{{#Wiki_filter:CATEGORY 1 REOUDRTOINEORMA'/ION,DISTRIBUTION TEM (RIDE)ACCESSION NBR:9704240079 DOC.DATE: 96/12/31 NOTARIZED:

NO FACIL:50-',315 Donald C.Cook Nuclear P6wer Plant, Unit 1, Indiana M 50-316 Donald C.Cook Nuclear Power Plant, Unit 2, Indiana M AUTH.NAME AUTHOR AFFILIATION FITZPATRICK,E.

Indiana Michigan Power Co., RECIP.NAME RECIPIENT AFFILIATION DOCKET 05000315 05000316 I  

"Annual Environ Operating Rept for 960101-961231." W/970418 ltr.DISTRIBUTION CODE: C001D COPIES RECEIVED:LTR ENCL SIZE: TITLE: Licensing Submittal:

Environmental Rept Amdt 6 Related Correspondence NOTES: E RECIPIENT ID CODE/NAME HICKMAN,J INTERNAL: IL~5575 0 1 OGC HDS2 EXTERNAL: NOAC COPIES LTTR ENCL 1 1 1 1 1 0 1 1 RECIPIENT ID CODE/NAME NUDOCS-ABSTRACT RGN3 DRS/RSB NRC PDR COPIES LTTR ENCL 1 1 1 1 1 1 0 D N NOTE TO ALL MRIDSN RECIPIENTS:

PLEASE HELP US TO REDUCE WASTE.TO HAVE YOUR NAME OR ORGANIZATION REMOVED FROM DISTRIBUTION LISTS OR REDUCE THE NUMBER OF COPIES RECEIVED BY YOU OR YOUR ORGANIZATION, CONTACT THE DOCUMENT CONTROL DESK (DCD)ON EXTENSION 415-2083 TOTAL NUMBER OF COPIES REQUIRED: LTTR 7 ENCL 6 1 ll"I I 4 Indiana Michigan Power Company 500 Circle Drive Buchanan, MI 49107 1395 lNQMMAl MlCNEGAM PSST April 18, 1997 AEP: NRC: 0806Q Docket Nos.: 50-315 50-316 U.S.Nuclear Regulatory Commission ATTN: Document Control Desk Washington, D.C.20555 Gentlemen:

Donald C.Cook Nuclear Plant Units 1 and 2 ANNUAL ENVIRONMENTAL OPERATING REPORT JANUARY 1, 1996 TO DECEMBER 31, 1996 Attached is the Donald C.Cook Nuclear Plant Annual Environmental Operating Report for the year 1996.This report was prepared in accordance with procedure 12 PMP 6010 OSD.001,"Offsite Dose Calculation Manual," section 4.8.1, and Technical Specification, Appendix B, Part 2, section 5.4.1.Sincerely, E.E.Fit trick Vice President vlb Attachment cc: A.A.Blind A.B.Beach MDEQ-DW 8(RPD NRC Resident Inspector J.R.Padgett<goi i C~9'704240079 9'6iR3i PDR ADOCK 050003i5 PDR IIIIIII IIIIIIII IIIIIIIIIIII IIIIIC II t 4, 1 j', f ATTACHMENT TO AEP:NRC:0806Q ANNUAL ENVIRONMENTAL OPERATING REPORT JANUARY 1, 1996 TO DECEMBER 31, 1996 9704240079 6

TABLE OF CONTENTS Pacae I.Introduction II.Changes to the Environmental Technical Specifications

..III.Non-Radiological'nvironmental Operating Report A.B.C.D.E.F.G.Plant Design and Operation Non-Routine Reports Environmental Protection Plan.Potentially Significant Unreviewed Environmental Issue.Environmental Monitoring-Herbicide Applications Mollusc Biofouling Monitoring

.Special Reports 1 1 1 1 2 IV.Radiological Environmental Operating Report A.Changes to the REMP B.Radiological Impact of Donald C.Cook Nuclear Plant Operations C.Land Use Census.D.Solid, Liquid, and Gaseous Radioactive Waste Treatment Systems Conclusion 3 3 3 LIST OF APPENDICES e~eedix Title I.Non-Routine Reports-1996 II.Environmental Screening Reports-1996 III.Herbicide Application Report-19'96 IV.Mollusc Biofouling Monitoring

-1996 V.Special Reports VI.Annual Report: Radiological Environmental Monitoring Program-1996 A.Radiological Environmental Monitoring Program Summary-1996 B.Data Tables C.Analytical Procedures Synopsis D.Summary of EPA Interlaboratory Comparisons E.REMP Sampling and Analytical Exceptions F.Land Use Census G.Summary of the Preoperational Radiological Monitoring Program H.Summary of the Spike and Blank Sample Program I.TLD Quality Control Program I.INTRODUCTION Procedure 12 PMP 6010 OSD.001,"Offsite Dose Calculation Manual," Section 4.8.1 and Technical Specification, Appendix B, Part 2, Section 5.4.1 require that an annual report, which details the results and findings of ongoing environmental radiological and non-radiological surveillance programs, be submitted to the Nuclear Regulatory Commission.

This report services to fulfill these requirements and represents the Annual Environmental operating Report for Units 1 and 2 of the Donald C.Cook Nuclear Plant for the operating period from January 1 through December 31, 1996.During 1996, based on the monthly operating repcrts for Unit 1 and Unit 2, the annual gross electrical generation, average unit service factors, and capacity factors were:~parameter Gross Electrical, Generation (MWH)Unit Service Factor (4)Unit Capacity Factor-MDC*Net (%)*Maximum Dependable Capacity 8,687,540 97.6 95.3 Unit 2 8,298,030 87.0 86.2 II.HANGES TO THE ENVIRONMENTAL TE HNICAL PECIFICATIONS There were no environmental Technical Specification changes in 1996.III.NON-RADIOLOGICAL ENVIR NMENTAL PERATING REPORTA.Plant Design and Operation During 1996, no instances of noncompliance with the Environmental Protection Plan occurred, nor were there any changes in station design, operations, tests, or exp riments which involved a potentially significant unreviewed environmental issue.There was one environmental screening during the reporting period.A copy of this screening is located in Appendix II of this report.It was concluded that no environmental evaluations were required and that n~unreviewed environmental questions existed.B.Non-Routine Reports A summary of the 1996 non-routine events is located in Appendix I of this report.No long-term, adverse environmental effects were noted.Environmental Protection Plan There were no instances of Environmental Protection Plan noncompliance in 1996.D.Potentially Significant Unreviewed Environmental Issues There were no changes in station design, operations, tests or experiments which involved a potentially significant unreviewed environmental issue.There was one environmental screening during the reporting period.A copy of this screening is located in Appendix II of this report.The screening determined that there were no unreviewed environmental 0

ques" ions E.Environmental Monitoring

-Herbicide Application Technical Specifications Appendix B, Part 2, section 5.4.1, states that the Annual Environmental Operating Report;hall include: summaries and analyses'f the results of the environmental protection activities required by section 4.2 of this Environmental Protection Plan for the report period, including a comparison with preoperational studies, operational controls (as appropriate), and previous non-radiological environmental monitoring reports, and an assessment of the observed impacts of the plant operation on the environment.

Herbicide applications are the activities monitored in accordance with section 4.2.There were no preoperational herbicide studies to which comparisons could be made.Herbicide applications are managed by plant procedure 12 THP 2160 HER.001.A summary of the 1996 herbicide applications is contained in Appendix III of this report.Based on observations, there were,no negative impacts or evidence of trends toward irreversible change to the environment as a result of the herbicide applications.

Based on our review of application records and field observations, the applications conformed with EPA and State requirements for the approved use of herbicides.

F.Mollusc Biofouling Monitoring Program Macrofouler monitoring and control activities during 1996 are discussed in Appendix IV of this report.Whole water sampling studies showed no adverse environmental impact.G.Special Reports There were no special reports identified during 1996.IV.RADIOLOGICAL ENVIRONMENTAL OPERATING REPORT The Radiological Environmental Monitoring Program annual report is located in Appendix VI of this report.The objectives of the operational radiological environmental monitoring program are: Identify and measure radiation and radioactivity in the plant environs for the calculation of potential dose to the population.

Verify the effectiveness of in-plant measures used for controlling the release of radioactive material.Provide reasonable assurance that the predicted doses, based on radiological effluent data, have not been substantially underestimated and are consistent with applicable standards.

Comply with regulatory requirements and Station Technical Specifications.and provide records to document compliance.

'M g Fnvironmental Evaluation U-2 Uprate Per AEP: NRC: 1223 On Juno 28, 1995, the Cook Nu lear Plant received a new NPDES Permit which included permission to inc."ase Heat Addition Discharge Limitation to 16.8 x 10'TU/hr with the following"As a condition of this permit, the permittee shall conduct a thermal plume study for outfal!s 001 and 002.The study shall bo conducted seasonally, during spring, summer and fall.Each seasonal study shalllndude a determination of the current velocity and volume which serves to dilute the discharge In Lake Michigan, a determination of the stratification of the effluent, if any in Lake Michigan, predominant wind direction and velocity at the time of the study, and detailed mapping of the plume for each study.Within three (3)months of the effective date of this permit, a plan for conducting the study shall be submitted to the Plainwell District Supervisor of the Surface Water Quality Division for approval.The study shall be implemented in accordance with the approved plan, which will include information regarding Initiation of the study.If the permittee desires to make any substantial changes ln tke approved plan, such proposed changes shall be submitted to and bo approved by the Plainwell District Supeiv',sor prior to implementation.

