5) Zn a zecent letter to John Aheaxne, Chairman ot the NRC. Cus Speth of t?>> president's Cornell on Environmental Quality outlLned sewxal generic deficiencies, vhich he characterized as disturbing'Ln the NRC Zzpact Statement Process of nuclear pover T~ most darning of C)X)>s criticisms vas that the discussion of potential accidents and their environmental Impacts in these Impact stat<<lents vas perfunctory> remarkably standardized> and uninfozmative to the public . Speth found that despite vide wriations in the size, Location, and design of nuclear pover plants that have 'been

.ILcensed by the ÃRC, virtually owxy EZS contaLns essentially Mentical boilerplate language vzltten in an unvarying toxmat . The failure to consider the versa case.

oz Class ZX accident is ex<<xplified Ln the Statssent prepared for the licensing of T.C Colts I s ZZ. vhere no consideration is given to the Class ZX scenario. This omission loons >Zuite large in vier of the Staft's ovn visv t.'>>t such an accLdent did 0CCur On )larch ZS, 1979.

!path also urges the Ccc<<Lesion to 'broaden.its rage of variables le.g. radiation pathvays) in determining accMent's Impacts, an4 ezpand its dLscussions Ln EZS's of the

v-Contacts 2 Source: Al Craven (2I 3) 22l-3JIO So, he said, PpfrL is offering flat to sell part ownership-imerests in the plant and then, if more should be sold, portions of the elec rdty it will produce through the l9SOs wUI be offered. He emphasised that, despite the sales of part ownership, PAL wUI retain control of the plan and be responsible for its operadcn.

PpfcL now has about a 40 percent generating capadty reserve.

Assuming that the *mand for ef~idty grows as PpftL expects it to, the company will have about a 43 percent reserve when the fil t generating unit at An opportunity to own part of a nuclear power plant or a percentage sharply tss of the efectridty it wUI generate during the first several years after it begins gus~hanna begins operation. PpfcL's agreement with PJM Is ~t it will maintain s cn 4 reserve of at least 6 percent operation has been offered in letters sent by Pennsylvania Power dt Light Co. to electric utiUtles ln Virginia, Vest Virginia, Ohio, New York, western Pennsylvania AUegheny Elec+le Cooperative'fnc a Harrisburg~ed power and New England. Similar letters had already been sent to the other companies ln cooperative, already owns IO percent of the)plant. A~sic CIty Eiecwfc Co., a the Pennsyfvan)a-New Jersey-Maryland Interconnection (PJSI), of which PPJtL is a private utiUty serving customers in the Atisnac City and southern New Jersey member.

area, has agrewf to buy about 6 percent of Susquehanna's electrical rxrput untU l99!. The sales to AUegheny Electric and Athntic City El~le total about ViUlam Hecht, manager of System Planning for PAL, said the 333,000 of Susquehar~'s 2.l milUon kUowatts.

company wUI be In a position to make a portion of the capacity or electric energy from Its Susque)mrna Steam Electr)c Station avaUable, since the company's 06C"40AI generating capadty will be greater than Its obUgations to the PJM power pool when NUCLEAR the nuclear plant near Eerwick begins operating. "The rate of growth for people' use of electr fdty has Popped considerably since we decided to buUd the plant," he explained.

SUSQUEHANNA RIVER BASIN CO>!I>IISSION Mr W H Rag an - 2 August 30< 1979 Pj 172l Marin Fsani Sissies Hssrisburg, Pssnsyivbnia itl02 Fme ee t%'ce ol the EIKwto OvK$0I August 30, 1979 cfs) ~ The basis for that umber is not clear, but appeazs to be based on four years of climatic data col-it lected at, the si.te. If so, it may not he representative of actual worst evaporative conditions experienced at Mr. William H. Regan, Jr., ChLef the site. The Commission's concerns f cga the viewpoint Envizo~ntal Pzof ccts Branch 2 oi water management, is the pzobability of maximum con-DLvision of SLte Safety and sumptive use, expected under the wozst set of clastic EnvLronaental Analysis conditLons, occurrLng concuzrently with low flow. The Nuclear Regulatozy Co~Ssion dzaft EIS statement has not. addressed this concern.

WashLngton, DC 20555 Also, the pzoceduzes and assumptions used in making the calculation of maximum and average consumptive use should Res Docket No. 50-387, 50-388 be clearly stated.

Dear Mr. Regans iii It is stated on page that the river flaw at which consunptive use aust be replaced is 23.2 cms (819 ~ 0 cfs).

Reference is made to your letter dated June 22, 1979 trans- This figure should be equal to the 7-day, 10-year low mitting the draft EnvLronmental Statement for Susquehanna Steam flow plus the consunptive use. Our analysis of 7&ay Electzic Station presently under constzuction by PaunsylvanLa average low flow frequency at WLlkes-Bazze, based on the Pc~sr and Light Ccmpany. The Ccmmission staff has the following perLod of zecord 1900-76, shows that the 7<ay, 10-year comments on this draft. low flow Ls 800 cfs. The applLcant has used the value of 770 cfs which is based on an analysis by USCF for

l. water In section 3.2.1, page 3-1< it is stated that station requirements have increased since the construc-the shorter period 1900-72. We believe our analysis is more correct by vLrtue of including additional record.

~t tLon permit stage. Apparently the basis for this state-Ls the rLver intake flow shown in Table 3.1 which is shown as increasing by 0.45 cms (about 15 cfs). How-Also, we believe that the consumptive use value used should be the maximum consumptive use, which is stated ever, we cannot verify the 1972 figure shown in Table to be 64 cfs, rather than the average consumptive use 3.1 nor can we detezmine the reason for the Lncreased uied in your report. This Ls Lssportant in detezminissg water witMrawals. Also, the text states that water the storage required for consumptive loss makeup. The withdrawal will be at a rate of 1.8 to 2.2 cas, but the applicant has stated that they have computations show-table shows 2.45 cms. Please clarify the dLsc=epancy ing that the desLgn of the zesezvoir based on the 50 and the reasons for Lncreased water witMzawal. Also cfs avezage loss will provide adequate storage Ln a re-please clarify the text to indicate whether the increase peat of the 1964 dzought of record. We have as yet not pe tains to watez wLthdrawal or conssrsptive use. seen that data.

2. In section 3.2.1, the discussion of the SRBC regulation In section 3.2.2.3, page 3-8, the 7-day, 10-year low flow is Lncozzect. The applicant will still be permitted to is identified as 23.2 cms (819.0 cfs) . That. appears to wi.thdraw water during periods of low flow, but the aaount be inconsistent with the above comments, and with section of the consumptive use aust be replaced. The pzoposed '4.3.2.1, page 4-2 where the 7-day, 10-yeaz low flow is resezvoir is not an alternative souzce of water but only stated as 21.8 cas (769 ~ 8 cfs).

a source of ~cup water. The regulation Ls correctly stated in section 4.3.2.1 except that the third sentence 6. The proposed intake structure may not meet the require-should read, 'The regulation zequires zeplace=ant of ments of sectLon 316(b) of pl,92-500. According to the consumotive use.. Envizonacntal Statement, the cmbaynent Lntake will re-move more biomass than an alteznative Lntake...'RBC

~

It is stated on page LLL and again in Table 3-1 that the ~ staff zeco ends that an Lntake stzucture be designed using hest available techrology before the plant is is-3

~inurn consmpuive use Ls estimated to be 1.81 cns (63.9 sued an opezatLng licenke.

800@ 0 Hr. W. H. Regan, Jr. 3 August 30, 1979 V"OS'.

~ ~ 4g Staff is concerned about the effect of the consumptive withdrawal on aquatic habitat during prolonged perLods or's oo SUSQUEHAi eNA RIVER BASIiI COiXDIISSIOih 1721 North Front Street Nerrtstorg. Pennsyrvenre 17102 oE low flow. This concern should be addzesse4 in the draft statementR fR12o e3o olreo or

8. The post operational monitorLng programs do not include eR~ Orooror ~ e3 AprLl 302 1980 any provision for metering plant intake and dLscharge flows. We zeco ended to PennsylvanLa DER that such of flow meters be required in connectLon with approval the encroachment permLt foz the intake and discharge Director structuresr but these are not addzessed Ln the Euviron- Division of Site Safety 8

~tal Statement. We still believe that meterLng flows is an essential pazt of the environmental monitoring Environ-enta1 Analysis Office of Nuclear Reactor RegulatLon progress ~ DRS. Nuclear Regulatozy Cession WashLngton, DC 20555 Thank you for the opportunity to comment on thLs environmental StaCCA1lt Ret Docket Nos. 50-387, 388 Very truly yours, Dear SLr/Madams Robert J. Lelo sLon, are The following co ants, prepared hy the staff o! this in zesponse to the Draft Supplement to the Dzaft En-

~s-ExecutLve DLrector virormental Statement'NURES-0564) zelating to the Susquehanna Steam Electric Station. They focus primarily on clazification of positions attributed to the Commission an4 apparent errozs of fact or methodology. The cc cats aze keyed to the section numbers of the 'Draft Supplement'.

Section 3. 1-Introduction We believe that the second sentence of the secon4 pazagraph would more accurately ref)ect tha circumstances if it follower 'Zn response to ccx ants by the Pennsylvania Dept. of read as Environrental Resources and SRBC regazdLng the desirability of optiml development of the sLte to meet watez supply needs sub- in addition to those of the Susquehanna plant, the applicant tlitted ....'learly, water conservacion.

our cct ants have, nothing to do with We note also that we have not seen copies of any of the coz espondence refezenced in the second pazagraph.

