 3 will be moderate. The large population within 96 km (60 miles) of the site and the projected population growth in the area is such that the addition of all 200 workers and their families would represent negligible impact to the area. Under the terms of Proposition 13, the property tax revenues received by the various funds and districts in San Diego County will be relatively small in proportion to existing revenues.

5-38 REFERENCES Escept as specifically noted, documents cited can be obtained through the listed publisher or public technical libraries.

1. B. M. Kilgore, U.S. Department of the Interior, National Park Service, letter dated May 13, 1977, to Division of Site Safety and Environmental Analysis, Nuclear Regulatory Commission.*

2. R. C. Y. Koh, N. H. Brooks, E. J. List, and E. J. Wolanski, "Hydraulic Modeling of Thermal Outfall Diffusers for the San Onofre Nuclear Power Plant," W. M. Keck Laboratory of Hydraulics and Water Resources, California Institute of Technology, Report KH-R-30, January 1974.*

3. "Energy Division Annual Progress Report," Report ORNL-5364, Oak Ridge National Laboratory, Oak Ridge, Tenn., April 1978.

4. Intersea Research Corporation, "Current Meter Observations and Statistics Off San Onofre Nuclear Generating Station, Jan. 5-Nov. 22, 1972," January 1973.*

5. C. D. Winant, R. E. Davis, and R. W. Severance, "A Study of Physical Parameters in Coastal Waters Off San Onofre, California, Final Report 1977," Scripps Institution of Oceanography, University of California, SIO Reference 77-ll, June 31, 1977.

6. "Current Meter Observations and Statistics Off San Onofre Nuclear Generating Station, 5 January- 22 November 1972," Intersea Research Corporation, January 1973.*

7. R. C. Y. Koh, "Estimation of Drift Flow at San Onofre," memo to Southern California Edison Company, June 12, 1978.*

8. C. W. Almquist and K. D. Stolzenbach, "Staged Diffusers in Shallow Water," Report No. 213, Ralph M. Parsons Laboratory for Water Resources and Hydrodynamics, Massachusetts Institute of Technology, Cambridge, Mass., 1976 (also C. W. Almquist, personal communi-cation, February 22, 1979).

9. G. F. Schiefelbein, "Alternative Electrical Transmission Systems and Their Environmental Impact," Report NUREG-0316, U.S. Nuclear Regulatory Commission, Washington, D.C., August 1977.**

10. Lockheed Center for Marine Research, "San Onofre Nuclear Generating Station Unit 1, Environmental Technical Specifications, Annual Operating Report, Vol. 11, Biological Data - 1977," March 1978. *

11. R. F. Ford and others, "Effects of Thermal Effluents on Marine Organisms, Annual Report for Phase II," Southern California Edison Co., Research and Development Series No. 76-RD-90, 1976.*

12. E. Y. Dawson, Marine Botany, Holt, Rinehart and Winston, Inc., New York, 1966.

13. R. C. Phillips, "Kelp Beds," in Coastal Ecological Systems of the United States, Vol.

II, H. T. Odum, B. J. Copeland, and E. A. McMahan, eds., The Conservation Foundation, Washington, D.C., 1974, pp. 442-87.

14. G. A. Jackson, "Nutrients and Production of Giant Kelp, Macrocystis pyrifera, off Southern California," Limno1. Oceanogr. 22: 979-995, 1977.

15. California Coastal Commission Marine Review Committee, "Annual Report to the California Coastal Commission, August 1976-August 1977, Summary of Estimated Effects on Marine Life of Unit 1 San Onofre Nuclear Generating Station," MRC Document 77-09 no. 1, September 1977.*

16. J. S. Mattice and H. E. Zittel, "Site-specific Evaluation of Power Plant Chlorination,"

J. Water Pollut. Control Fed. 48: 2284-2308, 1976.

17. U.S. Nuclear Regulatory Commission, "Calculations of Release of Radioactive Materials in Gaseous and Liquid Effluents from Pressurized Water Reactors (PWR-GALE Code),"

USNRC Report NUREG-0017, April 1976.**

18. U.S. Nuclear Regulatory Commission, "Occupational Radiation Exposure to Light Water Cooled Reactors 1969-1974," USNRC Report NUREG 75/032, June 1975.**

5-39

19. B. G. Blaylock and J. P. Witherspoon, "Radiation Doses and Effects Estimated for Aquatic Biota Exposed to Radioactive Releases from LWR Fuel-Cycle Facilities," Nucl. Safety 17: 351, 1976).

20. "The Effects on Population of Exposure to Low Levels of Ionizing Radiation (BEIR Report),"

National Academy of Science/National Research Council, 1972.*

21. U.S. Nuclear Regulatory Commission, "Environmental Survey of the Reprocessing and Waste Management Portions of the LWR Fuel Cycle," USNRC Report NUREG-0116 (Supplement 1 to WASH-1248), October 1976.**

22. U.S. Nuclear Regulatory Commission, "Public Comments and Task Force Responses Regarding the Environmental Survey of the Reprocessing and Waste Management Portions of the LWR Fuel Cycle," Report NUREG-0216 (Supplement 2 to WASH-1248), March 1977.**

23. U.S. Atomic Energy Commission, "Environmental Survey of the Uranium Fuel Cycle," Report WASH-1248, Washington, D.C., April 1974.***

24. Council on Environmental Quality, "Seventh Annual Report," September 1976, Figs. 11-27, 11-28, pp. 238-239.***

25. U.S. Nuclear Regulatory Commission, In the Matter of Duke Power Company (Perkins Nuclear Station), Docket No. 50-488, Testimony of R. Wilde, filed April 17, 1978.*

26. U.S. Nuclear Regulatory Commission, In the Matter of Long Island Lighting Company (Jamesport Nuclear Power Station), Docket No. 50-516, Deposition of Leonard Hamilton, Reginald Gotchy, Ralph Wilde, and Arthur R. Tamplin, July 27, 1978, p. 9274.*

27. U.S. Nuclear Regulatory Commission, In the Matter of Duke Power Company (Perkins Nuclear Stat*ion), Docket No. 50-488, Testimony of P. Magno, filed April 17, 1978.*

28. U.S. Nuclear Regulatory Commission, "Final Generic Environmental Statement on the Use of Recycle Plutonium in Mixed Oxide Fuel in Light-Water-Cooled Reactors," USNRC Report NUREG-0002, Washington, D.C., August 1976.~*

29. U.S. Department of Enet*gy, "Statistical Data of the Uranium Industry," Report GJ0-100(78),

January 1, 1978.***

30. U.S. Nuclear Regulatory Commission, In the Matter of Duke Power Company (Perkins Nuclear Station), Docket No. 50-488, Testimony of R. Gotchy, filed April 17, 1978.*

31. National Council on Radiation Protection and Measurements, Publication 45, 1975.

32. Letter from J. H. Drake, Southern Californ-ia Edison Co . , toW. H. Regan, Jr., U.S.

NRC, dated April 17, 1979.*

• Available for inspection and copying for a fee in the NRC Public Document Room, 1717 H St., NW.,

Washington, DC 20555.

• • Available from the NRC/GPO Sales Program, Washington, DC 20555, or the National Technical Information Service, Springfield, VA 22161.

• • • Available from NTIS only.

6. ENVIRONMENTAL MONITORING 6.1

SUMMARY

The applicant has expanded its San Onofre Unit 1 environmental monitoring program (biological, chemical, physical, and thermal) to determine environmental effects which may occur as a result of site preparation and construction of Units 2 and 3 and to establish an adequate preoperational baseline by which the operational effects of Units 2 and 3 may be judged.

The aquatic preoperational environmental monitoring program for SONGS 2 and 3 was approved by NRC and implemented by the applicant in April 1978. The NRC-approved program terminated in September 1980. However, all NPDES permit monitoring program requirements will continue to be met until an approved operational monitoring program is implemented.

Results of the preoperational monitoring program will be used in formulating the opera-tional monitoring program, which the applicant will submit for approval by the California Regional Water Quality Control Board to be incorporated in the NPDES permit monitoring program.

The environmental monitoring programs presented here differ somewhat from the description in the FES-CP. More detailed information is given here than in the FES-CP. Two state agencies, the California Regional Water Quality Control Board and the California Coastal Commission, have imposed environmental monitoring requirements in the vicinity of the San Onofre Station. NRC has discussed the results of its environmental review with the State agencies and has provided the State with recommendations for monitoring. The sections which follow include NRC staff recommendations based on its environment~

review. However, requirements for non-radiological monitoring of the aquatic environment will be the responsibility of the State.

6.2 PREOPERATIONAL ENVIRONMENTAL PROGRAMS The results from the preoperational monitoring program for Units 2 and 3 will be submitted with the Annual Operating Report for Unit 1.

6.2.1 Aquatic biological monitoring program The applicant's preoperational aquatic biological monitoring program was designed to determine the species composition, abundance, and the temporal and spatial distribution of phytoplanKton, zooplanKton, ichthyoplanKton, neKton, benthos, Kelp beds, and intertidal organisms. The data obtained will be used to provide a basis for comparison with future operational monitoring data to determine if plant operation has caused observable pertur-bations ;, the ecosystem.

The possible operational impacts identified in this document and the FES-CP include:

changes in local planKton populations due to entrainment; changes in the abundance of fish eggs, larvae, juveniles, and adults due to entrainment; adult fish population shifts due to fish impingement; alterations in some of the benthic and fish communities from thermal discharges; and changes in benthic and planKtonic communities from increased turbidity. Thus, results from the preoperational and operational monitoring programs will be used to determine the extent to which the above effects occur.

6.2.1.1 PhytoplanKton and zooplankton Phytoplankton and zooplankton were sampled bimonthly. Samples were collected from at least four fixed stations, one each in zones OB, 1B, 2B and 6 (Figure 6.1). A pump system is used to sample the water column and a 202 ~m mesh-size screen is used to collect the zooplankton. Zooplankton biomass is determined and predominant species are enumerated. Chlorophyll analyses are performed on whole-water samples. Collections are coordinated, as much as possible, with the collection of pertinent physical data such as temperature, ~ransparency, and current velocity and direction.

6-1

6-2 0 PLANKTON t:. FISii 0 BENTHIC 1 .5 0 ES-4560 0 TEMPERATURE PROFILES AND TURBIDITY 0 CONTINUOUS TEMPERATURE t:. DO, pli AND HEAVY METALS 5 .:L 1 .II 0 Fig. 6.1. Environmental monitoring stations for SONGS 2 and 3 preoperational monitoring program. Source: ER, Apendix 6A, Figs. 1 and 2.

6-3 The staff recommends that predominant phytoplankton genera also be enumerated to provide baseline conditions for this group. This would enable, for example, the determination of whether operation of the facility promotes red tide development (see Sect. 5.3.2, FES-CP).

6.2.1.2 Ichthyoplankton Ichthyoplankton will be collected monthly at two stations in the Units 2 and 3 discharge area, zone OB, and at two stations in the reference area, either zone 5 or 6. Additionally, the Unit 1 intake area will be sampled. The study began approximately two years prior to initial operation of Unit 2 and lasted one year. Sampling was conducted during the day, at night, at dawn, and at dusk at the intake; night sampling was employed at the other locations. The water surface, water column, and epibenthos was sampled at each station. Fish larvae were identified to the lowest taxon possible and enumerated. Fish eggs were sorted and enumerated ..

A study by the Marine Review Committee (MRC) was initiated in July 1976 (see Section 6.4.2) to assess the distribution, abundance, and entrainment of ichthyoplankton at SONGS 1.

It is expected that data acquired from this work will also help characterize the SONGS 2 and 3 environment.

6.2.1.3 Nekton Replicate fish samples were collected on a quarterly basis from at least two stations in zone OB, two in zone 5, two in the control zone, zone 6 (Figure 6.1). The gill nets used were 2- by 46-m (6- by 150-ft) full size, containing six 7.5-m (25-ft) panels of 19.05-,

25.4-, 31.75-, 38.1-, 44.5-, and 63.5-mm (3/4-, 1-, 1-1/4-, 1-1/2-, 1-3/4-, and 2-1/2-in.)

bar mesh. The fish were measured, their state of health was assessed, and sexual matura-tion was determined on subsamples. Synoptic measurements of temperature and transmissivity were taken at each station.

6.2.1.4 Benthos Benthic samples were .collected quarterly at at least two stations within each of zones OB, 28, 6 and 5 (or zones 3A and/or 38) (Fig. 6.1). Permanent sampling stations exist in which a 6-m 2 (64.56*ft2) sampling area has been established. Each sampling area contains '300 evenly spaced contact points which are used to estimate the distribution and relative abundance of sessile invertebrates, large motile invertebrates and macrophytes.

Species enumeration and substrate type are recorded for each contact point. Additionally, four 0.125 m2 (1.35-ft2) quadrants are randomly placed within the sampling area to evaluate the distribution and abundance of small, clumped, or patchily distributed organisms.

General observations to be recorded during sampling include: quantity and composition of drift algae, conspicuous or sparsely distributed biota not sampled with the point contact method, and substrate alteration (e.g., increased sedimentation). Selected species which are enumerated will be measured, and their general condition recorded.

Procurement of some of the physical data, such as temperature and turbidity, will be coordinated with the benthic sampling program.

6.2.1.5 Intertidal organisms Although not a required component of the preoperational monitoring program, quarterly observations were made along cobble intertidal transects at four monitoring stations and one control station. Predominant macroscopic species and substrate composition were identified and enumerated within three permanent 0.25-m2 (2.69-ft 2 ) quadrats along a line perpendicular to the beach. Photographs were also taken of each quadrat for a permanent record of any possible ecological changes.

The staff believes that it is unnecessary to begin the intertidal sampling program until the time of removal of the construction apron from SONGS 2 and 3 (See FES-CP, Sect. 4.3.2,

p. 4-9). At that time the intertidal monitoring program should be reinstated to assess the effect of the added sand movement in the intertidal zone. Provided the data show no significant effects, this program may be terminated after all translocation of sand has occurred or after two years. Until the time of apron removal, visual inspection of the intertidal zone will be sufficient, with biological sampling and laboratory analysis initiated only if needed. Deletion of the intertidal program may be reasonable during operational monitoring because of the extensive impact sustained by the intertidal area from activities unassociated with SONGS (Sect. 2.5.2.4) and because of the unlikely potential for any significant impact resulting from SONGS operation.

6-4 6.2.1.6 Kelp beds The three kelp beds, San Mateo, San Onofre, and Barn, located near SONGS (Fig. 6.1) are being studied. A brief outline of the scope of effort at the three kelp beds is as follows:

1. Three benthic stations are located in and about the San Onofre kelp bed and one each at Barn kelp and San Mateo kelp. Stations are quantitatively assessed quarterly.

2. Kelp canopies and rock substrate are mapped for areal extent on a quarterly basis.

3. Water nutrient analysis for ammonia, nitrates, nitrites, and phosphate are taken monthly at all three beds. Water samples are taken from the surface and bottom from within each bed and offshore of each bed. An additional offshore station serves as a monitoring area for upwelling.

4. Kelp tissue analysis for nutrient content is conducted on a monthly basis at all three kelp beds. Each leaf is analyzed for nitrogen content.

5. An assessment of the health of-the kelp plants in the three beds is made on a quarterly basis. Parameters assessed include: success of juvenile recruitment, density of kelp plants, amount of encrusting organisms and grazing by herbivores and abundance of senile and diseased plants.

6. Aerial infra-red photographs of the three kelp bed canopies will be taken on a monthly basis.

6.2.2 Water quality monitoring program The preoperational water quality monitoring program is an expansion of the existing program required by the Environmental Technical Specifications for SONGS 1. This program is designed to establish baseline characteristics of selected oceanographic parameters for comparison with data obtained during the operation of SONGS. This comparison will allow determination of the extent to which SONGS operation alters water quality. Those parameters identified in the FES-CP and in this document which might be altered. include: pH, temperature, turbidity, certain heavy metals, and dissolved oxygen.

Sea water temperature-depth profiles are measured bimonthly at stations in the area of the Units 2 and 3 diffusers and at a reference station outside of the area of predicted thermal influence. Stations are as follows: two within each of zones lB, 2B, lC, OC, 2C, and 6,

• six stations within zone OB (Fig. 6.1). Additionally, sea water temperatures are continuously monitored near the surface, at mid-depth, and near the bottom at a permanent station in zone OB. Temperatures from each depth are recorded hourly. The accuracy of the system is +/-0.5 degrees centigrade, +/-30 minutes per month.

Turbidity is monitored bimonthly at two stations within each of zones lB, 2B, lC, OC, 2C, and *6, and at six stations within zone OB (Fig. 6.1). The pH is monitored bimonthly at four sampling stations- one in each of zones OB, lB, 2B, and 6. Dissolved oxygen is measured bimonthly at four stations - one in each of zones OB, lB, 2B, and 6.

Mid-depth ocean water samples and grab samples of ocean bottom sediments are collected quarterly in the area of the Units 2 and 3 diffusers and an appropriate control area for analysis of heavy metals. One station in each of zones lB, 2B, OB, and 6 is sampled.

Samples will be analyzed for chromium, iron, and titanium. Copper will not be monitored as the applicant has indicated that SONGS 2 and 3 will have titanium condenser tubing.

The staff considers this program adequate with the following additions: (1) the water quality data should be collected within a two-day period at maximum to permit station-by-station comparisons and the investigation of possible cause and effect relationships, and (2) all control samples should be collected from an area predicted to be unaffected by any discharge effect.

6.2.3 Terrestrial monitoring program The baseline terrestrial environmental monitoring program for the FES-CP was very nominal.

As a condition of the construction permit, the applicant expanded its terrestrial monitoring program to establish an adequate preoperational baseline by which the operational effects of SONGS 2 and 3 may be judged. Biological data were collected seasonally in order to document changes in the biotic communities over a one-year time span. Methods utilized included

6-5 small mammal trapping; bird censusing; observations of reptiles, amphibians, and large mammals; plant species lists; and vegetation analyses using the line intercept and quadrat methods. Results of this expanded monitoring program are presented in Sect. 2.5.1.

The applicant has proposed and is currently monitoring areas of cut and fill associated with construction of the plant and transmission lines to detect areas of erosion (ER, Appendix 6A, Special Studies I). Visual inspections are conducted and documented biweekly; any erosion resulting from the applicant's construction activities will receive appropriate corrective action.

6.2.4 Radiological monitoring program Radiological environmental monitoring programs are established to provide data on measurable levels of radiation and radioactive materials in the site environs. Appendix I to 10 CFR Part 50 requires that the relationship between quantities of radioactive material released in effluents during normal operation, including anticipated operational occurrences, and resultant radioactive doses to individuals from principal pathways of exposure be evaluated.

Monitoring programs are conducted to verify the effectiveness of in-plant controls used for reducing the release of radioactive materials and to provide public reassurance that undetected radioactivity will not build up in the environment. A surveillance program is established to identify changes in the use of unrestricted areas to provide a basis for modifications of the monitoring programs.

The preoperational phase of the monitoring program provides for the measurement of background levels and their variations along the anticipated important pathways in the area surrounding the plant; the training of personnel; and the evaluation of procedures, equipment, and techniques.

This is discussed in greater detail in NRC Regulatory Guide 4.1, Rev. 1, "Programs for Monitoring Radioactivity in the Environs of Nuclear Power Plants," and the Radiological Assessment Branch Technical Position, August 1977, "Standard Technical Specification for Radiological Environmental Monitoring Program."

The applicant has proposed a radiological environmental monitoring program to meet the objectives discussed above. The applicant's proposed preoperational radiological environmental monitoring program is presented in Sect. 6.1.5 of the applicant's Environmental Report.

The applicant proposes to initiate parts of the program two years prior to operation of the facility, with the remaining portions beginning either six months or one year prior to operation.

The staff concludes that the radiological preoperational monitoring program proposed by the applicant is acceptable.

6.2.5 Onsite meteorological monitoring programl* 2 *3 The original onsite meteorological program began in late 1964 with wind measurements at the top of a 19.5-m (64-ft) mast. In December 1970, the current meteorological monitoring program began with the installation of a 36.6-m (120-ft) tower atop the coastal bluff about 100 m (330 ft) west-northwest from the Unit 1 containment and 420 m (1380 ft) west-northwest of the Unit 2 containment. In October 1975 the tower was extended to a height of about 43 m (140ft). Table 6.1 describes the kinds of measurements and their elevations on the tower between 1970 and the present.

Southern California Edison Company also conducted an onshore tracer test program at the San Onofre site. Among the objectives of the program were (1) to evaluate the appropriateness of using data measured on the existing site meteorological tower located on the coastal bluff for making dispersion estimates for onshore flows, and (2) to characterize dispersion representative of meteorological conditions during routine plant releases. NUS-19273 describes the test program and data.

On the basis of our analysis of the test data, we conclude that the wind and vertical temperature data measured on the San Onofre onsite (bluff) tower are acceptable for use in calculating atmospheric dispersion estimates for the* site vicinity using the staff's model, described in Sect. 2.4.4.

6-6 Table 6.1. SONGS onsite meteorological instrumentation Elevation above ground Period Measured parameter Meters Feet December 1970-January 1973 Wind direction, speed 36.6 120 and standard deviation Dry bulb vertical temperature 36.6-6.1 120-20 gradient January 1973-0ctober 1975 Wind direction and speed 10.36.6 33, 120 Wind direction standard 36.6 120 deviation Dry bulb temperature8 6.1 20 Wet bulb temperaturJ' 6.1 20 Dry bulb vertical gradient 36.6-6.1 120-20 October 1975-present Wind direction and speed 10, 20,c 40 33,66,131 Wind direction standard 10 33 deviation Dry bulb temperature 10 33.

Dry bulb vertical gradient 40-Hf 131-33

____________________ _________________ __ -----*----------

8

, ,

36.6-6.1c 120-20 1nstalled January 1974.

b Installed January 1974, removed January 1975.

cTemporary.

dTwo sets of instruments.

6.3 OPERATIONAL MONITORING PROGRAMS 6.3.1 Aquatic biological monitoring program The aquatic biological operational monitoring program will contain sampling programs which are extensions of the baseline and preoperational programs so that analyses can readily be made of the changes, if any, that occur in the aquatic environment due to plant operation.

Thus, the ichthyoplankton study now being conducted and the required kelp preoperational program should be continued during operation of the facility until such time as it is possible to state credibly that no significant impacts result from the facility.

The new fish return system (Sect. 3.2.2) is expected to be about 90% effective according to laboratory models (ER, p. 5. 1-20). Precise figures on its effectiveness-will not be available until it is operated in conjunction with the heat dissipation system. The staff recommends that the applicant include a program for optimizing the effectiveness of the fish return system. This should include consideration of the delayed mortality of the fish successfully diverted by the fish return system by holding them for 48 to 96 hours0.00111 days <br />0.0267 hours <br />1.587302e-4 weeks <br />3.6528e-5 months <br /> before returning them to the ocean.

Consideration of deletion of the intertidal sampling program from the operational monitoring program for SONGS 2 and 3 is discussed in Sect. 6.2. 1.5.

6.3.2 Water guaiity monitoring program The water quality operational monitoring program is a continuation of the existing preoperational water quality monitoring program (Sect. 6.2.2). This continuity will allow for confirmatory monitoring to assess any possible changes to water quality due to operation of San Onofre Ullits 2 and 3.

The NRC and the California Regional Water Quality Control Board, San Diego Region (CRWQCB) have worked in a cooperative manner in order to develop the preoperational monitoring program for SONGS 2 and 3. NRC and CRWQCB have agreed to continue to work together to establish an operational phase NPDES permit which will incorporate the aquatic concerns from each regulatory group.

6.3.3 Terrestrial monitoring program The applicant does not have an operational terrestrial monitoring program. The staff does not recommend any operational monitoring of floral or faunal species because no significant

6-7 effects have been identified between the operation of SONGS 2 &3 and the terrestrial environ-ment. The California Coastal Commission, however, requires the applicant to protect the bluffs 0.5 km (0.31 mile) south of the plant site for the duration of the site easement (expiration date, May 1, 2023) (ER, Appendix l2B).

6.3.4 Radiological monitoring program The operational offsite radiological monitoring program is conducted to measure radiation levels and radioactivity in the plant environs. It assists and provides backup support to the detailed effluent monitoring (as recommended in NRC Regulatory Guide 1.21, "Measuring, Evalua-ting, and Reporting Radioactivity in Solid Wastes and Release of Radioactive Materials in Liquid and Gaseous Effluents from Light-Water Cooled Nuclear Power Plants") which is needed to evaluate individual and population exposures and to verify projected or anticipated radio-activity concentrations.

The applicant plans essentially to continued the proposed preoperational program during the operating period. However, refinements may be made in the program to reflect changes in land use or preoperational monitoring experience.

6.3.5 Meteorological monitoring program The applicant plans to continue the program begun for the construction permit evaluation. The onsite meteorological tower provides data in accordance with the recommendations of Regulatory Guide 1. 23, "Onsite Meteorological Programs." Furthermore, operating technical specifications require meteorological monitoring as a condition of operation.

6.4 RELATED ENVIRONMENTAL RESOURCE DATA 6.4. 1 Thermal exception studies As a condition of the exception to the State Thermal Plan granted by the California Regional Water Quality Control Board, San Diego, the applicants are required to perform studies to determine the optimum mode of heat treatment to control fouling organisms while minimizing adverse effects on marine life and to permit the Regional Board to set precise limits on the frequency, degree, and duration of heat treatment. These studies were submitted to the State Water Resources Control Board on January 31, 1979. On December 18, 1980, the Board determined that the studies fulfilled the conditions set earlier and further determined that the heat treatment operating conditions proposed by the applicant will assure the protection and propagation of a balanced, indigenous population of shellfish, fish, and wildlife within the meaning of Section 316(a) of the Clean Water Act.

6.4.2 Marine Review Committee studies The California Coastal Commission specified in the Coastal Zone Permit issued in 1974 for SONGS 2 and 3 that an extensive study be conducted at San Onofre. The study program is funded by the utility and is being administered by a three-member Marine Review Committee (MRC) appointed by the Coastal Commission. The intent of the program is to provide an independent assessment of the marine environment and a prediction of the potential impact of SONGS 2 and

3. The MRC has identified the following areas for study: physical, oceanographic, and ecological monitoring and modeling; plankton- far field effects and entrainment; fish populations, impingement, and diversion; and benthic communities, intertidal zone organisms, and kelp beds.

MRC has conducted studies at SONGS 2 and 3 in some of the above mentioned areas since August 1976. In November 1980 the MRC issued a report containing its reco~endations, predictions, and rationale. The conclusions of the MRC are essentially consistent with those of the staff as described in Section 5 of this statement. Although noting uncertainties, the MRC has concluded that it does not predict at this time that substantial adverse effects on the marine environment are likely to occur from the operations of the SONGS cooling system. Accordingly, the report recommends no design changes but does recommend continued monitoring of the aquatic community to ensure that there is no serious ecological damage, especially to the kelp beds, as a result of plant operation. (See Appendix E for the options and recommendations of the Marine Review Committee.)

6.5 CONCLUSION

S The preoperational and operational monitoring programs as described above give adequate attention to impacts discussed in this environmental impact statement.

6-8 REFERENCES These documents are available for inspection and copying for a fee in the NRC Public Document room 1717 H Street, N.W., Washington, D.C. 20555

1. Southern California Edison Company, "San Onofre Nuclear Generating Station Units 2 and 3, Environmental Report- Operating License Stage," Docket No. 50-361/362, 1977.

2. Southern California Edison Company, "San Onofre Generating Station Units 2 and 3, Final Safety Analysis Report," Docket No. 50-361/362, 1977.