The result of this study'hall be submitted to the Plainwell District Supervisor vrithin four (4)months of the completion of the study." A plan for conducting the study was submitted on September 25, 1995 to the Michigan Department of Natural Resources (MDNR)(now known as the MichIgan Department of Environmental Quality or MDEQ)District Supervisor of tlie Surface Water Quality Division (SWQD)(Attachment A).Approval from the MDEQ SWQD was received on November 6, 1995 (Attachment 8).Schedules have been established to meet the other items of Special Condition 9.current NPDES Permit: "The Michigan Deoartment of Natural Resour es's cons!" dng the necessity of incorporatirg o incorpora ing Mi h'emperature limitations in this permit to assure that the requlroments of Rui 82 (1)f th ic igan Water Quality Standards are met.Thorefore, when consideration of this issue has been completed, the Department may modify this permit in.accordance with Part II.B.4 to add appropriate temperature limitations or requirements." view Action Ta The Final Environmental Statement (FES), National Pollution Discharge Elimination System (NPDES)Permit and Appendix S of Technical Specifications were reviewed In support of this screening to determine the potential environmental impact associated with this proposed uprate.in accordance with 661000-LTG-2200-1, Revision 0 Preparation and Distribution of Environmental Evaluations," an Environmental Check Skeet was completed.

The conclusions of this check skeet follow.  

Peg*3 Environmental Evaluation U-2 Uprato Per AEP: NRC;12231.Will the proposed activity result in a significant increase in any adverse environmental impact previously evaluated in the Final Environmental Statement (FES)7 No The proposed u'prate will result in an increase in temperature of the cooling w t th t'n er Lake Michigan as found in the summary of environmental Impact and adverse effects in the FES.The area of the thermal plume is also expected to increase from 593 to 700 acres, an increase of about 18'A.We believe that th" impact of this change will have a negligible effect on the environment end,does not represent a significant increaso in any adverse Impact discussed ln the FES.On the basis of the statement 7, in the summary and conclusions portion of the FES, all requirements set forth in the FES called forth by the National Environmental Policy Act (NEPA)such as License Conditions has been met and reviewed and approved by the Michigan Department lume stu Natural Resources and the United States Environmental Protection Agonc.A h p ume study as required per NPDES permit is scheduled once the uprate has occurred.Technical Speclficabons associated With the u prate will be Included in AEP: NRC: 1223.2.Is the ro o he proposed activity a matter not previously evaluated in the Final E ua e in e ina nvironmental No, The FES discusses thermal effluent-discharge and the Unit 2 uprate represents a change to the NPDES effluent limits as discussod In question 3 and 4, The proposed activity was not evaluated at ihe heat discharge levels that were evaluated in the original FES.However, tho FES did evaluate thermal effluent discharge.

Current modeling studies indicated that the calculated mixing zone vnli expand, yot this is not expected to be a significant deviation from the original study and does not indicate an adverse environmental impact previously evaluatod in the FES.This activity and associated effect have been proviously evaluated i>>tiio FES and are all potential adverse effects wore addressed via the NPDES Permit approval process.:,d J.Jude from the Center for Great Lakos and Aauatic Sciences for th U'iy Ic~, was contracted to perform an inves@ation of changes that might occur due to the heat Increase and how those changes might Impact the current Lako Mich'n fauna in the vicinity of the pl'ant (Attachment D).The review determined that the the int ri o requested heat input and increased iherma>pluine size will have e I'bl neg igi o impact on e integrity of the Lake Michigan ecosystem in this area of the lake.In add'tl h'a i on,t is po u e ying studies show tho size andincreased temperatures expected within the plume will have no discernible adverse environmental imp ct th'd mpa on e wi o array of is es, zooplankton, and benthic organlsrns that are common rare d d, , rare, en angered, or uncommon in the vicinity of the Cook Plant.The e he environmental impacts and adverse effects contained in the FES were reviewed an a I approprhte measures required under the National Environmental Policy Act end Appendix D to 10 CFR Part 50 wore addressed via the NP DES Permit approval process described and attached throughout this document i age4 i"=nrironrnentaf F valuation U-2 Uprato Por AEP: NRC: 1223 3.Will the proposed activity result In a significant change in constituent or quantity of effluent'No There is no significant change in constituent of effluent.The quantity of the effluen will only change in tho amount of heat being discharged.

amendment proposal to the USNRC.5.Will a previously undisturbed area be impacted by this activity?No The thermal"fume size is expected to Increase, although this increase ls not expected to impact previously undiisturbed areas in Lake Mlchlgan.The thermal plume study that vill bo performed as required in the NP DES permit vrilf document wheth er there will bo a sfgnificant environmental effect as a result of tho uorate.6.Will initiation or implementation of tlie proposed activity require modification to existing permits?No In accordance is%tho NPDES Permit No.MI0005827 for the Donald C.Cook Nuclear Plant PART II A2.Change of Conditions, a new application was submitted to the Chlof f tho Permit Section of tho Surface Water Quality Division to increase the he."'ejected to Lak~""".higan from 15.5 x 10'TU/hr to 16.8 x 10'TU/hr.Also submined to the Michigan Department of N"tural Resources per Part 4 of the general rules of tho h4'chigon Water Resource Commission (Water Quality Standards) was a Demonstration of Acceptability of Increase Heat Additfon proposed in accordance to, Rule 98 (Attachment C).~C~Ision Based on th'n this review of tho proposed uprate of Cook Nuclear Plant Unit 2 from 3411 MWt to 3588 MWt, lt ls concluded that an unreviowed environmental question does exist.As such, fnformalion concerning the change will be submitted to the Nuclear Regulatory Commission in accordance vrith procedure 661-LTG-220041

The purpose of this evaluation was to support the proposed Technical Specification Amendment submittal package.From a strictly environmental perspective, the proposed uprate is not consdored to have a significant adverse impact on the environment as discussed ln tho FES.Finally, the Michigan Department of Natural Resources has approved the proposed increase In the thermal effluent limit.Based on a review of the FES, Appendix B Technical Specifications, the current NP DES Permit for the Cook Nuclear Plant, and 10 CFR 51 requirements no environmental assessment (EA)or environmental impact statement (EIS)is required.EAs or EISs are not required for any action included in the list of categorical exclusions'et forth in 10 CFR 51.22(c).Specifically, 10 CFR 5'.22(c)(a), provides that an EA is not required;or the issuance of an amendment provided that: Qi the amondment involves no significant hazards consideration, there is no significant change in the types or significant increase in the amounts of any effluents that may be released offsite, and (iu)there is no significant increase in individual or cumulative occupational radiation exposure.Plant radiation protection features are designed to limit the radiation exposure to plant personnel and the genera)public to 10 CFR 20 limits under normal conditions.

Nlhile certain isotopes are present in greater concentration ln the fuol gap due to the uprated power levol, tho actual increases in occupational dose are expected to bo minimal.The fuel has been designed to operate at the higher p'urer level without any damage, which would negate any increases In radioactivity trapped within an intact fuel rod.Also, our technical specifications limit the concentration of radioactivity viithin the reactor coolant system (see Technical Specification 3.4.8), Nevertheless, acddent offsito doses have been recalcu;ated based on the uprated source term and other analysis assumptions used in the Uprating Program.In some cases, the resulting thyroid offsite dose consequence's increase slightly above the values presently in the UFSAR..The new calculated whole bc'y doses either romain the same as the UFSAR vaiuos or decrease~or both types ofcalculations, tne changes in tho offsite radiation dose for each accident are not significant and are within the acceptance criteria as defined in 10 CFR 100.Since systems and procedures controlling normal radioactive releases are based on limiting plant ffluents to a small fraction of regulatory limits, the proposed uprating of Unit 2 will not exceed 10 CFR 20 or 10 CF or C R100 limits.Basod on this information, there wIII bo no significant increase in the types or amounts of effluerits that may be released offsite and no significant increase in individual or cumulative occupational radiation exposure.AEPNO believes that the provisions of 10 CFR 51.22(c}(e}

Page 6 Environmental Evaluation U-2 Uprate Per AEP: NRC,.1223 The enviranmenta,'impacts at tho highor power level a bounded by the impacts assumed in tho existing FES and controllod by tho Michigan Department of Environmental Quality through the NPDES Permit program, arid Rule 98 of the Michigan Quality Standards.

A copy of the Demonstration of Acceptability of increased Heat Addition, which was submitted as part of the compliance requirements by the MDNR and EPA, is also included with this package for review at Attachment C.This submittal should assist the NRC in making a finding of no significant impact" in accordanco with 10 CFR 51.32.References 1.2.3.4.Unit 1 and 2 Technical Specifications, Appendix B.NPDES Permit No.MI0005827, June 28, 1995 Final Environmental Statement, August 1973 10 CFR 51.22.(c), 10 CFR 51.32 I/Approved by: D.H.Malin, Section Manager Nuclear Licensing and Fuels Attachments c: S.J.Brewer D.M.Fitzgerald M.A.Ackerman 0

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Cook Nuclear Plant 1996 Zebra Mussel Monitoring and Control Ressort Z~1ODUCTION The plant's zebra mussel monitoring and control program is presented in the followin report.Chlorine, molluscicides, mechanical cleaning, and chan es in lant des'emain the zebra mussel control strateg at the Cook Pl to assess the threat of z e rea o zebra mussel infestation and determine the effectiveness of to present a challen e to the plant control techniques.

circulating water pumps.This operation presents a challenge to the traveling screens and screenwash system in their ability to'handle the influx of zebra mussels sloughing off from the intake tunnels.Any" carryover that occurs, must be handled by the service water pump strainers or is impinged on the condenser tube sheets.The continuous operation of the traveling screens contributed to a large diver maintenance effort in 1996.DESIGN CHANGES Traveling Screens Modifications of the traveling screen spraywash sy tern begun in 1995 from a single to a dual spray header with improved nozzle design was completed in 1996 under PM-873.The dual spray header return piping was routed to the traveling screen trash trough to facilitate flushing of the spray headers and nozzles.In addition to the spray header and spray nozzle changes, the screen panels on traveling screen 2-OME-43-7 were replaced with a flatter stainless steel wire mesh.The improved design effectively removed the debris from the traveling screens.The old galvanized dipped screen panels are systematically being replaced on the remaining traveling screen units by the stainless steel panels as the old panels wear out.A component evaluation, CE-95-0345, performed on the north screenwash pump strainer in August of 1996, reduced the strainer mesh size from 1/8" to 5/64" to prevent the traveling screenwash nozzles from plugging.Miscellaneous Sealing&Cooling Water Pump Strainer and Filter Upgrade In the fall of 1996, the 2" miscellaneous sealing a cooling water pump strainers were replaced with 4" Hayward self cleaning strainers.