2 K 3.2.2-~2- 2 22 2 3 There Ls a mooor Hastate=ant of the SRBC consumptive use make-up requr "e-ent. The first sentence refezs to the 'average ccnstmqrtive use ... by SSES Ln defining the low Llaw czitezion, whezeas the regulaticn specif'es 'the 7'0~ca lcw flow plus

Dizector 2- April 30, 1980 Dizector - 3 AprL1 30, 1980 the project's total coasumptlve use and dedicated augmentation. design criteria of having multiple outlets '... so that zeleases (18 cPR 803.61(c) (1) (i)) As we Lntezpret the regulation, the can be made from the resezvoLz level vheze the vator temperatuze appropriate value is tho actual zather than the ave~ra e consump- most closely matches that of the Susquehanna River (TAVE g De tive use. This notioa is stated correctly in Seccoa .4.2.1. sign Report-Pond Rill Reservoir, Pebzuazy, 1979, p. 3-4) ~

Zt ihould be corzecte4 here.

Wo do note that tho flaal paragraphs of the Soctioa conclude Section 4 '-Zmuacts on Water Use that the release vL11 cause cold shock, contain large amouats of organic materials, be high Ln iroa, and may be anoxic. We have The last sentence refers to aa application for a NPDES per- three comments with zegazc( to these conclusions.

mit applicable to reservoir discharges. We aze not aware of any such yezmLts. 1. We find them difficult to reconcile with the assortion of Section 4 2 that all quality criteria, except foz iron, The section also concludes that '... the quality of the water will be met.

dLscharged from the Pond EL11 Resezvoir vL11 moot applicable DER and EPA criteria except for an occasional high level of Lzon. 2. Wo cannot accept the conclusion that such releases This conclusioa should be zeviewed La 1Lght of the comeats zo- ~should have little impact oa the Susquehanna RLver, lating to Sectioa 4.3.2 below. since augmentation releases mall in volume'p. 4-9). This bo vill iafzoquent and usually S ci i.3 2 2 Z..d-t1 i ~th \ ~t* argument seems to haag on a long time average concept. Under mlaimm Cally flov of record conditloas compensation releases would Oa page 4-5, Lt is stated, '... the potentLal that eutrophic represent about 10% of the river flow. Moreover, the conditions will occur Ln Pond EL11 Resezvoiz is zelatively hLgh. SRBC consumptive use requirements specify that, 'The suggesting that water quality yroblms are quite. likely. Later physicalt chemical an4 biological quality of water'sed on that page sedLments, very it islittle stated, ... once phosphozus reaches the bottom of it usually returns to the epillmnion.

foz compensatLon shall meet the quality yuzposes for (protection of publLc health4 stream quality controls The analysLs concludes that productivity levels time as '... vill nutzieats are lost to bottom sedLments.'e are Cecline over economic developaentg pzotectioa of fisheriesg zeczea-tioag dilation an4 abatement of pollution,) 'ong less optimistic that such vL11 be the casa. Zf the bottom vater others (18 CFR 803.61(h) (1) and (e)). Zt isn't clear becomes aaoxic, vhLch seems to be a distinct possLbility, phosphorus aad ~nia vill be released from the sediments. Duzlng turnovezs, that this requirement vill be met. PLaally, it bo note4 that ouz consumptive use regulations require should these nutrients vould be returned to the epL1Lmaion. compensation foz vatez rmoved fzcca the river and not returneK to it. A~umentation carries the idea of in-czeasLag the flow above Gie amount available under Section 4.3.2.3-Disc)are(a ~Sstem natural flow conditions.

Zn the fLzst paragraph under 0~rational Zmuacts, there is the statement, vill be vithdrawn.

'... as presently desagne~oa y y~TLmnetic water The zepozt thea goes on to point out that Lf

3. We feel that the applicant should more fully iavesti-gate vater quality problems assocLated vith the releases this is the case, tho result will be cold shock to many of the and pzesent procedures for meliorating them.

organims. The only way vo caa see that such a coaclusioa is possLble is to assume that foz the Cm presently yzopose4 the spacing SectLon 4.4.1Wonstzuctioa and elovatLoa of the Lnlet structures rmaia as planned for the orlgiaal dm vith top elevatioa at 950'sl. Do you kaov this to We have reservations about certain of the parameters used Ln the temperature modeling. The origLaal analysis by the applL-be the case? As zecently as April 19, 1980, PP4L has zeported to us that the project desiga has been revised to reflect tho 'full- cents'onsultant used 1975 climatic data to simulate the 1964 sise'esorvoiz (Elevatioa 990'sl top of dsm). Purthor< that correspondence states that the Lnletwutlet structure has been ze-drawdown. We feel 1964 climatic data.

it vould have beaa raze apyropriate to use Moreover, ve feel that tha results aze even vised fzom inclined to a conventional multiport veztical tover less appropriate for the larger zeservoir. Zt Ls our judgment that.

structure ~ We assume that the applicant intends to adhere to Lts a aev analysis shou14 be made of the larger resezvoir, using more .

appropriate parmetezs.

Director ApzL1 30, 1980 Director April 30, 1980 g ti ~ .).2dl g ~thd td I! i Zt is also stated that the pumpiag statLoa lies outside the 100-year flood plain. We aze unable to vezify that statement be- A statcmeat in the second paragraph misconstzues this Com-cause of the level of detail used in Piguze 2.5. Hoveverd the mission's position regarding tho use of existing reservoirs. The pumping station clearly lies outside of tho floodway. statement 'SRBC's zesponse to this request vas that the Covanesque Reservoir is not now a timely alternative,'isLntezprets the Section 4.4.2.1-Watdr ~Su 1 statement on p. 2-3, AppendLx H of the Environmental Report-Operating License Stage. The applicant correctly sum)arised the The secon4 and third paragraphs contain statements that. cormcats of our April 17, 1978 letter which suggested that a re-are incomplete and potentially misleading. The second pazagraph study of all potential vater supply uses, the impact ot these uses Lgaores the fact that the larger reservoir Ls planned to meet not on other project functions, aad detezminaCLon of the necessity only the consumptive use requirements of SSES during peziods of tor reauthorisation be made. Tho 4pplicaat then dzev its ovn

'e coa-

.low flov but also similar needs by other'ovastream users who clusion that, SRBC coments indicate that Covanesque Reservoir might contract for a portLon of the Pon4 Hill Water Supply. To is aot nov a timely alternative.'Ep)vlsis added) The draft state wLthout explanation that the applicaat has assumed a release rate of 2.9 cms, as against Lts ovn needs of up to 1.8 cmsg is un-suppl~t sets forth the as the positioa of this Commission a coa-applicant. of our April 17, 1978 clusion reached by (A copy fair to tho applicant, making Lt appear they aze planning a re- letter to the Corps of Eagineezs is attached.)

lease that bears ao relation to their ovn needs.

Section 5.1.3-~S

'ocher uses'ze recognized ia passing ia the third para- co graph. Hovever, vithout aay oxplanatLon as to the nature of Zn recent months, vo have been vorkLng closely with both the I Chose other uses g thc discussioa could leave the impression that ot Eagineers and Pa. Povez 4 Light Co. to explore the use they aze scmehov associated with the Susquehanna plant. Also, would be more accurate to note that, based oa the average consump-it Cozps of the Ccvaacsque project and an expaaded Poa4 Hill pzoject (en-lazge4 to approximately 22,000 acze-feet of active water supply tive use during the design dzought, 1.5 cas SSES for zeplacement of consumed vatez aa&.6 cms vill vill be neede4 by, Cho bc avail-stozage) as complementary vater supply sources to moot several needs in Chc basin, including SSES. The Corps has completed Stage able to other users. (A similar misstated zegazding the avezage COINWB~Sghg ) th <<d g g gh ) Itheofentire its Ccvaacsque Lake Reformulation Study and expects to have study completed by wazch, 1982. ppsL estimates at this gg time that vith coatinued work on the Pond Hill pzojcctg Cho com-last paragraph of the Section relates to the zefLlling pletion date tor ppsL storage only is suamerg 1983 and vith maximum The ot the reservoir. Tou state correctly that the planned opera-tional procedure calls for no pumping from the river when river stozage, s~r 1984. As you aze avare, ppsL has announced the in-service date for Unit 1 is aov Januazy, 1982 and Januazyg 1983 flov is below SS cms (3,000 cfs). Tou should be aware that ve for Unit 2. At its march, 1980 meeting, tho Susquehanna River which Peach have as yet unresolved concerns about possible environmental im- Basin Commission adopto4 July 1, 1984 as tho date by pacts ot pumping at such a lov level of river flov. Bottom Wucle4r Ccaor4tiag Statioug Three MLIO Zs14ad Nuclo4Z Ccn orating Stationg aad Susquehanna Steam Electric Station must be We assume Chat the refilliag rate of 3.7 cms refers to La compliance with the conceptive vater makeup requirements.

the pmping capacity of the cnlazged project. We have not seea these specifications Section 5. 2-AltomaCLvo Sites Section 4.6.2.3-~Hdrol)od(lc Des~can ot Dam The first paragraph specifies ceztaia parametezs relating to tho usable vater storage requirement La the Pond Hill Rcsezvoiz We note vith concern that the dam design does not meet NRC that a"e no longer relevaat. Za response to questions raised by czitczia and that your staff is concerne4 about poteatial ovez- ouz staff, PPCL estimated that the full load coasumpcive'uso at topping. We feel that the design criteria problem Ls a matter tor the Pa. Dept. of Environmental Resources and the applicant SSES vill be 52.S cts (1.49 cms) base4 on the drought of record>

the 07-10 at the Wilkes-Bazro gage is 800 cfs (24.06 'cms) l an4 to resolve. the consumptive use make~ storage for the full load operation at SSES consumiag 52.S cfs for 106 days Ls 11,030 acre-feet.