3. M. Septoff, A. E. Mitchell, and L. H. Teuscher, "Final Report of the Onshore Tracer Tests Conducted December 1976 through March 1977 at the San Onofre Nuclear Generating Station," Report NUS-1927, NUS Corporation, Rockville, Md., 1977.

7. ENVIRONMENTAL IMPACT OF POSTULATED ACCIDENTS 7.1 PLANT ACCIDENTS The staff has considered the potential radiological impacts on the environment of possible accidents at the San Onofre Nuclear Generating Station Units 2 and 3 in accordance with a Statement of Interim Policy published by the Nuclear Regulatory Commission on June 13, 1980. 1 The following discussion reflects these considerations and conclusions.

The first section deals with general characteristics of nuclear power plant accidents including a brief summary of safety measures to minimize the probability of their occurrence and to mitigate their consequences if they should occur. Also described are the important properties of radioactive materials and the pathways by which they could be transported to become environmental hazards. Potential adverse health effects and impacts on society associated with actions to avoid such health effects are also identified.

Next, actual experience with nuclear power plant accidents and their observed health effects and other societal impacts are then described. This is followed by a summary review of safety features of the San Onofre Units 2 and 3 facilities and of the site that act to mitigate the consequences of accidents.

The results of calculations of the potential consequences of accidents that have been postulated in the design basis are then given. Also described are the results of calcula-tions for the San Onofre site using probabilistic methods to estimate the possible impacts and the risks associated with severe accident sequences of exceedingly low probability of occurrence.

7.1.1 General characteristics of accidents The term accident, as used in this section, refers to any unintentional event not addressed in Section 5.5 that results in a release of radioactive materials into the environment.

The predominant focus, therefore, is on events that can lead to releases substantially in excess of permissible limits for normal operation. Such limits are specified in the Commission's regulations at 10 CFR Part 20 and 10 CFR Part 50, Appendix I.

There are several features which combine to reduce the risk associated with accidents at nuclear power plants. Safety features in the design, construction, and operation comprising the first line of defense are to a very large extent devoted to the prevention of the release of these radioactive materials from their normal places of confinement within the plant. There are also a number of additional lines of defenses that are designed to mitigate the consequences of failures in the first line. Descriptions*of these features for the San Onofre Units 2 and 3 plant may be found in the applicant's Final Safety Analysis Report, 2 and in the staff's Safety Evaluation Report. 3 The most important mitigative features are described in Section 7.1.3.1 below.

These safety features are designed taking into consideration the specific locations of radioactive materials within the plant, their amounts, their nuclear, physical, and chemical properties, and their relative tendency to be transported into and for creating biological hazards in the environment.

7.1.1.1 Fission product characteristics By far the largest inventory of radioactive material in a nuclear power plant is produced as a byproduct of the fission process and is located in the uranium oxide fuel pellets in the form of fission products. These pellets are contained in the fuel rods which make up the fuel assemblies. During periodic refueling shutdowns, the assemblies containing these fuel pellets are transferred to a spent fuel storage pool so that the second largest inventory of radioactive material is located in this storage area. Much smaller inven-tories of radioactive materials are also normally present in the water that circulates in the primary coolant system and in the systems used to process gaseous and liquid radio-active wastes in the plant.

7-1

7-2 These radioactive materials exist in a variety of physical and chemical forms. Their potential for dispersion into the environment is dependent not only on mechanical forces that might physically transport them, but also upon their inherent properties, particularly their volatility. The majority of these materials exist as nonvolatile solids over a wide range of temperatures. Some, however, are relatively volatile solids and a few are gaseous in nature. These characteristics have a significant bearing upon the assessment of the environmental radiological impact of accidents.

The gaseous materials include radioactive forms of the chemcially inert noble gases krypton and xenon. These have the highest potential for release into the atmosphere. If a reactor accident were to occur involving degradation of the fuel cladding, the release of substantial quantities of these radioactive gases from the fuel is a virtual certainty. Such accidents are very low frequency but credible events (see Section 7.1.2). It is for this reason that the safety analysis of each nuclear power plant analyzes a hypothetical design basis accident that postulates the release of the entire contained inventory of radioactive noble gases from the fuel into the containment structure. If further released to the environment as a possible result of failure of safety features; the hazard to individuals from these noble gases would arise predominantly through the external gamma r~diation from the airborne plume. The reactor containment structure is designed to minimize this type of release.

Radioactive forms of iodine are formed in substantial quantities in the fuel by the fission process and in some chemical forms may be quite volatile. For this reason, they have traditionally been regarded as having a relatively high potential for release from the fuel. The chemical forms in which the fission product radioiodines are found are generally solid materials at room temperature, however, so that they have a strong tendency to condense (or "plate out") upon cooler surfaces. In addition, most of the iodine compounds are quite soluble in, or chemically reactive with, water. Although these properties do not inhibit the release of radioiodines from degraded fuel, they do act to mitigate the release from containment structures that have large internal surface areas and that contain large quantities of water as a result of an accident. The same properties affect the behavior of radioiodines that may "escape" into the atmosphere. Thus, if rainfall occurs during a release, or if there is moisture on exposed surfaces, e.g., dew, the radioiodines will show a strong tendency to be absorbed by the moisture. Because of radioiodine's relatively high solubility and distinct radiological hazard, its potential for release to the atmosphere has also been reduced by the use of special containment spray systems.

If released to the environment, the principal radiological hazard associated with the radioiodines is ingestion into the.human body and subsequent concentration in the thyroid gland.

Other radioactive materials formed during the operation of a nuclear power plant have lower volatilities and therefore, by comparison with the noble gases and iodine, a much smaller tendency to escape from degraded fuel unless the temperature of the fuel becomes quite high. By the same token, such materials, if they escape by volatilization from the fuel, tend to condense quite rapidly to solid form again when transported to a lower temperature region and/or dissolve in water when present. The former mechanism can have the result of producing some solid particles of sufficiently small size to be carried some distance by a moving stream of gas or air. If such particulate materials are dispersed into the atmosphere as a result of failure of the containment barrier, they will tend to be carried downwind and deposit on surface features by gravitational settling or by pre-cipitation (fallout), where they will become "contamination" hazards in the environment.

All of these radioactive materials exhibit the property of radioactive decay with charac-teristic half-lives ranging from fractions of a second to many days or years (see Table 7.1).

Many of them decay through a sequence or chain of decay processes and all eventually become stable (nonradioactive) materials. The radiation emitted during these decay processes is the reason that they are hazardous materials.

7.1.1.2 Exposure pathways The radiation exposure (hazard) to individuals is determined by their proximity to the radioactive material, the duration of exposure, and factors that act to shield the individual from the radiation. Pathways for the transport of radiation and radioactive materials that lead to radiation exposure hazards to humans are genera.lly the same for accidental as for "normal" releases. These are depicted in Section 5, Figure 5.17. There are two additional possible pathways that could be significant for accident releases that are not shown in Figure 5.17. One of these is the fallout onto open bodies of water of radioactivity initially carried in the air. The second would be unique to an accident that results in temperatures inside the reactor core sufficiently high to cause melting and subsequent penetration of the basemat underlying the reactor by the molten core debris.

This creates the potential for the release. of radioactive material into the hydrosphere through contact with ground water. These pathways may lead to external exposure to radi-ation, and to internal exposures if radioactivity is inhaled, or ingested from contam-inated food or water.

7-3 Table 7.1 Activity of Radionuclides in a San Onofre Reactor Core at 3560 MWt Radioactive Inventory Group/Radionuclide (millions of curies) Half-life (days)

A. NOBLE GASES Krypton-85 0.63 3,950 Krypton-85m 27 0.183 Krypton-87 52 0.0528 Krypton-88 76 0.117 Xenon-133 190 5.28 Xenon-135 38 0.384 B. IODINES Iodlne-13i 95 8.05 Iodine-132 130 0.0958 Iodine-133 190 0.875 Iodine-134 210 0.0366 Iodine-135 170 0.280

c. ALKALI METALS Rubidium-86 0.029 18.7 Cesium-134 8.3 750 Cesium-136 3.3 13.0 Cesium-137 5.2 11,000 D. TELLURIUM-ANTIMONY Tellurium-127 0.029 18.7 Tellurium-127m 1.2 109 Te 11 uri um-129 34 0.048 Te 11 uri um-129m 5.9 34.0 Te 11 uri urn-131m 14 1.25 Te 11 uri um-132 130 3.25 Antimony-127 6.8 3.88 Antimony-129 37 0.179 E. AKALINE EARTHS Strontlum-89 100 52.1 Strontium-90 4.1 11,030 Strontium-91 120 0.403 Barium-140 180 12.8 F. COBALT AND NOBLE METALS Cobalt-58 0.87 71.0 Cobalt-60 0.32 1,920 Molybdenum-99 180 2.8 Technetium-99m 160 0.25 Ruthenium-103 120 39.5 Ruthenium-lOS 80 0.185 Ruthenium-lOG 28 366 Rhodium-lOS 55 1.50 G. RARE EARTHS 1 REFRACTORY OXIDES AND TRANSURANICS Yttr1um-99 4.3 2.67 Yttrium-91 130 59.0 Zirconium-95 170 65.2 Zirconium-97 170 0.71 Niobium-95 170 35.0 Lanthanum-140 180 1.67 Cerium-141 170 32.3 Cerium-143 150 1.38 Cerium-144 95 284

7-4 Table 7.1 (Continued)

Radioactive Inventory Group/Radi onuc 1ide * (millions of curies) Half-life (days)

G. RARE EARTHS, REFRACTORY OXIDES AND TRANSURANICS (Continued)

Praseodymium-143 150 13.7 Neodymium-147 67 11.1 Neptunium-239 1800 2.35 Plutonium-238 0.063 32,500 Plutonium-239 0.023 8.9 X 10 6 Plutonium-240 0.023 2.4 X 10!;

Plutonium-241 3.8 5,350 Americium-241 0.0019 1.5 X 10 5 Curium-242 0.56 163 Curium-244 0.026 6,630 NOTE: The above grouping of rad1onuclides corresponds to that 1n Table 7,3, It is characteristic of these pathways that during the transport of radioactive material by wind or by water, the material tends to spread and disperse, like a plume of smoke from a smokestack, becoming less concentrated in larger volumes of air or water. The result of these natural processes is to lessen the intensity of exposure to individuals downwind or downstream of the point of release, but they also tend to increase the number who may be exposed. For a release into the atmosphere, the degree to which dispersion reduces the concentration in the plume at any downwind point is governed by the turbulence characteristics of the atmosphere which vary considerably with time and from place to place. This fact, taken in conjunction with the variability of wind direction and the presence or absence of precipitation, means that accident consequences are very much dependent upon the weather conditions existing at the time.

7.1.1.3 Health effects The cause and effect relationships between radiation exposure and adverse health effects are quite complex 4 but they have been more exhaustively studied than any other environmental contaminant.

Whole-body radiation exposure resulting in a dose greater than about 10 rem for a few persons and about 25 rem for nearly all people over a short period of time (hours) is necessary before any physiological effects to an individual are clinically detectable.

Doses about to 10 to 20 times larger than the latter dose, also received over a relatively short period of time (hours to a few days), can be expected to cause some fatal injuries.

At the severe, but extremely low probability end of the accident spectrum, exposures of these magnitudes are theoretically possible for persons in the close proximity of such accidents if measures are not or cannot be taken to provide protection, e.g., by sheltering or evacuation.

Lower levels of exposures may also constitute a health risk, but the ability to define a direct cause and effect relationship between any given health effect and a known exposure to radiation is difficult given the backdrop of the many other possible reasons why a particular effect is observed in a specific individual. For this reason, it is necessary to assess such effects on a statistical basis. Such effects include cancer and genetic changes in future generations after exposure of a prospective parent. Cancer in the exposed population may begin to develop only after a lapse of 2 to 15 years (latent period) from the time of exposure and then continue over a period of about 30 years (plateau period).

However, in the case of exposure of fetuses (in utero), cancer may begin to develop at birth (no latent period) and end at age 10 (i~., the plateau period is 10 years). The health consequences model currently being used is based on the 1972 BEIR Report of the National Academy of Sciences.s Most authorities are in agreement that a reasonable and probably conservative estimate of the statistical relationship between low levels of radiation exposure to a large number of people is within the range of about.lO to 500 potential cancer deaths (although zero

7-5 is not excluded by the data) per million man-rem. The range comes from the latest HAS BEIR III Report (1980) 6 which also indicates a probable value of about 150. This value is virtually identical to the value of about 140 used in the current NRC health effects models. In addition, approximately 220 genetic changes per million person-rem would be projected by BEIR III over succeeding generations. That also compares well with the value of about 260 per million man-rem currently used by the NRC staff.

7.1.1.4 Health effects avoidance Radiation hazards in the environment tend to disappear by the natural process of radio-active decay. Where the decay process is a slow one, however, and where the material becomes relatively fixed in its location as an environmental contaminant (e.g., in soil),

the hazard can continue to exist for a relatively long period of time--months, years, or even decades. Thus, a possible consequential environmental societal impact of severe accidents is the avoidance of the health hazard rather than the health hazard itself, by restrictions on the use of the contaminated property or contaminated foodstuffs, milk, and drinking water. The potential economic impacts that this can cause are discussed below.

7.1.2 Accident experience and observed impacts The evidence of accident frequency and impacts in the past is a useful indicator of future probabilities and impacts. As of mid-1980, there were 69 commercial nuclear power reactor units licensed for operation in the United States at 48 sites with power generating capaci-ties ranging from 50 to 1130 megawatts electric (MWe). (The San Onofre Units 2 and 3 are designed for 1140 MWe each.) The combined experience with these units represents approximately 500 reactor years of operation over an elapsed time of about 20 years.

Accidents have occurred at several of these facilities. 7 Some of these have resulted in releases of radioactive material to the environment, ranging from very small fractions of a curie to a few million curies. None is known to have caused any radiation injury or fatality to any member of the public, nor any significant individual or collective public radiation exposure, nor any significant contamination of the environment. This experience base is not large' enough to permit a rel.iable quantitative statistical inference.

It does, however, suggest that significant environmental impacts due to accidents are very unlikely to occur over time periods of a few decades.

Melting or severe degradation of reactor fuel has occurred in only one of these 69 operating units, during the accident at Three Mile Island - Unit 2 (TMI-2) on March 28, 1979. In addition to the release of a few million curies of xenon-133, it has been estimated that approximately 15 curies of radioiodine was also released to the environment at TMI-2. 8 This amount represents an extremely minute fraction of the total radioiodine inventory present in the reactor at the time of the accident. No other radioactive fission products were released in measurable quantity.

It has been estimated that the maximum cumulative offsite radiation dose to an individual was less than 100 millirem. 8

• 9 The total population exposure has been estimated to be in the range from about 1000 to 3000 man-rem. This exposure could produce between none and one additional fatal cancer over the lifetime of the population. The same population receives each year from natural background radiation about 240,000 man-rem and apcroximately a half-million cancers are expected to develop in this group over its lifetime, 8

• primarily from causes other than radiation. Trace quantities (barely above the limit of detectability) of radioiodine were found in a few samples of milk produced in the area. No other food or water supplies were impacted.

Accidents at nuclear power plants have also caused occupational injuries and a few fatalities but none attributed to radiation exposure. Individual worker exposures have ranged up to about 4 rems as a direct consequence of accidents, but the collective worker exposure levels (man-rem) are a small fraction of the exposures experienced during normal routine operations that average about 500 man-rem per reactor year.

Accidents have also occurred at other nuclear reactor facilities in the United States and in other countries. 7 Due to inherent differences in design, construction, operation, and purpose of most of these other facilities, their accident record has only indirect relevance to current nuclear power plants. Melting of reactor fuel occurred in at least seven of these accidents, including the one in 1966 at the Enrico Fermi Atomic Power Plant Unit 1. This was a sodium-cooled fast breeder demonstration reactor designed to generate 61 MWe. The damages were repaired and the reactor reached full power four years following the accident. It operated successfully and completed its mission in 1973. This accident did not release any radioactivity to the environment.

7-6 A reactor accident in 1957 at Windscale, England released a significant quantity of radio-iodine, approximately 20,000 curies, to the environment. This reactor, which was not operated to generate electricity, used air rather than water to cool the uranium fuel.

During a special operation to heat the large amount of graphite in this reactor, the fuel overheated and radioiodine and noble gases were released directly to the atmosphere from a 123-m (405-ft} stack. Milk produced in a 512-km2 (200-mi 2) area around the facility was impounded for up to 44 days. This kind of accident cannot occur in a reactor like San Onofre, however, because of its water-cooled design.

7.1.3 Mitigation of accident consequences The Nuclear Regulatory Commission is conducting a safety evaluation of the application to operate San Onofre Units 2 and 3. Although this evaluation will contain more detailed information on plant design, the principal design features are presented in the following section.

7.1.3.1 Design features San Onofre Units 2 and 3 are essentially identical units. Each contains features designed to prevent accidental release of radioactive fission products from the fuel and to lessen the consequences should such a release occur. Many of the design and operating specifica-tions of these features are derived from the analysis of postulated events known as design basis accidents. These accident preventive and mitigative features are collectively referred to as engineered safety features (ESF}. The possibilities or probabilities of failure of these systems are incorporated in the assessments discussed in section 7.1.4.

Each steel-lined concrete containment building is a passive mitigating system which is designed to minimize accidental radioactivity releases to the environment. Safety injec-tion systems are incorporated to provide cooling water to the reactor core during an accident tp prevent or minimize fuel damage. The containment atmosphere cooling system provides heat removal capability inside the containment following steam release accidents and helps to prevent containment failure due to overpressure. Similarly, the containment spray system is designed to spray cool water into the containment atmosphere. The spray water also contains an additive (sodium hydroxide) which will chemically react with any airborne radioiodine to remove it from the containment atmosphere and prevent its release to the environment.

The mechanical systems mentioned above are supplied with emergency power from onsite diesel generators in the event that normal offsite station power is interrupted.

The fuel handling area of each unit is located in a fuel building, a low leakage structure with a safety-grade ventilation system for accident mitigation. The safety-grade ventilation system is an internal recirculation system and contains both charcoal and high efficiency particulate filters. If radioactivity were to be released into the building, it would be drawn through the ventilation system, and radioactive iodine and particulate fission products would be removed from the flow stream, reducing the concentration within the building and hence the amount that might leak to the atmosphere.

There are features of each unit that are necessary for its power generation function that can also play a role in mitigating certain accident consequences. For example, the main condenser, although not classified as an ESF, can act to mitigate the consequences of accidents involving leakage from the primary to the secondary side of the steam generators (such as steam generator-tube ruptures).

If normal offsite power is maintained, the ability of the plant to send contaminated steam to the condenser instead of releasing it through the safety valves or atmospheric dump valves can significantly reduce the amount of radioactivity released to the environment.

In this case, the fission product removal capability of the normally operating off-gas treatment system would come into play.

Much more extensive discussions of the safety features and characteristics of San Onofre Units 2 and 3 may be found in the applicant's Final Safety Analysis Report. 2 The staff evaluation of these features is addressed in the Safety Evaluation Report. In addition, the implementation of the lessons learned from the TMI-2 accident, in the form of improve-ments in design and procedures, and operator training, will significantly reduce the likeli-hood of a degraded core accident which could result in large releases of fission products to the containment. Specifically, the applicant will be required to meet those TMI-related requirements specified in NUREG-0737. As noted in Section 7.1.4.7, no credit has been taken for these actions and improvements in discussing the* radiological risk of accidents in this supplement.

7-1 7.1.3.2 Site features In the process of considering'the suitability of the site of San Onofre Units 2 and 3, pursuant to NRC's Reactor Site Criteria in 10 CFR Part 100, consideration was given to certain factors that tend to minimize the risk and the potential impact of accidents.

First, the site has an exclusion area as required in 10 CFR Part 100. The exclusion area of the *(33.8 hectare (83.6-acre)) site has a minimum exclusion distance of (1968 ft) 600 meters from the containment centerlines *to the closest site boundary. The applicant's authority to control all activities within the exclusion area was acquired by a grant of easement from the United States of America made by the Secretary of the Navy. The exclusion area is traversed by old U.S. Highway 101, the San Diego Freeway (Interstate 5), and the Atchison, Topeka and Santa Fe Railroad. The exclusion area on the ocean side extends over a narrow strip of beach and into the Pacific Ocean.

The applicant's control of the landward portion of the exclusion area extends to the mean high tide line but does not include the strip of beach lying between high and low tide that is occasionally uncovered. This strip of "tidal beach" is owned by the State of California and is used primarily as a passageway for individuals walking along the beach.

The applicant's lack of control of this strip of tidal beach has been adjudicated in a Commission proceeding (see ALAB-432) and has been determined to be de minimis on the basis of its occasional use, together with the high probability that any radiation exposure to individuals in this zone will be within the guideline values of 10 CFR Part 100 in the event of an emergency.

Activities within the exclusion area which are unrelated to plant operation include a gas pipeline, railroad traffic, through traffic on the San Diego Freeway, and local recreational traffic on old U.S. Highway 101. Recreational activities in the plant vicinity include swimming, camping, and surfing. Recreational activities, such as sun-bathing or picnicking, are discouraged within the landward portion of the exclusion area (the area landward of the contour of mean high tide). The seaward portion of the exclu-sion area (the area seaward of the contour of mean*high tide) may be occupied by small numbers of people for passageway transit between the public beach areas upcoast and down-coast from the plant. Additional small numbers of people may be anticipated to occasionally be in the water within the exclusion area.

Transient access to an approximate 2.02-hectare (5-acre) at the southwest corner of the site for the purposes of viewing the scenic bluffs and barrancas will be on an unimproved walkway. The applicant has estimated that at any one time a maximum of 100 persons will be in the walkway and a 2.02-hectare (5-acre) viewing area, and on the beach and water below the mean high tide. The improved walkway affords landward passage between the two beach areas.

In case of a radiological emergency, the applicants have made arrangements with agencies of the State and local *governments to control all traffic on the railroad, roadways, and waterways.

Second, beyond and surrounding the exclusion area is a low population zone (LPZ), also required by Part 100. This is a circular area of 3.14 km (1.95 mi) outer radius. Within this zone the applicant must assure that there is reasonable probability that appropriate measures could be taken on behalf of the residents in the event of a serious accident.

The San Onofre State Beach northwest and southwest of the San Onofre exclusion areas represents a public waterfront recreation area within an 8-km (5-mi) radius of the plant.

The beach south of the nuclear facility is used for swimming, hiking, and vehicle parking.

The 1036 m (3,400-ft) stretch of beach north of the site is used primarily for surfing.

The largest communities in the vicinity of the site are San Clemente, located about 4.8 km (3 mi) away, which had a 1976 estimated population of 23,000, and the U.S. Marine Corp base Camp Pendleton, with a total estimated population of about 33,000. The Marine Corp base consists of several population clusters or camps located at distances from 2.4 km to 19.31 km (1.5 mi to 12 mi) away.

The applicant has estimated a peak transient population in major tourist and recreational activities along Interstate 5 in a 16-km (10-mi) radius of the plant to be 56,600 persons.

This occurs during the summer months and is due to persons engaged in water sport recreation on the Pacific Ocean beach and coastal waters.

The Mexican border lies about 121 km (75 mi) from San Onofre, toward the southeast. The cities of Tijuana, Mexicali, and Ensenada are within 241* km (150 mi) of the site.

7-8 The safety evaluation of the San Onofre site has also included a review of potential external hazards, i.e., activities offsite that might adversely affect the operation of the plant and cause an accident. This review encompassed nearby industrial, transportation, and military facilities that might create explosive, missile, toxic gas, or similar hazards.

The staff concluded at the construction permit stage that the hazards from the nearby military facility are negligibly small. However, the hazards from the nearby interstate highway, the railroad right of way, and natural gas pipelines, are still under review by the staff. Reevaluation of these hazards has been requested by the staff, and the results will be reported in a supplement to the staff's Safety Evaluation Report. It is anticipated that the review will show that either the risks are acceptably small or may be acceptably small.

7.1.3.3 Emergency preparedness Emergency preparedness plans including protective action measures for the San Onofre facility and environs are in an advanced, but not yet fully completed stage. In accordance with the provisions of 10 CFR Section 50.47, effective November 3, 1980, no operating license will be issued to the applicant unless a finding is made by the NRC that the state of onsite and offsite emergency preparedness provides reasonable assurance that adequate protective measures can and will be taken in the event of a radiological emergency. Among the standards that must be met by these plans are provisions for two Emergency Planning Zones (EPZ). A plume exposure pathway EPZ of about 16 km (10 mi) in radius and an inges-tion exposure pathway EPZ of about 80 km (50 mi) in radius are required. Other standards include appropriate ranges of protective actions for each of these zones, provisions for dissemination to the public of basic emergency planning information, provisions for rapid notification of the public during a serious reactor emergency, and methods, systems, and equipment for assessing and monitoring actual or potential offsite consequences in the EPZs of a radiological emergency condition.

NRC findings will be based upon a review of the Federal Emergency Management Agency (FEMA) findings and determinations as to whether State and local government emergency plans are adequate and capable of being implemented, and on the NRC assessment as to whether the applicant's onsite plans are adequate and capable of being implemented. NRC staff findings will be reported in a supplement to the staff's Safety Evaluation Report. Although the presence of adequate and tested emergency plans cannot prevent the occurrence of an accident, it is the judgment of the staff that they can and will substantially mitigate the conse-quences to the public if one should occur.

7.1.4 Accident risk and impact assessment 7.1.4.1 Design basis accidents As a means of assuring that certain features of the San Onofre Units 2 and 3 plants meet acceptable design and performance criteria, both the applicant and the staff have analyzed the potential consequences of a number of postulated accidents. Some of these could lead to significant releases of radioactive materials to the environment, and calculations have been performed to estimate the potential radiological consequences to persons offsite.

For each postulated initiating event, the potential radiological consequences cover a considerable range of values depending upon the particular course taken by the accident and the conditions, including wind direction and weather, prevalent during the accident.

In the safety analysis of the San Onofre Units 2 and 3 plants, three categories of accidents have been considered. These categories are based upon their probability of occurrence and include (a) incidents of moderate frequency, i.e., events that can reasonably be expected to occur during any year of operation, (b) infrequent accidents, i.e., events that might occur once during the lifetime of*the plant, and (c) limiting faults, i.e., accidents not expected to occur but that have the potential for significant releases of radioactivity.

The radiological consequences of incidents in the first category, also called anticipated operational occurrences, are discussed in Section 5. Initiating events postulated in the second and third categories for the San Onofre Units 2 and 3 are shown in Table 7.2.

These are collectively designated design basis accidents in that specific design and operating features as described above in Section 7.1.3.1 are provided to limit their potential radiological consequences. Approximate radiation doses that might be received by a person at the nearest site boundary (600 meters from the plant) are also shown in the table, along with a characterization of the time duration of the releases.

~9 Table 7.2 Approximate Radiation Doses from Design Basis Accidents, Conservative Calculational Model Dose (rem at 600 ml)

Duration of Release Whole Body Thyroid Infreguent Accidents:

Waste Gas Tank Failure < 2 hr < 3 < 30 Steam Generator Tube2 Rupture < 2 hr < 3 2 Fuel Handling Accident < 2 hr 7 40 Limiting Faults:

Main Steam Line Break < 2 hr 6 10 Control Rod Ejection hrs-days <6 60 Large-Break LOCA hrs-days 3 wo 1The nearest site boundary.

2See NUREG-06516 for descriptions of three steam generator tube rupture accidents that have occurred in the United States.