In addition, two Ontario Hydro Industries 40 micron filters were installed to run in parallel.The new filters will become operational in 1997 when the filter backwash routing can be changed from the screenwash pump stainer backwash lines to the 30" turbine room sump overflow line to the intake forebay.Chemical Injection Pipeline A design has been issued under DCP-108 for installation of two chemical injection pipeline systems to be run through the center intake tunnel and branching at the center intake crib to the north and south intake cribs.This design is scheduled'o be installed in May 1997.Chemicals will be delivered out to the intake cribs effectively controlling zebra mussel colonization in the intake pipelines.

CONCLUSION For the foreseeable future, proprietary molluscicides will continue to be used for zebra mussel control.Mechanical cleaning can supplement chemical control methods in the circulating water system.Plant design changes including strainers, filters, screens, and chemical delivery systems, will work to resolve the plant s zebra mussel related problems.Continuous chlorination has proven to be effective in contro~~ing zebra mussels in the service water and the miscellaneous sealing a cooling water systems.Corrosion coupon studies in the service water systems have shown that alternatives to chlorine should be sought to minimize corrosion.

A zebra mussel monitoring program utilizing side-stream and arti,ficial substrate monitors, along with diver and heat exchanger inspections, will continue to be used to evaluate the effectiveness of chemical and physical control measures.2

Prepared for AMERICAN ELECTRIC POWER Donald C.Cook Nuclear Plant One Cook Place Bridgman, Michigan b IOI.LUSC BIOFOULING MONITORING DURING l996 March 1997 LMSE-97/0091&673/003 Prepared by: LAWLER, MATUSKY&SKELLY ENGINEERS LLP Environmental Science&Engineering Consultants 10207 Lucas Road%oodstock, Illinois 60098 TABLE OF CONTENTS LIST OF FIGURES LIST OF TABLES EXECUTIVE  

1 INTRODUCTION Page No.nI ES-1 1.1 Past History 1.2 Objectives 2 METHODS 2.1 Whole-Water Sampling 2.2 Artificial Substrates 2-1 2-1 2-2 2.2.1 Periodic Settlement 2.2.2 Cumulative Settlement 2.2.3 Periodic and Cumulative Sample Analysis 2.3 Quality Assurance/Quality Control 3 RESULT~AND DISCUSSION 2-2 2-3 2-3 2-4 3-1 3.1 Whole-Water Sampling 3.2 Artificial Substrate Sampling 3-1 3-2 3.2.1 Circulating Water System 3-2 3.2.2 Service and Miscellaneous Sealing and Cooling Water Systems 3-3 3.3 Quality Assurance/Quality Control Samples 4  

AND RECOMMENDATIONS 3-8 4-1 4.1 Summary 4.2 Recommendations 4.3 References 4-1 4-2 4-3 Lawler, Matusky&Skelly Engineers LLP LIST OF FIGE!LES Table No.Title Following Page 3-1 Whole Water Sampling Program Veligers Per Cubic Meter, D.C.Cook, 1996 3-1A 3-2 A'rtificial Substrate Settlement-Forebay Numbers Per Square Meter, D.C.Cook, 1996 3-2A 3-3 Artificial Substrate Settlement-Periodic Servic" Water and Miscellaneous Cooling Water Systems Postveliger Density Per Square Meter, D.C.Cook, 1996 3-3A 3-4 Wholewater Veliger Density and Periodic Settlement in the Service Water System, D.C.Cook, 1996 3-4A 3-5'Artificial Substrate Settlement-Cumulative Service Water and Miscellaneous Cooling Water Systems Postveliger Density Per Square Meter, D.C.Cook, 1996 3-7A Lawler, Matusky&Skelly Engineers LLP  

LIST OF TAI)LES Table No.Title Page No.2-1 Sampling Schedule for Zebra Mussel Monitoring, D.C.Cook, 1996 2-1A 3-1 Whole Water Sampling Program Veligers Per Cubic Meter, D.C.Cook,'996 3-18 3-2 Zebra Mussel Density, Average Size, and Size Range of Settled Postveligers from Periodic Sampling, D.C.Cook, 1996 3-28 3-3 Chlorination Data for the Service Water Systems, D.C.Cook, 1996 3-48 3-4 Zebra Mussel Density, Average Size, and Size Range of'ettled Postveligers from Cumulative Sampling, D.C.Cook, 1996 3-78 3-5 Results of QA/QC Samples, D.C.Cook, 1996 3-8A nl Lawler, Matusky&Skelly Engineers LLP EXECUTIVE  

Peak densities on the neriodic artific!al substrates which were placed on the service water systems occurred during the latter half of October for all service water systems.This followedthe peak densities in the wholewater samples by one to two weeks, as expected.Densities of postveligers on the cumulative artificial substrate samples were low from 23 May through 22 August and peaked at ESWR-I, ESWR-2, and the miscellaneous sealing and cooling water systems during the latter half of October.The highest density reported for NESW occurred on 12 December.Several unexpected observations were made during the 1996 sampling season.These includes:~Veligers were present in the wholewater samples through 12 December.Size data for artificial substrate samples (both periodic and cumulative) indicated that small postveligers were present through 12 December and that these specimens were ali ene on the substrates collected on the November and December sampling dates.A number of possible explanations are presented for these obs.rvations.

No one explanation by itself is considered to be the answer;but rather some combination of tnese factors is thought to be responsible for the unexpected results.These possible explanations include: o The abnormally warm lake water, as measured at the, intake, during October (particularly the latter half of the month)most likely extended the peak spawnin" season for zeura mussels until the first part of November.The efficacy of the chlorine may have been reduced by the combination of colder water and high pH during November and/or the possible presence of chloramines in the system.Zebra mussel metabolic rates slowed down with the decrease in water temperature during November;therefore, they were not as susceptible to chlorine as during the warmer weather months.Results may reflect presence of quagga mussels in the vicinity of the offshore.intake.These relatives of zebra mussels continue to spawn at much colder water temperatures than zebra mussels and are known to be present in the Great Lakes.ES-2 Lawler, Matusky&Skelly Engineers LLp  

CHAPTER I INTRODUCTION 1.1 PAST HISTORY American Electric Power Company (AEP)has been conducting zebra mussel monitoring studies at the Donald C.Cook Nuclear Plant since 1991.The purpose of the studies is to monitor the presence of zebra mussel veliger and postveliger settlement densities in the circulating water, essential service water (ESW), and nonessential service water (NESW)systems to help determine the effectiveness of zebra mussel control programs.The 1996 monitoring program conducted by Lawler, Matusky&Skelly Engineers LLp (LMS)was designed to detect the timing of spawning and senling of zebra mussels at the Cook Nuclear Plant and to collect and determine densities for: (1)wholewater samples for planktonic veligers;and (2)artificial substrates set within the circulating water, ESW, NESW, and miscellaneous sealing and cooling systems for periodic and cumulative postveliger settlement.

1.2 OMECTIVES Specific obje~...es for the 1996 biofouling monitoring program were as follows: Whole-water sampling of the circulating water system was conducted weekly (June-October), bimonthly (May and November), or monthly (April'nd December)to determine the presence and density of larval zebra mussels.Artificial substrates were deployed in the intake forebay and service water systems to detect settlement of post-veligers.

Samples were collected every two weeks from June through October and once every three weeks during November and December.Lawler, NIatusky&Skelly Engineer LLp 1

CHAPTER 2 METHODS 2.1 WHOLE-WATER SAMPLING Whole-water sampling of the circulating water system was conducted from 25 April to 12 December 1996 according to the schedule presented in Table 2-1.Samples were collected from mid-depth in the intake forebay by pumpjng lake water through an in-line flowmeter into a plankton net.The sampling location was consistent with that of previous studies.Two replicates (2000 liters each)were collected during each sampling event.A Myers Model 2JF-51-8 well pump, rated to deliver 8 gpm, was connected to an in-line flowmeter assembly (Signet Model il'P58640) and pumped water into a plankton net for approximately 45 minutes.To minimize organism abrasion, measured flow was directed into a No.20 plankton net that was suspended in a partially filled 55-gal plastic barrel.Valves were adjusted to reduce flow, thus preventing the plankton net from overflowing when heavy sediment loads or plankton concentrations were present.Samples were washed down gently into the cod-end bucket using filtered, circulating water system water a<<u then transferred into a 1 liter plastic jar.If needed, filtered water was added to the jar to ensure that a full liter was analyzed.After the second replicate was taken, both samples were transported to the on-site laboratory and analyzed immediately.