Director April 30, 1980 DLzector 7 April 30, 1980 PP4L stated further 'that the Poa4 Hill Pm)oct, if intended tive loss would stL11 be continuing for some tLme (uatLl colC shutdown Ls obtaLaed) and the consumptive use would solely for SSES flow compensatton, will be constructed to pzo- he decayiag from its value prior to the beginning of the vide an active storage of 11,600 acze-feet (11,030 acro-feet for shutdown.

SSES plus 570 acre-feet foz losses aad downstream consezvatLon flow). (Letter from H. W. Curtis, PP4L, to R. J. BLelo, SRBC, The poLat is that Lf our understanding is corzectg hot shut Septuor 4, 1979) Ccwn is not a viable alternative to cons~ttve Loss make up, first sentence to 'a because tEe cons~tive loss continues until cold shutdown Ls The of tho second paragraph zefezs 1970 SRBC study'. Tho study La question Ls oae made by the Sus- reached. That further L-plies that Ln order to we the river fol-

~tteo, lower method, coll shutdowa would have to exLst on the fLrst day quehaana RLver BasLa Study Coordinating aa interagency task fozce made up of repzeseatatLves from seven tedezal Cepazt- that the flow goes below 07-10'nd hot shutdown would have had mmts and agencies and the three basta states. Zt was chaize4 by to start some considerable period of ttmo prior to zhat date.

the Corps of EngLneezs. The report was co~lated and released PLaally, under the brief periods of shutdown postulated for several months before thts C~sston cuba into existence. The applicant cites the study correctly in the ERAL, Appendix H, the analysts< it is not obvious to us why there should be aay sigaificant savings in the costs of opezating SSES. While wo Sectioa 2.4. do not know the coapoaeats of the 'Nuclear Generating Price',

S ti 5.3.1-B sita t 1~1 ~1 -N ~'river .11'L following'lterna-surely they are not eatLzely vaziable operating costs. Xt ap-pears that zhts aspect of the analysis needs to be recoasLdered.

tive The benefit-cost analysis for the developed Ln this section poses several probleas. Pizst, the S tl S.S.2W f ~ht*tl I analysis presente4 La Tables 5.1 an4 5.2 is baso4 on the asaumpttoa The matter of cost of water fzcca the Cowaaesque Lake pzo]ect of a 4&ay shutdown occurring every year. This Ls the average Ls not resolved and will not bo for some tLme to ccma. This Ccm-a~or of days the plant would be shutdown based upoa the flow mission is Ln the process of developing a water supply maaage-duration cuzve. Tho latter asst~tton implies that aa average meat program, one ccmpoaeat of which Ls a watez pztciag plea. Tho flew year will occur Ln each yeaz of the life of the pro)oct. But pzeswptton is that SRBC wL11 serve as the wholesale vendor of

=hydrology Coesn't work that way. The analysis should have been any water supply storage developed La the basin. Until this sa-based upoa the expocte4 value of the present worth of the cost of tire natter is nore fully developed, no oao can make any meaningful pleat shutdown for diffezeat flow sequences. The aaalysis dis" ~ sttmates of the cost of ohtaLniag water from existing zesezvoLrs ~

played La Table 5.3 apparentLy uttltses raze realistic zepreseata-tion of the flows Certainly it would not be correct at thLs point to apply either the prLces oz pricing scheme of the Delaware River Basin Comntsston Second, the calculations whLch produced the 160,000 WH, to'he Cowanesque Lake pro)acti 170,000 WWH, aad 146,000 R values meationo4 ia the fi graph of the section aze aot evLdent to us. We feel this should st para- Section 5.3.3-Pond Hill Resezvotz be clarified. There Ls an error Ln the statemoat about the cost of elec

'Thizd, the analysts assumes an equal pzobabtlity of hot an4 tzLctty for p~tng wats= into the resezvotz. The annual pumping cold shutdown. Our understanding of these tezms Ls as followsc cost is tho orna of a capacLty chazge and an enezgy charge. T'e 4,500 hp of pmptng capacity Ls equLvalent to 3,357 XW. As<<

sumtag a (mLd-1978) capacity charge of $ 12/XW, the anaual capacL-

a. Cold shutdown means the aucleaz reaction Ls ossea- ty charge Ls (3,357 XW x $ 12/XW) ~ $ 40,300. The energy charge, tially stopped, an4 no heat is being geaerated) assuming 30 days of pumping, and an energy cost of $ 0.025 por XWH

b. Hot shutdown means that the reactor coatrol zcds have Ls 3>357 XW x 30 days x 24 hrs./day x $ 0.025/XWH ~ $ 60,400. Thus, been Lnserted to stop the reaction but the zea'ction has the total annual pumptag cost Ls ($ 60,400 + $ 40,300) ~ $ 100,700.

(See MLS Design Report, Pond Hill Reservoir, p. 7 2 and Figure not actually ceased, heat is still being generated, 15,)

an4 both prLmazy aad secoadary coolLng loops aze carzy-iag away the heat. Under this ctzcmstaace, the cons~-

Dfrector 8 April 30, 1980 1 n ~ ~ n SUSQUEHANNA RfV"R BASIN COMV.'-55ioi"'721 North Front Strcot ~ Ftcrrisburg. Pcnnsytvsn:o 17102 We appreciate thc opportunity to c>smcat on the Draft April 17> 1978 Supplcacat. We hope that our ccuncasa are helpful. fro>> o> Or!> at tn>

E>> t>t>>> oi>ct>t Very trull> yours>

Colonel G. K. Withers Robert . Bielo U.S. Dept. of the Amy Executive Director Corps of Engineers Baltfaore District P.O. Box 1715 Baltfnore, Maryland 21203 Dear Colonel Wftherst Thank you for providing us with a copy of a request froa PPCL asking your o!fice to detemfne vhether the use of the Cowanesque Reservoir's potential seasoaal storage capability to nee- Susque-hanna Ssean Electric Station's consuned water nake-up aeeds vould be coapatfble with Covanesques'ther functions aad whether such use would be practicable and ecoaoafcally justified. Wc nose froa the PP4L request that ii ft is dcscmfned such storage aad water use is pemfssible the conpaay intends to seek a contract with the Corps for -the use of Cowanesque water and to subaft such contracs to SRBC for'pproval.

I have polled the Conafssfoa alternates on the ~stud proposal and would advise that the Cornfssfon recognftes the ncaa for the coapany (PPBL) to explore various alternative acasures to obsafn snake-up water to conpensate for consu=psfve losses of water at fts Susquehanna Stean Electrfc Station during certain periods of low strean flow. Further, the Cornissfoa rccognf es a need to deternfne the potential for seasonal water supply storage fn the Cowanesque Reservofr for uses other than as outlined by tho conpany.

Fsseatially the Commission believes that any review of the srorage capabflfty of the Cowanesque Reservoir should include: a range oi vater supply and other water use storage alternatives at the site, a detem.natfon of the effects such alteraatfves would have on flood storage and other project uses, ard a deteraiaatfcn vhether such alternatives vould require reau:hori=ctfon or could be acconplfshcd under current project authorization cnd Corps'uthority.

'TS0 Rest Second Col. C. X. Withers April ly>> 197S PA 19515 Street'locasburg, 20 August 1979 Director, Divisioa of Site Safety ard Bcvironaental Aaalyeis The Connission also wishes to note that if as a result, of the 0ffioe of Wuclear Reactoz Regulation study a positive detezainazion is nade of the potential capability II.S>> Hucleer Regulatory Cccmieeioa of Cowancsque Reservoir to neet the water storage coeds outlined by Raebingtoa>> IZ 20555 PPSL in its request that such finding doos not Ln any way pze)udice futuro Commission ection regarding allocation of water fzoa this The followLg connects acacew the Draft ZavironaeateI Stateaeat project. foz P-'PL's Suecsxehenaa Stem Rlectric Station> Waits I end R We will look'forward to your fLndLngs sad will be pleased to I'rge the Ceaiel of ea operating license fo the PPK pleat foz the following reasonsz nosiest'ower cooperate ia any wey possible.

Yezy truly yours, 1>> Reed

/dc./.'/? c:.i a>> the pro)ection of the PJR ~er petit (Table 7>>5) shows Robert . Bielo Executive Director ~

a Sf% Lnoreasez the national average Le, La acreeILty>>

slightLy over 2$ , a mre reasonable projection en4 one that decreases need> pushing becIt the dzop La z'eeerve over b

ven peale>>

while needs of the PJR power grid a.e a naia reason for the need co buLIC the 2PdrX nuclea. Power pleat SS 1 Sc 2) those aeeCs oea be bypassed end PPPX cea eelI direct to amber ccapanies (e>>g>> ~ sales to QP0 to replaoe-TRg electrioity) ~ PPK's growth elonee with a geaerating czar I

capaoity Ln exoess of 4'( cvez'eeIt Ceaead (Table 'F>>4) e does not show conclusive aced for ncz' generating cepac if ity

~

by 1981, especially the strong conservation neasures of the service area continue. Zn faot, Lf the aee4 were real, PAL be obliged to conduct a oraab, progzm to build a co~solid waste/solar (or whee-have-you) plea, since the nuciosr pleat asy very we11 not be in operation by thea>>

c. t"e stateaeat tha. wadditionel reierve capacity above 20~ ney be desirable foz' eyetea with units which ere large in relatioa to eystea siss (as will be the oase with gn zhe Susquehanna facility La servioe) ~ (p 7-5) rather then showing the need fcr the plaate shows that the plant, ia feote creates need lees ~

2, Rvelua.ioa of zhe Proposed Aotioa reaching the coa'clusioa that the nuclear power cycle Ls to nea thea the coal cycle> Lasufficieat nttea >

tica was peiC to the aouatiag evidence of the effects of low-level radiatiorI the unknown effects o rad'oactive waste Cis poealI an4 the reliability of evidence suppAed eInest eatizrely