The calculational model used is a conservative one in that it is expected to provide a reasonable estimate of the potential upper bound for individual exposures. The results are used to implement the provisions of 10 CFR 100 and to establish performance require-ments for certain engineered safety features. The conservative assumptions used in these analyses include: (1) large (upper bound) amounts of radioactive material released by the initiating event, (2) single failures in important equipment, including operating the engineered safety features in a degraded mode,* (3) very adverse meteorological condi-tions, and (4) no reduction in exposure due to possible protective actions.

The results of these calculations show that, for these events, the limiting whole-body exposures are not expected to exceed 7 rem. They also show that radioiodine releases have the potential for offsite exposures ranging up to about 100 rem to the thyroid.

For such an exposure to occur, an individual would have to be located at a point on the site boundary where the radioiodine concentration in the plume has its highest value and inhale at a breathing rate characteristic of a person jogging, for a period of two hours.

The health risk to an individual receiving such a thyroid exposure is the potential appearance of benign or malignant thyroid nodules in about 4 out of 100 cases, and the development of a fatal cancer in about 2 out of 1000 cases.

The realistically expected consequences, were one of these initiating events actually to occur, would be very substantially less. Therefore, the risk is judged to be extremely small for these design basis accidents. The subject of risk is more fully discussed in Section 7.1.4.6 below.

7.1.4.2 Probabilistic assessment of severe accidents In this and the following three sections, there is a discussion of the probabilities and consequences of accidents of greater severity than the design basis accidents identified in the previous section. As a class, they are considered less likely to occur, but their consequences could be more severe, both for the plant itself and for the environment.

These severe accidents, heretofore frequently called Class 9 accidents, can be distinguished from design basis accidents in two primary respects: they involve substantial physical deterioration of the fuel in the reactor core, including overheating to the point of melting, and they involve deterioration of the capability of the containment structure to perform its intended function of limiting the release of radioactive materials to the environment.

• The containment structure, however, is assumed to prevent leakage in excess of that which can be demonstrated by testing, as provided in 10 CFR Section lOO.ll(a).

7-10 The assessment methodology employed is that described in the Reactor Safety Study (RSS) which was published in 1975. 10* The San Onofre Units 2 and 3 are Combustion Engineering-designed pressurized water reactors (PWR) having similar design and operating character-istics to the Surry Unit 1 facility used in the RSS as a prototype for PWRs. This assess-ment has used as its starting point, therefore, the same set of accident sequences that were found in the RSS to be dominant contributors to risk in the prototype PWR. The same set of nine release categories, designated PWR 1 through 9, have also been used to repre-sent the spectrum of severe accident releases that are hypothesized for the San Onofre Units 2 and .3. Characteristics of these categories are shown in Table 7.3. Sequences initiated by natural phenomena such as tornadoes, floods, or seismic events and those that could be initiated by deliberate acts of sabotage are not included in these events sequences. The radiological consequences of such events would not be different in kind from those which have been treated. Moreover, it is the staff's judgment, based upon design requirements of 10 CFR Part 50, Appendix A, relating to effects of natural phenomena, and safeguards requirements of 10 CFR Part 73, that these events do not contribute sig-nificantly to risk. The facts upon which the staff based its Safe Shutdown Earthquake and its conclusions regarding the effects of natural phenomena on the plant are given in the Safety Evaluation Report.

A calculated probability per reactor year associated with each release category is also shown in the second column in Table 7.3. These probabilities are the result of a detailed engineering analysis of the prototype PWR in the Reactor Safety Study. There are substan-tial uncertainties in these probabilities. This is due, in part, to difficulties associ-ated with the quantification of human error and to inadequacies in the data base on failure rates of individual plant components that were used to calculate the probabilities 11 (see Section 7.1.4.7 below). Also, the detailed engineering analysis represents a plant designed by a different nuclear steam supply system designer (CE versus Westinghouse) with different detailed designs. The probability of accident sequences from the Surry plant were used to give a perspective of the societal risk at San Onofre Units 2 and 3 because, although the probabilities of particular accident sequences may be substantially different, the overall effect of all sequences taken together is likely to be within the uncertainties. Except as indicated in the footnotes in Table 7.3, the staff has no present basis for judging whether the probabilities may be too high or too low. The error band for the probabilities of some of the event sequences could be as great as a factor of 100. The event sequences in categories PWR 1-7 lead to partial or complete melting of the reactor core while those in the last two categories do not involve melting of the core. In release categories 1 to 3, the event sequences include containment failure by steam explosion, hydrogen burning, or overpressure. In release categories 6 and 7, the dominant containment failure mode is by melt-through of the containment *base mat. The other release categories contain event sequences in which the systems intended to isolate the containment fail to act properly.

The magnitudes (curies) of radioactivity releases for each category are obtained by multiplying the release fractions shown in Table 7.3 by the amounts that would be present in the core at the time of the hypothetical accident. These are shown in Table 7.1 for a San Onofre plant at a core thermal power level of 3560 megawatts.

The potential radiological consequences of these releases have been calculated by the consequence model used in the RSS 12 and adapted to apply to a specific site. The essen-tial elements are shown in schematic form in Figure 7.1. Environmental parameters specific to the San Onofre site have been used and include the following:

(1) Meteorological data for the site representing a full year of consecutive hourly measurements and seasonal variations.

(2) Projected population in the United States and Mexico for the year 2000 extending throughout regions of 80 and 560 km (50 and 350 mi) radius from the site.

(3) The habitable land fraction within the 560-km (350-mi) radius.

(4) land use statistics, on a state-wide basis, including farm land values, farm product values including dairy production, and growing season information, for the State of California and each surrounding State within the 560-km (350-mi) region.

(5) land use statistics for Mexico on a country-wide basis. Farm land values, growing season information, and comparison between agriculture and dairy products are based on comparison with U.S. values for nearby States. Farm product values are based on Mexico-average Gross National Product and "agriculture" percentage.

• Because this report has been the subject of considerable controversy, a discussion of the uncertainties surrounding it is provided in Section 7.1.4-7.

Table 7.3 Summary of Atmospheric Release Categories Representing Hypothetical Accidents in a PWR Fraction of Core Inventory Released(a~

Release Probability Categor~ (reactor-xr- 1 2 Xe-Kr I Cs-Rb Te-Sb Ba-Sr Ru(b) La(c)

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(b)

Includes Ru, Rh, Co, Mo, Tc.

(c)

Includes, Y, La, Zr, Nb, Ce, Pr, Nd, Np, Pu, Am, Cm.

(d)Current understanding of the phenomenon of containment failure by steam explosion embodied in this release category indicates the probability should be lower than stated.

NOTE: Refer to Section 7.1.4.6 for a discussion of.uncertainties in risk estimates.

7-12 WEATHER DATA RELEASE CATEGORIES ATMOSPHERIC DISPERSION t--

r-a-- DOSIMETRY

- ........ HEALTH EFFECTS CLOUD DEPLETION

...... POPULATION ~--~

PROPERTY DAMAGE GROUND CONTAMINATION f-a EVACUATION Figure 7.1 Schematic outline of consequence model

7-13 To obtain a probability distribution of consequences the calculations are performed assum-ing the occurrence of each accident release sequence at each of 91 different "start" times throughout a one-year period. Each calculation utilizes the site specific hourly meteoro-logical data and seasonal information for the time period following each 11 start" time.

The consequence model also contains provisions for incorporating the consequence reduction benefits of evacuation and other protective actions. Early evacuation of people would considerably reduce the exposure from the radioactive cloud and the contaminated ground in the wake of the cloud passage. The evacuation model used (see Appendix F) has been revised from that used in the RSS for better site-specific application. The quantitative characteristics of the evacuation model used for the San Onofre site are best estimate values made by the staff and based upon evacuation time estimates prepared by the appli-cant. Actual evacuation effectiveness could be greater or less than that characterized but would not be expected to be much less, even under adverse conditions.

The other protective actions include: (a) either complete denial of use (interdiction),

or permitting use only at a sufficiently later time after appropriate decontamination of food stuffs such as crops and milk, (b) decontamination of severely contaminated environment (land and property) when it is considered to be economically feasible to lower the levels of contamination to protective action guide (PAG) levels, and (c) denial of use (interdic-tion) of severely contaminated land and property for varying periods of time until the contamination levels reduce to such values by radioactive decay and weathering so that land and property can be economically decontaminated as in (b) above. These actions would reduce the radiological exposure to the people from immediate and/or subsequent use of or living in the contaminated environment.

Early evaucation and other protective actions as mentioned above are considered as essen-tial sequels to serious nuclear reactor accidents involving significant release of radio-activity to the atmosphere. Therefore, the results shown for San Onofre reactor include the benefits of these protective actions.

There are also uncertainties in the estimates of consequences, and the error bounds may be as large as they are for the probabilities. It is the judgment of the staff, however, that it is more likely that the calculated results are overestimates of consequences rather than underestimates.

The results of the calculations using this consequence model are radiological doses to individuals and to populations, health effects that might result from these exposures, costs of implementing protective actions, and costs associated with property damage by radioactive contamination.

7.1.4.3 Dose and health impacts of atmospheric releases The results of the calculations of dose and health impacts performed for the San Onofre facility and site are presented in the form of probability distributions in Figures 7.2 through 7.5 and are included in the impact Summary Table 7.4. All of the nine release categories shown in Table 7.3 contribute to the results, the consequences from each being weighted by its associated probability.

Figure 7.2 shows the probability distribution for the number of persons who might receive whole body doses equal to or greater than 200 rem and 25 rem, and thyroid doses equal to or greater than 300 rem from early exposure,* all on a per-reactor-year basis. The 200 rem whole body dose figure corresponds approximately to a threshold value for which hospitalization would be indicated for the treatment of radiation injury. The 25 rem whole body (which has been identified earlier as the lower limit for clinically obervable physiological effects in nearly all people) and 300 rem thyroid figures correspond to the Commission's guidelines values for reactor siting in 10 CFR Part 100.

The figure shows in the left-hand portion that there is less than 1 chance in lOO,OOO per year (i.e. 10- 5 ) that one or more persons may receive doses equal to or greater than any of the doses specified. The fact that the th.ree curves run almost parallel in hori-zontal lines initially shows that if one person were to receive such doses, the chances are about the same that several tens to hundreds would be so exposed. The chances of larger numbers of persons being exposed at those levels are seen to be considerably smaller.

For example, the chances are about 1 in 100,000,000 (i.e. 10- 8 ) that 100,000 or more people might receive doses of 200 rem or greater. A majority of the exposures reflected in this figure would be expected to occur to persons within a 80-km (50-mi) radius of the plant.

Virtually all would occur with a 160-km (100-mi) radius.

• The containment structure, however, is assumed to prevent leakage in excess of that which can be demonstrated by testing, as provided in 10 CFR Section 100.11(a).

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Table 7.4 Summary of Environmental Impacts and Probabilities Population Latent*

Probability Persons Persons exposure, mil- cancers, Cost of offsite of impact exposed over exposed over Acute 1ions of man- 80 km/ mitigating actions, per year 200 rem 25 rem fatalities rem 80 km/tota 1 total $ mill ions

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NOTE: Refer to Section 7.1.4.6 for a discussion of uncertainties in risk estimates.

7-19 Figure 7.3 shows the probability distribution for the total population exposure in person-rem, i.e., the probability per reactor-year that the total population exposure will equal or exceed the values given. A substantial fraction of the population exposure would occur within 80 km (50 mi) but the more severe releases (PWR 1-6) would result in exposure to persons beyond the 80-km (50-mi) range as shown.

For perspective, population doses shown in Figure 7.3 may be compared with the annual average dose to the population within 80 km (50 mi) of the San Onofre site due to natural background radiation of 700,000 man-rem, and to the anticipated annual population dose to the general public from normal station operation of 460 man-rem (excluding plant workers)

(Section 5, Table 5.3 and 5.5).

Figure 7.4 shows the probability distribution for acute fatalities, representing radiation injuries that would produce fatalities within about one year after exposure. Virtually all of the acute fatalities would be expected to occur within a 64-km (40-mi) radius. The results of the calculations shown in this figure and in Table 7.4 reflect the effect of evacuation within the 16-km (10-mi) plume exposure pathway EPZ only. For the very low probability accidents having the .Potential for causing radiation exposure above the threshold for acute fatality at distances beyond 16 km (10 mi), it would be realistic to expect that authorities would evacuate persons at all distances at which such exposures might occur. Acute fatality consequences would therefore reasonably be expected to be very much less than the numbers shown.

Figure 7.5 represents the statistical relationship between population exposure and the induction of fatal cancers that might appear over a period of many years following exposure. The impacts on the total population and the population within 80 km (50 mi)

• are shown separately. Further, the fatal, latent cancers have been subdivided into those attributable to exposures of the thyroid and all other organs.

7.1.4.4 Economic and societal impacts As noted in Section 7.1.1, the various measures for avoidance of adverse health effects including those due to residual radioactive contamination in the environment are possible consequential impacts of severe accidents. Calculations of the probabilities and magnitudes of such impacts for the San Onofre facility and environs have also been made. Unlike the radiation exposure and adverse health effect impacts discussed above, impacts associated with adverse health effects avoidance are more readily transformed into economic impacts.

The results are shown as the probability distribution for costs of offsite mitigating actions in Figure 7.6 and are included in the impact Summary Table 7.4. The factors contributing to these estimated costs include the following:

o Evacuation costs o Value of crops contaminated and condemned o Value of milk contaminated and condemned o Costs of decontamination of property where practical o Indirect costs due to loss of use of property and incomes derived therefrom.

The last named costs would derive from the necessity for interdiction to prevent the use of property until it is either free of contamination or can be economically decontaminated.

Figure 7.6 shows that at the extreme end of the accident spectrum these costs.could exceed tens of billions of dollars but that the probability that this would occur is exceedingly small, less than one chance in a hundred million per year.

Additional economic impacts that can be monetized include costs of decontamination of the facility itself and the costs of replacement power. Probability distributions for these impacts have not been calculated, but they are included in the discussion of risk considerations in Section 7.1.4.6 below.

7.1.4.5 Releases to groundwater A pathway for public radiation exposure and environmental contamination that could be associated with severe reactor accidents was identified in Section 7.1.1.2 above. Consid-eration has been given to the potential environmental impact of this pathway for the San Onofre plant. The principal contributors to the risk are the core melt accidents associ-ated with the PWR-1 through 7 release categories. The penetration of the basemat of the

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7-21 containment building can release molten core debris to the strata beneath the plant.

Soluble radionuclides in this debris can be leached and transported with groundwater to downgradient domestic wells used for drinking or to surface water bodies used for drinking water, aquatic food and recreation. In pressurized water reactors, such as the San Onofre unit, there is an additional opportunity for groundwater contamination due to the release of contaminated sump water to the ground through a breach in the containment.

An analysis of the potential consequences of a liquid pathway release of radioactivity for generic sites was presented in the "Liquid Pathway Generic Study" (LPGS). 13 The LPGS compared the risk of accidents involving the liquid pathway (drinking water, irriga-tion, aquatic food, swimming and shoreline usage) for four conventional, generic land-based nuclear plants and a floating nuclear plant, for which the nuclear reactors would be mounted on a barge and moored in a water body. Parameters for the land-based sites were chosen to represent averages for a wide range of real sites and are thus "typical," but represented no real site in particular.

The discussion in this section is an analysis to determine whether or not the San Onofre site liquid pathway consequences would be unique when compared to land-based sites con-sidered in the LPGS. The method consists of a direct scaling of the LPGS population doses based on the relative values of key parameters characterizing the LPGS "ocean" site and the San Onofre site. The parameters which were evaluated included amounts of radioactive materials entering the ground, groundwater travel time, sorption on geological media, surface water transport, aquatic food consumption, and shoreline usage.

Doses to individuals and populations were calculated in the LPGS without consideration of interdiction methods such as isolating the contaminated groundwater or denying use of the water. In the event of surface water contamination, commercial and sports fishing, as well as many other water-related activities would be restricted. The consequences would therefore be largely economic or social, rather than radiological. In any event, the individual and population doses for the liquid pathway range from fractions to very small fractions of those that can arise from the airborne pathways.

The San Onofre reactors are situated above the San Mateo Formation, which is about 274-m (876.8-ft) thick and consists of medium to coarse-grained sandstone. 2 Groundwater at the site occurs between elevation 0 and 1.5 m (4.8 ft) Mean Low-Low Water, under water table conditions. The basemat of the reactors would be beneath the water table.

The groundwater gradient is clearly toward the ocean. There are no wells between the site and the ocean, so no groundwater users could be affected by an accidental contam-ination from the plant. There is virtually no possibility of a reversal of the ground-water gradient due to heavy pumping inland, particularly because such a reversal would at the same time cause an unacceptable intrusion of saltwater into the aquifer. Therefore, liquid radioactivity released from a core melt accident could only cause contamination by being transported through the groundwater and subsequently released to the Pacific Ocean.

The staff's most conservative estimate of the groundwater travel time would be 215 days.

For groundwater travel times of this magnitude, it is clear that the most important radio-nuclide contributors to the liquid pathway population dose would be Sr-90 and Cs-137.

Conservative values of the retardation factors, which reflect the effects of sorption of the radionuclides on geologic materials, were estimated on media similar to the granular materials under the site 14 to be 31 for Sr-90 and 2204 for Cs-137. The mean transport time from the reactor building to the Pacific Ocean is therefore conservatively estimated to be about 16 years for Sr-90 and 1080 years for Cs-137. When these travel times are compared to 5.7 years for Sr-90 and 51 years for Cs-137 in the LPGS land-based ocean site case, the relatively larger travel times for the San Onofre site would allow a smaller portion of the radioactivity to enter the surface water. This reduces the Sr-90 release to about 78% of the LPGS value. Virtually all of the Cs-137 would have decayed before reaching surface water.

Contaminants released from the shoreline would disperse in the oceanic turbulence. The LPGS made no distinction between the turbulence which would be found in the east, gulf, or west coasts of the United States. The only assumption which can be made without*site-specific data is that the mixing at the San Onofre and LPGS sites are similar.

The two major liquid pathway exposure pathways for an ocean site are aquatic food consump-tion and direct shoreline exposure.

The commercial and recreational finfish harvest for a rectangular block 80 km along shore and stretching 40 km offshore has been estimated by the staff from data provided in the

7-22 Environmental Report 15 to be about 13.1 x 10 6 kg. For comparison, the same size block using the LPGS ocean site fish catch densities would yield 5.8 x 106 kg of finfish.

Approximately 62% of population dose due to finfish consumption calculated in the LPGS was due to Cs-137 and approximately 38% was due to Sr-90. The only significant radio-nuclide which could reach the ocean in the San Onofre case would be Sr-90. The staff has conservatively estimated that the uninterdicted population dose in the San Onofre case would be about 69% of the lPGS land-based ocean case population dose for seafood consumption. ,

Nearly all of the direct shoreline exposure in the LPGS ocean-based site case was deter-mined to emanate from Cs-137. Since virtually all of the Cs-137 would decay before reach-ing the ocean, the shoreline direct exposure can be eliminated from further consideration.

The San Onofre liquid pathway contribution to population dose has, therefore, been demon-strated to be smaller than that predicted for the LPGS land-based ocean site, which repre-sents a "typical" ocean site. Thus, the San Onofre site is not unique in its liquid pathway contribution to risk.

There are measures which could be taken to minimize the impact of the liquid pathway.

The staff estimated that the minimum groundwater travel time from the San Onofre site to the Pacific Ocean would be hundreds of days. In addition, the holdup of important radio-nuclides would provide additional time to utilize engineering measures such as slurry walls and well-point dewatering to isolate the radioactive contaminants at the source.

7.1.4.6 Risk considerations The foregoing discussions have dealt with both the frequency (or likelihood of occurrence) of accidents and their impacts (or consequences). Since the ranges of both factors are quite broad, it is useful to combine them to obtain average measures of environmental risk. Such averages can be particularly instructive as an. aid to the comparison of radiological risks associated with accident releases and with normal operational releases.

A common way in which this combination of factors is used to estimate risk is to multiply the probabilities by the consequences. The resultant risk is then expressed as a number of consequences expected per unit of time. Such a quantification of risk does not at all mean that there is universal agreement that people's attitudes about risk, or what constitutes an acceptable risk, can or should be governed solely by such a measure. At best, it can be a contributing factor to a risk judgment, but not necessarily a decisive factor.

In Table 7.5 are shown average values of risk assoc-iated with population dose, acute fatalities, latent fatalities, and costs for evacuation and other protective actions.

These average values are obtained by summing the probabilities multiplied by the conse-quences over the entire range of the distributions. Since the probabilities are on a per-year basis, the averages shown are also on a per-year basis.

Table 7.5 Annual Average Values of Environmental Risks Due to Accidents Population exposure man-rem within 80 km 170 man-rem total 380 Acute fatalities permanent residents 0.001 beach visitors 0.00002 Latent cancer fatalities all organs excluding thyroid 0.022 thyroid only 0.011 Cost of protective actions and decontamination $19,000 NOTE: See Section 7.1.4.6 for d1scuss1ons of uncerta1nt1es in risk estimates.

7-23 The population exposure risk due to accidents may be compared with that for normal operational releases. These are shown in Section 5, Tables 5.3 and 5.5, for San Onofre Units 2 and 3 operating concurrently. The radiological dose to the population from normal operational releases may result in:

(1) late somatic effects in the form of fatal and nonfatal cancer in various body organs--

following age and organ-specific latency periods--of the exposed population, and (2) fatal and nonfatal genetic disorders in the future generations of the exposed population.

Because of the randomness of these effects, calculations of these effects are made from the population dose (man-rem). Absolute risk estimators of 140 deaths from expression of latent cancer in various body organs per 106 total-body man-rem in the exposed population and 260 cases of all forms of genetic disorders per 106 total-body man-rem in the future generations of the exposed population were*derived from the 1972 BEIR report. 5 This derivation assumes a linear and nonthreshold dose-effect relationship at all sublethal dose levels. Using these risk estimators and 228 man-rem as the annual population dose (Table 5.5, adjusted for one reactor), the staff calculated that there may occur 0.03 cancer deaths in the exposed population and 0.06 genetic disorders in all future generatons of the exposed population from each year of operation of one reactor.

The comparison of 0.03 cancer deaths given above with about the same value for latent cancer deaths from Table 7.1.4-5 shows that the accident risks are comparable to those for normal operational releases.

There are no acute fatality nor economic risks associated with protective actions and decontamination for normal releases; therefore, these risks are unique for accidents.

For perspective and understanding of the meaning of the acute fatality risk of 0.001 per year, however, the staff notes that to a good approximation the population at risk is that within about 16 km (10 mi) of the plant, about 92,000 persons in the year 2000.

Accidental fatalities per year for a population of this size, based upon overall averages for the United States, are approximately 20 for motor vehicle accidents, 7 from falls, 3 from drowning, 3 from burns, and 1 from firearms (ref. 5, p. 577).

As a separate item under acute fatalities in Table 7.5 is an entry of 0.00002 for "Beach visitors." As discussed in Section 7.1.3.2, the beaches near the site are heavily used for recreation. The average number of visitors has been estimated, based on seasonal and daily variation. The effects on the visitors are tallied separately because in actuality they are likely to be permanent residents from other nearby locations.

Figure 7.7 shows the calculated risk expressed as whole-body dose to an individual from early exposure as a* function of the distance from the plant within the plume exposure pathway EPZ. The values are on a per-reactor-year basis and all accident sequences and release categories in Table 7.3 contributed to the dose, weighted by their associated probabilities. Cal~ulated risk to an individual living within the plume exposure pathway EPZ of San Onofre of acute death due to potential accidents in the reactor is shown in Figure 7.8 as curves of constant risk per year to an individual as a function of distance due to potential reactor accidents. Figure 7.9 shows the same type of isopleths for death from latent cancer. Directional variation of these curves reflect the variation in the average fraction of the year the wind would be blowing into different directions from the plant. For comparison the following risk of fatality per year to an individual living

. in the U.S. may be noted (ref. 4, p. 577); automobile accident 2.2 x 10- 4 , falls 7.7 x 10- 5 ,

drowning 3.1 x 10-s, burning 2.9 x 10- 5 , and firearms 1.2 x 10-s.

The economic risk associated with protective actions and decontamination could be compared with property damage costs associated with alternative energy generation technologies.

The use of fossil fuels, coal or oil, for example, would emit substantial quantities of sulfur dioxide and nitrogen oxides into the atmosphere, and, among other things, lead to environmental and ecological damage through the phenomenon of acid rain (Ref. 4, 559-560).

This effect has not, however, been sufficiently quantified to draw a useful comparison at this time.

There are other economic impacts and risks that can be monetized that are not included in the cost calculations discussed in Section 7.1.4.4. These are accident impacts on the facility itself that result in added costs to the public, i.e., ratepayers, taxpayers, and/or shareholders. These are costs associated with decontamination of the facility itself and costs for replacement power.

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7-27 No detailed methodology has been developed for estimating the contribution to economic risk associated with cleanup and decontamination of a nuclear power plant that has under-gone a serious accident toward either a decommissioning or a resumption of operation.

Experience with such costs is currently being accumulated as a result of the Three Mile Island accident. It is already clear, however, that such costs can approach or even exceed the original capital cost of such a facility. As an illustration of the possible contri-bution to the economic risk, if the probability of an accident serious enough to require extensive cleanup and decontamination is taken as the sum of the nine categories in Table 7.3, i.e., about 5 chances in 10,000 per year, and if the "average" decontamination cost for these nine categories is assumed to be one billion dollars, then the estimated economic risk would be about $500,000 per year.

Other costs, besides damage to or loss of the facility, result from accidents. The major additional costs are replacement power and replacement of the capacity. These costs are affected by the point in the lifetime of the plant at which an accident might occur.

The present worth* cost is highest for an accident occurring at the beginning of the plant operating life and decreases over the plant life. It is assumed for these calculations that one unit of San Onofre 2 or 3 is permanently lost and replaced by new capacity after eight years and the undamaged unit is shut down for three years before restart. For illustrative purposes, the costs and economic risk have been estimated for a "worst case" situation for the approximately 2200-megawatt (electric) San Onofre Units 2 and 3 complex by postulating a total loss of one of the units in the first year of a projected 30-year operating life. Net replacement power cost of 45 mills/kWh is assumed (nearly all fossil units in southern California are oil-fired). Using a 60% capacity factor, the annual cost of replacement power would be $520 million for the two units in 1980 dollars. The additional capital costs as a result of having to construct a new facility are $60 million per year, again in 1980 dollars.

If the probability of sustaining a total loss of the original facility is taken as the probability of the occurrence of a core melt accident (approximately by the sum of probabilities for the categories PWR-1 through 7 in Table 7.3, i.e., about 5 chances in 100,000 per year), then the average contribution to economic risk that would result from a loss early in the operating life of a San Onofre unit is about $29,000 for each of the first three years until the undamaged plant is returned to service, then $16,000 per year until the damaged unit is replaced, and $3000 per year additional capital costs for the assumed remaining 22 years of plant service.

7.1.4.7 Uncertainties The foregoing probabilistic and risk assessment discussion has been based upon the method-ology presented in the Reactor Safety Study (RSS), 10 which was published in 1975.

In July 1977, the NRC organized an Independent Risk Assessment Review Group to (1) clarify the achievements and limitations of the Reactor Safety Study Group, (2) assess the peer comments thereon and the responses to the comments, (3) study the current state of such risk assessment methodology, and (4) recommend to the Commission how and whether such methodology can be used in the regulatory and licensing process. The results of this study were issued September 1978. 11 This report, called the Lewis Report, contains several findings and recommendations concerning the RSS. Some of the more significant findings are summarized below.

(1) A number of sources of both conservatism and nonconservatism in the probability calculations in RSS were found, which were very difficult to balance. The Review Group was unable to determine whether the overall probability of a core melt given in the RSS was high or low, but they did conclude that the error bands were understated.