Samples were initially mixed thoroughly for 3 minutes using a magnetic stir plate.Then, using a calibrated disposable Pasteur pipette, a 1-ml aliquot of mixed sample was placed into a Sedgewick-Rafter cell for counting, using an Olympus SZ-1145 binocular microscope (18-110X)equipped with cross-polarizing filters.Ten replicates were counted, and the average was extrapolated to determine the number of individuals per cubic meter.This process was repeated for the second replicate and the mean of the two values was calculated to yield a final density value.The density was calculated as follows.2-1 Lawler, NIatusky&Skelly Engineers LLp C

Density (0'im')=(average O'*DF)/0.001L*I L/2000L*1000L/m Size measurements were recorded for up to 50 organisms from each sample.Veliger length (pm)was measured using an ocular micrometer that was calibrated to a stage micrometer.

2.2 ARTIFICIAL SUBSTRATES To determine zebra mussel settlement in the circulating water, ESW, and NESW systems, artificial substrates were placed in the intake forebay upstream of the trash racks;sidestream samplers were set on the return side of both service water systems and on the miscellaneous sealing and cooling system.Monitors were equipped with modified test-tube racks designed to hold slides for periodic and cumulative sampling.(Periodic settlement is defined as short-term monitoring, either two-or three-week periods, depending on the month.Cumulative settlement is long-term monitoring that extends from initial deployment

[23 May]to the end of the sampling season.)Both periodic and cumulative sampling dates are presented in Table2-1.2.2.1 Periodic Settlement Artificial st-'"ates that were designed to measure periodic settlement were placed in the intake forebay and consisted of cinderblocks with test-tube racks secured inside the openings,.

Periodic samplers were deployed by rope in the central location at approximately mid-depth.

Sidestream monitors were placed on the return side of the service water systems (ESW and NESW)and the miscellaneous sealing and cooling water system.Each monitor contained two modified test-tube racks that held all slides above the monitor base.This allowed silt and sediment to fall out before they could influence postveliger settlement.

Monitors were covered 4 with a plant-approved fireproof fabric to limit light exposure.Plant personnel checked the monitors periodically to ensure that adequate flow was available, and flow was adjusted as necessary.

Slides were placed in labeled 2-2 12 Lawler, Matusky A Skelly Engineers LLP 0

racks, covered, with a plastic bag, and transported to the on-site laboratory where they were analyzed immediately.

2.2.2 Cumulative Settlement A sufficient number of substrates were initially placed in the biobox samplers to allow 10 slides to be removed once per month at the service water and miscellaneous sealing and cooling water locations.

These slides were not replaced.Cumulative settlement was monitored in the forebay using two pieces of PVC pipe that were each six inches long and had an inside diameter of two inches.Each pipe was cut in half lengthwise, rejoined using hose clamps, and attached to a rope at intervals of about three feet.These were deployed at the central location at mid-depth.

One sampler was intended to be exposed to Clam Trol CT-2 and the other was not to be exposed to the toxicant during the Clamtrol treatment.

Cumulative monitoring was designed to provide information on accumulated infestation throughout the growing season.There were no proprietar'y molluscide treatments in 1996.2.2.3 Periodic and'umulative Sample Analysis~~~Analysis was conducted with an Olympus SZ-1145 binocular microscope (18-110X)equipped with cross-p".larizing filters.After one side of the slide was scraped clean, the slide was placed on the microscope so that the attached postveligers could be counted.When s..beche heavily infested, a subsampling technique was followed: The slides were subsampled using a splitter that permitted either half or a quarter of the slide to be counted.Counts were then proportionally extrapolated to one square meter.Settlement rates were computed by taking the average value of the 10 slides and multiplying this value by 533.34 to obtain the density of zebra mussels per square meter." (One postveliger/microscope slide equals 533.34 veii~ers per square meter.)2-3 Lawler, Matusky 8'kelly Engineers LLP

Shell diameters were measured for up to 50 selected and random individuals for both unsubsampled and subsampled slides to obtain maximum, minimum, and mean sizes.Diameters were measured using an ocular micrometer calibrated to a stage micrometer.

2.3 QUALITY ASSURANCE/QUALITY CONTROL A total of three sampling dates were reanalyzed by Mr.Jeffrey Mensinger (who conducted this zebra mussel monitoring program for LMS during the period 1992 through 1994}for precision and accuracy of the counting procedures.

Samples were shipped to an off-site laboratory and analyzed using the same procedures as the original analysis.Dates reanalyzed included 27 June, 31 October, and 12 December 1996.One liter of wholewater and one slide from each sampling site (both cumulative and periodic artificial substrates) were reinspected.

24 Lawler, Matusky Sc Skelly Engineers LLp  

The continued use of an electronic flowmeter provided data comparable to those of the 1993, 1994, and 1995 monitoring programs.As a result, direct comparisons with those data can be made.Results of sampling are presented in Figure 3-1 and Table 3-1.With the exception of the 25 April sampling date, veligers were present in all samples collected.

It is thought that the June 1994 peak was more the result of unusually hot weather that occurred turing the first two weeks of June than environmental differences between the early fall periods amongst the years of record.3-1 Lawler, Matusky 4 Skelly Engineers LLP FIGURE 3-1 WHOLE-WATER SAMPLING PROGRAM VELIGERS PER CUBIC METER, D.C.COOK, 1996 292)750 10 4 4 7 0)rD 7 O o 1 O.0 Z A pr 25 May 23 Jun 1 Nov2 SAMPLING DATE 13 Jun 27 Jul 11 Jul 25 Aug 8 Aug 22 Sep 5 Sep 19 Ocl 3 Ocl 17~3 1 May 9 Jun 6 Jun 20 Jul 3 Jul 18 Aug 1 Aug 15 Aug 29 Sap 12 Sep 26 Ocl 10 Ocl 24 Ncy 7 0

TABLE 3-1 WHOLE WATER SAMPLING PROGRAM VELIGEP.S PER CUBIC METER, D.C.COOK, 1996 DATE DENSITY (No./m3)SIZE RANGE (pm)MEAN SIZE (pm)4/25/96 5/09/96 5/23/96 6/06/96 6/13/96 6/20/96 6/27/96 7/03/96 7/11/96 7/18/96 7/25/96 8/01/96 8/08/96 8/15/96 8/22/96 8/29/96 9/05/96 9/12/96 9/19/96 9/26/96 10/03/96 10/10/96 10/17/96 10/24/96 10/31/96 11/07/96 11/21/96 12/12/96 0 150 1,175 250 1,375 500 25 3,625 625 1,950 17,000 6,325 1,700 9,675 15,925 975 5,975 8,275 35,425 96,250 6,200 292,750 57,250 53,450 55,650 17,475 4,600 925 100-160 75-625 120-500 80-130 90-330 125 90-320 100-150 90-130 90-180 90-200 100-230 90-330 100-330 100-260'0-230 100-260 90-300 100-300 100-390 90-330 90-330 100-400 100-430 130-330 100-560 100-560 130 118 213 100 140 125 105 114 103 110'142 193 138 158 174 150 I/4 144 165 189 197 219 216 202 216 232 363

Size data for the 1996 sampling season shows that translocators were active in the forebay on 23 May and 6 June.Spawning commenced between 25 April and 9 May and continued through the middle of December as indicated by the lower portion of the size range data.Size range data also show that translocators were present in the water column from 23 May through 6 Jure but then were absent from the samples for the remainder of the sampling season.On most other data, the upper end of the size range exceeded the size of settlement (200-225pm) and was in or exceeded this range on every sampling date from 1 August through 12 December.However, mean size did not approach this settlement size range until October.In summary, zebra mussel veligers were present in the water column on all sampling dates except 25 April.Spawning commenced between 25 April and 9 May and continued through mid-December.

Peak veliger densities occurred during the seven week period from mid-September to the end of October which is typical for the lower Great Lakes and has been reported at the Cook Plant for three of the last four years (1993, 1995, and 1996).3.2 ARTIFICIAL SUBSTRATE SAMPLING 3.2.1 Circulating Water System Artificial substrate monitoring was conducted at the center forebay location (which is protected by a deflector-"11):;om 23 May to 12 December 1996.Periodic settlement r;.',ar the circulating water system (forebay)are shown in Figure 3-2.Table 3-2 provides density and size information for settled postveligers.

Settlement in the forebay occurred on all periodic sampling dates in 1996 except 6 June and 25 July.Density information presented in Table 3-2 indicates that settlement was low from 6 June through 5 September (0-8600lmz).