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auc ea. Powe. indus~ ~ While Rgeeh~ebl ~ sots ney) at present, point to the coal cycle as nore

~~e for hara rendezs the nuclear oycle W aoz ~ Cestrzctive

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S~ Seaeff~ost Laalysfs ai The benefit of LLANO - L2i9 bfLLfoa Qh of eloctrLo powez'o the PR interohaage is base4 oa a not necess ar<<Jy valid asmytion of a ylant capaoity factor of fcrnsaco averages less b The addition of

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Ct0-70$ , when, ia actuilfty, nuclear power pleat yez 1S90 Mg g(74 of geaeratfng capacity to the PJM

~s a interchange and 210 )I to the oooyezative is Listed beaefLt thea, fa reality, it night be coastrue4 as a cost since powez'se ~

it noy encourage additional eleoMcal c The saviags of 7S nfllfoa (1980 0) fn yrodcctioa oosts per unit yer year oan be ~caged if total coatee fnclud-ing Sew~at subsiCies of the nuclear power indus~,

sro included Za nore concrete tersse the weavers" would accrue oaly if radioactive waste disposal fs not pirated into the coatee snd if tho plant-operates at 50 70fe efff cfoacy> wfCou sccfdeate for its pro)ected lifotfaez there are no nodels that would l.ea4 to the belief that th's wiLl happeni 4 The conolusioa that there am no si~~fcaat socioeco acnfc costs tc be ezyeoted frcn statioa oye atfoa Coca cze I

aot give sufficent weight to the very real s~ss cryo~ ~

Vl i<<aced sfaco QK by those LLviag ia a 20 nile radfus of the plant the.oonstant feeliag of a radioactive volcsao wfLL costi Lf~ on the ed-e of ei The ecoacafo casts are preseated fn absolute tezas raM~r than as ccayarod to not operating the pleat Cal culaticas frees sources ethos~ the utility have not been tshea fully'nto accountz Ec"a"off, ~ hagi, pro)ecto Zn ~~,

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~ lectz" ofty geaeraco4 Tron coaL-fired plants as c"capo ruclear sad the 4'or<<ace wfLL Lnereasei I urge the Xuclea. Regulatory CMssfcn to Cony sa operatiag License to 22$ foz'usquehaan Stesa (Ãuclea ) Z.ectrfc Statfoae Units 1 snC 2, because operating the nuclea" plant will advez'eely effect ao> as a PPK coamer eccncafcally, eavfwaaen tally sad eaotionallye saC because, t e ~need for aCditfoaal gener atfag oayacity has~ dfnfafshede there is eno~ lead. tfae to develop alternate energy sources (Lnclu~ the use of increased coaservatLoa sad ef icfcacy). to suyyly the elec~ c2ty aeeCeC fa nona en eccnccfcaLLye or ~

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APPENDIX C. ENVIRONMENTAL ASSESSMENT BY THE DIVISION OF SITE SAFETY AND ENVIRONMENTAL ANALYSIS FOR PROPOSED. MODIFICATIONS TO THE TRANSMISSION LINE SYSTEM, SUSQUEHANNA STEAM ELECTRIC STATION UNITS 1 AND 2 (PENNSYLVANIA POWER & LIGHT COMPANY CONSTRUCTION PERMIT NOS. CPPR-101'AND CPPR-102 DOCKET NOS. 50-387 AND'50-388)

C.l. INTRODUCTION By letter received on 15 Octob'er 1975, the Pennsylvania Power & Light Company proposed changes in the transmission routes previously evaluated for the Susquehanna Steam Electric Station.

The proposed changes involve:

a. Shortening of the Susquehanna-Lackawanna 500-kV line and resulting in the Susquehanna-Stanton 500 kV line.

b. Elimination of the Susquehanna-Frackville 500-kV line and replacement with a 500-kV line between SSES and Sunbury Substation and a 500-kV line between SSES and the Wescosville-Siegfried Substation.'~,z k

r Additional details concerning these changes were provided in Amendments 4 and 5 to the SSES Environmental Report, construction permit stage, submitted on 26 February 1976 and 30 June 1976.

C.2. REASON FOR THE PROPOSED CHANGE PP&L is a member of the Pennsylvania-New Jersey-Maryland (PJM) power pool. Prior to 1974, the reliability of the PJM bulk power transmission system was considered inadequate without the network addition of a 500-kV line from Lackawanna 500-kV substation to an existing 500-kV system in northern New Jersey. This line, which would have been jointly owned by PP&L and two other PJM utilities, was approximately 121; km long and was expected to be placed. in service by 1982 to provide overall improvement in the reliability of'he PJM bulk power network. This line was not analyzed in the Final Environmental Statement (June 1973). Based on the data provided by the applicant (ER-CP, Amendment No. 5) it appears that these 121-km transmission lines from Lackawanna to an existing system in northern New Jersey would be more environmentally sensitive than the proposed addition of 90 km of transmission lines.'ixty percent of the 121-km transmission lines was expected to pass through the Pocono Mountains. The staff did analyze the environmental impacts of the Lackawanna transmission line and related facilities that were to be constructed between the Susquehanna Nuclear Power Plant and the proposed Lackawanna Substation. In late 1974, modifications were made in the planned development of the PJM bulk power network due to changing patterns of load growth and capacity expansion of other companies. As a result, the proposed 121-km line was canceled. Without this line, the appli-cant has stated that a single contingency failure of the Susquehanna-Frackville 500-kV line would cause electrical instability of the Susquehanna generators and would necessitate restrict-ing output of SSES. Therefore, in order to obtain an adequate level of reliability, the pre-viously planned transmission system for SSES needs to be modified (ER-CP, Amendment No. 5, Sec. 3.9.1) ~

C.3. ENVIRONMENTAL IMPACT OF THE PROPOSED CHANGE The staff's,evaluation of the two proposed changes is as follows:

a. The staff analyzed the impacts associated with changes detailed in Amendment No. 4 (Susquehanna-Stanton 500-kV line) and it was concluded that modifications proposed in Amendment No. 4 are acceptable, as discussed in a letter to PP&L, dated March 8, 1976.s

b. The staff has analyzed the .impacts associated with changes detailed in Amendment No. 5 (proposed Susquehanna-Sunbury and proposed Susquehanna-Siegfried 500-kV lines), and this evaluation is detailed below. The review included a helicopter overflight by C-l

C-2 the staff on September 3, 1976, of the proposed Susquehanna-Sunbury line and tlie pro- '

posed Susquehanna-Siegfried line. Alternative routes were also investigated.

Descri tion of Line Routin and Transmission Corridor Environment Two lines are being proposed to replace the Susquehanna-Frackville 500 kV. The Sunbury-Susquehanna 500-kV line, shown in Figure BE 1, will terminate at the existing Sunbury 500-,230 kV substation. This line is approximately 71 km long and proceeds in a southerly direction from SSES, crossing the Susquehanna River where it intersects with the existing Sunbury-Susquehanna 230-kV route. From this intersection, the route parallels this existing line before terminating at the Sunbury Substation. This line will cross parts of Columbia, Nontour, and Northumberland counties. At a point 1.9 km south of Sunbury, the proposed line will again cross the Susquehanna River to the Sunbury Substation on the west bank in Snyder County.

The Susquehanna-Siegfried 500-kV line crosses approximately 87 km between SSES and the Siegfried Substation north of Northampton, Pennsylvania (Figure C.l). The line traverses parts of Columbia, Lucerne, Carbon, and Northampton counties.

Right-of-way data as supplied by the applicant are included in Tables C.l and CD 2.

The study areas for the Sunbury and Siegfried lines encompass characteristic steep forested ridges and valleys and gently rolling farmland. The proposed Sunbury-Susquehanna line routes would traverse approximately 55Ã crop and pasture lands and about 33% forested lands. The proposed Susquehanna-Siegfried line would occupy nearly 66K forest cover and 33K crop and pasture cover.

The forest cover is primarily comprised of a mixture of oaks and pines. In general, ridges and high plateaus are composed of scrub oak (Quercus ilicifolia), white oak (Quercus alhx), red oak (Quercus ruba), pitch pine (Eiinus rigida), and short-leaf pine (pinus echinata). Valleys are composed primarily of red, white, and chestnut oaks (guercus prinus), white pine (Pinus strcbus),

hemlock (Tsuga candufensis), several types of birch (Betula spp.), red maple (Acer rubrum), and yellow poplar (Stwiodendron tutipcferal The .slopes contain a diverse mixture of hardwoods and conifers; oaks, red birch (Betula nigra), white pine, hemlock, pitch pine, and white ash (Pnxzinue ame~ana) are dominant species.

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Dominant understory species include azalea and rhododendron (Bhodcdenchcn spp.), mountain laurel (Zalmia Zatifclia). blueberry (Vaccinium spp.), and willow (SaHa spp.) (ER-CP, Amend-ment No. 5).

The applicant has listed a wide variety of terrestrial and aquatic fauna within the Sunbury and Siegfried study areas (ER-CP, Amendment No. 5). The staff and the applicant have consulted the Pennsylvania Game Commission, the Pennsylvania Department of Environmental Resources, and the U.S. Department of the Interior. Local resource agencies, such as Bloomburg State College, have individually determined that the proposed routes do not cross areas contafning any known unique floral or faunal habitats or state forest natural areas and wild areas.4 Threatened and Endan ered S ecies The State of Pennsylvania lists no birds, maw@Is, or floral species as being threatened or en-dangered in the state. The Department of the Interior lists two endangered mamnals and three endangered birds whose range encompass the study area.s These are the eastern cougar (PeZis -.

ccncclcr cougar), Indiana bat (Myotis scdaZis), arctic peregrine falcon (Paleo peregrinus tunchius), American peregrine falcon (Paleo peregrinus anatum), and bald eagle (Haliacetus Zeucccephalus). The applicant indicates that no endangered or threatened mamnals have been observed in the study area. Critical habitats have been identified for the Indiana bat.7 No areas fn Pennsylvania have been identified as critical habitats for this species. Peregrine falcons have been sighted at Hawk Mountain, south of the study area (ER-CP, Amendment No. 5).