(2) The methodology, which was an important advance over earlier methodologies that had been applied to reactor risk, was sound.

(3) It is very difficult to follow the detailed thread of calculations through the RSS.

In particular, the Executive Summary is a poor description of the contents of the report, should not be used as such, and has lent itself to misuse in the discussion of reactor risk.

On January 19, 1979, the Commission issued a statement of policy concerning the RSS and the Review Group Report. The Commission accepted the findings of the Review Group.

7-28 The accident at Three Mile Island occurred in March 1979 at a time when the accumulated experience record was about 400 reactor years. It is of interest to note that this was within the range of frequencies estimated by the RSS for an accident of this severity (ref. 4, p. 533). It should also be noted that the Three Mile Island accident has resulted in a very comprehensive evaluation of reactor accidents like that one, by a significant number of investigative groups both within NRC and outside of it. Actions to improve the safety of nuclear power plants have come out of these investigations, including those from the President's Commission on the Accident at Three Mile Island, and NRC staff investigations and task forces. A comprehensive "NRC Action Plan Developed as a Result of the TMI-2 Accident," NUREG-0660, Vol. I, May 1980 collects the various recommendations of these groups and describes them under the subject areas of: Operational Safety; Siting and Design; Emergency Preparedness and Radiation Effects; Practices and Procedures; and NRC Policy, Organization and Management. The action plan presents a sequence of actions, some already taken, that will result in a gradually increasing improvement in safety as individual actions are completed. The San Onofre plant is receiving and will receive the benefit of these actions on the schedule indicated in NUREG-0660. The improvement in safety from these actions has not been quantified, however, and the radiological risk of accidents discussed in this chapter does not reflect these improvements.

7.1.5 Conclusions The foregoing sections consider the potential environmental impacts from accidents at the San Onofre facility. These have covered a broad spectrum of possible accidental releases of radioactive materials into the environment by atmospheric and groundwater pathways. Included in the considerations are postulated design basis accidents and more severe accident sequences that lead to a severely damaged reactor core or core melt.

The environmental impacts that have been considered include potential radiation exposures to individuals and to the population as a whole, the risk of near- and long-term adverse health effects that such exposures could entail, and the potential economic and societal consequences of accidental contamination of the environment. These impacts could be severe, but the likelihood of their occurrence is judged to be small. This conclusion is based on (a) the fact that considerable experience has been gained with the operation of similar facilities without significant degradation of the environment; and (b) a probabilistic assessment of the risk based upon the methodology developed in the Reactor Safety Study.

The overall assessment of environmental risk of accidents, assuming protective action, shows that it is roughly comparable to the risk for normal operational releases although accidents h~ve a potential for acute fatalities and economic costs that cannot arise from normal operations. The risk of acute fatalities from potential accidents at the site are small in comparison with the risk of acute fatalities from other human activities in a comparably-sized population.

The staff has concluded that there are no special or unique features about the San Onofre site and environs that would warrant special or additional engineered safety features for the San Onofre plants.

REFERENCES

1. Statement of Interim Policy, "Nuclear Power Plant Accident Considerations Under the National Environmental Policy Act of 1969," 45 Federal Register 40101-40104, June 13, 1980.*

2. "Final Safety Analysis Report (FSAR), San Onofre Nuclear Generating Station Units 2 and 3, Docket Numbers 50-361 and 50-362," Southern California Edison Company and San Diego Gas and Electric Company, December 1, 1976, as amended.*

3. "Safety Evaluation Report related to the operation of San Onofre Nuclear Generating Station, Units 2 and 3 Docket Numbers 50-361 and 50-362," NUREG-0712, February 1981, as supplemented.**

4. "Energy in Transition 1985- 2010," Final Report of the Committee on Nuclear and Alternative Energy Systems (CONAES), Chapter 9, pp. 517-534, National Research Council, 1979 (available in public technical libraries) (also C.E. Land, Science 209, 1197, September 12, 1980).

5. "The Effects on Populations of Exposure to Low Levels of Ionizing Radiation," Advisory Committee on the Biological Effects of Ionizing Radiations (BEIR)*, National Academy of Sciences/National Research Council November 1972.***

6. "The Effects on Populations of Exposure to Low Levels of Ionizing Radiation,"

Committee on the Biological Effects of Ionizing Radiations (BEIR), National Academy of Sciences/National Research Council, July 1980.***

7. H.W. Bertini and others, "Descriptions of Selected Accidents that Have Occurred at Nuclear Reactor Facilities," Nuclear Safety Information Center, Oak Ridge National Laboratory, ORNL/NSIC-176, April 1980;*** also, "Evaluation of Steam Generator Tube Rupture Accidents," L.B. Marsh, USNRC Report NUREG-0651, March 1980.**

8. "Three Mile Island- A Report to the Commissioners and the Public," Vol. I, Mitchell Rogovin, Director, Nuclear Regulatory Commission Special Inquiry Group, January 1980, Summary Section 9.*

9. "Report of the President's Commission on the Accident at Three Mile Island,"

October 1979, Commission Findings B, Health Effects.*

10. "Reactor Safety Study," WASH-1400, USNRC Report NUREG-75/014, October 1975.**

11. H. W. Lewis and others, "Risk Assessment Review Group Report to the U.S. Nuclear Regulatory Commission," NUREG-CR-0400, September 1978.**

12. "Overview of the Reactor Safety Study Consequences Model," USNRC Report NUREG-0340, October 1977.**

13. "Liquid Pathway Generic Study," USNRC Report NUREG-0440, February 1978.**

14. Dana Isherwood, "Preliminary Report on Retardation Factors and Radionuclides Migration,"

Lawrence Livermore Laboratories, UCID-A3.44, August 5, 1977 (available in public technical libaries).

15. San Onofre Nuclear Generating Station Units 2 and 3, Applicant's Environmental Report, Operating License Stage, Volume 2, November 1976.*

• Available for inspection and copying for a fee in the NRC Public Document Room, 1717 H St. N. W., Washington, DC 20555.

• • Available from the NRC/GPO Sales Program, Washington, D. C. 20555 and the National Technical Information Service, Springfield, VA, 22161.

• • • Available from NTIS only.

8. NEED FOR THE STATION

8. 1 RESUME The ownership of Units 2 and 3 of the San Onofre Nuclear Generating Station is divided among Southern California Edison Company (SCE), 76.55%; San Diego Gas & Electric Company (SDG&E) 20%; the City of Riverdale, California, 1.79%; and the City of Anaheim, California, 1.66%. This section presents an analysis of the need for the station based on the energy demands of the applicant's service areas, the potential for production cost savings, and the potential *for increasing the reliability of the applicant's systems.

8.2 APPLICANT'S SERVICE AREAS AND REGIONAL RELATIONSHIPS 8.2.1 Applicant's service areas Southern California Edison Company's service area extends over a 15-county area of southern and central California, covering about 130,000 km2 (50,000 mi 2 ) and containing a population in excess of 7.5 million. In 1978, SCE served 2.95 million customers, over 88% of which were residential. San Diego Gas & Electric Company supplies electricity to about 700,000 customers in San Diego County and in portions of Orange and Imperial counties. The boundaries of the service area enclose a 10,630-kffi2 (4105-mi 2 ) area. The cities of Anaheim and Riverside serve their respective municipalities. A map of the applicant's service area is presented in Figure 8.1.

8.2.2 Regional relationships SCE and SDG&E are members of the Western Systems Coordinating Council (WSCC) and the California Power Pool (CPP). The WSCC is the regional reliability council for the interconnected power network that serves the states west of the Rockies and parts of British Columbia. Established in 1967, the WSCC's primary function is to facilitate coordinated planning among its member systems and to provide technical support. In relation to these duties, the WSCC compiles load and resource data for the region, performs reliability studies, and recommends minimum reserve criteria. The California Power Pool, whose members are Pacific Gas & Electric Company (PG&E), SCE, and SDG&E, was formed in 1964 to provide for the continuous interconnected operation of the member utilities' power supply systems. This interconnected operation allows the utilities to make more efficient, and therefore more economical use of their generation resources and increases the overall reliability of electric service.

8.3 BENEFITS OF STATION OPERATION 8.3.1 Minimization of production costs To minimize energy production costs, it is necessary to use the most economical mix of generation resources. The impact of the operation of SONGS 2 & 3 on the applicant's total cost of generation will be a major factor in determining the desirability of such operation. In assessing this impact, it is important to note that the fixed costs of each facility, such as the sunken capital investment and the fixed portion of the operating and maintenance costs, are irrelevant to the choice of which generation resources will be used to meet a given load, precisely because these costs are fixed and will not vary with an altered mode of system operation.

To assess the impact of station operation on the applicant's overall production costs, the staff first reviewed the latest production costs reported by the applicants for their electric generation stations. These data, presented in Tables 8.1 and 8.2, show that all oil/gas- and oil-fired facilities that are listed as base and/or intermediate units had production costs ranging from $29.2 to $56.7 per MWh, whereas Unit 1 of the San Onofre Nuclear Generating Station had a production cost of $9.0/MWhr. In determining how the additional units of the San Onofre Station would compare with these figures, the staff estimated the 1983 fuel cost for these units to be $10.8/MWhr. 1 Because SCE's and SDG&E's installed capacity is predominately oil- and oil/gas-fired, the staff concludes 8-1

8-2 ES-4116

... ~OJJ

---..... ...-;-.

I I

I I

\\1:l+l=m=~:t:+/-:ti/

SOUTHERN CALIFORNIA EDISON SOUTHERN CALIFORNIA EDISON SAN DIEGO GAS 8 ELECTRIC r

'

Fig. 8.1. Service areas of the member utilities of the California Power Pool.

p. 5.2-193.

~: ER,

8-3 Table 8.1. Southern California Edison Co. thermal-electric generating stations and production costs On-line dates Total station 1980 Production Station tor first and Function Fuel type capacity cost Name last unit (MW) (dollarsiMWh)*

Long Beach 1926-1977 p OiVgas 156 77.9 530 38.1 Redondo Beach 1946-1967 8,1 Oil/gas 642 41.5 31.8 Huntington Beach 1956-1969 I, p OIVgas 870 39.3 114 49.2 Mandalay 1959-1970 I, p Oil/gas 430 44.0 117 94.7 Ormond Beach 1971-1973 I Oil/gas 1,500 50.6 Alamitos 1956-1969 B, I, P Oil/gas 990 41.6 960 45.5 114 80.7 El Segundo 1955-1965 Oil/gas 1,020 41.8 Etiwanda 1953-1969 I, p Oil/gas 904 42.2 108 71.8 Mohave 1971 8 Coal 885 11.8 Four Corners 1969-1970 8 Coal 788 4.6 San Onofre Unit 1 1967 8 Nuclear 349 9.0 Coolwater 1961-1978 I Oil/gas 146 29.2 482 56.7 Highgrove 1952-1955 p Oil/gas 154 50.5 San Bernardino 1957-1958 p Oil/gas 126 35.0 Garden State 1967 p Oil/gas 12 67.0 Ellwood 1974 p Oil/gas 48 61.6 Note: B := base, I "' intermediate, and P := peaking.

• Fuel only.

Source: Letter from K. P. Baskin, Southern California Edison Co., to Frank Miraglia, USNRC, undated; received by USNRC on February 25, 1981.

Table 8.2. San Diego Gas & Electric Co. thermal-electric generating stations and production costs On-line dates Total station 1979 Production Station Name for first and Function Fuel type capacity cost last unit (MW) (dollarsiMWh)

Station "B" 1923-1941 p Oil/gas 90 188.8 Silver Gate 1943-1952 I OiVgas 230 48.9 Encina 1954-1978 B Oil/gas* 917 33.7 EncinaGT 1968 p Oil/gas 16 98.6 South Bay 196o-1971 8 Oil/gas 706 33.7 South 8ayGT 1966 p Jet Fuel 18 233.4 San Onofre Unit 1 1967 8 Nuclear 87** 9.3 El Cajon 1968 p Oil/gas 17 62.2 Kearny 1969 p Oil/gas 147 77.5 Division 1968 p Oil 16 97.6 Naval Training Center 1968 c Oil/gas 16 46.0 Miramar 1972 p Oil/gas 38 53.1 North Island 1972 PIC Oil 41 43.7 Naval Station 1976 c Oil/gas 26 41.0 Rohr 1979 c Oil 1 75.8 Note: P = peaking, I = intermediate, B = base, and C = Cogeneration.

• Encina Unit 5 (320 MW) oil only.

• • SDG&E's 20% share.

Source: Letter from K. P. Baskin, Southern California Edison Co., to V. A. Moore, USNRC, dated April11, 1980.

8-4 that the operation of SONGS Units 2 and 3 would tend to reduce reliance on these facilities with corresponding savings in production costs.

To quantify the magnitude of the production cost savings, the staff made a comparison between the fuel cost that would be incurred in 1983 (the first full year in which both units are scheduled for full operation) if the two nuclear units were operated at a combined capacity factor of 50%, and the fuel cost that would be incurred if an oil-fired facility produced the same amount of electricity. In this comparison, the staff assumed a nuclear fuel cost of $10.8/MWhr in 1983, an oil cost of $4.4 per million Btu in 1983, and an oil-fired plant conversion ratio of 9,000 Btu/kWhr. These assumptions lead to an oil cost of $39.6/MWhr. All costs have been adjusted by the Producers Price Index to reflect costs in 1980 dollars. The results show that operating the nuclear units will save $270 million in fuel costs during 1983. Lowering the assumed plant capacity factor to 40% resulted in a fuel cost savings of $210 million, and raising the capacity factor to 60% gave a cost savings of $320 million. The cost of nuclear fuels would have to rise by a factor of about 3-1/2, and the price of oil would have to remain the same for the fuel savings of operating the nuclear units to disappear. These results, coupled with the information presented in Tables 8.1 and 8.2, clearly indicate that the applicant's production costs will be reduced significantly by the operation of SONGS 2 &3.

8.3.2 Energy demand Table 8.3 presents SCE's forecasts of peak demand, energy requirements, installed generating capacity, arid reserve margins through 1985. These projections indicate that without SONGS 2 & 3 reserve margins fall below 13% from 1982-84 and dip to 7.1% in 1985. From 1980-85 SCE forecasts peak demand to grow at an average annual rate of 2.8%. A comparison with the State Level Electricity Demand2 (SLED) forecasting model developed at Oak Ridge National Laboratory indicates that over the same period the electrical energy demand in California is forecasted to grow at an average annual rate of 4.5%. SCE's projected reserve margins without SONGS 2 & 3 clearly indicates a need for this capacity to maintain system reliability. The comparison of the applicant's forecasts of demand with the SLED forecasts reinforces the need for the additional capacity and reserve margins provided by SONGS 2 & 3.

Table 8.3. Southern CaiHomia Edison Co. forecasts of peak demand, energy requirements, Installed generating capacity, and reserve margins through 1985 8 Installed Capacity Reserve Margin (MW) (%)

Area peak Total Growthb energy Growthb Year demand With Without With Without

(%) requirements (%)

(MW) SONGS SONGS SONGS SONGS kWh X 1()6 2&3 2&3 2&3 2&3 1976 11292 59428 14071 14071 24.6 24.6 1977 11564 2.4 63345 6.6 14278 14278 23.5 23.5 1978 12159 2.9 63877 0.8 14966 14966 23.1 23.1 1979 12662 4.1 66217 3.7 15071 15071 19.0 19.0 1980 12841 1.4 65459 -1.1 15504 15504 20.7 20.7 1981 13274 3.4 67120 2.5 15471 15471 16.6 16.6 1982 13647 2.1 67910 1.2 16184 15304 18.6 12.1 1983 13895 1.8 70220 3.4 17446 15686 25.6 12.9 1984 14305 3.0 72590 3.4 17837 16077 24.7 12.4 1985 14735 3.0 75130 3.5 17535 15775 19.0 7.1 8

Per November 18, 1980 Resource Plan.

bpercentage increase over previous year. 1976 through 1980 is recorded.

Source: Letter from K. P. Baskin, Southern California Edison Co., to Frank Miraglia, USNRC, undated, received by USNRC on February 25, 1981.

Table 8.4 provides .analogous projections of electricity demand, installed capacity, and reserve margins for SDG&E. Without SONGS 2 & 3 reserve margins drop below 15% in 1984 and below 10% in 1985. The average annual growth in peak demand has been forecast at 1.3% which is signific~ntly below the 4.5% rate forecast by SLED 2 for electrical energy demand in the State of'California. Reserve margins forecast by SDG&E indicate a need for

8-5 Table 8.4. San Diego Gas & Electric Co. forecasts of peak demand, energy requirements, Installed generating capacity, and reserve margins through 1987 Installed Capacity Reserve Margin (MW)c (o/o)C Area peak Energy Growthb Growthb Year demanda requirements With Without With Without (o/o) (o/o)

(MW) kWh X 1()6 SONGS SONGS SONGS SONGS 2&3 2&3 2&3 2&3 1978d 1981 13.5 10053 7.8 2030 2030 2.5 2.5 1979d 2019 1.9 10548 4.9 2363 2363 17.0 17.0 1980d 2050 3.7 10403 -1.4 2401 11 2401 8 17.1 17.1 1981 1975 -3.7 10738 3.2 2366 236fl 19.8 19.8 1982 2004 1.5 10824 0.8 2586 2366 29.0 18.1 1983 2033 1.4 11108 2.6 2806 2366 38.0 16.4 1984 2077 2.2 11407 2.7 2806 2366 35.1 13.9 1985 2184 5.2 11762 3.1 2806 2366 28.5 8.3 1986 2272 4.0 12244 4.1 2806 2366 23.5 4.1 1987 2361 3.9 12763 4.2 2806 2366 18.8 0.0 a 1981-1987 SDG&E CFM Ill Forecast .adopted by California Energy Commission in December 1980.

bPercentage increase over previous year.

0 Excludes purchased capacity.

d 1978 through 1980 are recorded.

BJuly net rating.

Source: Letter from K. P. Baskin, Southern California Edison Co., to Frank Miraglia, USNRC, undated, received by USNRC on February 25, 1981.

SONGS 2 & 3 to maintain system reliability. Once again comparing the applicant's fore-casts to the SLED forecasts reinforces the need for the additional capacity and reserve margins provided by SONGS 2 & 3.

The staff concludes on the basis of the analysis of the applicant's projected reserve margins that operation of SONGS 2 & 3 will be needed to ensure reliability within the time frame that operation is anticipated to begin. Furthermore, the analysis of cost savings due to a shift from oil-fired to nuclear generation (Sect. 8.3.1) makes operation of SONGS 2 & 3 economically desirable independent of load forecasts.

REFERENCES The documents references below are available from the NRC/GPO Sales Program, Washington, DC 20555 and the National Technical Information Service, Springfield, VA 22161.

1. J. 0. Roberts, S. M. Davis, and D. A. Nash, "Coal and Nuclear: A Comparison of the Cost of Generating Baseload Electricity by Region," U.S. Nuclear Regulatory Commission Report NUREG-0480, December 1978.

2. W. S. Chern, J. W. Dick, C. A. Gallagher, B. D. Holcomb, R. E. Just, and H. D.

Nguyen, "The ORNL State-Level Electricity Demand Forecasting Model," Oak Ridge National Laboratory Report ORNL/NUREG-63, July 1980.

9. CONSEQUENCES OF THE PROPOSED ACTION 9.1 ADVERSE EFFECTS THAT CANNOT BE AVOIDED The staff has reassessed the physical, social, and economic impacts that can be attributed to SONGS 2 &3. The identification of adverse effects that cannot be avoided, given in Chap. 8 of the FES-CP, remains valid. The major effects identified were the destruction of a small amount of wildlife habitat in the area occupied by the plant buildings and the loss of fish and other marine organisms that will be entrained in the circulating cooling water system.

In addition, construction has resulted in the excavation of about 16.4 ha (40.5 acres) of the San Onofre Bluffs, and operation of the plant will result in the removal of approximately 1.4 km (0.85 mile) of beach from unrestricted public use.

9.2 SHORT-TE~1 USES AND LONG-TERM PRODUCTIVITY The assessment of the short-term uses and long-term productivity contained in Chap. 9 of the FES-CP remains valid. About 21 ha (52 acres) of the total of 36 ha (90 acres) comprising all three units will be devoted to the production of electrical energy for the next 30 to 40 years.

If, at the end of this period, the site is no longer needed for the production of electrical energy, it could be used for other purposes (see Sect. 9.4, below).

9.3 IRREVERSIBLE AND IRRETRIEVABLE COMMITMENT OF RESOURCES There has been no change in the staff's assessment of these commitments since the earlier review (FES-CP, Chap. 10) except that the continuing escalation of costs has increased the dollar values of the materials used for construction and for fueling the plant. The staff has, however, expanded and updated the discussion on uranium fuel availability. This updated discussion is presented below.

9.3.1 Replaceable components and consumable materials Uranium is the principal natural resource irretrievably consumed in facility operation. Other materials consumed, for practical purposes, are fuel-cladding materials, reactor-control elements, other replaceable reactor core components, chemicals used in processes such as water treatment and ion-exchanger regeneration, ion-exchange resins, and minor quantities of materials used in maintenance and operation. Except for the uranium isotopes U-235 and U-238, the consumed resource materials have widespread use; therefore, their use in the proposed operation must be reasonable with respect to needs in.other industries. The major use of the natural isotopes of uranium is for production of useful energy.l The reactor will be fueled with uranium enriched in the isotope U-235. After use in the plant, the fuel elements will still contain U-235 slightly above the natural fraction. This slightly enriched uranium, if separated from plutonium and other radioactive materials (separation would take place in a chemical reprocessing plant), would be available for recycling through the gaseous diffusion plant if required. Scrap material containing valuable quantities of uranium may also be recycled through appropriate steps in the fuel production process. Should chemical reprocessing of spent fuel be effected in the future, the fissionable plutonium recovered is potentially valuable for fuel in power reactors.

In' view of the quantities of materials in natural reserves, resources, and stockpile and the quantities produced yearly, the expenditure of such material for the power facility is justified by the benefits from the electrical energy produced. A detailed discussion of uranium supply and demand follows.

9-1

9-2 9.3.2 Uranium resource availability This section reviews information available from the Department of Energy (DOE) on the domestic uranium resource situation ~nd the outlook for development of additional domestic supplies, avail-ability of foreign uranium, and the relationship of uranium supply to planned nuclear generating capacity.

• Analysis of uranium resources and their availability has been carried out by the government since the late 1940's. The work was carried out for many years by the Atomic Energy Commission (AEC).

The activity was made part of the Energy Research and Oevelo~ment_Administration (ERDA) when the agency was created in early 19751 and was subsequently transferred to the DOE when it was formed October 1, 1977.

9.3.2.1 u.s. resource position To establish some basic terminology, a review of resource concepts and nomenclature would be worthwhile. Figure 9.1 defines resource categories based on varying geologic knowledge.

Resources designated as ore reserves have the highest assurance regarding their magnitude and economic availability. Estimates of reserves are based on detailed sampling data, primarily from gamma ray logs of drill holes. DOE obtains basic data from industry from its exploration effort and estimates the reserves in individual deposits. In estimating ore reserves, detailed studies of feasible mining, transportation, and milling techniques and costs are made. Con-sistent engineering, geologic and economic criteria are employed. The methods used are the result of over 30 years of effort in uranium resource evaluation.

Es.3336A

--

URANIUM RESOURCES RESERVES- Defined by direct sampling

+ POTENTIAL RESOURCES-Incompletely defined or undiscovered DECREASING KNOWLEDGE AND ASSURANCE Fig. 9.1. DOE uranium resource categories.

Resources that do not meet the stringent requirements of reserves are classed as potential resources. For its study of resources, DOE subdivides potential resources into three categories:

probable, possible, and speculative.2 Probable potential resources are those contained within favorable trends, largely delineated by drilling, within productive uranium districts, i.e.,

those having more than 10 tons of U308 production and reserves. Quantitative estimates of potential resources are made by considering the extent of the identified favorable areas and by comparing certain geologic characteristics with those associated with known ore deposits.

Possible potential resources are outside of identified mineral trends but are in geologic pro-vinces and formations that have been productive. Speculative resources are those estimated to occur in formations or geologic provinces which have not been productive but which, based on the evaluation of available geologic data, are considered to be favorable for the occurrence of uranium deposits.

9-3 Because any evaluation of resources is dependent upon the availability of information, the estimates themselves are, to a large degree, a scorecard on the state of development of informa-tion. Thus, appraisal of U.S. uranium resources is heavily dependent on the completeness of exploration efforts and the availability of subsurface geologic data. Since the geology of the United States as it relates to mineral deposits can never be completely known in detail, it will not be possible to produce a truly complete appraisal of domestic uranium resources. It is likely that the total resource picture will eventually prove larger than currently estimated given the nature and status of estimation methodology. The key factor may be the timeliness with which resources are identified, developed, and produced.

Conceptually, a resource, whether uranium or other mineral commodity, would initially be in the potential category. Development of additional data and clarification of production techniques and economics would be required to delineate and understand specific ore deposits to a degree that they could be categorized as reserves.

We can expect a dynamic balance between anticipated markets and prices and the extent to which exploration and reserve delineation will be done. There is no economic incentive for industry to expand reserves if the additional uranium will not be needed for many years ahead, and especially if the long-term market outlook is uncertain. This has been true for uranium. The mining companies are concentrating on markets for the next 5 to 15 years. The utilities and government are concerned with the outlook for the next 30 to 40 years.

Conversion of the currently estimated potential resources into ore reserves will take many years and will cost several billion dollars. It would be difficult to economically justify acceler-ating such an effort to delineate ore reserve levels equal to lifetime requirements of all planned reactors covering some 30 to 40 years in the future simply to satisfy planners. Supply assurance through continued timely additions to reserves and maintenance of a resource base adequate to support production demands, coupled with carefully developed information on potential resources, is considered to be adequate and a more realistic and economic approach. The conversion of potential resources to ore reserves and expansion of production facilities can be accomplished when needed as markets expand and production is needed.

All uranium resource estimates made by DOE and its predecessor agencies before 1979 were single estimates of tons of ore and grade for various cost categories. The estimtes were made by experienced geologists and engineers according to standard procedures, and represented a reason-able measure of resources. The current procedures for estimating uranium resources provide both mean values and distributions to characterize the reliability of the estimates at specific con-fidence levels. All available geologic information and the expertise of the estimators are fully utilized. These procedures are standardized and documented to minimize personal biases and to facilitate reviews and revisions as new information is acquired.

The estimates of resources in the United States are developed from a data base accumulated during the past three decades of Government and industry activities and enhanced by National Uranium Resource Evaluation program investigations of the past five years. Data acquired to support resource assessment have been extensive and varied. The assessment includes the evaluation of several hundred thousand industry-drilled holes; aerial radiometric surveys;,sampling and geochemical analyses of groundwater, stream water, and stream sediment; selective drilling to fill voids in subsurface information; and extensive geologic field examinations. These data have been evaluated to determine those areas favorable for uranium occurrences. Evaluation criteria have been developed from studies of uranium deposits throughout the world. In favorable areas, the uranium endowment, material greater than 0.01 percent U308 , is estimated, and subsequently economic factors are applied to assess the potential resources available at selected costs.

The costs used to calculate uranium resources are forward costs which consider both operating and capital costs, in current dollars, that would be incurred in producing the uranium. These costs include power, labor, materials, royalties, payroll, severance and ad valorem taxes, insurance, and applicable general and administrative costs. All previous expenditures (before the time of the estimate) for such items as property acquisition, exploration, mine development, and mill construction are excluded. Also excluded are income taxes, profit, and the cost of money. The resources assigned to the various.cost categories are independent of the market price at which the uranium might be sold.