Several translocators settled on the substrates during the 6"June to 11 July period.First evidence of settlement of 1996 spawned zebra mussels was observed on 20 June.Heaviest settlement occurred between 5 September and 21 November with the peak occurring during the 3 October to 17 October period.This is typical for the lower Great Lakes and is consistent with results reported for the 1992, 1993, and 1994 3-2 Lawler, Matusky&Skelly Engineers LLp

FIGURE 3-2 ARTIFICIAL SUBSTRATE SETTLEMENT-FOREBAY NUMBERS PER SQUARE METER, D C COOK, 1996*~14 E1 8 U 8 0 tD CL 0 Z Jun 6 Jul 11 Aug 8 Sep 5 Jun 20 JUI 25 Aug 22 Sop 19 SAMPLING DATE Oct 3 Oct 17 Oct 31 Nov 21 Dec12

TABLE 3-2 ZEBRA MUSSEL DENSITY, AVERAGESIZE, AND SIZE RANGE OF SETTLED POSTVELIGERS FROM PERIODIC SAMPLING, D.C.COOK, 1996 PERIODIC SAMPLES DATE FOREBAY Avg.Density Size Range (No/.m)(r m)Qm)Dense (Norm)NESW Avg.Size Range Qm)(pm)Dense (Norm)MS&,C Avg.Size Range Qm)Qm)ESW R-1 Avg.Dens/Size Range (No Jm)(r m)Dense (No./m)ESW R-2 Avg.Size Range (pm)gm)6/06/96 6/20/96 7/1 1/96 1'25/96 8/08/96 8/22i96 9/05/96 9/19/96 10/03/96 10/17/96 10/31/96 11/21/96 12/12/96 9,600 3.200 640 747 46,453 64,533 158,613 70,560 25,867 2,880 193 415 140-260 140-1,475 251 245 1$4390 2$M30 200430 395 1~80 274 200460 8&400 180400 200-460 291 26M40 1,600 1,600 2720 4,253 5,600 31,680 1,707 5,173 120-1 80 100-160 267 373 125 1M-160 3,520 175 249 140-200 1M.280 130460 6,347 2,2"0 13O330 199 130400 4,000 1,173 310 100-760 207 1M-260 12,053 130 130 130 130 238 200430 126 100-160 116 90-230 271 167 140-200 199 100-260 148 1 00430 235 100460 223 lOM30 230 1 Eh%0 53 1,600 160 480 373 3,147-1,173 5,920 20,480 1,813 98 9O-1OO 117 100-130 117 100-130 137 100-170 193 100-230 221 10O440 239.180300 268 160-360 233 100400 210 10O430 160 207 747 2,080 2.560 9,280 4,960 2.720 5,387 120 120 126 100.160 124 100-160 153 100.200 212 100-260 192 100~0 226 100-500 194 100-330 386 200-1.050 337 200430 4 One translocator at 4620 (r m)not inlcluded.  

monitoring programs (LMS 1993, 1994, 1995), but later than 1995 when settlement in the forebay peaked between 13 July and 17 September (GLEC 1996).Similar to 1994 and 1995 results, very little settlement occurred during the late November to mid-December period.Based on size data, the majority of those individuals settling during this period were postveligers whose average size ranged from 283 to 290 pm.Two six inch long pieces of PVC (ID 2 in.)were suspended in the forebay to monitor cumulative settlement.

The objective of this program element is to compare the post Clamtrol treatment settlement to that of the entire sampling season.Data collected in previous years indicates that much of the annual settlement occurs after the treatment.

This program objective was not met in 1996 because molluscicide treatment was not administered and the samples were lost.3.2.2 Service and Miscellaneous Sealing and Cooling Water Systems The return sides of the ESW and NESW systems were monitored during 1996.The ESW systems of both Units 1 and 2 were monitored throughout the sampling period;but only the Unit 1 NESW system was sampled in 1996.A sidestre w biobox monitor was also placed on the miscellaneous sealing and cooling water system which draws its water from a source separate frc::;that of the service water systems.The ESW, NESW, and miscellaneous sealing and cooling water systems were scheduled for chlorination from mid-May tt.u..nd of November.Periodic settlement densities for the service water systems and die miscellaneous sealing and'ooling water system are shown in Table 3-2 and Fibre 3-3: Settlement occurred in low densities at NESW R-l, ESW R-l, and miscellaneous sealing and cooling water system on the first retrieval date (6 June), but did not appear on artificial substrates set at ESW R-2 until 11 July.Density and size information (Table 3-2)shows that settlement was sparse at all locations during June with densities ranging from 0 to 160U/mz.Size data indicate that most postveligers collected in June were spawned during May, with several translocators also appearing on the substrates.

3-3 Lawler, Matusky Bc Skelly Engineers LLP  

FIGURE 3-3 ARTIFICIAL SUBSTRATE SETTLEMENT-PERIODIC SERVICE MfATER AND MISCELLANEOUS COOLING IfATER SYSTEMS POSTVELIGER DENSITY PER SQUARE METER, D.C.COOK'f 996 31,680 20>480 h~h h h h h h h h ihh'h h ht ESW R-1 NESW MS&C ESW R-2 Jun 6 Jun 20 Jul 11 Jul 25 Aug 8 Sep 5 Aug 22 Sep 19 SAMPLING DATE Oct 17 Oct 31 D Nov 21 ec 12 Figure 3-4 presents the comparison of periodic settlement densities with those of wholewater veligers for the sampling season.As expected, these data show that periods of increased'ettlement in the systems monitored lag increases in wholewater densities by about one to two weeks.This is particularly evident during the mid-September to end of October period.Because total residual chlorine data are not available for the last,two weeks of October, it can not b: determined whether the settlement.

These include 18 July and 25 and 31 October.The October dates coincide with the laner part.of the peak spawning period and inadequate chlorination may be responsible for the high densities recorded at both NESW (31,680/m)and ESW R-1 (20,480/m)locations on 31 October.Conversely, lower densities were recorded at miscellaneous sealing and cooling and ESW R-2 locations on 31 October than on the previous sampling date (17 October)when peak settlement occurred at both locations.

FIGURE 3-4 WHOLE WATER VELIGER DENSITY AND PERIODIC SETTLEMENT IN THE SERVICE WATER SYSTEM, D.C.COOK, 1996 E3 NESW MSEC mI ESW R-1 K3 ESW R-2 Whole Water 250 Q)E O S)O tD EO C 150: ">o~m C 0)CI L 0)6$100 tD 0~P xs Apt 25 May 23 Jun 13 Jun 27 Jul 11 Jul 25 Aug 8 Aug 22 SeP 5 SeP 19 Oct 3'ct 17 Oct 31 Nov 21 May 9 Jun 6 Jun 20 Jul 3 Jul 18 Aug 1 Aug 15 Aug 29 Sep 12 Sep 26 Oct 10 Oct 24 Nov 7 Dec 12 SAMPLING DATE

TABLE 3-3 CHLORINATION DATA FOR THE SERVICE WATER SYSTEMS, D.C.COOK, 1996 DATE NESW ppm UNIT I ESW ppm MS&C ppm UNIT 2 ESW ppmMay 17 May 23 May 30 Jun 6 Jun 13 Jun 21 Jun 27 Jul 3 Jul 11 JUI 25 Aug 1 Aug 8 Aug 15 Aug 22 Aug 29 Sep 5 Sep 12 Sep 24 Sep 27 Oct 2 Oct 10 Oct 17 Nov 6 Nov 21'ov 28 0.49 0.22 0.51 0.48 0.29 0.82 0.30 0.76 0.50 0.09 0.48 0.39 0.27 0.25 0.47 0.41 0.28 0.01 0.04 0.08 0.52 0.53 0.47 0.89 0.65 0.47 0.78 0.38 0.02 0.30 ND 0.73 0.30 0.41 0.08 0.26 0.15 0.14 0.13 0.40 0.04 0.21 0.09 0.01 0.62 1.04 0.01 0.03 0.02 0.78 ND'.06<0.01<0.01 0.13 0.71 0.58 0.38 0.85 0.14 0.29 0.47 0.29 0.31 0.60 0.55 0.01 0.03 0.42 1.11 0.08 0.65 0.02 0.88 0.67 0.11 0.93 0.24 0.40 0.31 ND 0.64 0.41 0.57 0.13 0.42 0.81 0.45 0.28 0.89 1.12.23 0.15 ND 0.58 0.92 0.01 0.85 0.05 0.60*ND-No data3-4B 25 0

with lack of chlorination data).Size data show that the mean size of postveligers on the substrates were generally below the threshold for settlement until 19 September.

These continued to appear on the substrates until the end of the sampling season.For the first time in this monitoring program, settlement of postveligers continued in all the systems through November until the program was concluded in mid-December.

The observation of an increase in density at three of the four in-plant monitoring locations between 21 November and 12 December was unexpected.

This appears to be a combination of the densities of veligers in the intake water and the efficiency of the chlorine at cooler water temperatures in water that typically exhibits high pH.Figure 34 presents information showing wholewater veliger and periodic settlement densities for the sampling season.Wholewater densities continued to be above 50,000/m~until the first week of November and remained above 17,000/m~through 7 November.These veligers continued to grow and became postveligers of settleable size by the third week of November.Most likely, veligers were present in the lake water after 21 November and these then were included in the unexpected periodic densities recorded on 12 December.Wholewater densities recorded during the 1993 through 1995 programs for the November-December sampling periods were less than 1000/m3 for sampling conducted afte~~Nc.~mber.This suggests that spawning continued into the late'early winter period in 1996.This is atypical in the vicinity of D.C.Cook Plant based on four years of data.A preliminary review of chlorine chemistry indicates that pH may have a greater influence driving the reaction than temperature as shown in the following table.Percent Hyperchlorous Acid in Solution Temperature pH 7.5 pH 8.0 5'C 64.3 36.3 10'C 33.0 3-5 Lawler, Matusky&Skelly,Engineers LLP

between years in temperature and/or pH will modify the effectiveness of the chlorine.Comparison of daily water temperatures recorded on the DMR's for the months of October, November.and December for 1993 through 1996 indicates that intake water temperatures in October 1996 were considerably warmer than the previous three,"ears, particularly during the second half of the month.November and December (first 15 days)mean intake water temperatures in 1996 were similar to those of 1993 and 1994 but warmer than in 1995.As can be seen in the table below, December mean intake water temperatures recorded in 1996 were cooler for this period than in both 1993 and 1994.Mean Intake Water Temperatures

'F Year 1993 1994 1995 1996 Oct(1-15)59.8 56.7 60.1 63.4 Oct(16-31) 56.7 55.6 55.1 59.8 Nov 49.0 48.1 45.8 48 9 Dec(1-15)44.6 43.4 38.8 42.2+can intake water temperatures reflect lake conditions which were more conducive to zebra mussel spawning during both halves of October in 1996 than they were in the previous years.However, the data for both November and the flr t half of December do not suggest that intake water temperatures in 1996 would have been conducive to continued spawning during the November-December period.Therefore, it is reasonable to conclude, that the favorable spawning temperatures during the second half of October 1996 were at least partially responsible for the settlement observed on the artificial substrates in both November and December.Changes may also have occurred in the water quality constituents that use chlorine as an oxidant, e.g., iron, manganese, and ammonia.Ammonia is particularly important because it forms chloramines with chlorine.These often are measured in the TRC readings suggesting that the target is being met.However, chloramines are not as reactive as free chlorine (therefore, not as effective) although they are more persistent in the water column.In the case 3-6 Lawler, Matusky&Skelly Engineers LLp 27 of Cook Plant, this would reduce the effectiveness because the flow through the service water systems remains relatively rapid, that is, it does not remain in the system long enough for the chloramines to be effective.