The bog turtle (CZimmys muhlenbergii) is the only endangered herpetile listed on the Pennsylvania Fish Commission list whose range falls within the study area. The applicant indicates that two endangered and two rare fish are listed by the Pennsylvania Fish Commission as having ranges falling within the study area for the proposed transmission line (ER-CP, Amendment No. 5). The applicant has provided the staff with its construction specifications program and vegetative management program and, based upon the mitigative and construction measures detailed, staff's position that any rare and endangered fish species that may inhabit the general area it is the along the applicant's preferred routes will not be affected by construction of SSES transmission lines.

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C-4 Table C.l. Right-of-way Data: Susquehanna-Sunbury Line Required Required Width of Width of Width of Area'f Existing New Additional Additional Lengt) Lineb Config. ROW Required ROW Required Segment of Line (ft) (ft) (ft)b (ft)b (acres)b Parallels existing Sunbury-Susquehanna 230 kV 222,600 150 325 175 894.3 Parallels proposed Susquehanna-Siegfried 500 kV 9,000 162.5 325 162.5c 33.6 Total 231 $ 600 927.9 Source: ER-CP, Amendment No, 5, Table 3.9-A1.

Conversion factors:

ft to m, multiply by 0.3048.

acres to ha, multiply by 0.40469.

With respect to the Sunbury line, the Siegfried line is considered to be existing and the required 325-ft right-of-way is equally divided between the two lines.

Table C.2. Right-of-way Data: Susquehanna-Siegfried Line Required Required Width of Width of Width of Area of Existing New Additional Additional Lenqth Line Confiq. ROW Required ROW Required Segment of Line (ftJb ft)b (ft)b (ft)b ( cres)b Parallels proposed Sunbury-Susquehanna 500 kV 9,000 152.5 325 162.5 33.6 Parallels existing Sunbury-Susquehanna 230 kV 4,400 150 325 175 17.7 New right-of-way 184,400 200 200 846.6 Parallels existing East Palmerton-L. Harmony (outside of BWAd land) 32,800 100 300 200 150:6 Parallels existing (north) Siegfried Harwood 230 kv 20,000 150 325 175 80.3 Parallels existing (south) Siegfried Harwood 230 kv 27,000 150 300 150 93.0 Parallels existing East Palmerton-L. Harmony (within BWAd land) 6,400 100 200 100 14.7 Total 284,000 1,236.5 Source: ER-CP, Amendment No, 5, Table 3.9-A2.

Conversion factors:

ft to m, multiply by 0.3048.

acres to ha, multiply by 0 '0469.

With respect to the Siegfried line, the Sunbury line is considered to be existing and the required 325-ft right-of-way is equally divided between the two lines.

BWA = Bethlehem Water Authority.

C-5 The applicant indicates that the only unique flora noted in the area, American chestnut (Caetenea The staff has dentata), is not endangered and will not be affected by the proposed routes. threatened or en-investigated the possibility of existence of any critical habitat containing dangered floral species as proposed by the Department of the Interior.a Ho critical The staff habitats have yet been determined for any proposed threatened or endangered floral species.

and the applicant, in response to staff questions (see Reference 24), have found no evidence that any threatened or endangered floral species are located along the proposed transmission routes.

Effects of Transmission Line Construction on Land Use and Im acts to the Land and Mater

1. Land Usa The Sunbury-Susquehanna line crosses approximately 38 km of open land, predominantly utilized for crops or pastures. A small orchard will be traversed as well as 4.3 km of land classified as small farm woodlots (ER-CP, Amendment Ho. 5). The remaining portion of the route crosses 24.3 km of forest land and 2.6 km of state game lands. The applicant has submitted a detailed inventory of residential and commercial units; institutional and historic features; river, stream, railroad and major road crossings; as well as selected environmentally sensitive features such as wetlands, game and~forest lands, etc., for each route.

The proposed Susquehanna-Siegfried line crosses 58.4 km of forest land, which includes state game land and state forest land. The line crosses a section of the Beltzville Reservoir in Beltzville State Park. At the crossing of the Lehigh River Gorge, the line will traverse 915 m of a proposed state park involving the crossing of an existing canoe trail and a proposed foot trail along an abandoned railroad right-of-way (ER-CP, Amendment Ho. 5). The line also crosses the Appalachian Trail at Blue Hountain while paralleling an existing 230-kV line. It is the staff's opinion that proposed paralleling 500-kV lines will not cause additional adverse impact to the Appalachian Trail. Approximately 25 km of agricultural land (29K of the total length) will be crossed by the proposed Siegfried-Susquehanna line.

2. ~tn acts The staff's analysis of the originally proposed Susquehanna-Frackville 500-kV line in the FES-CP (Sec. 5.5.1) indicated that approximately 23.4 km of this route would traverse forested land requiring the alteration of 143 ha of forest cover. Approximately 14.8 km of agricultural .land (79 ha) would also be temporarily impacted. Replacement of the Susquehanna-Frackville line with the Susquehanna-Sunbury and Susquehanna-Siegfried lines will result in an increase in both total forest and agricultural acreages required for new rights-of-way.

Impacts to the vegetative comnunities along the proposed paralleling Sunbury-Susquehanna line will be primarily limited to the selective removal of approximately 153 ha of forest cover along the proposed paralleling Sunbury-Susquehanna line. An additional 13.75 ha of state game lands will be disturbed, but the applicant will minimize impacts by preserving to the greatest extent possible all existing vegetation within rights-of-way limits except where removal is required for erection of line structures or installation of conductors (ER-CP, Amendment 5, Appendix I, Exhibit 8, p. 11). In addition, the applicant indicates that planting and reseeding will be undertaken where required by the Pennsylvania Game Commission.

The applicant indicates that the Siegfried-Susquehanna proposed route would traverse 54.3 km of forest cover requiring 61 m of new right-of-way and 6.9 km of paralleling line requiring an average width of 52 m. The applicant estimates that the proposed Susquehanna-Siegfried right-of-way will impact 367 ha of forest land. Host of the land will be cleared by selective cutting, which will remove all trees except specified low-growing varieties (ER-CP, Amendment No. 5).

Impacts to animals along the corridor may take several forms. Host directly, some less mobile animals may be killed by construction equipment. Loss or partial alteration of habitat will result in the displacement of some faunal residences and may result in the loss of some animals.

Disturbance of fauna will temporarily result from increased human activity during con-struction. This type of impact is not expected to extend beyond the construction phase of the project. s s ~

D ata on aquatic ecology, geology, and soil can be found in the ER-CP, Amendment No. 5. To reduce and minimize erosion and siltation problems the applicant has committed to detailed mitigative action specified in the ER: "Transmission Construction Specifications:

Development of Erosion Control Plan for Line Construction" (ER-CP, Amendment No. 5, Appen-dix 1, Exhibit A) and "Vegetation Management" (ER-CP, Amendment No. 5, Appendix 1, Exhibits B and C).

Measures and Controls to Limit Adverse Effects Durin and From Construction The applicant has submitted detailed erosion control plans (ER-CP, Amendment No. 5, Exhibit 8) for staff review. It is the staff's conclusion that all actions outlined by the applicant will result in acceptable soil erosion control. The staff concurs with the applicant's plans to notify in advance the Soil Conservation Service (SCS) at the Conservation District of the county in which line construction activities will involve any earth-moving work. It is the staff's opinion that such contact with SCS will further reduce the possibility of serious erosion problems.

The applicant has selected two clearing methods, "selective" or "tailored" (ER-CP, Amendment No. 5, Appendix 1, Exhibit B), which the staff concludes will minimize construction impacts associated with more severe methods of clearing as well as reduce visual impacts. The applicant has provided a plan for corridor redress (ER-CP, Amendment No. 5, Appendix 1, Exhibits B and C). The staff has reviewed these plans and finds that they are acceptable as proposed; there-fore, the staff does not recommend additional steps for redress.

The applicant states that no known archeological sites are crossed by either line and indicates that if any objects of possible archeological importance are unearthed, the Pennsylvania State Archeologist will be notified for an evaluation of the site.

Neither of the lines crosses or passes in the near vicinity of any registered historic site (ER-CP, Amendment No. 5, 3.9-13).

Effects of Transmission Line 0 eration on Land Use and on the Environment The assessment of those impacts of station operation discussed in the FES-CP are still valid.

Additional or new information is presented in this sections

l. Environmental Im a'ct Transmission line inspection and maintenance will not impact the involved ecosystems, especially since periodic inspections will be conducted by aircraft or on foot.

Use of hand clearing and selective sprayirg of herbicides are planned for routine mainte-nance. Chemical control of vegetation will conform to state and federal regulations and will be applied as directed by these authorities.

All chemicals, when used, will be applied by hand. The applicant has specified numerous precautions so that the possibility of chemical herbicides entering into water bodies will be remote. Herbicides will not be applied aerially (ER-CP, Amendment No. 5).

Ozone and other gaseous pollutants, such as nitrogen oxides, are formei as a result of ionization of air molecules that surround the cylindrical conductors use'd for transmitting electrical energy at high voltages. This ionization is caused by electrical discharge that is termed "corona." The, degree of ionization depends on voltage, humidity, conductor diameter, surface roughness, and spacing between conductors. Calculations indicate that ozone production could be 45 times higher in foul than fair weather. Measurements at 765-kV lines show, however, that at ground level beneath the conductors the ozone concentration does not rise above ambient; furthermore, ground level concentration of ozone is the same on foul days as fair days, presumably because factors favoring increased production rates also favor increased destruction rates. ~ o Recently, experiments were run over a one-year period in Jefferson County, Indiana, on 765-kV lines running over open, flat corn-fields. When instruments were placed six meters downwind from the 765-kV conductors at conductor height, where corona-produced ozone concentration should be greatest, "no ozone attributable to the transmission lines was detectable during the test."'o The natural increase in ozone concentration of 2 to 3 ppb for an increase of 30 m in elevation was observed.