There are two major methodologies in uranium assessment; one is used for the estimation of reserves based on sample results from drill holes on specific properties; the second involves the use of a variety of geologic information to subjectively estimate potential resources.

Reserves are calculated individually for properties throughout the United States using data voluntarily provided by the uranium companies to DOE. The data consist primarily of radio-metric drill hole logs and maps. Parameters evaluated include thickness and tenor of mineralized rock; depth and spatial relationships, mining methods, ore dilution, and recovery; and amenability of ores to processing. The amounts of uranium that could be exploited at the for-ward cost levels are calculated according to conventional engineering practices utilizing available engineering, geologic, and economic data.

9-4 A regional reserves distribution estimate is obtained by mathematically combining the estimates of individual distributions for each property. These regional distributions are then combined to provide a total for the United States. Estimates include all material over a selected minimum thickness with a uranium content above 0.01% U308

• A recovery factor is applied, after rate procedures are used for properties on which solution mining is in progress or is planned.

Potential resource estimates are based on geologic analogy. Geologic characteristics related to uranium potential in the area being investigated are compared with those in an area with similar characteristics, that is, a control area that contains uranium deposits for which the frequency distribution of grades and tonnages in the deposits has been developed. The analogy-based methodology is made feasible by DOE's extensive data base from which detailed characterizations of the distribution of uranium have been developed. From systematic comparison with an appro-priate control area, an estimate is developed of the total amount of uranium, above 0.01% U308 ,

that might be present in an area being evaluated. Uranium endowment factors, such as surface area, fraction underlain by endowment, grade, and tonnage are estimated at three confidence levels, i.e., a modal value which is considered as most likely, and a low and high estimate corresponding respectively to a 95 and 5% probability that the factor is at least that large.

The endowment estimate is analyzed to determine the portions that are producible at various.cost categories within stated confidence levels.

Table 9.1 provides the mean reserve and potential resource estimates for each cost category, as well as estimates at the 95th and 5th percentile. The 95th percentile value provides an estimate for which there is a 95% confidence that at least that amount exists. The 5th percentile pro-vides an estimate for which there is a 5% probability that it will be exceeded. Due to the correlation of the individual estimates that are aggregated to generate the regional and national totals, the estimates at the 95th and 5th percentile are not directly additive; however, the mean values are additive.

Tabla 9.1. Uranium mou,_ of the United States a Reserves as of January 1, 1980 Other Resources as of October 1, 1980 Tons UaOe Probability distribution values Forward-cost Me111 95th percentile 6th percentile category At $15 per pound of Ua08 C Reserves 226,000 190,000 260,000 Probable 296,000 186,000 448,000 Possible 87,000 42,000 166,000 Speculative 74,000 30,000 162,000 Totals 681,000 447,000 1,026,000 At $30 per pound of U3 0ab, d Reserves 646,000 667,000 729,000 Probable 886,000 669,000 1,161,000 Possible 346,000 194,000 630,000 Speculative 311,000 166,000 600,000 Totals 2,187,000 1,731,000 2,748,000 At $50 per pound of lJaOa b ,e Reserves 936,000 821,000 1,060,000 Probable 1,426,000 1,102,000 1,802,000 Possible 641,000 346,000 973,000 Speculative 482,000 261,000 890,000 Totals 3,485,000 2,771,000 4,313,000

• At$100 per pound of u3 o8 b, f Reserves 1,122,000 971,000 1,291,000 Probable 2,060,000 1,646,000 2,673,000 Possible 1,005,000 621,000 1,526,000 Speculative 696,000 378.000 1,225,000 Totals 4,903,000. 3,876,000 6,056,000 a

bUranium resources are estimated quantities recoverable by mining.

Includes lower cost resource categories.

~$6.80 per kilogram.

$13.60 per kilogram.

~$22.65 per kilogram.

$45.30 per kilogram.

(To convert pounds to kilograms, multiply by 0.454; to convert tons to tonnes, multiply by 0.907.}

9-5 Most of the uranium resources are located in a few areas in the Colorado Plateau of New Mexico, Arizona, Colorado, and Utah, in the Wyoming Basins, and in the Texas Gulf Coastal Plain, Figs. 9.2 and 9.3. It should be noted that the reserve estimates in Table 9.1 were as of January 1, 1980, and the lower cost reserves have undoubtedly decreased since that date because of continuing rising costs.

E5-3331A TOTALS !THOUSANDS OF TONS UAI PROIIA8LE 1,<l211 POSSIIILE 641 SPECULATIVE 482 lu ot10/80 Fig. 9.2. Potential uranium resources by region ($22.65 per kilogram

($50 per pound) of u3o8 ).

9.3.2.2 Uranium exploration activities Uranium exploration in the United States reached its all time high in 1978 as measured by the principal exploration indicator, surface drilling. Data provided to DOE by the exploration companies indicated a total of 14.6 million meters (48 million feet) of drilling in 1978. In 1979, however, drilling declined to 12.5 million meters (41 million feet), and during 1980 the downward trend steepened with drilling estimated to be approximately 8.5 million meters (28 million feet) for the year (see Figure 9.4).

Annual gross additions to reserves, a measure of exploration success, have been at high levels for the higher cost, i.e., $13.60 to $22.65 per kilogram ($30 and $50 per pound) U3 08 categories, but have been decreasing for lower cost levels. Costs have increased significantly in recent years raising the quality of resources needed to produce at a given cost level and reducing the quantities available at that level.

For exampJe, in 1979 only 907 tonnes (1000 tons) were added to $6.80 ($15) cost revenues, but 47,164 tonnes (52,000 tons) were removed, largely because of inflation, and an additional 12,698 tonnes {14,000 tons) were depleted by production. Hence, in 1979, $6.80 ($15) reserves decreased from 263,030 to 204,075 tonnes (290,000 to 225,000 tons). This trend continued in 1980. On the other hand, in 1979 some 84,351 tonnes (93,000 tons) were added to $22.65 ($50) reserves and 69,839 tonnes (77,000 tons) removed for a net increase of 14,512 tonnes (16,000 tons) U3 08

• Thus, while exploration has been successful, the costs of producing the resources found are high in comparison with current prices and concurrently the cost of producing previously found resources has also increased.

The sharp rise in exploration resulted from the increase in prices in the 1974 to 1976 period, the active procurement activity of utilities, and the optimistic projections of future growth in uranium demand.

Many new companies became active in exploration. Over 150 companies were involved in exploration in 1979.

Considering the drop in requirement projections the level of activity reached probably was in excess of real needs. Therefore, some reduction of effort more in line with future needs is not detrimental.

9-6 E5-4104A GEOLOGIC PROVINCE

• URANIUM AREA Fig. 9.3. Uranium areas of the United States.

Es-45028 U.S. EXPLORATION ACTIVITY & PLANS 360 320 280

-ACTUAL

- - - PLANNED- 1979 240 oaaeoeo PLANNED- 1960

"'

oo * * * *

• 1960 ESTIMATE 200 :5"'....

0 0

u.

0 160 (I) z 0

....

120 :E 50

....

lli40 60 u.

u.

5!30 z

0 40 320

E 0

10 1966 1968 1970 1972 1974 1976 1978 1960 YEAR Fig. 9.4. u.s. exploration activity and plans. {To convert feet to meters, multiply by 0,3048.)

~7 9.3.2.3 Domestic uranium production and capability Domestic uranium production in 1980 was 19,573 tonnes (21,850 tons) U3 08 in concentrate. This represents a 15% increase over 1979 and is the highest U.S. production level for any single year. Production in recent months has been at record rates; the equivalent of over 19,954 tonnes (22,000 tons) U3 08 per year.

This production comes from conventional mine-mill operations as well as nonconventional sources such as solution mining and byproduct recovery from processing of other minerals. The high production levels are in response to prior sales contracts. Buyers are actually receiving uranium in excess of their currently scheduled needs.

Several new uranium processing facilities are under construction or planned which could bring the total national capacity to around 27,000 tonnes (30,000 tons) per year by the mid-l980s.

Despite the increases in ore throughput and uranium production in 1980, a widespread curtailment of uranium mining and milling activities is underway. Production at some operating mines has been reduced and some planned mill expansions and construction are being postponed. The reduction in mine output will not be reflected in decreased uranium production until mine and mill ore stockpiles are reduced.

Studies have been conducted on attainable uranium production levels from uranium reserves in the United States and related costs. The uranium production capability projections should not be construed as being estimates of actual future supply, but simply as potential production which may be available to meet whatever demand eventually exists.

Using the "production center" concept, U.S. uranium production capability has been projected from ore reserves estimated as of January 1980, to be available at forward costs of $13.60 to $22.65 per kilogram

($30 and $50 per pound) U3 08 or less. The production centers consist of operating (Class 1), committed (Class 2), planned (Class 3) uranium extraction and processing facilities, and projected (Class 4) facili-ties based on probable potential resources. The study included conventional mills supplied by open pit and/or underground mines; solution mining and heap-leach operations; and operations where uranium is recovered as a byproduct of phosphate, copper, or beryllium mining and processing activities.

Projections are based primarily on operating conditions - average ore grades, mill recoveries, and oper-ating and capital costs- similar to those currently prevalent in the uranium mining and milling industry.

Specific information on company plans, costs, and operating methods has been considered.

Figure 9.5 shows the total projected production capability for $13.60 ($30) resources by resource category.

Figure 9.6 shows the capability for $22.65 ($50) resources. Projected uranium demand and current sales commitments are also shown. Domestic demand is based on the DOE's Office of Uranium Resources and Enrich-ment 1980 nuclear power growth projections, assuming no reprocessing and a 0.20% U-235 enrichment tails assay.

9.3.2.4 Domestic reactor requirements The outlook for uranium requirements is closely related to the growth of nuclear power. On December 1, 1980, there were 75 nuclear power reactors licensed to operate in the U.S., concentrated mostly in the East and Midwest. These plants have an electrical generating capacity of 55 Gigawatts (GWe). In addition to operating plants, there are under construction 86 plants with a total rated capacity of 95 GWe. Some of the plants are at such an early construction stage that they may be deferred or cancelled completely.

An additional 17 reactors with 20 GWe capacity are on order. Together the group aggregates 170 GWe of capacity. However, the future for some of the ordered reactors is questionable.

Latest projections of nuclear power growth by the DOE's Office of Uranium Resources and Enrichment (URE) and the Energy Information Administration (EIA), Table 9.2, show an increase in nuclear power licensed to operate from 55 GWe at the end of 1980 to 96 GWe in 1985, 129 GWe in 1990, 155 GWe in 1995, and 180 GWe in 2000. EIA also projected a low case of 160 GWe *and a high case of 200 GWe in 2000.

There are alternative views on U.S. power growth. The DOE's Office of Planning and Analysis has projected nuclear growth to the year 1990 at 125 GWe and to the year 2000 at 150 GWe, based on historic delays to nuclear power growth. The DOE Office of the Assistant Secretary of Nuclear Energy has projected 400 GWe, based on energy demand, growth, nuclear competitiveness, and industry construction capability. All of these values are sharply reduced from the projected growth of the nuclear industry of just a few years ago. For example, in 1976 U.S. nuclear capacity in the year 2000 had been projected to be 500 GWe, and in 1978 it had been projected to be 320 GWe.

9-8 E&6733 ESTIMATED ANNUAL NEAR-TERM PRODUCTION CAPABILITY FROM R!SOURCESAVAILABLEAT $30/LB U30 8 OR LESS WITH CLASS 1, 2, AND 3 EXPANSIONS AND CLASS 4 70 rn Classes 1-3, without expansions 60 I') 50

~

X co o.., 40

>

(/.)

z

~ 30 20 10 80 82 84 86 88 90 92 94 96 98 00 02 04 06 08 09 YEAR Fig. 9.5. Estimated annual near-term production capability from resources available at

$13.60 per kilogram ($30 per pound) of U30s or less with Class 1, 2, and 3 expansions and Class 4. (To convert tons to tonnes, multiply by 0,907,}

Even at the more conservative estimates, nuclear capacity still is expected to expand substantially and to provide a significant portion of future domestic electric capacity. Current methods of proiecting nuclear growth and uranium requirements are based on estimates of reactor startup dates considering construction .

and licensing times, and systems power requirements. Accurate forecasts have proven to be difficult.

The uranium needed_ to be delivered by uranium concentrate-producing plants as fuel for the nuclear plants will also increase over time; for the URE mid-case, from 12,063 tonnes (13,300 tons) U3 08 in 1981 to 21,405 (23,600) in 1985, 26,212 (28,900) in 1990, 31,745 tonnes (35,000 tons) in 1995, and 36,280 tonnes (40,000 tons) in 2000, if the enrichment plants are operated at 0.20% U-235 tails assay. Cumulative uranium requirements through the year-2000 range from 462,570 to 562,340 tonnes (510,000 to 620,000) tons U3 08 with 516,990 tonnes (570,000 tons) U3 08 for the mid-case.

Uranium requirements are based on normal lead times for fuel cycle steps and current technology for enrich-ment and for reactor design and operation. There are possible improvements in enrichment which would allow use of lower tails assays which would reduce uranium requirements. There are also possible improve-ments to reactor design and operation that could reduce uranium requirements. These factors .are not likely to have a significant impact on uranium demands until at least well into the 1990s.

9.3.2.5 Uranium inventories Buyers* inventories of uranium have been increasing for several years as actual deliveries have been in excess of needs. Inventories at the beginning of 1980 totalled 32,742 tonnes (36,100 tons) of natural uranium (Table 9.3), with 25,033 tonnes (27,600 tons) held by utilities. In 1980, U.S. utilities sent an

9-9 E~732 120~--------------~------------------~

Uranium requirements based on URE

-...

0

.... 100 enrichment planning cases at 0.20% tails assay

....w<[

~ 80

.... From possible and z speculative resources w

0 z 60 0

0 z

.. 40 0...

>

(/)

z 20

....0 From reserves 1980 1990 2000 2010 2019 YEAR Fig. 9.6. Annual production capability from resources available at $22,65 per kilogram

($50 per pound) of U30s or less projected to meet nuclear power growth demand.

(To convert tons to tonnes, multiply by 0.907.)

Table 9.2. U.S. nuclear power growth projections (June 19801 Power Range End of year [GW(e)]

Low Mid High

--~*-***---*

1985 85 96 105 1990 125 129 140 1995 142 155 165 2000 160 160 200

Table 9.3. Buyers' inventories of natural uranium (Tons U3 0 8 1 Beginning of Domestic Foreign Total year origin origin 1976 22,600 1,100 23,700 1977 25,600 3,500 29,300 1978 25,100 3,600 28,700 1979 28,000 5,200 33,200 1960 30,800 5,300 36,100

(To convert tons to tonnes, multiply by 0.907.)

9-10 equivalent of 15,691 tonnes (17,300 tons) U3 08 to the DOE gaseous diffusion plants for enrichment. Thus, the 25,033 tonnes (27,600 tons) inventory level amounted to 1.6 years of U.S. utilities' needs. Of those U.S. utilities who have responded to questions on inventory levels, most have indicated that they desire a level amounting to about one year's needs, although some have reported inventory levels as small as three month's needs, while others desire inventories as great as two year's needs. Producers also had inventories of about 2,177 tonnes (2,400 tons) U3 08 at the beginning of 1980, which is about a normal working inventory.

The outlook is for a continuing buildup of buyers' inventories, as current contracted deliveries are in excess of actual needs.

9.3.2.6 Analysis of production capability and reactor capacity Study of attainable production capability from currently estimated $13.60 ($30) U.S. ore reserves an~

probable potential resource, previously referenced, indicates that production levels of 40,815 tonnes (45,000 tons) U3 08 per year can be achieved with aggressive resource development and exploitation including both mining and milling. Although the level may be achieved by use of domestic $13.60 ($30) ore reserves and probable resources alone, development and utilization of $30 possible and speculative cate-gories and use of $22.65 ($50) ore reserves and potential resources would provide added assurance that the levels could be attained and sustained. Considering the use of $22.65 ($50) resource, a level of 54,240 tonnes (60,000-tons)/year supply is achievable from currently estimated resources. Such a level could be reached by the early 1990s. Imported uranium and inventories would add to the supply from these projections.

The level of nuclear generating capacity supportable with 54,240 tonnes (60,000 tons)/year of uranium, will vary with enrichment tails assay and recycle assumptions. Without recycle of uranium or plutonium and with a 0.30% U-235 enrichment tails assay, about 260,000 MWe could be supported. Without recycle and at 0.20% tails assay, about 310,000 MWe could be supported. With recycle of uranium and plutonium and a 0.20% tails assay, about 520,000 MWe could be supported. All the levels of supportable capacity are above the 170,000 MWe of capacity in operation (55,000 MWe), under construction (95,000 MWe), and on order (20,000 MWe), as of late 1980. Thus, currently estimated resources can provide adequate uranium supplies for a sizable expansion to U.S. nuclear generating capacity.

The cumulative lifetime (30 years) uranium requirements for all of the above reactors (170,000 MWe) would be about .907 million tonnes (1.0 million tons) U3 08 at 0.20% enrichment tails with no recycle, compared to the 1.45 million tonnes (1.6 million tons) mean value in $13.60 (($30) or the 2.27 million tonnes at

$22.65 (2.5. million tons at $50)) ore reserves, by-product, and probable potential resources. Evaluation of long-term fuel commitments on the basis of ore reserves and probable potential resources is considered a prudent course.for planning. The lifetime commitment would be less than one*third of currently estimated

$22.65 ($50) domestic resources, including the possible and speculative categories (see Table 9. 1).

9.3.2.7 Uranium resource recovery In regard to the availability of estimated uranium resources considering recoveries in mining and ore processing, estimates of U.S. uranium resources represent the quantity of uranium estimated to be minable expressed as tons of U3 08 of ore in the ground. These estimates are a reflection of the information available to DOE at the time of the estimate and thus are dependent on the extent of exploration. In view of the considerations involved in preparing the resource estimates and the uranium resource outlooK, no adjustment for losses is warranted.

U.S. mining practice results in recovery of high percentages of the uranium contained in a deposit. DOE resource estimation procedures consider the capabilities and requirements of mining systems currently in use so that the estimates are a realistic appraisal of what is minable. Because deposits frequently are not fully delineated before they are developed, it is not unusual for more uranium to be recovered from deposits than was included in ore reserves before such deposits were put into production. Mining company practice seeks to recover as much of the contained mineral content as possible before abandoning a mine.

A strong incentive for such practice is the increase in financial returns. In the processing of uranium ores, recoveries generally are over 90%. In 1980, mill recovery averaged about 93%. Higher recoveries are usually possible if economically justified.

9.3.2.8 High cost resources An alternative to identification of additional low-cost resources is the utilization of higher cost resources. The highest cutoff cost category included in DOE resources in Table 9. l, is $45.30 per kilogram ($100 per pound) of U3 08

• This level is an upper range of what might be of interest for utilization in light water reactors over the next few decades.

9-11 The increased price of oil and coal in the last few years has been a contributing factor to the increased price of uranium economically acceptable in light water reactors. This impact results from the relative insensitivity of nuclear electric power costs to increases in uranium prices. The cost of fuel is a very small fraction of the cost of power from a nuclear plant. In turn, the cost of natural uranium is only a small fraction of the fuel cost; enrichment, fabrication, reprocessing, and carrying charges make up the balance. As a result, large increases in uranium prices result in comparatively small increases in power costs. As pointed out in Section 9.3.2.6, nuclear capacity currently in operation, under construction, and on order, is expected to have adequate supplies of U3 08 at prices much lower than $45.30 per kilogram

($100 per pound) in 1980 dollars.

Knowledge of U.S. resources in the above $22.65 ($50) category is meager, largely because of the lack of past economic interest. There has been virtually no industry activity to search for or to develop such resources. Prospects for discovery of higher cost resources in the United States are considered promising at this stage of U.S. exploration. The principal large, very low-grade deposits that have been studied in some detail in the past are the shales and phosphates. The Chattanooga shale in Tennessee is of particular interest because of its large size. This deposit was extensively drilled, sampled, and studied in the 1950s. The higher grade part of the Chattanooga shale has an average uranium content of about 60 to 80 ppm compared to 1500 ppm in present-day ores. It contains in excess of 4.5 million tonnes (5 million tons) of U3 08 that may be producible at a cost of $45.30 or more per kilogram ($100 or more per pound) of U3 08

• Additional work to develop production technology will be needed.

If Chattanooga shale were mined to fuel an 1150-MWe reactor, assuming recycle of uranium (but not of plutonium) and a 0.3% enrichment tail, about 11,428 tonnes (12,600 tons) of shale would have to be processed each day; with uranium and plutonium recycle (should that be practiced) and 0.20% enrichment tails, about 7,710 tonnes (8500 tons) per day would have to be processed. An average of about 10,250 tonnes (11,300 tons) of coal would have to be burned each day if 20 MJ/kg (8700 Btu/lb) of coal were used to produce power equivalent to that produced by a 1150-MWe reactor.

Utilization of the very low-grade resources such as Chattanooga shale would, of course, involve mining and processing very much larger quantities of ore than is currently mined to produce the same amount of uranium.

From an environmental as well as from an economic point of view, identification and utilization of addi-tional higher grade ores would be preferable. However, the shales are available if their use should become necessary.

9.3.2.9 Prices During the period 1973-1979, the average delivery price per kilogram (pound) of U3 08 for sales from domestic producers to domestic buyers, in year-of-delivery dollars, increased from $3.22 to $10.80 ($7. 10 to $23.85), as shown in Table 9.4.

Table 9.4. Historical trend of average uranium prices (Dollars' per pound of U3 0 8 )

Year Final Price 1973 $ 7.10 1974 7.90 1975 10.50 1976 16.10 1977 19.75 1978 21.60 1979 23.85 8

Year*of*delivery dollars.

(To convert dollars per pound to dollars per kilogram, multiply by 0.453.)

Future prices for material under contract as of July 1, 1980, as reported to DOE, is shown in Table 9.5.

Also shown are the p~rcent~ge~ of materia~ under contract ~rice arrangements covering the price data presented. The rema1nder 1s 1n market pr1ce contracts or 1n captive production.

9.3.2. 10 Foreign uranium resource position The most reliable source of information on world uranium resources is that compiled by the Working Party on Uranium Resources sponsored jointly by the Nuclear Energy Agency (NEA) and the International Atomic

9-12 Table 9.5. Average contract prices and *ttled market price contracts for uranium July 1,1980 IDollan" per pound of U3 0 8 I Percentages of procurement under Year Price contract price contracts 1980 26.oo" 66 1981 2a7fl> 55 1982 34.80 47 1983 41.40 43 1984 43.45 35 1985 43.45 32 1986 46.85 16 1987 43.55 18 1988 42.70 22 1989 51.85 23 1990 53.25 16 8

Year-of-<lelivery dollan.

bThese yaan include settled market price contracts.

Market price contract prices are determined sometime before delivery, based on prevailing market prices.

(To convert dollars per pound to dollars per kilogram, multiply by 0.453.)

Energy Agency (IAEA). This group has been gather'ing and publishing uranium resource estimates since 1965 and includes most of the significant uranium resource countries. In compiling its estimates this group classifies resources as Reasonably Assured resources (roughly comparable to ore reserves in the usual mining industry sense) and Estimated Additional resources (roughly comparable to DOE's probable potential resources). Resources in the world outside of the centrally planned econ0111ies area (WOCA) are tabulated by continents and major countries in Table 9.6.

Almost 80% of these resources are concentrated in three continents: North America, Africa, and Australia.

Six countries within those continents- U.S., Canada, South Africa, Namibia, Niger, and Australia- have about three-quarters of the Reasonably Assured resources. This geographic concentration is a reflection of the geologic favorability of these areas as well as the extent of exploration and resource appraisal efforts to date.

9.3.2. 11 Foreign production capacity and plans Studies by the NEA and the IAEA have also provided reliable information on world production capacity. The current production capacity of existing non-U.S. plants (Class 1) is about 34,466 tonnes (38,000 tons)

UsOs annually, as shown in Table 9.7. This production is primarily in Canada, France, Namibia, Niger, an~

South Africa.

Construction of new plants (Class 2) with a capacity of about 7,256 additional tonnes (8,000 tons) is taking place, primarily in Australia and Canada. Plants that are planned (Class 3), could increase total annual production by another 32,652 tonnes (36,000 tons) U308 for a total of 76,188 tonnes (84,000 tons)

U3 0a by 1990. Since needs for uranium are well below attainable production capacity levels, and prices would not justify all operations, it is likely that many of the projected plants will be built on a deferred schedule. It is also possible that some new plants will replace existing operations. Countries of particular significance in future production expansion are Australia and Canada, which have 82% of capacity under construction and 70% of the planned additional capacity.

9.3.2. 12 Foreign reactor requirements The uranium requirements in non-Communists foreign countries have been projected by the Energy Informatior Administration based on the reactors planned and timing of construction. Table 9.8 shows three cases of power plant growth which, by the year 2000, range from 300 GWe to 400 GWe of nuclear power in operation.

The mid-case is taken as the most likely one. However, nuclear power growth projections have been subject to continual downward revision in the last several years.

9-13 Table 9.6. Worid uranium resources by continent" (World outside centrally planned economies area)

(thousand tons U3 0al

Reasonably assured Estimated additional

$30/lb $50/lbb $30/lb $50/111' North America u.s. 645 940 885 1,430 Canada 280 305 480 945 Other 9 44 44 65 Total 930 1,290 1,410 2,440 Africa South Africa 320 508 70 180 Niger 210 210 69 69 Namibia 152 173 39 69 Other 109 115 2 22 Total 790 1,000 180 340 Australia Total 380 390 165 180 Europe France 51 72 34 60 Spain 13 13 11 11 Sweden 1 390 0 4 Other 22 31 19 53 Total 90 510 60 130 Asia India 39 39 1 31 Other 13 21 0 0 Total 50 60 0 30 South America Brazil 96 96 t17 117 Argentina 30 36 5 12 Other 0 0 7 8 Total 130 130 130 140 Worldwide total (rounded) 2,400 3,400 1,900 3,300

~ *-*-*--------

aModified from "Uranium Resources, Production and Demand" OECD, Nuclear Energy Agency (NEAl, and the International Atomic Energy Agency (IAEA), December 1979.

b Includes resources at $30 per pound of U3 0 8 *

(To convert tons to tonnes, multiply by 0.907; to convert

$ per pound to$ per kilogram, multiply by 0.453.)

In order tq supply these nuclear plants, EIA has estimated the amount of uranium required assuming 0.20%

U-235 enrichment plant tails and no recycle of uranium or plutonium. Table 9.8 gives the annual tons U3 08 from 1980 to 2000 for high-, mid-, and low-cases.

For the mid-case, foreign requirements increase from 16,689 tonnes (18,400 tons) U3 08 in 1980, to 23,763 tonnes (26,200 tons) U3 08 in 1985, and to 49,069 tonnes (54,100 tons) U3 08 in the year 2000, Cumulative requirements through the year 2000 total 650,319 tonnes (717,000 tons) U3 08

• If all the planned foreign mine-mill production came on-stream as currently projected, there would be considerable excess capacity. If only operating mills or those under construction were available by the late 1980s, production capacity would cover annual demands through the late 1990s.