Another possible explanation for the veligers and postveliger senlement observed during November and December is that the individuals were early life stages of quagga mussels (Dreissena bugensis), a relative of zebra mussels.Quagga mussels tend to inhabit deeper, colder waters and spawning is not limited by colder water temperatures.

Therefore, it is feasible that, as lake water temperatures decreased during November and December, these H mussels (if present)continued to spawn and the early life forms were collected.

Early life stages of muss'els believed to be quagga mussels have begun to appear during cold weather months at other sampling sites along the Great Lakes during the last, two to three years (L.Ray Tuttle, personal communication).

It is plausible that an adult pop!lation of quagga mussels has become established in the vicinity of the Cook Plant intake and has reached sufficient numbers such that the effects of their spawning is beginning to be observed in this project.A second set of data was collected from each of the service water systems and miscellaneous sealing and cooling water system for the purpose of determining the effectiveness of chlorination during the entire sampling season.These cumulative densities and associated size information:"-

~resented in Figure 3-5 and Table 3-4.Artificial substrates used for cumulative analyses were set on 23 May and sets of 10 slides were retrieve~from each location at monthly intervals throughout the sampling'season beginning on 20 June.Results were evaluated in conjunction with periodic data to better understand pcstveliger settlement in the systems.Density data indicate that few postveligers were on the artificial substrates collected from 20 June through 22 August at NESW, ESW R-2, and miscellaneous sealing and cooling systems.Concentrations at the ESW R-1 location was somewhat higher than the other locations during this period.Size information shows that, with the exception of several translocators collected at the miscellaneous sealing and cooling water location, most of the individuals on the slides at all locations were below the threshold size for settlement.

Furthermore, these specimens 3-7 28 Lawler, Matusky 4 Skelly Engineers LLp FIGURE S-S ARTIFICIAL SUBSTRATE SETTLEMENT-CUlVlULATIVE SERVICE WATER AND MISCELLANEOUS COOLING WATER SYSTEMS POSTVELIGER DENSITY PER SQUARE METER, D.C.COOK 1996 I 1 L 6)1E Q)4 1 GJ to tD O.0 Z Jun 20 Jul 25 Aug 22 t k..Sep 19 SAMPLING DATE Oct 17 Nov 21 Dec 12 NESW MS8C ESW R-2 ESW R-1

TABLE 3-4 ZEBRA MUSSEL DENSITY, AVERAGESIZE, AND SIZE RANGE OF SETTI.ED POSTVELIGERS FROM CUMULATIVESAMPLING, D.C.COOK, I99ti CUMULATIVE SAMPLES DATE NESW Avg.Density Size (No./mz)(pm)Range (pm)Density (No./m)MS&C Avg.Size Range (pm)(pm)ESW R-I Avg.Density Size (No./m)(pm)Range (pm)Density (No./mz)ESW R-2 Avg.Size Range (pm)t pm)6/20/96 7/25/96 8/22/96 9/19/96 10/1 7/96 11/21/96 12/12/96 53 230 230 587 2,987 6,080 3,520 113 90-160 221 100-300 232 100450 387 200-1,030 17,013 425 200-800 1,920 2,880 15,893 1,173 2,987 121 90-390 203 100400 218 90<00 380 180-880 314 100-660 373 279 170-460 1,067 155 130-200 2,133 103 90-120 1,173 119 100-160 2,667 174 100-260 6,613 246 100-700 1,120 327 160-690 3,466 376 200-730 5,227 3,467 1,600 6,880 199 130-260 246 100-500.307 160-460 415 200-860 0 373 103 100-120 0

exhibited no signs of lite (beating cilia and stomach movement).

The reasonable conclusion is that the chlorine was very effective throughout the summer.As the densities of veligers increased in wholewater samples during the fall, densities on the cumulative artificial substrates also increased as might be expected.The observation that peak densit cccurred at the miscellaneous sealing and cooling water systems and the ESW R-I systems on 17 October was not surprising because wholewater densities peaked on 10 October.However, peak densities occurred at the other two locations on 12 December with the NESW density being the highest (17,013/m)for the year for all cumulative samples.This was unexpected and may have been the result of a lack of sufficient chlorination that seems to have occurred during the latter half of October.The discussion regarding efficacy of chlorine during this late fall period which is presented above (periodic artificial substrate results)applies to the cumulative results as well.Size data show two expected and one unexpected results.Mean sizes progressively increased'hroughout the fall period at all locations (except for the last sampling at the miscellaneous sealing and cooling system);and generally, the high end of the size ranges also increased during the fall period.The somewhat unexpected result was the low end of the size ranges which indica'.d that recently hatched postveligers continued to settle on these substrates until the middle of December.The presence of these smaller veligers suggests that settlement may have continued at some low rate after the monitoring program was discontinued for i.season.Furthermore, most of those organisms observed on the artificial substrates in December were alive.It is reasonable to conclude that chlorination was not very effective during the late fall period in 1996.3.3 QUALITY ASSURANCE/QUALITY CONTROL SAMPLES The results of the QA/QC samples analyzed in 1996 are summarized in Table 3-5.These reinspections included both original analyzers used for this project and were conducted by a third analyzer.Because one slide from each set of 10 analyzed on each sampling date was randomly selected for re-analysis, no statistics were applied.However, results were compared 3-8 Lawler, Matusky&Skelly Engineers LLP TABLE 3-5 RESULTS OF QA/QC SAMPLES)D.C.COOK, 1996 SAMPLE SAMPLE SAMPLE DATE TYPE LOCATION ONSITE DENSITY QA/QC DENSITY%AGREEMENT Jun 27 Wholewater Forcbay 25 25 100.0 Oct 31 Wholewater Periodic Periodic Periodic Periodic Periodic Forebay Forebay ESW R-1 ESW R-2 NESW MS&C 56,000 53,866 21,333 4,780 25,600 4,800 59,400 44,800 19,733 4,267 4,800 94.3 83.2 92.5 89.3 ltK.O Dec 12 Wholcwatcr Periodic Periodic Periodic Periodic Periodic Periodic Cumulative Cumulative Cumulative Cumulative Forcbay Forcbay ESW R-1 ESW R-2 NESW MS&C Circ.H>O ESW R-1 ESW R-2 NESW MS&C 925 3,200 3,200 3 733 3,200 533 1,066 5,333 3,200 6,933 3,200 750 3,200 2,667 3,733 3,200 533 2,133 5,333 2,667 6,400 3,200 81.1 100.0 83.3 100.0 100.0 100.0 50.0 100.0 83.3 92.3 100.0'lide broken in transit.3-8A 32 t'or percent agreement between the two analyses.In each case where artiticial substrate results fell below 100%, the reinspection result was lower than the original.It was observed by the QC inspector that specimens were lying free, i.e., off the slide, in the packaging.

The difference in the wholewater analyses for the 12 December sample is attributed to low numbers of veligers in the sample.These may have settled in the!iter bottle during shipment and not resuspended when agitated by the QC inspector.

3-9 33 Lawler, Matusky&Skelly Engineers LLP CHAPTER 4  

REFERENCES Lawler, Matusky,&Skelly Engineers U.t.1994.Mollusc biofouling monitoring during 1993, Donald C.Cook Nuclear PLant: Final Report.46 pp.Lawler, Matusky,&Skelly Engineers t.t.p.1995 Mollusc biofouling monitoring during 1994 Donald C.Cook Nuclear Plant: Final Report.52 pp.Great Lakes Environmental Center.1996.A zebra mussel (Dreissena) monitoring survey for the Donald C.Cook Nuclear Plant.Final Report.37 pp.4-3 Lawler, Matusky&Skelly Engineers LLP 36

APPENDIX V SPECIAL REPORTS APPENDIX V.A No special reports were identified during the 1996 reporting period.  