The sensitivity of measuring instruments is about +2 ppb; hence, increases in ozone concen-tration above ambient due to corona from 765-kV lines are within the sensitivities of measuring instruments.'~

C-7 The national, primary air-quality standard for photochemical oxidants prescribes a level of 80 ppb as a maximum one-hour arithmetic mean not to be exceeded more than once per year. Susceptible plant species show damage symptoms from ozone exposure at concentrations as low as 30 ppb,'z~~~ but over prolonged periods ozone is not considered injurious to vegetation, animals, or human beings unless concentrations exceed 50 ppb.~4 On the basis of these considerations, the staff concludes that ozone from SSES's 500-kV lines will be environmentally inconsequential. p There is a possibility that electrical fields set up around transmission lines could affect persons in the .field. Studies have been performed to determine the effects of electrostatic fields on humans. s ~e These studies did not incorporate controls and are limited in both scope and time. For example, cases are known of adults who were unaffected by doses of agents that are teratological or lethal to the fetus or child, and lag times between dose and effect of 20 years or more are known. Since the above studies do not consider children, since children may play beneath the transmission lines, and since controlled studies of long duration have not been carried out, the long-term effect of high voltage transmission lines is currently unknown. However, the staff is not aware of any reported observable effects on humans resulting from exposure to electric fields radiated from high voltage power, lines. The physiological effects reported by the Russians>s were observed on maintenance workers in EHV substations, not on individuals below transmission lines. A recent Russian paper~s stressed that present standards apply only to maintenance personnel working on electrical installations. Russian standards permitting higher voltage gradients for local populations and agricultural workers are currently being considered since these populations will be exposed only infrequently.

The applicant will install a phasing arrangement and increase structure height, if neces-sary, at highway crossings to limit the electrostatic field strength at ground level to 7.5 kV/m. Where the applicant predicted the worst potential gradients (11 kV/m on a single circuit and double circuit 500-kV corridor), a phasing arrangement that will result in a worst-case gradient no greater than 7.83 kV/m at 11 '8 m ground clearance will be used. Significantly lower field gradients will exist at highway crossings where a 16.5-m clearance will be maintained (ER-CP, Amendment No. 5, Section 5.5.1.5 and Applicant's Response to Staff guestions of October 15 and November 18, 1976). Field gradient levels at the edge of rights-of-way will be on the order of 2.4 kV/m or less.

If these gradients occur, using the more consei vative Russian study ~ intended for mainte-nance personnel, a person could spend three hours daily working beneath the lines without adverse effects. The general public is not expected to spend significant amounts of time in the transmission line~right-of-way corridors.

Staff's literature survey indicates that adverse health effects on switchyard workers have been observed, but no such observations were reported from studies on transmission line workers and on individuals outside the switchyard environment exposed to voltage gradients well above 7.5 kV/m.

The staff has analyzed data on the effects of high voltage electric lines on plants and animals and has found no evidence to date indicating hazardous effects to plants or animals from present levels of fields generated from existing transmission line technology.zo In the absence of such observations, the staff believes that there should be no changes in the applicant's proposed design. A number of carefully designed studies of the biological effects of electric fields are currently underway and 'additional studies are planned.

These research projects are being sponsored by Federal agencies, including NRC, to study the effects of transmission line voltage gradients along with long-term effects on the general popu'iation. The staff will keep abreast of these studies and of any guidelines resulting from them and will consider the impacts of the transmission line operation prior to or at the time of the Operating License stage review, taking into consideration any new information (Sec. 4.4.1.2).

Induced currents are unlikely to ignite fuel vapors. but currents capable of shocking people could be induced in vehicles without grounding straps. Any stationary structure with metal parts in and along the right-of-way will be limited to a maximum electrostatic short circuit current of 5 millfamperes (rms);"any object not meeting this criterion will be grounded by the applicant, especia'Ily such objects as metal fences or rail lines that run parallel to the right-of-way. In such objects that are ungrounded, shock causing involuntary muscle reaction may,occur, but no permanent physiological harm is likely.>>

The staff believes grounding measures wil'1 reduce the likelihood of shock to a level that is of no concern.

A transmission line design guideline pertaining to induced currents which the applicant plans to follow, and which the staff considers prudent, fs that ground clearances should

C-8 be maintained so that a maximum induced current of 5 milliamperes (rms) is not exceeded under conditions of maximum line sag when the largest anticipated truck, vehicle, or equipment under the line is short-circuited to ground (ER-CP, Amendment No. 5, Secs.

3.9.5.5 and 5.5.1.5).

The applicant estimates that foul-weather noise (maximum) produced at the edge of the right-of-way of a 500-kV line will be 59 dB(A) (ER-CP, Amendment No. 5, Sec. 5.5.1.2).

However, these worst case conditions will not occur frequently and noise levels will diminish as soon as the conductors begin to dry. The applicant states, and the staff concurs, that the area traversed is very sparsely populated and, therefore, impact due to noise will be minimal.

The applicant addressed the potential impacts of transmission operation on radio and TV reception interference and indicates that investigation and correction of reception problems due to radio interferences will be done on an individual basis as each problem will be unique. Corona-produced television interference is not foreseen for those areas where good television reception is presently obtained during fair weather-. There may be some foul-weather phenomena, but the applicant indicates that the low precipitation type television influence has been found to be less than two percent of foul-weather radio influence at a point 61 m from the outermost conductor; therefore, lines are not expected to cause any significant television disturbances (ER-CP, Amendment No. 5, Sec. 3.9.5.4).

Sunbury-Susquehanna will parallel'n existing 230-kV transmission line for 67.9 km or 96K of its length. In addition, it is proposed that 2.7 km of the line (or the remaining 4X) will parallel the proposed Susquehanna-Siegfried 500-kV line. The staff believes that the paralleling nature of this route, as outlined by Federal guidelines, z a will assure that

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all visual impacts will be on an acceptable level. In addition, it is the staff's opinion that the applicant's right-of-way clearing and maintenance practices will further aid in reducing any potential visual impact associated with both the Sunbury-Susquehanna line and Siegfried-Susquehanna line (ER-CP, Amendment No. 5, Appendix I, Exhibits 8 and C).

The Siegfried-Susquehanna line will cross several esthetically sensitive areas; zamely, the Lehigh River Gorge crossing being considered for use as a state park and Beltzville Reservoir and State Park.

In both cases, the applicant is designing the line to minimize visual impacts. At the Lehigh River crossing, the tower structures will be set back from the gorge, being screened from the canoe run and hiking trail at the bottom of the gorge by the natural terrain.

The applicant has received approval from the Pennsylvania Oepartment of Environmental Resources for this crossing (Applicant's Response to Staff I)uestions, November 18, 1976).

The applicant conducted a feasibility study regarding crossing of Beltzville Reservoir by using new double circuit tubular steel poles instead of existing 66-kU tower structure in front of scenic view. The study concluded, and the U.S. Corps of Engineers agreed, that such a combined crossing presents serious reliability problems. The staff believes that the parallel crossing will not create additional adverse visual impacts to the area.

Based upon the implementation of the applicant's proposed mitigative measures, such as tailored clearing or feather cutting at improved road crossings, parks, peaks and ridges, and stream and river crossings (ER-CP, Amendment No. 5, Sec. 5.5.4.2.b and Appendix 1, Exhibit B), combined with the remote location of large portions of this route, making it unlikely that many people would be affected by it, the staff does not expect unacceptable esthetic impact along the Susquehanna-Siegfried proposed corridor.

Alternatives to the Pro osed Routes The applicant has considered a variety of alternative routes, analyzing both predicted minimum impact routes and minimum cost routes. Three routes were fully examined and compared for each

1. Sunbur -Sus uehanna Line Alternatives Two alternatives to the proposed Sunbury-Susquehanna route (Alternative Rout e A) are co nsi d ered (Figure C.2). Alternative Route 8 leaves the Sunbury Substation in a no th 1 d'Irection and crosses the west branch of the Susquehanna about 3.2 km above the confluence of the Susquehanna. It then proceeds eastward, paralleling the north branch of the Susquehanna, until it passes north of Berwick where it heads southeast to SSES. Alter-native Route C parallels the applicant's preferred corridor out of Sunbury for approxim ox ma t e 1 y 20 km and then leads north, where it jointly crosses the north branch of the Susquehanna

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just east of Reeds Island (southeast of Danville) with an existing line. It proceeds in a basically nor therly direction until it meets with Alternative Route B and then follows the Alternative B corridor into the plant.

It appears to the staff that the applicant has endeavored to utilize existing corridors wherever practical in selection of preferred and alternative routes for the Sunbury-Susquehanna corridor. The preferred route (Alternative A) parallels an existing line (a 230-kV Sunbury-Susquehanna line) for more than 67 km and the remaining 2.7 km will parallel the proposed Susquehanna-Siegfried 500-kV line. Interpretation of the available data indicates that all three alternatives recoamended by the applicant are acceptable and that the applicant's preferred route would be the most environmentally acceptable in terms of fine tuning of environmental impact reduction due to extensive "parallelin9."

2. Sus uehanna-Sie fried Route Alternative figure C.3 shows the three routes examined for termination at the Siegfried Substation.