9-14 Table 9.7. Foreign uranium production capability

!Thousand tons U3 0al Niger S. Africa Other:b Foreign Total Year 18 Australia 2 3 Canada 2 3

France 2 3 Namibia 2 3 1 2 3 1 2 3 2 .3 1 2 3 1980 1.3 0 0 9.8 0 0 4.5 0 0 5.3 0 0 5.2 0 0 aa o o 4.1 0 0 38.5 0 0 1981 1.8 1.1 0 9.8 1.4 0 4.5 0.2 0 5.3 0 0 5.2 0 0 8.3 0 1.2 4.1 0 0.8 39.0 2.7 2.0 1982 1.8 3.3 0 9.8 1.9 0 4.5 0.5 0 5.3 0 0 5.2 0 0 8.3 0 2.9 4.1 0 3.0 39.0 5.7 5.9 1983 1.8 3.3 0 10.5 1.9 2.0 4.5 0.7 0 5.3 0 1.2 5.2 0 0 8.3 0 4.6 4.1 0 4.1 39.7 5.9 11.9 1984 1.8 3.3 0 11.0 2.9 4.0 4.5 0.7 0 5.3 0 1.2 5.2 0 0.7 8.3 0 5.2 4.1 0 4.4 40.2 6.9 15.5 1985 1.8 3.3 6.5 12.0 2.9 5.0 4.5 0.7 0 5.3 0 1.2 5.2 0 2.5 8.3 0 5.5 4.1 0 5.1 41.2 6.9 25.8 1986 1.2 3.3 11.5 12.0 2.9 7.2 4.5 1.4 0 5.3 0 1.2 5.2 0 5.2 8.3 0 5.6 4.1 0 5.1 40.6 7.6 35.8 1987 1.2 3.3 11.5 12.0 2.9 7.2 4.5 1.4 0 5.3 0 1.2 5.2 0 5.2 8.3 0 5.6 4.1 0 5.2 40.6 7.6 35.9 1988 1.2 3.3 11.5 12.0 2.9 7.2 4.5 1.4 0 5.3 0 1.2 5.2 0 5.2 8.3 0 5.5 4.1 0 5.3 40.6 7.6 35.9 1989 1.2 3.3 11.5 12.0 2.9 7.2 4.5 1.4 0 5.3 0 1.2 5.2 0 5.2 8.3 0 5.5 4.1 0 5.4 40.6 7.6 36.0 1990 1.2 3.3 11.5 12.0 2.9 7.2 4.5 1.4 0 5.3 0 1.2 5.2 0 5.2 8.3 0 5.2 4.1 0 5.5 40.6 7.6 35.8 Total 84.0 a Class: 1. Currently operating plants

2. Plants under construction

3. Planned plants b Includes: Argentina, Brazil, CAR, Gabon, India, Italy, Mexico, Portugal, Spain, Yugoslavia. Based on "Uranium Resources, Production and Demand,"

December 1979. *

(To convert tons to tonnes, multiply by 0.907.)

Table 9.8. ForeiiJn nuclear capacity and uranium requirements Capacity Requirements

[GW(e)J (tons U3 0el" Low Mid Hi\tl Low Mid Hi\tl 1980 66 68 77 17,300 18,400 19,800 1985 117 124 128 24,000 26,200 29,200 1990 165 181 201 27,500 31,600 32,700 1995 229 252 280 34,600 41,500 47,800 2000 300 350 400 42,700 54,100 64,300 "0.20% U-235 tails assay.

(To convert tons to tonnes, multiply by 0.907.)

Additional projections of WOCA nuclear growth and uranium requirements were developed during the Inter-national Nuclear Fuel Cycle Evaluation (INFCE). While the projections are now considered ~s high by many, they do provide an additional, more optimistic, viewpoint on future nuclear growth. The INFCE low case-.

modified to exclude the U.S. - indicated a growth in foreign (WOCA} nuclear capacity from 82 GWe at the end of 1980 to 217 GWe in. 1990 and 580 GWe in the year 2000. Corresponding foreign uranium requirements would be 19,047 tonnes (21,000 tons) in 1980, 45,350 tonnes (50,000 tons) in 1990 and 108,840 tonnes (120,000 tons) in 2000. Such projections indicate a much larger p~ssible growth in future uranium demands 9.3.2. 13 Foreign competition and the domestic industry The concentration of world uranium resources and production has, in past periods of low prices and ore production, fostered attempts to form cartel-like organizations seeking to restrict the free movement of uranium and influence pricing. The concentration of uranium production in a few countries will continue for some time, though there is an increasing diversity of supply sources. The opportunity for future foregin cartel*like activities will continue; particularly if uranium producer country governments are involved, which has been the case in the past. However, the severe criticism of such practice and. the legal actions that have resulted in tne United States might operate to discourage such activities in the future. Since the U.S. has the capability of producing a large portion- or all -of its uranium needs, and since the U.S. uranium buyers historically have shown a strong preference for domestic uranium, the U.S. is not expected to develop a large dependence on foreign uranium. These factors would tend to reducE the susceptibility of the U.S. to direct impacts of any carte1*1ike activity.

9-15 9.3.2. 14 Conclusions In conclusion, DOE assessment of uranium resources indicates that currently estimated ore reserves and probable potential resources at forward costs up to $13.60 per kilogram ($30 per pound) U3 08 total over 1.36 million tonnes (1.5 million tons), and at forward costs up to $22.65 per kilogram ($50 per pound)

U3 08 total almost 2.17 million tonnes (2.4 million tons). The 2.17 million tonnes (2.4 million tons) U3 08 will support 390 GWe of nuclear power generating capacity, assuming a 30-year life for the reactors, no spent fuel reprocessing and an enrichment plant tails assay of 0.20% U-235. Under the latest DOE forecast for nuclear generating capacity in the post-2000 period, these resources should support U.S. nuclear power growth, including SONGS 2 and 3, well into the next century. However, meeting the uranium requirements for an expanding U.S. nuclear power industry will require extensive industry efforts to sustain exploration, and success in discovering and developing the potential uranium resources.

Foreign uranium resources are substantial and have been growing. Some of the more recently discovered deposits, especially in Canada and Australia, will have comparatively low-cost uranium production. The staff, therefore, concludes that there will be sufficient nuclear fuel available for SONGS 2 and 3.

9.4 DECOMMISSIONING A license to operate a nuclear power plant is issued for a period of 40 years, beginning with the issuance of the construction permit. At the end of the 40-year period the operator of a nuclear power plant must renew the license for another time period or apply for termination of the license and for authority to dismantle the facility and dispose of its components. 8 If prior to the expiration of the operating license, technical, economic, or other factors are unfavorable to continued operation of the plant, the operator may elect to apply for license termination and dismantle authority at that time. In addition, at the time of applying for a license to operate a nuclear power plant, the applicant must show that he possesses "or has reasonable assurance of obtaining the funds necessary to cover the estimated costs of permanently shutting the facility down and maintaining it in a safe condition." 9 These activities, termination of operation and plant dismantling, are generally referred to as "decommissioning."

NRC regulations do not require the applicant to submit decommissioning plans at the time the construction permit and operating license are obtained; consequently, no definite plan for the decommissioning of the station has been developed. At the end of the station's useful lifetime, the applicant will prepare a proposed decommissioning plan for review by the Nuclear Regulatory Commission. The plan will comply with NRC rules and regulations then in effect.

The decommissioning of reactors is not new. Since 1960, five licensed nuclear plants, four demonstration nuclear power plants, six licensed test reactors, 28 _licensed research, and 22 licensed critical facili-ties have been or are in the process of being decommissioned. 10 The primary methods of decommissioning consist of mothballing, entombing, dismantling, or a combination of these three alternatives. The primary methods are defined below in terms of the definitions provided in Regulatory Guide 1.86. 11 Mothballing is the process of placing a facility in a nonoperating status. The reactor may be left intact except that all reactor fuel, radioactive fluids, and nonfixed radioactive wastes such as ion exchange resins, contaminated scrap materials, and contaminated chemicals are removed. The existing license is amended to a "possession only" status and continues in effect until residual radioactivity decays to levels acceptable for release to unrestricted access or until residual radioactivity is removed. The "possession only" license is a reactor facility license that permits a licensee to possess the facility but prohibits operation of the facility as a nuclear reactor.

Entombment consists of removing all fuel assemblies, radioactive fluids, and wastes followed by the seal-ing of remaining radioactive material within a structure integral with the biological shield or by some other method to prevent unauthorized access into radiation areas. A program of inspection, facility radiation surveys, and environmental sampling is .required for a licensed facility that has been entombed.

Dismantling is defined as removal of all fuel, radioactive fluids and waste, and all radioactive structures. Surface contamination levels, established in Table 1 of Regulatory Guide 1.86, must be met prior to termination of the facility license. In addition to meeting the surface contamination levels, the acceptability of the presence of materials which have been made radioactive by neutron activation would be evaluated on a case-by-case basis prior to termination of the license. If the facility owner so desires, the remainder of the reactor facility may be dismantled and all vestiges removed and disposed of.

9-16 For a single nuclear reactor, the mothballing alternative costs about $2.45 million initially plus an annual maintenance and surveillance cost of $167,000. If a 24-hr manned security force is not required (e.g., a site with continuing operations), the annual cost could be reduced to $88,000. Translating thes*

costs into unit cost of generating electricity, the 30-year levelized unit cost* would be about 0.04 mills/kWhr and if a manned security force is not required about 0.03 mills/kWhr. 12 The entombing alternative costs about $7.58 million initially for a single unit facility plus an annual maintenance and surveillance cost of $58,000 for the duration of the entombment period. 13 These costs~

when translated to a 30-year levelized unit cost* basis, amount to about 0.06 mills/kWhr.

The dismantling alternative for a single nuclear power reactor costs about $33.3 million to remove the radioactive structures associated with NRC requirements for terminating a possession only license. 12 An additional $4.8 million would be needed to remove the nonradioactive structures (cooling towers, adminis-tration buildings, etc.) to below grade. 13 There are no annual costs associated with this alternative.

When the dismantling costs are translated to a 30-year levelized unit cost* basis, this amounts to about 0.17 mills/kWhr.

Combinations of mothballing and delayed (about 100 years) dismantling have 30-year levelized unit costs that are about the same as the mothballing alternative costs. Likewise, the costs for the entombing delayed dismantling combinations are about the same as the entombing cost. In both instances the annual maintenance cost for mothballing and entombing alternatives, on a present value basis, is sufficient to cover all the delayed dismantling cost for the mothballing alternative and about 80% for the entombing alternative.

Although the above costs are for a one-unit station, the savings associated with multiunit stations are small; thus, the unit cost (mill~/kWhr) is essentially the same for a single unit station or multiunit station. For the San Onofre Nuclear Generating Station Units 2 and 3 the decommissioning costs would be about double that indicated for all of the decommissioning one-unit alternatives.

Studies of social and environmental effects of decommissioning large commercial power generating units have not identified any significant impacts. 1 3 Also, studies indicate that occupational radiation doses can be controlled to levels comparable to occu*

pational doses experienced with operating reactors through the use of appropriate work procedures, shielding, and remotely controlled equipment. 13 The applicant may retain the site for power generation purposes indefinitely after the useful life of the station. The degree of dismantlement would be determined by an economic and environmental study involvint the value of the land and crop value versus the complete demolition and removal of the complex. In any event, the operation will be controlled by rules and regulations in effect at the time to protect the health and safety of the public.

SONGS 2 and 3 are designed to operate for about 30 years, and the end of their useful life will occur approximately in the year 2011. The applicant has made no firm plans for decommissioning, but assumes that the following steps would be taken as minimum precautions for maintaining a safe condition:

1. All fuel would be removed from the facility and shipped offsite for disposition.

2. All radioactive wastes- solid, liquid,.and gas- would be packaged and removed from the site insofa1 as practical.

A decision as to whether the station would be further dismantled would require an economic stuqy involvin!

the value of the land and scrap value versus the cost of complete demolition and removal of the complex.

However, no additional work would be done unless it is in accordance with rules and regulations in effect at the time.

In addition to personnel required to guard and secure the station, concrete and steel would be used to prevent ingress into any building, particularly the radioactive areas.

Since the San Onofre site is located on U.S. Marine Corps property, the applicant must, if desired by the government, remove all of the improvements installed on the site at the end of the applicant's lease arrangement. This requirement could potentially entail complete removal and dismantling of the plant (ER, Section 5.8).

Based on a 1200-MWe generating unit beginning operation in 1958, a capacity factor of 60%, an escalation rate of 5%, and a discount rate of 10%. A more complete analysis of decommissioning costs can be found in Appendix B of NUREG-0480.6

9-17 REFERENCES Unless otherwise noted, documents are available in public technical libraries.

1. U.S. Department of the Interior, Bureau of Mines, "Mineral Facts and Problems," 1970, p. 230.

2. U.S. Atomic Energy Commission, "Uranium Industry Seminar," Grand Junction, Colorado, Office, Report GJ0-108(74), October 1974.***

3. Energy Research and Development Administration, "Survey of U.S. Uranium Marketing Activity," Report ERDA 77-46, May 1977.***

4. U.S. Atomic Energy Commission, "Survey of U.S. Uranium Marketing Activity," Report WASH-1196(74), April 1974.***

5. U.S. Nuclear Regulatory Commission, "Final Generic Environmental Statement on the Use of Recycle Plutonium in Mixed Oxide Fuel in Light Water Cooled Reactors," Report NUREG-0002, vol. 4, U.S. Government Printing Office, Washington, D.C., August, 1976, Table XI-32, Section 4."'"'

6. U.S. Nuclear Regulatory Commission "Coal Vs. Nuclear: A Comparison of the Cost of Generating Baseload Electricity by Region," NUREG-0480, December 1978.**

7. U.S. Atomic Energy Commission, Press Release, No. T-517, Oct. 25, 1974.*

8. Title 10, "Rules and Regulations," Code of Federal Regulations, Part 50, "Licensing of Production and Utilization Facilities," Section 50.51, "Applications for Termination of Licenses."

9. Title 10, "Rules and Regulations," Code of Federal Regulations, Part 50, "Licensing of Production and Utilization Facilities, Section 50.33, "Content of Applications; General Information."

10. P. B. Erickson and G. Lear, "Decommissioning and Decontamination of Licensed Reactor Facilities and Demonstration Nuclear Power Plants," presented at Conference on Decontamina-tion and Decommissioning in Idaho Falls, Idaho, Aug. 19-21, 1975.*

11. U.S. Nuclear Regulatory Commission, Regulatory Guide 1.86, "Termination of Operating Licenses for Nuc 1ear Reactors. "

12. U.S. Nuclear Regulatory Commission, "Draft Generic Environmental Statement on Decommissioning of Nuclear Faci 1it i es," USNRC Report NUREG-0586, January 1981.

13. Atomic Industrial Forum, Inc., "An Engineering Evaluation of Nuclear Power Reactor Decommissioning Alternatives," Report AIF/NESP-009.

• Available for inspection and copying for a fee in the NRC Public Document Room, 1717 H Street, N.W.

Washington, D.C. 20555.

• "' Available from NRC/GPO Sales Program, Washington, D.C. 2D555, and the National Technical Information Service, Springfield, VA 22161.

• • • Available from NTIS only.

10. BENEFIT-COST

SUMMARY

~ ~

10.1 RESUME There have been minor changes in the benefit-cost analysis of station operation since the issuance of the FES-CP in March 1973. The most significant changes are that the staff has revised the economic cost estimates upwards to reflect the rapid escalation seen during the last few years and has included among the benefits of station operation the fuel oil savings that will be made possible by having additional non-oil-fired, base-load capacity available in the California Power Pool. There have been essentially no significant changes in the staff's assessment of the environmental costs of operating SONGS 2 &3; however, a broadening of the review process has occurred and is reflected in Table 10.1.

10. 2 BENEFITS The primary benefits of station operation will be the 9.3 to 13.0 billion kWhr of electricity produced by the two additional units each year (assuming a range of capacity factors of 50 to 70%), the increase in the reliability of electric service resulting from the addition of 2114 MWe of generating capacity, and an estimated regional decrease in the consumption of fuel oil of 13.2 million to 18.5 million barrels of oil per year (again assuming a range of capacity factors of 50 to 70%).

The staff also notes that operation of SONGS 2 &3 will result in the generation of local revenues through property taxes and state sales and use taxes (annual property taxes will be approximately $13 million while state sales and use taxes resulting from station operation are estimated to be $3 million per year) and will increase local employment (over 300 new jobs will be directly created, with the average income of station workers being approximately

$30,000 per year in 1980 dollars). However, these considerations are not included in the staff's benefit-cost analysis because from a societal viewpoint these local benefits are in actuality transfer payments from those using the electricity generated by the station to the recipients of the tax and employment benefits.

10.3 ECONOMIC COSTS Since the issuance of the FES-CP the fuel, operating, and maintenance costs of nuclear plant operation have escalated more rapidly than anticipated by the staff in 1973. Based on more recent information, the staff now estimates the 1983 costs of station operation to be as follows: fuel costs- $120 million per year; operating and maintenance costs -$45 million per year; and decommissioning costs- $2.7 million per year.

10.4 ENVIRONMEiHAL COSTS Since the issuance of the FES-CP the applicants have accumulated additional environmental data and have made modifications in the station design. The staff, on making a reassessment of the environmental costs of station operation based on this new information, has found that the conclusions reached in the FES-CP are still valid. Table 10.1 summarizes the staff's assessment of the environmental impacts of station operation.

10.5 SOCIAL COSTS The restriction in public use of 1.4 km (0.85 mile) of the San Onofre Beach is a significant cost of operation of the station. The number of personnel needed to operate SONGS 2 & 3 is a small fraction of the expected population growth in the communities near the station. As a result, the extra cost of providing public services to station personnel who relocate in the area is not likely to be discernible in these communities.

10-1

10-2 Table 10.1. Benefit-cost 111mmary for the operetion of SONGS2&~

Primary impact and population or Unit of measure Magnitude of impact resource affected DIRECT BENEFITS ENERGY (60-70% capacity factor) kWhr/yr X toa 9,3()0-13,000 CAPACITY kWX 103 2,114 REDUCED FUEl Oil CONSUMPTION bbl/yr X 106 13.2-18.5 (50-70% capacity factor)

ECONOMIC COSTS OPERATING (1980 dollars, 60% capacity factor)

,_Fuel $/year 120,000,000 Operation and maintenance $/year 45,000,000 DECOMMISSIONING (annualized value) $/year 1.100,000 ENVIRONMENTAL COSTS IMPACT ON LAND Land use Insignificant Terrestrial ecology Negligible IMPACT ON WATER Fresh water consumption gal/day 1,066,000 Salt water consumption Insignificant Heat di$Charge to natural water body Aquatic biota Insignificant Migratory fish Insignificant Chemical di$Charge to natural water body People Not discernible Aquatic biota Not discernible Water quality Not discernible Radionuclide contamination of natural surface water body All except tritium Ci/vear /unit 1.1 Tritium Ci/year/unit 300 Chemical contamination of groundwater People Not discernible Plants Not discernible Radionuclide contamination of groundwater People Not discernible Plants and animals Not discernible Effects on natural water body of condenser cooling system operation Primary producers and consumers Small Fisheries Small Natural water drainage Flood control No damage Erosion control Insignificant IMPACT ON AIR Chemical discharge to embient air Air quality, chemical Negligible Air quality, odor Negligible Radionuclides di$Charged to embient air

• Noble gases Ci/year/unit 8,800 Radloiodines Ci/year/unit 0.195 Carbon*14 Ci/year /unit B Argon-41 Ci/year/unit 25 Tritium Ci/year/unit 1,100 Particulates Ci/year/unit 0.34 Fogging and icing None TOTAL BODY DOSES TO U.S. POPULATION General public, unrestricted area Man-rem/year 442 SOCIETAL COSTS OPERATIONAL FUEL DISPOSITION Fuel transport (new) Trucks per year 11 Fuel storage In-building storage Waste products (spent fuel) Trucks per year 200 PLANT LABOR .FORCE Insignificant

• See Appendix C for calculations and explanations of table entries.

(To convert gal to liters, multiply by 3,7.)

10-3 10.6 ENVIRONMENTAL COSTS OF THE URANIUM FUEL CYCLE AND TRANSPORTATION The staff has evaluated the environmental impacts of the uranium fuel cycle as presented in Table 5.8 and has found these impacts to be sufficiently small so that when superimposed upon the other environmental impacts assessed against the operation of the station, they do not alter the overall benefit-cost balance.

10.7

SUMMARY

OF BENEFIT-COST As the result of this second review of potential environmental, economic, and social impacts, the staff has been able to forecast more accurately the effects of station operation. The higher economic costs identified by the staff would not alter the staff*s previous conclusion as to the overall balancing of the benefits of the station versus the environmental costs, whereas the benefit from the reduction in the regional consumption of fuel oil is felt to add significantly to the total benefits of station operation. Additional environmental costs have been identified as: (1) removal of approximately 1.4 km (0.85 mile) of beach from unrestricted public use, (2) possible destruction of at least a portion of the San Onofre Kelp Bed durin9 the summer months by the heated water discharge, (3) occupation of about 7.2 ha (17.8 acres) of land by new towers, access roads, and switchyards associated with new transmission facilities, (4) environmental effects of the uranium fuel cycle as enumerated in Table 5.8, and (5) environ-mental impacts of transportation of fuel and waste to and from nuclear power plants as indicated in Table 5.7. Consideration of these additional costs together with those identified in the FES-CP does not alter the position taken in the FES-CP that the environmental and social costs are acceptable and that these costs are outweighed by the primary benefits of operating SONGS 2 & 3.

11. DISCUSSION OF COMMENTS RECEIVED ON THE DRAFT ENVIRONMENTAL STATEMENT Pursuant to 10 CFR Part 51, the Draft Environmental Statment and a supplement to the Draft Environmental Statement related to the operation of the San Onofre Nuclear Generating Station, Units 1 and 2, were transmitted, with a request for comments, to:

Department of Agriculture Department of Army (Corps of Engineers)

Department of Commerce Department of Energy Department of the Interior Department of Health, Education, and Welfare Department of Housing and Urban Development Department of Transportation Environmental Protection Agency Federal Energy Regulatory Commission Advisory Council on Historic Preservation California Department of Health (Water Pollution Control Commission, Air Pollution Control Commission, Occupational Health Office)

Ca 1 iforni a Department of Natura 1 Resources California Department of Parks and Recreation In addition, the NRC requested comments on the Draft Environmental Statement and its supplement from interested persons by a notice published in the Federal Register on December 6, 1978 (43 FR 25183) and January 13, 1981 (46 FR 7435), respectively. In response to the request referred to above, comments were received from:

Draft Environmental Statement U.S. Department of Agriculture, Science and Education Administration (DASEA)

U.S. Department of Agriculture, Economics, Statistics and Cooperative Services (DAESC)

U.S. Department of Agriculture, Soil Conservation Service (DASCS)

Department of Housing and Urban Development (HUD)

Department of the Army, Corps of Engineers (COE)

Federal Energy Regulatory Commission (FERC)

U.S. Department of the Interior (DOl)

Rourke and Woodruff Law Offices (RWL)

U.S. Department of Commerce (DOC)

Department of Health, Education, and Welfare (HEW)

Southern California Edison Company (SCE)

U.S. Environmental Protection Agency (EPA)

Mr. Marvin I. Lewis (MIL)

Richard J. Wharton (RJW)

Supplement to the Draft Environmental Statement U.S.

Dearptment of Agriculture,

Economics, Statistics and Cooperative Services (DAESC)

Federal Energy Regulatory Commission (FERC)

U.S. Department of the Interior (DOl)

U.S. Environmental Protection Agency (EPA)

Union of Concerned Scientists (UCS)

Richard J. Wharton (RJW)

Southern California Edison Company (SCE)

Frank H. Grundel (FHG)

San Diego Association of Governments (SAG)

U.S. Department of Agriculture, Soil Conservation Service (DASCS)

11-2 The comments are reproduced in this statement as Appendix A. The staff's consideration of the comments received and its disposition of the issues involved are reflected in part by changes in the text in the pertinent sections of this Final Environmental Statement and in part by the discussion in Section 11. The comments are categorized by subject and are referenced by the use of the abbreviations indicated above. The pages in Appendix A on which copies of the respective comments appear are indicated by each subject title relating to the comment, and in the index to Appendix A.

11.1 EROSION CONTROL (OASCS, A-4)

The applicant's erosion control plans are briefly discussed and referenced in Sections 6.2.2 and 6.3.2. In addit~on, the treatment of disturbed areas is addressed in the FES-CP. Such discussions are beyond the scope of the OL review.

11.2 LOSS OF PRIME LANDS (OASCS, A-4)

The discussion of prime lands lost to access roads and transmission towers, which is presented in Appendix E of the DES, is based on available information as a result of staff discussions with Mr. Jack Smith and Mr. Ted Thee of the Soil Conservation Service (SCS)

Escondido Field Station and Mr. Jon Christianson of the SCS Tustin Field Office.

11.3 RECREATION RESOURCES (DOl, A-5; RJW, A-48)

The original plan to allow recreational use in the beach area immediately adjacent to the nuclear plant was altered in the course of hearings before the ASLB and ASLAB based on safety considerations. The staff reasserts its judgment that, while significant, the impact of beach closure is not sufficient to warrant denying the applicant an Operating License for SONGS 2 & 3. While the 1.4 km (0.85 mile) of beach to be closed must be considered a valuable recreational resource, there are approximately 5.6 km (3.5 miles) of State Beach immediately south of this area and almost 1.1 km (0.7 miles) immediately north which remain open to the public. Of those three parcels of beach, the one to be closed gets substantially less use than the other two and is directly adjacent to the SONGS complex, where the natural aesthetics of the area have been altered by plant development. Finally, while the 30 years of beach closure is clearly a long time, it does not represent an "irreversible and irretriev-able commitment of resources" as the intervenors contend. For these reasons, it is the judgment of the staff that the closure of this stretch of beach, while significant, is not sufficiently adverse to warrant forbidding plant operations.

11.4 RADIOLOGICAL IMPACTS (HEW, A-10; SCS, A-30; EPA, A-40/A-42; MIL, A-45; RJW, A-50)

The NRC staff agrees it is appropriate to note that dose commitments to any individual will also meet EPA regulation 40 CFR 190 which requires that such doses will not exceed 25 mrem/

year to any individual.

The recent AIF study* referred to in this comment was an effort to provide the potential impact'of lowering the exposure limit to 500 millirems per year. The data were developed to fit the model that the AIF developed to evaluate the impact of the exposure limit reduction.

The exposure data were meant to portray the~ of exposure situations which occur at PWR's but are not likely to occur every year at each plant. (See Section 5.5.1.4 for staff con-sideration of occupational radiation exposures.)

Table 5.8 is based on NRC Table S-3, from 10 CFR Part 51, and is a generic discussion of impacts for the balance of the uranium fuel cycle. The staff is bound by the Commission standard as shown in Table 5.8. A discussion of alternative handling of HLW.or TRU wastes is therefore inappropriate for considerations of licensing SONGS 1 & 2.

• 11 A Preliminary Assessment of the Potential Impacts on Operating Nuclear Power Plants at a 500 millirem per Year Occupational Exposure Limit," J. Vance, C. Weaver, E. Lepper, AIF, April 1978 (unpublished).

11-3 The staff has made its own independent and reasonably conservative estimates of potential doses to maximum individuals as a result of the operation of SONGS 2 & 3. Considering the uncertainties involved in such calculations, the staff finds a factor of 3 difference to be in very good agreement. Therefore, the staff rejects the request that Table 5.4 of the DES be revised in order to be consistent with applicant's estimated doses.

The staff calculation was for sport fish taken in the mixing zone, not 0-10 miles from the outfall, and is an independent and a reasonably conservative estimate of doses to a maximum individual. It is true that doses would be much less at greater distances from the outfall.

However, the staff rejects the suggestion that Tables 5.6 (and 5.2 and 5.3) are in need of revision in order to be consistent with the applicant's estimates, particularly when both sets of estimates are orders of magnitude below the Appendix I design objective doses.