APPENDIX VI ANNUAL REPORT: RADIOLOGICAL ENVIRONMENTAL MONITORING PROGRAM 1996  

~~~~~~~~~~~~~~~~~~~~~~~~~~~~~29 V.References

33 0 0 TABLE OF CONTENTS.(Cont)APPENDICES APPENDIX A-Radiological Environmental Monitoring Program Summary-1996....35 APPENDIX 3-Data Tables.40 APPENDIX C-Analytical Procedures Synopsis~~~~~o~67 APPENDIX D-Summary of EPA lnterlaboratory Comparisons

TABLE OF CONTENTS (Cont)LIST OF FIGURES 1.Onsite REMP Monitoring Locations 2.Offsite REMP Monitoring Locations 3.Fish Sampling Locations....4.Milk Farm Survey Table 5.Residental Land Use Survey Table............

6.Milk Farm Survey Map Residential Survey Map 12 13 14.114 115 116 117 LIST OF TRENDING GRAPHS Average Monthly Gross Beta in Air Particulates

....17 Direct Radiation-Quarterly TLD's Tritium in Groundwater Tritium in Drinking Water..EPA Cross Check Program Quality Control TLDs..~~~~~~~~~~~~o 20 22~~~~~~~~~26.83~~~~~~~~~~~~~~~~~~~~~~~~~1 37 0

LIST OF TABLES TABLE TITLE PAGE B-l Concentrations of Gross Beta Emitters in Weekly..................

41 Airborne Particulates B-2 Concentrations of Gamma Emitters in Quarterly....................

45 Composites of Airborne Particulate Samples B-3 Concentrations of Iodine-131 in Weekly Air Cartridge...............

47 Sample's B-4 Direct Radiation Measurements

-Quarterly TLD Results.............

51 B-5 Concentrations of Iodine, Tritium and Gamma Emitters in Surface Water 52 B-6 Concentrations of Tritium and Gamma Emitters in......~....~.....54 Groundwater B-7 Concentrations of Gross Beta, iodine, Tritium and.Gamma Emitters in Drinking Water 57 B-8 Concentrations of Gamma Emitters in Sediment..........59 B-9 Concentrations of Iodine and Gamma Emitters in Milk..............

60 B-10 Concentrations of Iodine and Gamma Emitters in..................

61 Broadleaf Vegetables B-11 Concentrations of Gamma Emitters in Fish 63 B-12 Concentrations of Gamma Emitters in Food/Vegetation

.64 B-13 Gamma Spec LLDs and Reporting Levels...65 iv  

INDIANA MICHIGAN POKER COMPANY DONALD C.COOK PO~R NUCLEAR PLANT RADIOLOGICAL ENVIRONMENTAL MONITORING PROGRAM  

INTRODUCTION  

I.INTRODUCTION 0 The Donald C.Cook Nuclear Piant's Radiological Environmental Monitoring Program (REMP)is conducted" in compliance with NRC Regulatory Guide 1.21 and 4.1, licensing commitments, and Technical Specifications.

The REMP was developed in accordance with the NRC Radiological Assessment Branch Technical Position (BTP), Rev.1, November 1979.A synopsis of the sampling program and maps can be found in Section II, Sampling and Analysis Program.This report represents the Annual Radiological Environmental Operating Report for Units 1 and 2 of the Donald C.Cook Nuclear Plant for the operating period from January 1, 1996 through December 31, 1996.A.The Donald C.Cook Nuclear Plant of American Electric Power Company is located on the southeastern shore of Lake Michigan approximately one mile northwest of Bridgm"n.Michigan.The plant consists of two pressurized water reactors, Unit 1, 1030 MWE and Unit 2, 1100 hAVE.Unit 1 achieved initial criticality on January 18, 1975 and Unit 2 achieved initial criticality on March 10, 1978.B Object'ives The objectives of the operational radiological environmental monitoring program are: l.Identify and measure radiation and radioactivity in the plant environs for the calculation of potential dose to the population.

2.Verify the effectiveness of in-plant measures used for controlling the release of radioactive materials.

3.Provide reasonable assurance that the predicted doses, based on effluent data, have not been substantially underestimated and are consistent with applicable standards.

4.Comply with regulatory requirements and Station Technical Specifications and provide records to document compliance.  

During 1996 the following changes were made to the Offsite Dose Calculation Manual (ODCM)The changes became effective on 10/22/96 and included: Adding an attachment which approved on-site storage of contaminated concrete Changed Unit Ventilation H-3 requirement from continuous to weekly grab samples.Removed emergency plan values-due to upcoming implementation of revised Emergency Action Levels (EAL).Clarified section describing collection of broadleaf vegetation samples in lieu of milk samples.Corrected error in numbering of electrical pole where TLD station&#xb9;OFT-11 is located.Eliminated the need for compensatory sampling of Essential Service Water (ESW)system when respective radiation monitors are inoperable unless the containment spray heat exchangers are in service.

II.SAMPLING AND ANALYSIS PROGRAM Table 1 summarizes the sampling and analysis program for the Donald C.Cook Nuclear Plant for l996.For each sample medium, the table lists the sample locations, including distance and direction from the center of the two units, and the station identification.

TABLE 1 DONALD C.COOK NUCLEAR PLANT-1996 ltAI)IOI.OGICAI SAMPLING STATIONS I>ISTANCI-:

AN(I I>Ilail'C.I ION I'ltOM I'LANT AXIS Loca Uon Distance Direction De rees Collection Pre ucnc Anal/uenc Environmental (TLD's)ONS.I ONS-2 ONS-3 ONS-4 ONS-5 ONS-6 (T.O I)(T-02)(T.03)(T-04)(T-05)(T-06)(T-07)(T-08)(T-09)(T-10)(T-I I)(T-12)I!)15 A.2:138 A.2407 A.1852 A.1895 A.1917 A.2103 A.2208 I\.1368 A.1390 A.1969 A.2292 ft.18'8o 90'18'8qo 210'6o 82'490 127'1'3'uarterly Direct Radiation/Quarterly New Buffalo South Bend Dowaglac Coloma (N BF)(SBN)(DOW)(COL)15.6 ml SSW 26.2 mt SE 24.3 ml EN E 18.9 ml NN E Intersection of Red Arrow Hwy.&Marquette Woods Rd, Pole&#xb9;B294-44 Stevensvllle Substatlon Pole&#xb9;B296-13 Pole&#xb9;B350-72 Intersection of Shawnee&Cleveland.

Pole&#xb9;B387-32 Snow Rd., East ol'Holden Rd.,&#xb9;B426-1 Brldgman SubstaUon Callfornla Rd., Pole&#xb9;B424-20 Ruggles Rd., Pole B369-214 IntersecUon of Red Arrow Hwy..&Hlldebrant Rd.,Pole&#xb9;B422-152 IntersecUon of Snow Rd.&Baldwin Rd., Pole&#xb9;B423-12 (OFT-I)(OFT-2)(OFT-3)(OI'T-4)(OFT-5)(OFT-6)(OFT-7)(OFT-8)(OFT-9)(OFT-10)4.5 ml N E 36 ml NE 51 ml NE 4.1 ml E 4.2 ml ESE 4 9 n>l SE 25 ml S 40 ml S 4.4 mi ESE 3.8 ml S (OFT-11)3.8 ml S

TABLE 1 I<>>>>i.l DONALD C.COOK NUCLEAR PLANT-1996 1th l)I()1.()(ilCA I.SA411'l.l N G STATIONS I)ISTAN(I:.ANI)I)II(ECTION FltOM l>IDENT AXIS Loca Uon Air Charcoal/Particulates StaUon Distance Dlrectlon De rees CollecUon Fre ucnc Anal Is/Fre uenc ONS.I ONS-2 ONS-3 ONS-4 ONS-5 ONS-6 New llunalo South (3cnd Oowaglac Coloma (A.I)(A-21 (A.:I)(A-4)(A.5)(A-6)(NI3F)(SBN)(Dow)(COL)I!)15>A.2:I:38 A.2107 A.1852 A.1895 n.1917 n.15.6 nil 26.2 ml 24.3 n)I 18.9 n)I SSW SE F.N E NNE 18'8o)0'IHo 18!)'10o Weekly Gross Beta/Weekly 1-131/Weekly Gamma Isotopic/Quarterly Composllc Groundwater Onslle Onslte Onslte Onslte Onslle Onsltc Onslte Onslte Onslte Onslte Onslte Onslte Onslte Onslte (W-I)(W-2)(W-3)(W-4)(W-5)(W-6)(W-7)=(W-8)(W-9)(W-10)(W-1 I)(W-12)(W-13)(W-14)=1969 A.2292 A.3279 ft.4 18 ft.404 I'.424 A.1895 ft.1279 I'.1447 A.4216 A.3206 n.2631 A.2152 A.1780 n.11'3o 107o 301 o 290'73'89'3'2'29'53 162'82'64 Quarterly Gamma Isotopic/Quarterly Trltlum/Quarterly Steam Generator Groundwater Steam Generator Storage Faclllty Steam Generator Storage Faclllty Steam Generator Storage Facility Steam Generator Storage Faclllty (SG-I)(SG-2)(SG-4)(SG-5)08 ml 0.7 m I 07 m I 07 ml.95'2o 93'20 Quarterly Gross Beta/Quarterly Gross Alpha/Quarterly Gamma Isotopic/Quarterly TABLE 1 (('urer I DONALD C.COOK NUCLEAR PLANT-1996 l(AI)IOI.()(ll(:Al.