Alternative B proceeds in a southeasterly direction from the plant, paralleling an existing 230-kV line for almost its entire length until it joins Alternative routes A, the preferred route, and C just north of the Siegfried Substation. Alternative Route C is similar to the preferred corridor except that it departs from the preferred corridor approximately 1.6 km northwest of the intersect'ion of Interstates 80 and 81 and proceeds easterly until it rejoins Alternative A southwest of White Haven. According to the applicant, this route was originally investigated and selected as the prime connection to the Siegfried Sub-station, but a potential generating plant north of White Haven resulted in modification of Alternative C to form Alternative A. It is the staff's evaluation that there are few major differences between alternative routes A and C. The applicant's analysis (Table 10.9-Az) indicates only marginal differences between alternatives A and C. The major difference is that Route C will approach more residential units than Route A. The appli-cant indicates that, from an environmental standpoint, Route B is more desirable. The staff's own analysis also concludes that the paralleling nature of Route 8 would cause a reduction in 68.3 ha of primary forest land needed for additional right-of-way. However, it appears to the staff that none of the corridors pass through any areas requiring unique siting constraints and that the additional acreage required for Alternative A will be an insignificant impact to the large inventory of forested lands in the region. The staff has assessed the applicant's proposed mitigative measures to insure minimal environmental impact and has concluded that these will reduce construction and operating impacts to an acceptable level.

The applicant has provided the staff with more detailed estimates of the length and land area requirements for the above alternatives (Table C.3). Alternative B requires less land area 68.3 ha than the applicant's preferred route (A). Land area requirements for alternatives A and C are judged by the staff to be of similar magnitude. However, Alter-native C does approach approximately twice the number of residences (607) as alternatives A (359} and B (342}. The staff concludes that based on this residential impact, Alter-native C is not preferable to alternatives A or B. Therefore, the staff's environmental analysis of impacts associated with construction of the preferred route (A) and two alter-native routes (B and C) indicates that 1) the applicant's preferred route is environ-mentally acceptable and 2} that selection of Alternative B would cause a slight reduction in terrestrial impacts primarily due to lower right-of-way land requirements.

Table C.3. Right-of-way Data for Alternative Analysis Alternative Length (km) 86.6 81.6 82.4 Area for total right-of-way (ha) 500.4 432.1 474.4 Source: Applicant's Response to Staff guestions, November 18, 1976 (Reference No. 24).

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The applicant has supplied data for the economic costs of the three alternatives.z4 Route A is estimated to cost $ 28,586.522; Route 8 is estimated to cost $ 29,273,095, and Route C is estimated to cost $ 28,346,991. Interpretation of the available data indicates that all three alternative routes for, the Susquehanna-Siegfried line recomnended by the applicant are acceptable. AlternaOve A provides an economic advantage over Alternative B, even though Alternative B would require 68.3 ha less land area to construct. The estimated construction cost'for Alternative C is slightly lower than that for Alternative A; Alterna-tive C would approach more residential units and does not appear to offer unique advantages over Alternative A. In conclusion, although Alternative A does not represent the minimum environmental pat),in the Susquehanna-Siegfried line, from an overall point of view it" does offer the best compromise>bf economic and environmental. considerations. Therefore, the applicant's selection of Route A is reasonable.

II Unavoidable Adverse Environmental Im acts

1. Land Except for small land areas used for tower bases, land will be available for multiple use within the transmission line right-of-way.

2. Water No impacts on water are expected since extensive mitigative measures will be in effect at all water-body cro'ssings ~

3. Air

", Construction activities may cause some dust and emissions of particulates. However, with the applicant's mitigative measures, little air quality deterioration will occur. Little ozone should be produced during operation of the lines.

4. Noise No unacceptable noise levels are expected during construction and operation of SSES trans-mission lines.

C.4. CONCLUSIONS On the basis of the foregoing analysis, the staff has determined that modifications proposed in Amendment No. 4 and 5 combined involve greater environmental impact primarily with respect to the increase in total line lengths from 116 km to 206 km. On a region-wide basis, however, the net environmental impact could be considered lessened, since the additional 90 km of lines are necessitated by the cancellation of a proposed 121-km long line, The proposed transmission routes would pass through areas similar to the Susquehanna-Frackville lines; therefore, the environmental impact evaluation conducted in connection with the initial application still characterizes the nature -of the impacts, and the extent of impacts associated with the proposed change has been analyzed in this assessment. The staff concludes that impacts associated with=the newly proposed transmission routes are acceptable and not substantial.

O Further, impacts of the proposed change in transmission lines discussed above are sufficiently small so that, when they are superimposed upon the other environmental impacts assessed with respect to construction of the plant, the changes in the overall .environmental impact from construction of the plant are not significant, After considering the impacts attributable to the proposed changes, the staff concludes the overall cost-benefit balance previously developed in the FES-CP remain unaltered.

l. "Susquehanna Steam Electric Station: Applicant's Environmental Report," Amendment No. 4, Revised July 1972, Pennsylvania Power & Light, Company, February 1976.

2. "Susquehanna Steam Electric Station: Applicant's Environmental Report, Amendment No. 5, Revised July 1972, July 1976.

3.. Letter dated 8 March 1976, from W. H. Regan, Environmental Projects Branch No. 3, Nuclear Regulatory Commission, to M. W. Cur tis; Pennsylvania Power and Light Company.

I 4, Comnonwealth of Pennsylvania, Department of Environmental Resources, "Pennsylvania State Forest Natural Areas and Wild Areas," August 16, 1976.

5. U.S. Department of the Interior, Federal Register, Vol. 40(188):44418-44423, September 26, 1975.

6. U.S. Department of the Interior, Federal Register, July 12, 1976.

7. U.S. Department of the Interior, Federal Register, Vol. 41(187):41914-41916, September 24, 1976,

8. U.S. Department of the Interior, Federal Register, Vol. 40(127):27824-27924, July 1, 1975. k 9," S. A. Sebo, J, T. Heibel, M. Frydman, and C. H. Shih; "Examination of Ozone Emanating from EHV Lines Corona Discharges"; IEEE Trans. PES 95(2):693-703; March/April 1976.

10. M. Frydman, et al., "Oxidant Measurements in the Vicinity of Energized 765-kV Lines,"

IEEE Transactions on Power Apparatus and Systems, Vol. PAS-92(3):1141-1148, 1973.

W. Davis, Jr., "Ozone Formation by High-Voltage Transmission Line Coronas," Oak Ridge National Laboratory, Central Files Report No. 72-7-25, 19 July 1972.

12. A. C. Costonis and W. A. Sinclair, "Relationships of Atmospheric Ozone to Needle Blight of Eastern White Pine," Phytopathology 59:1566-1574, 1969.

13. P. R. Miller, J. R. Parameter, Jr., B. H. Flich, and C. W. Martinex, "Ozone Dosage Response of Ponderosa Pine Seedlings," University of California, Berkeley Press, 1969.

14. "Coranunity Air guality Guides, Ozone," J. Am. Ind. Hyg. Assoc., 29:299-303, 1968.

15. W. B. Kouwenhoven, et al., "Medical Evaluation of Man Working in AC Electric Fields," IEEE Transactions on Power Apparatus and Systems, Vol. PAS-86, No. 4, April 1967.

16. V. P. Korobkova, et al., "Influence of the Electric Field in 500- and 750-kV Switchyards on Maintenance Staff and Means for Its Protection," Paper 23-06, International Conference on Large High Tension Electric Systems, 25 August - 6 September 1972.

17. M, L. Singewald, et al., "Medical Follow-up Study of High Voltage Linemen Working in AC Fields," IEEE Power Engineering Society Transactions, New York Meeting, 28 January 1973

18. Joint American-Soviet Comnittee on Cooperation in the Field of Energy. "Discussion of Papers Presented at the Symposium on EHV AC Power Transmission," U.S. Department of the Interior, Bonneville Power Administration, Washington, DC, February 1975.

19. Y. I. Lyskov, Y. S. Emma, and M. D. Stolyarov; "Electr ical Field as a Parameter Considered in Designing Electric Power Transmission of 750-1150 kV; the Measuring Methods, the Design Practices and Direction of Further Research"; US-USSR Symposium on EHV AC Power Transmission; Bonneville Power Administration; Washington, DC; February 1975.

20. J. W. Bankoski, A. B. Graves, and G. W. Meku; "The Effects of High Voltage Electric Lines on the Growth -and Development of Plants and Animals!', Proceedings of the First National Symposium on Environmental Concerns in Right-of-Way Management; Mississippi State University; 1976.

21. L. 0. Barthold, et al., "Electrostatic Effects of Overhead Transmission Lines," IEEE Working Group on Electrostatic Effect of Transmission Lines, Paper No. TP 644-PWR, August 1971.

22. Federal Power Coranission, "Electric Power Transmission and the Environment," 1970.

23. United States Oepartment of the Interior and United States Oepartment of Agriculture, "Environmental Criteria for Electric Transmission Systems," 1970.

24. "Susquehanna Steam-Electric'tation: "

Applicant's Environmental Report, Amendment No. 5,"

guestion and Responses,, November 18, 1976.

APPENDIX D. NEPA POPULATION DOSE ASSESSMENT Employing the same models used for individual doses, population dose commitments are for all individuals living within 80 km of the facility (see Regulatory Guide 1.109, Rev.

In addition, population doses associated with the export of food crops produced within the Bb.

region and the atmospheric and hydrospheric transport of the more mobile effluent species such as noble gases, tritium, and carbon-14 have been considered.

NOBLE GAS EFFLUENTS For locations within 80 km of the reactor facility, exposures to these effluents are calculated using the atmosphere dispersion models in Regulatory Guide 1.111, Rev. l., and the dose models described in Section 4.5 and Regulatory Guide 1.109, Rev. 1. Beyond 80 km, and until the efflu-ent reaches the northeastern corner of the United States, it is assumed that all the noble gases are dispersed uniformly in the lowest 1000 m of the atmosphere. Decay in transit was also considered. Beyond this point, noble gases having a half-life greater than one year (e.g.,

Kr-85) were assumed to completely mix in the troposphere of the world with no removal mechanisms operating.