The staff agrees that the DES contains relatively little information regarding beach use at the SONGS site. Detailed discussion is presented in the Applicant's ER (e.g., pp. 2.1-4 to 2.1-7, and 5.2-1 through 5.2-54). In addition, more information regarding the staff conclu-sions and assumptions relating to doses to transient populations at the beach is presented in response to EPA comments.

The dose to individual users of the beach was not calculated for the following reasons:

1. The prevailing wind direction generally carries radioactive effluents away from the beach, thereby lowering potential exposures.

2. The beach is part of the exclusion area of the plant site, and public use (e.g., sun-bathing and picnicking) is not permitted (e.g., seep. 2.105 of the applicant's ER).

3. The walkway connecting the south and north beaches is at the bottom of a 28-ft seawall which effectively shields passerbys from any direct radiation from the plant.

4. Although the dose rates at the site boundaries are expected to be low, annual doses to individuals would be even lower due to limited exposure times in transit between beaches.

Doses to individuals at the visitor center (0.1 mi E) were calculated, but occupancy factors result in much lower annual doses than calculated from permanent residents assumed living year-around at the WNW site boundary (0.36 mi) reported in the DES. As noted in Section 5.5.1.4, direct radiation (other than from the gaseous plume) from SONGS 2 & 3 is expected to be very low at the beach area. When coupled with limited exposure periods for transients, and shielding from the 28-ft-high seawall, the potential annual doses would be insignificant.

Population doses included transient populations by sector within 10 miles of the site. Trans-ient populations were added to the projected resident populations for the year 2000 by assuming each transient spent one full day (24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br />) visiting during each year.

10 CFR Part 20 (10 CFR 20.105a) has been modified to include the provisions of 40 CFR Part 190. Also, the SONGS 2 & 3 technical specifications will require a demonstration to show compliance with 40 CFR Part 190 considering the operation of three reactors at the SONGS site.

Section 5.5.3 of the FES has been modified to include the long-term environmental effects associated with,carbon-14, krypton-85, and tritium releases of the fuel cycle excluding the reactor releases. These modifications were added to the earlier discussion which focused largely on the radon-222 impacts.

Staff estimates of the longer term effects of carbon-14, tritium, krypton-38, and releases of the reactor contribute less than 30% of the total fuel cycle impacts presented in Section 5.5.3 of the FES. Health effects reported in the FES on a "per reactor year" basis can be multiplied by the reactor operating time (i.e., 30 years) to obtain'the total or integrated estimate.

Neve"rtheless, the staff is in the process of modifying its calculation methodology to auto-matically consider the radiological impacts of effluent releases of the entire nuclear fuel cycle.

It is important to note that the FES results conservatively include the impacts of both uranium and plutonium recycle even though such operations are not currently permitted.

Thus, the FES results are conservative for any recycle option, especially the "throw-away" cycle, the option currently allowed.

11-4 The NRC staff has reevaluated the proposed preoperational radiological environmental monitor-ing program for SONGS 2 and 3. The proposed program is based on the existing SONGS 1 ppera-tional program. That program will be revised in the near future to meet the Appendix I (10 CFR Part 50) requirements now being incorporated into the Environmental Technical Specifications for Unit 1, thereby updating the preoperational program for Units 2 and 3.

Response to specific EPA comments are as follows:

1. Current NRC criteria require collection and measurement of I-131 only, since it is the radioiodine which accounts for essentially all of the radioiodine environmental pose commitment (nearly all of which is through food pathways). The reason the applicant specified a maximum of 8 days was to be certain that the samples can be collected, transported to a laboratory (often at a considerable distance), and analyzed "within 8 days" under difficult circumstances (e.g., storms, trucking strikes, etc.). In most cases the elapsed time will be much less.

2. The intent of the air sampling program*is to monitor continuously at all sites.

However, experience has shown that occasionally air sampling equipment fails during a 7-day period, and the samples are of no value. The same experience indicates the applicant can almost always achieve 75-80% reliability.

That is the only reason for mention of "a minimum of 10 samples per quarter" by the applicant.

3. The staff agrees that it might be desirable to have a TLO station along the walkway below the seawall. However, as noted in response to the previous comment, the walkway is 28 ft below the top of the seawall and there is no line-of-sight between the beach and any radiation sources on the site. The beach in front of the site is part of the exclusion area (i.e., no sunbathing, picnicking, etc. is permitted). Therefore, there is no possibility of any member of the public receiving a measurable radiation dose since individual exposure times would be very small.

4. The NRC has included U.S. population dose commitment estimates in Section 5.5 for a few years (see, for example, Table 5.5). In addition, the staff has been including dis-cussion of the Rn-222 question since mid-1978 (see Section 5.5.3).

Table 5-8 says Rn-222 releases are "Presently under reconsideration by the Commission," and in footnote a, "These issues which are not addressed at by this table may be subject to litigation in individual licensing proceedings." The results of generic testimony by the staff at other hearings is summarized briefly on pp. 5-36 to 5-40. Contrary to Mr. lewis' assertion, NEPA does not require quantification of the impacts of Rn-222 releases over the "full period of toxicity" (presumably he is referring to Th-230, the parent of Rn-222). The staff feels the conservative evaluation in Section 5.5.3 probably accounts for the releases and potential doses resulting from Rn-222 releases over periods of many millenia. In addition, the FES will provide a revised Section 5.5.3 which also includes potential impacts of C-14 over periods up to 1,000 years into the future.

The staff agrees that stabilization of surface tai 1i ngs piles cannot be assurec;t "forever."

However, numerous options, including deep burial in worked-out open pit mines or underground mines, are being voluntarily used by some applicants and may be used increasingly in the future by others. It should be noted that if such tailings are exposed by acts of God (e.g., glaciation), the potential long-term impacts could be lower than for the natural uranium ore since milling will remove over 90% of the U-235 (the parent of Th-230).

Environmental releases from "nuclear waste*materials, including the interim storage of spent fuel, on site" are so small relative to normal operational releases as to be inconsequential.

Such releases and potential impacts have been estimated* and do not significantly change the estimated impacts presented in the DES for normal operations. In that sense, the releases have been included in the DES assessment of environmental impacts.

11.5 METEOROLOGY (SCE, A-16)

The onshore tracer test results indicated that measured ground-level centerline one-hour average concentrations were less than concentrations estimated from the usual staff calculations. But a reduction for annual average values would not be the same.

• Draft Generic Environmental Impact Statement on "Handling and Storage of Spent light Water Power Reactor Fuel," NUREG-0404, U.S. Nuclear Regulatory Commission (March 1978).

11-5 Over a long period of time, such as a year, the wind direction within a sector should be randomly distributed, and thus the path of the plume should be randomly distributed. The time that any part of the plume is over a point within the sector contributes to the annual average at that point. This time integration and random path of plume have the net effect of uniformly distributing an effluent horizontally within a sector. Any enhanced dispersion due to additional horizontal plume spreading would not reduce the annual average concentra-tion. In the staff calculations it was assumed that the effluent was uniformly distributed horizontally over the sector.

The ground-level annual average concentration would be dependent on the wind frequency and on the vertical distribution of the effluent within the plume. No direct measurements of vertical plume distributions were made during these onshore tests or the tests referenced in NUS-1927. Without a more definitive description of the vertical distribution of the plume, it has been the staff position not to adjust annual average dispersion estimates.

11.6 THERMAL ANALYSIS (SCE, A-20/A-21)

The air temperatures used by the staff in its thermal model are too high and, therefore, the staff's ambient temperature predictions are too high. However, nonlinear effects of the air temperature on the water temperature are negligible so that the staff's excess temperature predictions are correct despite the systematically high ambient air temperatures used in the mathematical model.

Higher near-shore predicted ambient water temperatures appear as a result of the depth-averaged format of the predictions. The near-shore region is shallow, resulting in near homogeneous vertical temperature structure. In deeper water, strong stratification is present so that the depth-averaged water temperatures are lower due to the presence of cool bottom water. The staff's actual ambient surface temperature predictions show no variation in the offshore direction. Ambient temperatures based on field measurement have been used in Section 5.4 of the FES.

A brief discussion of the applicant's error analysis is given in Section 5.3.1.1 of the FES.

Errors in the staff's mathematical model can be introduced in several ways. First consider the accuracy of the numerical method. The TEMPTWO algorithm is consistent and stable. The use of direct upwind differencing can produce numerical dispersion when the Courant Number is not equal to 1. To minimize this error, the staff used a time-step that produced a Courant No. of 1 near the diffusers. This essentially eliminated numerical dispersion error around the discharge areas. Far from the discharges, numerical dispersion exists; however, this makes the predictions less conservative. To correct for this, the staff could raise the predicted excess temperatures in the far field. The staff believes that inaccuracies due to numerical dispersion are slight and, therefore, corrections of such inaccuracies are unnecessary.

Errors could also have been introduced through the methods used to represent turbulent transport and surface heat transfer. In developing the model, an effort was made to incorporate formulations which are universal; that is, to create a model that requires no adjustment of coefficients on a site-specific basis. The TEMPTWO model has been applied to other plants and results have compared favorably with available data. Thermal predictions for the Peach Bottom Plant and the Anclote Plant, including comparison with field data, are shown in Figures 11.1 through 11.8. The Peach Bottom Plant is on an impoundment of a river in Pennsylvania and the Anclote Plant is located on the Gulf of Mexico. The success of the TEMPTWO model at two quite different sites indicates that the submodels for turbulent transport and surface heat transfer can confidently be applied to San Onofre.

The staff's model did not include plant-induced densimetric flows. The staff performed a scale analysis and determined this effect to be insignificant at the San Onofre site.

Individual jet mixing is not calculated within the staff's model. However, th;s effect was included based on the applicant's near-field results.

11-6 Figure 11.1 Computer simulation results for the two-dimensional depth-averaged (with self-similar vertical variation) flow conditions and temperature conditions (isotherms with 1°F gradation (l/1.8°C} in the Conowingo Pond Reservoir in the vicinity of the Peach Bottom Atomic Power Station at 9 a.m. on July 18, 1974, during reservoir conditions: down-stream low flow after slack water.

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downstream low flow slack water.

25 JUNE 1974

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11-9 95 --------------------------------------------------------,

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11-10

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11-11 43 y

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5.5 Figure 11.6 Computer simulation results for the two-dimensional depth-averaged water temperature conditions (isotherms with 1 F (1/1.8 C) gradation between minimum 84 F(28.9 C) and maximum 92 F(33.3 C)in the Anclote Anchorage region for the actual Unit 1 operational condition of the Anclote Power Plant at 3 p.m. on June 25, 1976, during tidal stage: approximate maximum ebb,

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bJ 27 80 26 78 00:00 06:00 l2:00 t8*00 00:00 06:00 12:00 18*00 24:00 24 JUNE 1976 25 JUNE 1976 Figure 11.7 Comparison of the computer simulation results for the water temperature conditions (as continuous hourly variations) and the available field-measured water temperature data (intermittent) in the Anclote Anchorage region during the 2*day period June 24-25.

1976. at the field-sampling station 25.

11-13 Figure 11.8 *Comparison of the computer simulation results for the ~~ter temperature conditions (as continuous hourly variations)'and the available field-measured water temperature data (intermittent) in the Anclote Anchorage region during the 2-day period June 24-25 1976, at the field-sampling station 1.

11-14 11.~ THERMAl EFFECTS (SCE, A-14, A-24/A-25)

It is true that the ambient temperature data supplied by the applicant (Attachment T) indicate the presence of lower ambient temperatures, at both the surface and the bottom, within the region of the San Onofre Kelp Bed than those predicted by the model. Typically, the discrepancy between the maximum values reported by the applicants and from the thermal model (for both surface and bottom) during the late summer is on the order of 4-5°C (7-9°F).

However, the recently supplied values are for a period of record which spans only a few years (1975-1978). Thus, it is not possible to know if some of these data were collected during a period of time in which the waters are naturally warmer than long-term average. In evaluating the potential impacts of a long-lived facility such as SONGS (which will operate for up to 30 years), a worst-case evaluation is usually made to determine the effects which might occur under extreme conditions. Without knowledge of the relationship between the data supplied by the applicant and worst-case temperature conditions, these data cannot be relied upon for an assessment of the impacts on the kelp.

If the assumption is made that these data do include an interval in which there are tempera-tures which are warmer than usual (e.g., the warmest values reported in the last 15-20 years), then the conclusions of the applicant regarding the effects on kelp are probably correct. That is, the incremental temperature increase due to the operation of SONGS will not result in an adverse impact to the community, even under worse-case conditions.

The staff does not concur that the bottom water will necessarily remain unaffected.

The staff does not feel that the ambient temperature data available are complete enough for use in a worst-case analysis. Because such an analysis (based on the temperature data gen-erated by the model) concluded that the impact to the benthic community will be insignificant (overall), it is clear that the effect under average conditions will likewise be insignificant. If the model does predict maximum temperatures which are unrealistically high, the conclusions based on such data provide additional assurances that the impacts will be negligible.

11.8 BIOLOGICAL RESOURCES (DOC, A-8/A-9; SCE, A-25/A-30; RJW, A-47)

The statement was not meant to imply that the only relationship between kelp beds and the coaaercial fishes is thrbugh the kelp detritus. Certainly. several of the commercially important species inhabit the beds (at least part of the time) for food-seeking activities and refuge. The paragraph was intended to portray, in brief, the ecological and commercial importance of kelp beds. Additional information on this subject is contained in the FES-CP.

Any revision to station design or operation for the express purpose of mitigating nonradio-logical impact to aquatic biota will be accomplished through procedures under the NPOES Permit Program administered by the California Water Quality Control Board. NRC is working closely with this Board and with other State resource agencies in the review of monitoring programs.

The cost-benefit analysis for the potential loss of biological resources due to the opera-tion of SONGS 2'and 3 is addressed in the SONGS FES-CP, March 1973, Sections 13.2.4 and 13.4, and in Section 10 of this FES.

Technically, the statement is still correct. Although man-induced thermal effects may not be documented, their occurrence is likely in some areas.

It is true that the association of decreased kelp "health11 with turbidity was made in con-junction with observations on the effects of sewage outfalls. However, the effect of turbidity on light attenuation. is not a function of the source or type of the turbidity, except that a certain type of turbidity may not produce the same light reduction, at a given concentration, as another type of turbidity (e.g., as in the case of fine sand particles vs.

suspended clay). Reference 15 includes a statement on the reduction of kelp "health" as a function of reduced available light for photosynthesis. It is reasonable to assume, therefore, that kelp "health" can be affected by many different types of turbidity.

It is true that nutrient depletion has been implicated in kelp canopy deterioration. It is also true that the exact mechanisms of kelp deterioration are not well known. Most studies have attributed cause-effect relationships between temperature and kelp demise, but the operating factors may well be complex, and may involve, for example, synergisms between several factors. To reflect this uncertainty, the text has been changed as per the suggested revision.

11-15 The study cited (number 13) gives one indication of the importance of kelp beds to fish com-munities. The relative importance of kelp for fish rearing, refuge, etc. may be disputed.

However, for purposes of a worst-case analysis, it must be assumed that a more conservative interpretation is correct. It should be noted that the subject paragraph does not state that kelp beds are the most important fish habitat. Rather, it indicates that the community does have some unspecified importance.

The ecotypic variability of kelp temperature to tolerance is not well documented, though it may occur. Without definite knowledge, the more conservative values should be used in a worst-case analysis.

As stated earlier (see response to SCE, A-2), the ambient temperature data supplied by the applicants do not appear to be entirely adequate for an analysis.

Increased survace nutrient levels from outfall induced upwelling have not been adequately demonstrated, though the phenomenon may occur.

The discharge for SONGS will be more or less continuous (except during shutdowns and power reductions), although it is true that when the plume reaches the kelp bed it is not likely to impinge the bed for a long period of time. This is acknowledged in the text and is one major reason why the conclusion was reached that the effect on the kelp bed is not likely to be severe (p. 5-27, paragraph 5). To avoid ambiguity, the subject statement has been revised.

The reference to Sect. 5.3.1 as the basis for the 19°C figure has been deleted. It is, however, based on results of the staff's thermal model. If this temperature represents the extreme high end which occurs during an average year, then it may well represent a tempera~

ture which could occur over an extended period of time during a "warm year." Because the values from the model are conservative, the word "typical" has been deleted from that sentence.

The staff's thermal analysis (Sect. 5.3.1) does not support the conclusion that increases in bottom temperatures are unlikely. The statement remains valid, even if the turbid water is discontinuous and relatively low in suspended solids; i.e., the presence of any increased turbidity will add to the probability of detrimental effects occurring to the kelp bed.

The analysis of the effect of the operation of SONGS on the closest kelp bed (San Onofre) was based on the latest thermal-hydraulic predictions made by our staff. The staff agrees that if this assessment of temperature configurations proves to be inaccurate that the analysis of kelp bed effects would have to be reassessed.

The granting of a 316(a) exception for normal operation, if such is needed, will not affect the operating characteristics of the facility; thus, the pedicted impacts remain valid. If a 316(a) type process becomes required by the State which results in operational changes, the impacts of that altered operating mode will have to be assessed when such conditions are known.

11.9 WATER QUALITY (EPA, A-38/A-40)

Section 5.3.1.1 and Fig. 5.3 are based on the applicant's thermal analysis. Section 5.3.1.2 is a description of the staff's thermal analysis. This analysis includes all. three units operating at 100% capacity and the ambient temperature is defined as the water temperature in the absence of all units. The possibility of recirculation among all units is an integral part of the staff's model. The results described in Section 5.3.1.2 address all aspects of the State thermal standards including excess temperatures at the surface of ocean substrates.

Additional information on the effects of the operation of the facility are found in the FES-CP, although in some cases the modification of operational characteristics since the CP stage has necessitated a reevaluation of the impacts. Such reanalyses are found in this document.

• In the staff's opinion, the two documents (the FES-CP and FES-OL) provide "state-of-the-art" evaluations of how the acquatic ecosystem will be affected. In most cases, too little information is available to quantitatively predict the areal extent of an effect on a given species. For this reason, operational monitoring programs are required which are designed to detect significant changes which may occur so that mitigation can be instituted.

11-16 The terms "minimal," "acceptable," and "not significant" relate to a judgment made regarding the predicted impacts of the facility on the environment. A possible effect ts termed insignificant if, for example, the impact is predicted to only occur locally in a nonunique, or widespread, population community of organisms, etc. When it is not possible to reach a firm conclusion regarding the significance of a projected impact (even under worst-case conditions), mitigation is either recommended immediately or an extensive monitoring program is stipulated.

The study report concerning use of the heat treatment process addresses a matter beyond the NRC's purview in accordance with the federal Water Pollution Control Act Amendments of 1972.

Thus, while the NRC must evaluate and consider the environmental impacts attributable to use of such heat treatment process, such consideration is limited to a determination of the impacts and their significance in terms of the cost-benefit analysis for this facility; any changes in the system or its use must be directed by the California Regional Water Quality Board and/or the Environmental Protection Agency. The applicant will provide the study report directly to those agencies, as well as to the NRC, when available.

For the foregoing reasons, we do not believe that the report itself is an integral part of the Draft Environmental Statement. Of course, as noted above, the NRC will consider the impacts attributable to the heat treatment process in the Final Environmental Statement as stated in Section 5.4.2.1. In this connection, the staff considers it to be no different than any other report of a study or analysis performed by a license applicant in support of its application. The staff is aware of no legal requirement which would give the report independent status such as EPA suggests, tn the context of the NRC's licensing review. The status of this report in terms of the determination to be made under Section 316(a) of the FWPCA is a matter left to that agency charged with making that determination.

Sect. 5.4.2.2 concludes that significant impacts are unlikely, even under worst-case conditions.

The effluent characteristics of SONGS must conform to the State standards prevailing at the time of the operation of the facility.

It is not the purpose of the staff analysis, as provided in the DES, to make rulings regarding statutory requirements, but rather to assess the impacts of proposed operation. In making this analysis it is not assumed that standards will be satisfied and, therefore, the environ-mental consequences of any violations resulting from the proposed plant operation is inherent in the staff's conclusions.

11.10 NEED FOR PLANT (MIL, A-45)

Table 2.2 of the FES relates to projected population growth within 16 km of the San Onofre site for the period 1976 to 2020.

Tables 8.3 and 8.4 are related to the electrical growth projected within the service areas of Southern California Edison Company and San Diego Gas and Electric Company for the periods 1976-1985. The combined annual growth rates for peak demand and energy for this period is 4.3 and 4.6%, respectively.

Population within 16 km of the site does not necessarily reflect electrical growth in the applicant's service areas.

11.11 SEISMOLOGY (EPA, A-40; MIL, A-45; RJW, A-49)

The staff's review and evaluation of the geological and seismological aspects of the San Onofre Nuclear Generating Station Units 2 and 3 is presented in the staff's Safety Evaluation Report, published December 1980. Included in the SER is a discussion of the potential for and nature of seismic activity at the site and its vicinity as well as of the design and construction measures taken by the applicants to prevent damage to the facility and its component parts.

The staff considers that its assessment of the environmental impact of postulated accidents presented in Chapter 7 adequately accounts for the consequences of any accident caused by seismic activity. This chapter discusses the consequences of accidents regardless of cause.

Regarding the potential for affecting water quality and for offsite radiological contamina-tion, to the extent such impacts are the result of airborne transportation of radionuclides, the consequences are included in the discussion in Chapter 7. The liquid pathway, because of the hYdrological environment at the site, does not present a viable transport mechanism which could impact water quality or would otherwise result in offsite radiological consequences.

11-17 11.12 URANIUM PRICES (RJW, A-49)

The cost-benefit analysis in the DES is based on 1976 data, at which time the price of uranium was $18.10/kg ($40/lb) U3 08

• Presuming SCE used the then existing U3 08 price in their cost-benefit analysis for SONGS 2 and 3, they would be using a price that reflected the rapid increase in prices in the 1973-1976 period. To extrapolate future prices on the basis of the 1973-1976 price increase would be erroneous in that uranium prices decreased 9% in real terms during 1977. Thus, it is inappropriate to consider a price escalation which is not even valid for a 5-year period of the uranium market for a cost-benefit analysis which covers the 30-year lifetime of a reactor. It would be just as appropriate (or inappropriate) to extrapolate the recent 9% decrease in uranium prices for use in the analysis. Many factors must be carefully investigated to estimate future uranium prices, and simplistic methods can-not be justified.

Long-term contracts are not generally tied to market prices at time of delivery or a 7% per year escalation, whichever-is greater, based on current data. In fact, most long-term uranium requirements are not under contract, so it is inappropriate to make any generaliza-tion about the nature and terms of those contracts. Even if future contracts were based on the greater of market price or 7%/year escalation, it does not follow that fuel costs will increase to prohibitively high levels. If future prices were related to market prices and market prices do not increase substantially (it has not been established that they will),

then the uranium cost component of fuel costs would not increase very much. And, if prices increase at 7%/year, they would probably just be keeping pace with inflation and thus not be relevant to a constant dollar analysis.

The cost of purchasing uranium is only one component of nuclear fuel costs, the other being, for example, separative work, UF 6 conversion, and fabrication. Thus, overall nuclear fuel costs would not escalate in proportion to the increase in uranium prices.

11.13 ACCIDENTS (HEW, A-10; MIL, A-45; RJW, A-49)

These comments were addressed to the Accident Section (Section 7) published in the Draft Environment Statement (DES), dated November 1978. In January 1981, the staff revised Section 7 and issued it for comment as a supplement to the DES. The January 1981 Supplement is included as Section 7 of this Final Environmental Statement (FES). The staff believes FES Section 7 is responsive to those accident comments previously addressed to the DES.

(FHA, A-53)

Part 50.13 of 10 CFR does not require a licensee "to provide for design features or other measures for the specific purpose of protection against the effects of (a) attacks ... by an enemy of the United States ... or (b) use or deployment of weapons incident to U.S. defense activities." The staff recognizes that acts of war would likely produce severe environmental impacts wherever they might take place.

{RJW, A-56, A-59)

The supplement is based on site-specific data, as described in Section 7.1.4.2. While not specifically stated in the supplement, U.S. average, year 2000 estimated, population data were used beyond 560 km (350 miles). The site-specific meteorological data used included lid heights to account for vertical mixing characteristics.

(RJW, A-58)

Both the staff and SAl used very similar methodologies in their analysis, and they both represent improvements over the Reactor Safety Study. There are some differences, however, in assumptions and data used in each study that lead to the variabilities or uncertainties that are inherent in such calculations. These differences appear in:

0 accident release characteristics - probabilities and magnitudes; 0

emergency response assumptions; 0

meteorological data; and 0

demographic data.

Specific consequence values that commentors quote from the SAI-OES report cannot be directly compared with those reported in the staff's draft supplement since the former are not associated with specified probability levels while the latter are. The staff has not made a

11-18 detailed comparison of the results of the two reports but judges that they are in agreement within the estimated bounds of uncertainties and assumptions associated with the current state of probabilistic risk assessments.

(RJW, A-58, A-59, A-60)

The studies of the San Onofre site relative to earthquake potential is extensively discussed in Section 2.5 of the Safety Evaluation Report (NUREG-0712, December 1980). The staff's position is that the safe shutdown earthquake is correctly determined for this site. A discussion of natural phenomena as initiators of accidents has been added to Section 7.1.4.2.

(RJW, A-58, A-59)

If Unit 1 had a meltdown, the staff agrees that it would impact the operation of Units 2 and

3. However, the ability to shut down both units following an accident at Unit 1 would not be impaired.

(RJW, A-59)

The reactor vessel was installed with its reference mark 180 degrees from the desired location.

As discussed in the Safety Evaluation Report (Section 5.3.4), the flow skirt, which is not symmetrical, was installed in the direction to agree with the vessel's orientation and pro-cedures for fuel handling, which reference the vessel orientation, were modified. No rewiring was necessary as a result of the error.

(RJW, A-59)

The dewatering well cavities were discussed in the Safety Evaluation Report in Section 2.5.

It was determined that there would be no impact on seismic Category I structures.

(RJW, A-59)

The beach visitors were specifically addressed (e.g., Sections 7.1.3.2 and 7.1.4.6 and Table 7.1.4-5).

(RJW, A-60)

The staff has concluded that acts of sabotage, as initiating events, do not contribute significantly to the probability of accidents due to the Commission's safeguards requirements.

Section 7.1.4.2 has been modified to discuss this point.

(RJW, A-60)

While it is true that one-half of the population of the State of California lies within 160 km (100 miles) of the San Onofre site, the staff does not consider this to be a relevant observation. The staff's focus on demographic data for site suitability and site comparison purposes has been traditionally within 80 km (50 miles) of plant sites.

The discussion in Section 7.1.4.3 indicates that most of the accident impacts occur within 50 miles of the site. The staff has compared the total population within 50 miles of the site with the total population within 80 km (50 miles) of other nuclear plant sites and has found that San Onofre does not have a uniquely large population. Moreover, it is important to note that, as stated in Section 7.1.4.2, the site-specific population projected to the year 2000 both in magnitude and distribution has been used in the calculations through all regions to 160 km (100 miles) and beyond. Those fractions of the consequences which take place up to 16, 48, 80, 160. km (10, 30, 50, 100 miles) or beyond, are accounted for in the results presented. The site does not have a uniquely large population contained within any of the above mentioned distances.

(RJW, A-60)

The San Onofre Units 2 and 3 at 3390 MWt are typical of the upcoming generation of reactors.

The power level of each plant was specifically used in determining the inventory of the core for the risk calculations. Salem 1 is presently operating at a comparable power level of 3338 MWt.

(RJW, A-.60)

The production of farm and dairy products is specifically considered in the calculation.

Differences among the states (and countries) potentially impacted are taken into account.

11-19 (RJW, A-60)

The impacts within the Mexican borders were included in the evaluation. The method of determination of data for Mexican agricultural products is discussed in Section 7.1.4.2.

Although not explicitly stated, the population within the Mexican border was included on a site-specific basis out to 560 km (350 miles) from San Onofre.

(RJW, A-61)

The staff recognizes the potential efficacy of drugs in mitigating consequences of offsite exposures. However, in the case of potassium salts of stable iodine, the staff does not require provision for distribution to the public.

(RJW, A-61)

Section 7.1.4.4 discusses that the condemning of foodstuffs was specifically considered and the interdiction of contaminated property " ... until it is either free of contamination or can be economically decontaminated" was assumed.

(RJW, A-61)

The subject of filtered venting systems for the containment is being addressed in rulemaking, as discussed in NUREG-0660, 2.8.8. The whole subject of TMI-2-related improvements and the fact that no credit would be taken for them is discussed in the last paragraph of the section cited.

(RJW, A-61)

It is the staff's position that such a "worst case accident" is much too remote and specu-lative to require analysis under NEPA.

(UCS, A-63)

The staff believes that its treatment of a multiplicity of possible accident scenarios represents a reasonable and appropriate implementation of the guidance provided in the Commission's Statement of Interim Policy.

(UCS, A-63)

The probabilities of occurrence of releases in the nine categories are explicitly given in Table 7.3 and the probabilities of occurrence of specific levels of environmental con-sequences are given in Table 7.4. The staff judges that this is within the intent of the quoted part of the sentence and the additional directive in the Interim Policy which states:

"The environmental consequences of releases whose probability of occurrence has been estimated shall also be discussed in probabilistic terms." See also the staff's answer to Joint Intervenors RJW, A-58.

(UCS, A-64)

The staff has presented a measure of individual risk in Figures 7.7 and 7.8. Table 7.4 and its associated figures and Table 7.5 provide group information. The discussion of relative susceptibility of various sub-groups of the population is given in Section 7.1.1.3. The staff judges that this conforms to the further directive that the discussion be " ... in a manner that fairly reflects the current state of knowledge regarding such risks."

(EPA, A-66)

The Supplement is a replacement for Chapter 7 in the existing Draft Environmental Statement for the Operating License stage (November 1978). It is not a replacement for the accident sections of the Construction Permit stage Environmental Statements of 1973.

(EPA, A-66)

Nine tables could have been provided to show the impact contributions of the nine categories.

It is the staff's judgment, however, that the summary table, reflecting sums of the contri-butions from all of the categories, is sufficient. Information regarding the relative contributions of the release categories is available in the Reactor Safety Study, WASH-1400.

11-20 (EPA, A-66)

The Design Basis Accidents are included because they are used in the Safety Evaluation Report to assess the adequacy of the performance of certain engineered safety features. In the SER, the DBAs are compared to the suitably small fractions of 10 CFR 100 for those accidents that are. considered likely (infrequent accidents).

(EPA, A-66)

The DBAs are judged not to be significant contributors to environmental risks and have not been subjected to the same kind of probabilistic analysis as the more severe accidents that are treated.

(EPA, A-66)

The staff believes that it is more informative to discuss the environmental risks associated with accidents separated from those attributable to normal operations. Both may be found in the Final Environmental Statement. Risks associated with the operation of both Units 2 and 3 are, to a first approximation, the sum of the risks associated with each unit individually.

(EPA, A-67)

We agree certain biological changes in children and adults may be detected occasionally at doses as low as 10 rem (e.g., slight, temporary reductions in circulating lymphocytes).

However, at doses of 25 rem or greater, such effects become measurable in nearly all exposed persons. In addition, although such changes have no physiologically significant impact, they can be clinically measured. We selected 25 rem as a point above which potentially serious effects due to radiation exposure (e.g., prodromal vomiting) become apparent to physicians and a point below which no difference between exposed and unexposed populations is apparent in terms of latent cancer incidence.

(EPA, A-67)

The NRC State liaison Officer has informed us that the Region IX RAC has completed its review of the local plan~ for the environs of San Onofre. The licensee has transmitted to the NRC copies of emergency plans for the following:

San Onofre, San Clemente and Daheny State Park and Beach Areas San Juan Capistrano City Camp Pendleton Orange County Unified San Diego County Interagency Agreement between San Diego County, Orange County, City .of San Clemente, City of San Juan Capistrano; Marine Corps, Camp Pendleton; State Department of Parks, Pendleton Coast Area.

The staff preliminary review of these documents affirms its judgment that the plans are, in fact, in an advanced stage of development even though they have not been submitted for formal review. A full-scale exercise for the San Onofre site and its environs is scheduled for May 13, 1981.

(EPA, A-67)

The NRC staff Safety Evaluation Report, dated February 1981, states that the San Onofre onsite emergency plan, when revised in accordance with the applicant's commitments, will provide an adequate planning basis for an acceptable state of emergency preparedness, and will meet the requirements of 10 CFR Part 50 and Appendix E, thereto. This is still the staff's conclusion.

The SER states that the plan must be revised to address the final criteria and implementa-tion schedule for the emergency centers and their functions, emergency manpower levels, and upgraded meteorological program, and to address the impact of earthquakes on emergency plans for the site and its environs. The NRC staff position is that the emergency plans are sufficiently complete to justify the estimates of parameters used in the consequence model.

11-21 It is true that the State of California does not use the U.S. EPA Protective Action Guides (PAGs). The State of California has elected to base its Protective Action Guides on the concept that no member of the general public should receive more than 500 millirem per year.

The emergency plans of the local authorities in the environs of the San Onofre plant have followed the State's guidance. This guidance is more conservative than the EPA guidance, i.e., protective actions would be recommended at a lower projected dose. Consequently, it is reasonable to expect that if protective *actions were to be taken at a lower value of projected dose, then exposures would be reduced.

(EPA, A-67)

The figure has been revised to present a more meaningful directional risk. The meaning of the new figures is discussed in Section 7.1.4.6. The scale of the figures has been expanded (a smaller distance from the plant shown) and it has been redrawn in an attempt to improve legibility.

(EPA, A-67)

Standard methods for estimating costs of reactor building cleanup and decontamination and replacement power for the economic risk calculations are under development. Reasonable estimates of plant decontamination and replacement power have been made, however, and are discussed in Section 7.1.4.6. Staff conclusions on the benefit cost balance are reported in Section 10 of the FES.

(SCE, A-68)

It is clearly stated in the third paragraph of Section 7.1.4.1 that the evaluations of the limiting faults and infrequent accidents are used to implement the provisions of 10 CFR 100.

The conclusions regarding siting are in the Safety Evaluation Report and its supplements.

(SCE, A-69)

Section 7.1.4.2 states that the estimates of the consequences may have as large error bounds as for the probabilities. Any uncertainty in the fractions of nuclides released contributes to the error bounds on the consequences, as well as uncertainties in the meteorological and health effects models. The subject of releases of certain nuclides, mainly the radioiodines, is presently under review by the staff.

APPENDIX A COMMENTS ON DRAFT ENVIRONMENTAl STATEMENT

Table of Contents u.s. Department of Agriculture, Science and Education Administration ..................................... A-2 U.S. Department of Agriculture, Economics, Statistics and Cooperatives Service ****************************** A-2 Department of Housing and Urban Development ************************ A-3 Department of the Army, Corps of Engineers ************************* A-3 U.S. Department of Agriculture, Soil APPENDIX A Conservation Service ............................................. A-4 Federal Energy Regulatory Commission ............................... A-4 COMMENTS ON u.s. Department of the Interior ************************************ A-5 DRAFT ENVIRONMENTAL STATEMENT Rourke and Woodruff Law Offices ***********.************************ A-6 r

- U.S. Department of Commerce ........................................ A-7 Department of Health, Education, and Welfare *********************** A-10 Southern California Edison Company ................................. A-11 U.S. Environmental Protection Agency ............................... A-38 Mr. Marvin I. lewis,., ............... , ............................. A-45 Southern California Edison Company ................................. A-45 Richard J. Wharton ................................................. A-46

UNITED STATES DEPARTMENT OF AGRICUI.TURE SCIENCE AND EDUCATION ADMINISTRATION U.S. DEPARTMENT OF AGRICULTURE OPFICI! OP 'n<E 0111'1./TY OIA&CTOR FOA AGFUCIJLTUAAL A!SEARCH liCONCMICS. ITATII'TICS, and COOPI!RAnVU SIIMCI!

WASHIMClTOH, O.C. 202tO w-~o.c.-

Subject:

NRC Draft EnviromHntal Stata~~U~D.t December 8, 1978 To: William ll. Regan, Jr.

U.S. Nuclear Regulatory Collllllisaion Erxltironmental Projects Branch 2 Division of Site Safety and Env. Analysis Waabingcon, D.C. 20S55

SUBJECT:

Draft Environmental Statement We have reviewed the draft eaviroUIICltal impact atatlliii8Dt 1111titled TO: Willima H. Regan, Jr., Chief San Onofre Nuclear Ganerating Station, Units 2 and 3, Southern Califomia Environmental Projects Branch 2 Edison Company, San Diego Gas & !Uectric Company, dated November 1978. Division of Site Safety and EnviroJUDental Analysis We have uo em=eucs to add to the evaluation provided by your staff.

do sppreeiate the opportullity of tevieving chis atat..,ent.

We u.S. Nuclear Regulatoey Collllission Washington, D.C. 20SSS

,;;:"(?.Z::.,.c.,-~- We have no COliiiiiOilts on the Draft Environmental Statement

=-1 N

ll. L. 1IAlUtOWS Acting Deputy Assistant Adm1niatrator related to operation of San Onofre Nuclear Generating Station, Units 2 md 3 by Southam Califomia Edison and San Diego Gas md Electric C~anies.

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P.O. 84¥ JIOOj S*n ftaact*eo. t::.-.'.u;~ ')t.\01 December 19, 1978 362..0 IS "fil.'tlfi..Y ~~ ... " ":'01 S?LE!l-E 2 January 1979 MJ:, Win. H. ~tegan, Jr., Chief en~iro~ntal Projects Branah 2 u.s. Nuclea>: R~l&t.Ol:)' COIIlalia&ton Dirision of Si.ta safety and li:ltvi.t<ltlll>>ntal l\lllllysis l.t.tentton: Dtucccrr, O:l.Vidon of Site Safety On~ted States Nuclear Rsqulatory C~ssion and Envtroll!llental Anlllysh l'luhinqton, o.c. 2DS55

\luhingt<lt\, o.c. 20555 Cantl..,.en:

Dear Mr. s..qan:

Subject:

San Qnofr~ Nuclear Generating Station trnits 2 an<) 3 Tllis is in respo~tse to a lett.>l: fl:Olll. your office da.ted 30 llovall:t>"r Draft tn~ironmental Statmuent 1!}78 whiah r&<~.uested reVi"" and COI!It!lents on the Or"'ft. Snvironi!Mitltal Docket Nos. S0-361 and 50-362 :tmpact Statement tor tha San <mofn GeneratintJ Station, llnits 2 and 3, pt't>posed lly Southern C1l.ifoxnia Edison Company and San Diego Ga.<

We have nview..d the caption4d document and have and flectrio Company.

> no eomm.ertts to offer on it. ~ere is no need to 'l'he ptepo5ed plan dou I:'J:>t. =nflic:t with el<ist:inq or authodz.ad plans

'

w send this office a copy of tne Final Environmental of the Cotps of Engine""". "'" have no eollll!ll!nts on the envirorunental statement for the p~e~d ~ction.

Statement. Thank you for the oppol::t\IDit:1 to reviow and comment on this statement.

Sincerely yours,

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UNITED STATES DEPARTMENT OF AGRICULTURE FEDERAL ENERGY REGULATORY COMMISIIION

. SOIL CONSERVATION HlWlC£ WASHIH<JTON, C.C. 20426 2828 Chiles Road, Davis, CA 95616 IN IIIJtiiiLY IIID'IDt TOt January 17, 1979 January 9, 1979 William H. Regan, Jr., Chief Enviro~~meneal Projects Branch 2 Division of Site Safety and

• Environmental Analysis United States Nuclear Regulatory Mr. William H. Regan Comm1seion Division of Site Safety and Washington, D. c. 20535 Environmental Analysis Docket No.: SD-361 Nuclear Regulatory Commission and 50-362 Washington, D. c. 20555

Dear Mr. Regan:

Dear Mr. Regan:

We acknowledge receipt of the draft environmental statement for San I am replying to your request of November*30, 1978 to the Onofre Nuclear Generating Station, Units 2 and 3, Southern California Federal Energy Regulatory Commission for comments on the Draft Edison Company, San Diego Gas & Electric Company in San Diego County, Environmental Impact Statement for the San Onofre Nuclear Station California, that was addressed to USDA Soil Conservation Service on Units 2 and 3, California. This Draft £IS has been reviewed Nav.,..ber 30, 1978, for review and c'""""'nt. by appropriate FERC Staff components upon whose independent evaluation this response is based.

r.... We have revieved the above draft and have the following c"""""nts.

1) Provisions for erosion control and water management during The staff concentrates its review of other agencies' environ~

mental impact statements basically on those areas of the electric conscruction as well as conservation treatlilent of disturbed areas power, natural gas, and oil pipeline industries for which the following construction ware inadequately addressed. We suggest t:hat Commission has jurisdiction by law, or where staff has special an erosion control plan be developed to adequately address the erosion expertise fn evaluating environmental impacts involved with the hazard both during and following construction. proposed action. It does nat appear that there would be any significant impacts in tnese areas of concern nor serious con~

2) Approximately 10 ac:.;es of prime land will be lost to access roads flicts with this agency's responsibilities should this action be and transmission ta'Wers. Mitigation or projected impacts from this loss undertaken.

'Were not adequately discussed. l<e suggest further discussion in the staCil!lle1lt to address the pri111e land issue. Thank you for the opportunity to review this statement.

We appreciate the opportunity to review and calll!lleilt on this proposed Sincer:!ly, project.

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Sincerely,

.'~".-}ft~

vJacR M. Heinemann

~~..,:. a/.;t.J FRA.'iC!S c. H. LUM Advisor on Environmental Quality State Conservationist f\Qo?-

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.<5it::ff,:/ WASHINGTON, D.C. 20240 Cultural Resources We are pleased that the NRC staff has directed the applicant to JAN 1 G 1979 consider historic, archeological, and Native American cultural*

In Reply Refer To: resources in its planning process. We understand that existing ER 78/1161 and possible new t~ansmission corridors will be surveyed for such resources~ However; we strongly urge that the applicant allow enough flexibility in its planning to actually take the results of these surveys into account in its final placement of Mr. William H. Regan, Jr. tower bases, access roads, and proposed substations. This would Chiaf, Environmental Projects Branch 2 include allowing the State Historic ?reservation Officer enough Diviaion of Site Safety and time to properly evaluate the surveys results and make appropriate Environmental Analysis recommendations. In addition, any nev land used for. material U.S. Nuclear Regulatory Commission storage or other project activities outside the transmission Washington, D.C. 20555 corridors should also be checked for cultural resources.

Dear Mr. Regan:

We hope these comments will assist your efforts in preparing the final environmental statemenr.

The Department of the Interior has completed its review of the draft environmental statement for San Onofre Nuclear Generating Station Units 2 and 3. We have comments in only two areas of our jurisdictional concern as set forth below.

f t.11 Recreation Resources De~ As:!~ta!lt The discussion of recreation impacts states that restrictive use of the beach area wa* unanticipated at the time issuance of the construction permit was being considered. Since no explanation is given, it is unclear to us how such a significant impact, the loss of recreational and scenic open space, could have been overlooked during the earlier planning stages. The final statement should disclose the reasons which nov require restrictions upon beach use.

Al~hough there ia nov recognition of the impact, we sea no attempt being made by the applicant to mitigate tho loss of recreation space and opportunity. With respect to the scenic quality of the area, we find the intended plan to construct an eight foot chain-link fence extending over three-fourths of a mile along the beach quite objectionable. Design of the walkway deserves

~ueh more attention. Given the fact taat this stretch of beach is rather removed from the developed portions of the state park units and therefore receives minimal use and given the 1cenic nature of the beach area and bluffs it would certainly seem more pref~rable and pe~haps sufficient to consider posting the area as to ita rest=ictive use. If a barrier is still needed, a more aesthetically sensitive, light railing ~ay best fulfill the need to restrict access. /'

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of their ener8)' requirements from SCE. Anaheim and Riverside have agreements with Nevada Power Com?lllly wherein eacfl City purchases economy non-firm energy JtOeCitT ""I,.AYCIC from Nevada Power Company. These agreements wiU expire by their own terms O.JUitiC'- 11* *,.ACUH in 1930. Anaheim and Riverside do not currently own any generating resources.

lllfi1JllrY 19, 1979 In 1973 Anaheim's peak demand was 338 megawatts. The estimated peak demand for 1973 was 39~ megawatts. Durlns 1978 Anaheim purc::llased two billion kilowatt United States Nuclear Regulatory Cammmlon hours of energy. For the period 1979 throuzh 1990 it ls estimated the peak demand Washinaton, D. C. 20"' for Anaheim wllllnc:rease In diff~ amounts. The smallest amount of Incntase for electrlc:al demand In any year during that period is estimated to be 3.1 percent Attentlom Director, Division ot Site, Safety and Environmental Analysis and the highest amount of Increase for any year ~.ll percent. lt ls also estimated for the same period of tlme that energy requirements for Anaheim will lnaease Gentlemen: with the lowest estimated annual. ~!~crease being 3.6 perc:ent and the highest est!*

mated annual .Jnc:reasa belns '*0 percent.

Pursuant 10 the notice pub.IJ.shed In the Federal Resister with respec1: to comments on the 011111: i!.rwlrcnmental Statement (DES), the Cities ot Anaheim and Riverside, In 1978 Riverside's peak demand was 27S megawatts. 1be estimated peak demand Califoml4 wish 10 submit the followlns comments. for 1978 was 260 megawatts. Durlns 1978 Riverside purc:hased over one blllion kUowatt hours of energy. For the period 1979 through 1990 It Is estimated the Anaheim and Riverslde beUeve the !'lnaJ Environmental Statement !Pt!S) should peak demand for R.iverslde will lnc:rease with the smallest annuatlnc:rease to be be amended In Seet1on ll, entitled "Need for the Station", 10 reflect probable owner- ~.0 percent and the highest annuallnerease to be 5.(J: perc:ent. lt Is also estimeted ship by the Cities of a portion of Sou1:bern Califoml4 Edison Company (SCE>, a~ for the same period ot tlme"that the energy requltements for Rlvemde will lnereue Interest In Units 2 and 3. with the lowest annuallnc:rease to be ~.o percent and the highest annua.l lnaeasa to be '*~ percent.

1be AllPiicutts and Anaheim and Riverside, entered ln10 a Letter Agreement dated November 1, 1977 wi1ldllncorpora.ted other prcpost!d ~ents, lnc:Judlns a Partld* The acquisition of an ownership Interest In Units :Z and 3 by Anaheim and Riverside

! paticn A&reement whfcfl provides for Anaheim to ao:!Uire 1.66~ of SCE's liO~ In-terest In Units 2 and 3, and for Riverside to acquire 1.7996 of Edison's S0\16 interest ln Units 2 and 3. The Lett<<' Agreement was entered Into by the Parties because does not cflanse the c:oncluslon that the Units are needed to meet the e!ectrlc:al load served by SCI!, Anaheim and Riverside. The load forecasts of see Include the loads served by Anaheim and Riven!de. Therefore, whether you lnc:Jude the loads ot A.nahe1m and Riverside In the SCE forec:ast of loads or break them out a question was raised as 10 whether SCE or SOC&:E would lose the Investment tax credit with respect to its ownership share ot Units 2 and 3 due to Anaheim and and Identify them sep&rate!y, the need for the station Is the same.

Riverside, publlc: agencies, own1nz an undlvided interest In Units 2 and 3. The Letter Agreement further provides, however, tha't when this question Is satlsfaetarlly re- Very truly youn, solved In the oplnicn of eacfl party to said ~ent, the Participation Agreement atuched thereto '111111 be executed bY the Parties. ~v j{. ZtJ/at;;-

The Internal Revenue Service has Issued Revenue Rl.lllns78-263, whicfl holds that ALA.N R. WATTS unc:llv1ded ownership In property by exempt and IIOIM!lfempt entitles does not of Spe<:!al Counsel Itself cf1squallfy the portion ot the property owned by the non-exempt entity from Cities ot Anaheim and Riverside takJng Investment tax credlt with respect 10 Its share of sucfl property. ~loreover, SCf and SOC&:E recelved a private letter ruling, dated August 16, 1973 whidl holds with respect to San Onofre Nuclear Ceneratins Station, Units 2 and 3, that SC!

and SDG&:E will not lose Investment tax credlt with respect 10 their undivided In-

n terest Units :Z and 3 after the sale ot the Interest to Anaheim and Riverside. ARW:jm:D:ll Howt!Ver, that Private Letter Ruling contained langUage whldl SCE and SOC&! cc: Att<<ched Ustlng believe to be ambiguous and therefore on O<:tobar 27, 1!178 they filed a Request tor Clarification of the Private Letter R.ul.lng of Ausust 16, 1973. The Request for Clarlflc:ation ls still pending before the Internal Revenue Service, but we belleve it will be favorably ¥:ted upon In the next several weeks.

Anaheim and Riverside are omently, and have for some years, been wholesale (\ cP t--

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Mr. John Bury Southern Ca.Lifomla edison Company 224/j. Walnut Grove Avenue P;o. Box soo ~ ~ .

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UNITID STATI!S DIJIIAATMENT OF COMMIUICI Rosemead, California 9Jno TIM! Aulatant !lllot'lltllry for Sclaftt:e *lid T..,.natogy Wllahington. D.C. <D2:l0 Mr. Mark Me<lford \...._,;/ 12021377- 4335 Southern California Edison Company 224/j. Walnut Grove Avenue P. 0. BoxSOO so- 3(c(

Rosemead, Calf!omia 926n January 22, 1979

'"3"2-Mr. Robert J. Pate U. S. Nuclear Regulatory Commwlon Director, Oivision.of Site Safety P. 0. Box ~167 and Environmental Analysis San Clemente. California 92672 U.S. Nuclear Regulatory Commission Washington, D.c. 20555 Samuel B. Calley, ~q.

David R. Pigott, ~q.

Dear Sir:

Chickering IX Gregory Three Embarcadero Center, This is in reference to your dra~t environmental impact Suite 2300 statement entitled *san Onofre Nuclear Generating San Francisco, CA. 94111 Station, Units 2 and 3, Southern California Edison Janice E. Ke!1", E$q.

Company, San Diego Gas & Electric Company. " The

3. Calvin Simpson, Esq.

enclosed comments from the National Oceanic and Lawrence Q. Carc:la, Esq. Atmospheric Administration are forwarded for your

$066 State Building consideration.

San FranciJco, Cali1omla 94102 Thank you for giving us an opportunity to provide these comments, which we hope will be of assistance to you.

T'...., Wm. H. Regan, Jr.

Environmental ProjectS Branch 2 Division of Site Safety and Environmental We would appreciate receiving lO copies of the final Analysis statement.

United States Nuclear Regulatory Commission Washington, 0. C. 20$" Sincerely, Richard J. Wharton, E$q, 46" Cass Street San Diego, California 92109 David W. Gilman Rober-t C. l.acy ctl....~~ Ql_.g~

Deputy Assistant ~~ry A

San Diego Cas &: Electric Company for Environmental Affairs P. 0. Box 1331 San Diego, Callfomla 92112 Enclosures from: Gordon G. Lill.--Natianal Ocean Survey Gerald v. Howard--National Harine Fisheries Ser1.*

Phyllis M. Gallagher, Esq.

Suite 220 61' Civic Center Drive West 5.t.nta Ana, C:ilitornia 92701 Gordon W. Hoyt Utilities Director P. 0. Box 32:22 Anaheim, CA. 92S03 Qoe~, \'

Everett C. Ross Public Utilities Director City of Riverside 3900 Main Street Riverside, CA. 92522 7 9 01 3 I 0 O'f7

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blwtd, Callfomla 9tlr.l' TO: PP - Richa1JI L. Lehman ...- Date January 8* 197 9 FSW33/JJS FR<Jf: ./:,J..,. -~- /} d.t OA/Cxl - G<ifdOn G. L1l1 To t £t.Off1ce of Ecology and Conservation

SUBJECT:

OEIS #781Z.06 - San Onofre Nuclear Generating Station, .zm'&l!.~

Units 2 and 3 .Tltru  : ff. ~nnetll~.M:s. Acting Dii"'ICtor, Office of H.t.b1t&t p~*'

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The subject statement has been reviewed within the areas of NOS responsi- ,\. .. u /{l:f-' '

bility and expertise, and in terms of the impact of the proposed action on NOS activities and projects.

The following comments are offered for your consideration.

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Mo. 1su.OG - San onofrt Nuclear Generating Station. Units t and 3 (NRCl Section 2.3.1, Surface-water hydrology, has been found to be very adequate for the purposes intended. the authors are to be commended for the Tile SUbject. DElS whfdl IC!;III'fi1)1R1td .)IOUI' IHI'IIOrandUII Of lltcUibel' 8, 1978,

> thorough bibliography on the subject. has bien r'IYiawed by the National Marintt F1sheriu Service. The followin I CCIIIIII!nts are offered for' .)IOU,. consideration:

00 NOS concurs with and encourages the oceanographic monitoring program de-scribed ln Section 6.Z.2. We feel this program wilT ensure environmental sssc1f1c COmm!nts protection and help allay public concern.

s. Env1ro~ntal Effects of Station Operation 5.4 Env 1ron11111nta l Ifllllac:ts 5.4.2 Impacts on the aquatic: environment Page 5-26, paragraph 7, Kelp In paragraph 7 little information ts included doc:umentfng the importance of kelp ~ coastal commercial fis" species. Information available 1n the ta\1fornia Department of Ffsh and Game Fish Bulletin 139 (Quast, 1968}

provides SOII!t insight in that r.egard.

Data developed by Jay Quast of the then u.s. Bureau of Commercial Fl&heries, and included in that publfc:at1on, indicate that in his studfes he found more than twenty commere1ally important flsh speciea occurring in the kelp beds off southern CalifOrnfa. According to those $tudfes the relationship of many of those spec:fes to the kelp habitat was mort extensive than indicated by the ffnal sentence of the !Ubject paragr1ph.

_This should be refhcted fn ttte text of the final EIS,

6. Enviromaental llon1tor1ng 6.3 O~rational ~nftoring Programs

~.3,3 Aqu.tic biological monitoring liTERATURE CIT!D Page 6-7. paragraph 1 Quast. Jay c. t968. B. Observations on the food of the kelp-bed fishes.

The concept of continuing a kelp study program into the operational stage In: California Department of Fish and Game. Fish Bulletin 139, of SONGS is a good one. However. should those studies determine that Pp 109-142,

• S1gn1f1cant harm is occurring to that resource. then some method of compensation satisfactory to the National Marine F1sherfes Service would need to be developed. This should also apply to the studies being conducted on fish impingement at SONGS 2 and 3.

tf such measures are not adopted and ad~erse Impacts do appear the monitoring program may be merely documenting the demise of a valuable eoastal.resource,

10. Benefit-Cost Summary 10.7 Sum.&rY of Benefit-Cost Page 10-J, p!ragraph 3 Th! potential additional cost of compensating for loss of biological

.. resour~s due to the operation of SOHGS Z and 3 should be addressed.

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DEPARTME!'lT OF \"lEALTH. EOUC).TION. AND WELF).R£ PUBLIC HEAL.. TH SltAVIC:&;

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