Transfer of tropospheric air between the northern and southern hemispheres, although inhibited by wind patterns in the equatorial region, is considered to yield a hemisphere average tropo-spheric residence time of about two years with respect to hemispheric mixing. Since this time constant is quite short with respect to the expected midpoint of plant life (15 yr), mixing in both hemispheres can be assumed for evaluations over the life of the nuclear facility. This additional population dose coranitment to the U.S. population was also evaluated.

IODINES AND PARTICULATES RELEASED TO THE ATMOSPHERE Effluent nuclides in this category deposit onto the ground as the effluent moves downwind; this continuously reduces the concentration remaining in the plume. Within 80 km of the facility, the deposition model in Regulatory Guide 1.111, Rev. 1, was used in conjunction with the dose models in Regulatory Guide 1.109, Rev. 1. Site-specific data concerning production, transport, and consumption of foods within 80 km of the reactor were used. Beyond 80 km, the deposition model was extended until no effluent remained in the plume. Excess food not consumed within the 80-km distance was accounted for, and additional food production and consumption representative of the eastern half of the country was assumed. Doses obtained in this manner were then assumed to be received by the number of individuals living within the direction sector and distance described. The population density in this sector is taken to be representative of the eastern United States, i.e., about 62 people per square km.

CARBON-14 AND TRITIUM RELEASED TO THE ATMOSPHERE Carbon-14 and tritium were assumed to disperse without deposition in the same manner as krypton-85 over land. However, these nuclides do interact with the oceans. This causes the carbon-14 to be removed with an atmospheric residence time from four to six years, with the oceans being the major sink. From this, the equilibrium ratio of the carbon-14 to natural carbon in the atmosphere was determined. The same ratio was then assumed to exist in humans so that the dose received by the entire population of the United States could be estimated. Tritium was assumed to mix uniformly in the world's hydrosphere, which was assumed to include all the water in the atmosphere and in the upper 70 m of the oceans. With this model, the equilibrium ratio of tritium to hydrogen in the environment can be calculated. The same ratio was assumed to exist in humans and was used to calculate the population dose in the same manner as carbon-14.

Concentrations of effluents in the receiving water within 80 km of the facility were calculated in the same manner as described for the Appendix I calculations. No depletion of the nuclides D-1

D-2 present in the receiving water by deposipion on the bottom of the Susquehanna River was assumed.

The assumption that aquatic biota co>centrate radioactivity in the same manner as was assumed for the Appendix I evaluation w~6 also made. However, food consumption values appropriate for the average individual, r>ther'han the maximum, were used. It was assumed that all the sport and coranercial fish and.shellfish caught within the 80-km area were eaten by the U.S. population.

Beyond 80 km~1 was assumed that all liquid effluent nuclides ~ with the exception of tr itium, have d ~ted on the sediments so they make no further contribution to population exposures.

T ~ritium was assumed to mix uniformly in the world's hydrosphere and to result in an exposure the U.S. population in the same manner as discussed for tritium in gaseous effluents.

APPENDIX E. EXPLANATION AND REFERENCES FOR BENEFIT-COST SUHHARY Economic Im act of Plant 0 eration Direct Benefits - The staff has evaluated the total direct benefit of the Susquehanna Nuclear Station production of baseload energy by calculating entire -"

output of the facility at 60K capacity factor. Applicant owns 90%

of the facility. Refer to Section 7.

Indirect Benefits - A small portion of the state tax is provided to the impacted local, counties ($ 65,000). Refer to Sections 4.6.6.1 and 4.6.6.2.

Economic Costs - Operating costs: Supplied by applicant.

Decommissioning costs: The staff has estimated decoranissioning costs in 1975 dollars at $ 59 million.

1. Deactivating the reactors

2. Decontaminating of process systems and areas of plant

3. Removing all nuclear fuel from the site for recovery of fuel materials and ultimate disposal of radioactive wastes

4. Sealing of building or portion of building containing activated process piping and components by means of blocking, bolting, or welding plates over openings, etc.

5. Dismantling and sealing of all gaseous and liquid waste systems and effluent lines

6. Haintaining some security and fire systems

7. Ultimate dismantling of station Environmental Im act of Plant*

Item 1 - Impact on water Item 1.1 - Consumption (nuclear station consumption): The amount of water consumed by the applicant for operation is estimated to average 1.4 ms/s. This amounts to 26,000,000 m~/yr at a 60K capacity factor.

,, Item 1,2 - Heat discharge to natural water body 1.2.1 - Cooling capacity of water body: J/hr rejected heat 3.4 x 10 (max) 1.2.2 - Aquatic biota: insignificant.

1 2.3 - Higratory fish:

~ insignificant.

Item 1.3 - Chemical discharge to natural water body (Includes Items 1.3.1, 1.3.2, 1.3.3, and 1.3.4): chemicals will be discharged to the Susquehanna River. The 1,400,000 kg/yr chemical discharge is an annual average, mainly sulfate.

Item 1.4 - Radionuclide contamination of natural water body: See Sec. 4.5.

Item 1.5 - Chemical contamination of groundwater: see Item 1.3, above.

Item 1.6 - Radionuclide contamination of groundwater: See Sec. 4.5.

• The index numbers used in this and the next section correspond to those used in Table 9.1.

E-1

E-2 Item 1.7 - Raising/lowering of groundwater levels ( Includes is expected.

Items 1.7.1 and 1.7.2): no effect ~

Item 1.8 - Effects on natural water body of intake structure and condenser cooling systems:

unknown.

1.8.1 - Primary producers and consumers: chemical discharges are discernible (Sec. 4.3.3).

1.8.2 - Fisheries: additional studies are warranted relative to the effect of construction and operation of the intake structure upon fish productivity.

Item 1.9 - Natural water drainage 1.9.1 - Flood control: no damage to station or immediate vicinity.

1.9.2 - Erosion control: no significant erosion is expected.

Item 2 - Impact on air Item 2.1 - Chemical discharge to ambient air 2.1.1 - Air quality-chemical: no impact. Entries for CO, NOx, and HC are non-zero because of operation of diesel equipment several hours per month.

2 '.2 - Air quality--,odor. no impact.

Item 2.2 - Radionuclides discharged to ambient air 2.2.1 - Noble gases: See Sec. 4.5.

Item 2.3 - Fogging and icing: offsite icing may occur when the spray pond is operating (Sec. 4.4.1).

Item 2.4 - Salt discharge from cooling system 2.4.1 - People: see FES-CP, p. 3-41.

2.4 ' - Plants and soil: See ER-OL, p. 5.3-5.

Item 3 - Impacts on terrestrial systems Item 3.1 - Station area: acceptable. See ER-OL, Section 3.1-5.

Item 3.2 - Bird impingement on station facilities: should be monitored. See Sec. 5.3.6.

Item 4 - Transmission line corridors Item 4.1 - Right-of-way maintenance and inspection: See Sec. 4.5 and Appendix C.

Item 4.2 - Production of ozone, other gaseous pollutants: See Sec. 4.5 and Appendix C.

Item 4.3 - Audible noise: See Sec. 4.5 and Appendix C.

Item 4.4 - Radio and TV interference: See Sec. 4.5 and Appendix C.

Item 4.5 - Electrical field effects: See Sec. 4.5 and Appendix C.

Item 5 - Total body dose commitments to UPS. population general public, unrestricted area:

See Sec. 4.5 and Appendix C.

Societal Im act of Plant Item 1 - Operational fuel disposition Item 1.1 - Fuel Transport: Ten truck shipments of new fuel plus 13'rain shipments of radio-active spent fuel assemblies per year.

Item 1.2 - Fuel Storage: The staff assumes storage of new fuel to be provided for in plant design within the reactor building.

Item 1.3 - Waste Products: Onsite storage of spent fuel assemblies is normal and is assumed for SSES.

E-3 Item 3 - Historical arid archeological sites: (see Sec. A.2.7).

Item 4 - Station operational noise: exceeds EPA standard but is to be- monitored by applicant.

Refer to Section 5.3.5.

Item 5 - Social costs: include social stresses, demand on public services, and housing.

Item 6 - Esthetics: acceptable. Refer to Section 4.4.1.1.

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APPENDIX F. APPLICATION FOR NATIONAL POLLUTANT DISCHARGE ELIMINATION SYSTEM (NPDES) PERMIT TO DISCHARGE TO STATE WATERS NPDES Application No. PA-0047325

F-2 DEPARTMENT OF ENVIRONMENTAL RESOURCES Bureau of Water Quality Management Wilj:es Barze Regional Office 90 East Union Street - 2nd Ploor Wilkes Bazre, Pa. 18701 July 31, 1979 Zndustzial Waste NPDES Permit No. PA-0047325 Pennsylvania Power s Light Company Susquehanna Steam Electric Salem Township RECEIVED Luserne County AI3G' 1979 Pivla IiIcalzg,g Pennsylvania Power S Light Company Susquehanna Steam Electric c/oNr. John T. Kauffman Executive Vice President, Operations Two North Ninth Street Allentown, Pa. 18101 Gentlemen'he subject permit is enclosed.

Please study the perad.t carefully and direct any questions to this office. Our telephone number is (717) 826-2553.

V truly yo, g wrence A. Pawlush Regional Water Quality ttanager LAP:JPLihp Enclosures - NPDES Permit NPDES Discharge Honitoring Repozt DMt Znstructions

,cc: Pile Program Services Richard L. Constrisciano Environmental Engineer Water Enforcement Branch Pennsylvania Section 3EN22 U.S. Environmental Protection Agency Si"th S Walnut Streets Philadelphia, Pa. 19106.,