SAMI'l.l NG STATIONS 1)ISTAN(E ANI)l)lltl'.C I ION FltOM I'IDENT AXIS Location Station Distance Dtrectlon Dc rees CoUcctton Fre ucnc Anal Is/Fre enc Drlnkln Water Sl.Joseph Public Intake Lake Townslrlp Ptrbllc Intake Station Surface Water ISTJ)!).0 nrl ILTW)0.4 nrl NF.S Dally Gross Beta/14 Day Com posit e Gamma Isotopic/14 Dny Composl te 1-131/14 Day Conrposltc Tritium/gtrartcrly Conrposllc Condenser Circulating Water Intake Lake Mlchlgan Shorellnc Lake Mlchlgan Shorcllne SWL-I Intake SWL-2 500 A.SWL-3 500 ft.S N Dally Gamn)a Isotopic/Monthly Composlle Tritium/guarterly Composltc C7~Sediment Lake Mlchlgan Shoreline Lake Mlchlgan Shorcllne SL-2 SL3 500 A.500 A.S N Scml-annually Gamma Isotopic/Scml-Annual Freehllng Farm Buchanan Mlle-Bac round (a)Freehl1ng 7.0 ml SE 14 Days Gamma Isotopic/Sample 1-131/Sample Wyant Farm Dowagalc Llvinghouse Farm La Porte Wyant 20.7 ml Llvlnghouse 20.0 ml E S 14 Days Gamma l~~toplc/Sample 1-131/Sample Broadleaf Ve etatton (a)3 Indicator Samples 1 Control Sample Wlthln 8 mlles ol'lant 15-25 mlles distant Hlghcst D/Q Land SectorMonthly when Less prevalent wind dlrectlon aval)able Gamma Isotopic'/Monthly 1-131/Monthly Ial No mtlk samples were obtained tn 1996 as 2 of 3 Indtcator farms dropped from program and no replacements could be found.Broadleaf vegctatton samples were obtained In ltcu of mt tk In 1996.

TABLE 1 I('o>>l.l DONALD C.COOK NUCLEAR PLANT-1996 l(AI)I()I.O(<<ICAI.

SAMI'I,ING STATIONS l)IS I'AN(I:.r Nl)l)II<I:.C1 ION I:feOM I IDENT AXIS Location Station Distance Direction De rccs Collection Frc ucnc Anal is/ucnc I'Ikc Michigan I>kc Mlclilgan I'ikc Mlclilgan I eke Mlcl>i@an ONS-N ONS.S OPS-N Ol'S-S.:I a>l a3.5>>ll 5.0 all S S 2/year Gamma Isotopic/2 per year Gra s/Broadleaf Ncarcst sample lo Plant In highest D/Q land sector contalnlng media.~Gra<<<<In a land sector contalnlng grapes approximately 20 mlles from the Plant In one of the less prevalent D/Q land sectors.Sector D Sector K At time ol harvest At time of harvest Gamma Isotopic at time of harvest.Gamma Isotopic at Umc of harvest.Composite samples of Drinking and Surface.water shall be collected at least.dally.Particulate sample filters should be analyzed for gross beta activity 24 or more hours following Alter removal.This will allow for radon and thoron daughter decay.If gross beta activity In air or water Is greater than IO times the yearly mean of control samples lor any medium, gamma Isotopic analysis should be performed on the individual samples.Please note the following defenltlons:

IVeekly at least once every seven (7)days Monthly-at least once every (3I)days Quarterly-at least once every ninety-two (92)days Semi-annually

-at least once every one hundred eighty-four (184)days

On-@i te HEMP Monitoring Locclt ions c)'II TLO T-O I TLD T-02 AIR ONS-2 h~.c Ys.a~'B TLD T-Ol AIR ONS-I C c WELL'w-2!SVRFACE WATER (SWL-3l SEOIHENT (SL-3(WELL w-I iLD wE(.L w-9 TLD T-I2~(TLD T-O Ii ('LL SG-S WELL SG-2 I ELL SG-I~//AIR 0NS-3 WELL w 4 WELL w 5 SURFACE WATER (SWL-Il I~o o (l U'WEl.l.w-0 WELL SG-4 c I sELL w-6 SvoFACE vA(ER (SWL-2(~SEDI((E((((5<-2((LD I 05 AIR D((5 5 I TLO T-AIR O((5-6 ((~~.1 r TLO T-IO TLO T-09 tLD T-04 ,~~~AIR ONS-4/wELL w-IO~J)WELL w-l3 WELL w-I I LAKE TwP WELI.LEGEND ONS I ONS-6(Alr Soeo((no Stations T-Ol-'-I2: TLD Sano(ino Stations V-I-r-I~(REHP T/5 Grovndsote(Wells SG-I, SG-2, SG-4, SG-5(REHP Non T/5 Groundsoter

'Wells SWL-I,2.3: 5~tace Water Soso((no Stat(one SL-2, 3: Sediment Sow(in((Stat(one 12

LEGE<O GffSITE REIC'GHIIORIHG LOCAII bye<o<vv<o A<rvlLO<ocot<o~0<<~II~ILO<ocr<i vv OOC<,Or<VV<O H>>a faraa Oi<va<oo votre<ocot<o~I~<CO<a>HI<a fO aa CQ.OHA St<OSSASIOH

~<SAC<<GROS<HO AIR<<ILO ICCC I Vrvr'R y O<f I Ac p st<<Is<as<OH O A C a Go O<pCS~11 f ISO oclf I 4~Of<<<~Sl.JOSE<a<S I.yATER TREAT%HI RAHI<ST J<ac<~V VAIC~Car I'>>A<<(1 I t~~<HH<sac tao<t<V(H at(R GH<S<I SLO (F'I~~SLO Ofl e<TLO Gf I~RS TLO tFT R~$<I r(HS I<I I (TLO Gf T.oa TLO O'RS D.c, co<a<H<sLIAA IS>>,<Q LA<<E SoyHS>>lo yATER TREAT~HI RAHI<Lly<IL Of I~OA IGG<<av SS Ofl:<R~ILO as~II'ILO Gf I~ILO Ofl S(MPH S<H<<<CS HILLBUsG$L~AIRE/////ILES~I<S a<re<>>a\1 I OOvAG<AC St<BSTAIIOH OACKGRO<<HO AIR I ILO tv<~AGIAC OACRGRGs<HO f AA VIC ysAHI LAAGR<E OICaGAGLrCS f~~~Llyl Cr Gs<SE~<<<ac~a>><a SOUTH BEIe RAN<A<<EE STAIIO<daeva<(Ape<

AIR I TLO<S<TH<13 I')$~~g J$l I l.,;8%@rK~.II'/~i'.P~gp.48%<g]'Klli.:i.aR 1.i/%7=.~J Kl&~~,-s.a

III.

AND DISCUSSION OF 1996 ANALYTICAL RESULTS 15  

III.

AND DISCUSSION OF 1996 ANALYTICAL RESULTS A discussion of the data from the radiological analyses of environmental media collected during the report period is provided in this section.Analyses of samples for 1996 were analyzed by Teledyne Brown Engineering, Inc.{TI)in Westwood, New Jersey.The procedures and specifications followed at Teledyne Brown Engineering are in accordance with the Teledyne Brown Engineering Quality Assurance Manual and are explained in the Teledyne Brown Engineering Analytical Procedures.

A synopsis of analytical procedures used for the environmental samples are'roved in Appendix C.In addition to internal quality control measures performed by Teledyne, the laboratory also participates in the Environmental Protection Agency's Interlaboratory Comparison Program.Participation in this program ensures that independent checks on the precision and accuracy of the measurements of radioactive material in environmental samples are performed.

The results of the EPA Interlaboratory Comparison are provided in Appendix D.Radiological analyses of environmental media characteristically approach and frequently fall below the detection limits of state-of-the-art measurement methods.Teledyne Brown Engineering analytical methods meet or exceed the Lower Limit of Detection{LLD)requirements given in Table 2=f the USNRC Branch Technical Position of Radiological Monitoring, Revision l.November 1979.The following is a discussion and summary of the results of the environmental measurements performed during the reporting period.Comparison is made where possible with radioactivity concentrations measured in the preoperational period of August 1971 to the initial criticality of Unit 1 on January 12, 1975.A brief summary of the preoperational program is found in Appendix G.A.Airborne Particulates Airborne particulate samples are collected with an oil less pump at approximately 56 LPM using a 47 mm particulate filter.Results of 16 0

Trending Graph-1 AYERAGE MONTHLY GROSS BETA IN AIR PARTICULATES 40 a.35 L a.30 O O O 25 O O 20 O O 15 10 0 5 Qi (ot 0 0 1/89 7/89 1/90 7/90 1/91 7/91 1/92 7/92 1/93 7/93 1/94 7/94 1/95 7/95 1/96 7/96 Indicators

~--e'--Controls gross, beta activities are presented in Table B-l.The measurement of the gross beta activity on the weekly air particulate filters is a good indication of the levels of natural and or manmade radioactivity in the environment.

The average gross beta concent.ation of the six indicator locations was 0.020 pCi/m~with a range of individual values between 0.007 and 0.036 pCi/m~.The average gross beta concentration of the four control locations was 0.020 pCi/m~with a range between 0.007 and 0.033 pCi/m~.In.Trending Graph 1 the., monthly average gross beta concentrations for the indicator locations and for the control locations are plotted.The gross beta concentrations in air particulate filters in 1996 were lower than at the end of the preoperational period when the effects of recent atmospheric nuclear tests were being detected.Air particulate filters were composited by location on a quarterly basis and were analyzed by gamma ray spectroscopy.

Results are presented in Table B-2.Beryllium-7, which is produced continuously in the upper atmosphere by cosmic radiation, was measured in all forty samples.The average concentration for the control locations was 0.128 pCi/m~and the values ranged from 0.088 to 0.154 pCi/m~.The average concentration for the indicator locations was 0.139 pCi/m~with a range of 0.075 to 0.195 pCi/m.These values are typical of beryllium-7 measured at various locations throughout the United States.Naturally occurring potassium-40 was measured in seven of the twenty-four indicator quarterly composites with an average concentration of 0.005 pCi/m~and a range of 0.004 to 0.009 pCi/m~.Potassium-40 was measured in four of the sixteen control quarterly composites with a concentration of 0.004 pCi/m~and a range of 0.003 to 0.004 pCi/m~.No other gamma emitting radioactivity was detected.B Airborne iodine Airborne iodine samples are collected with an oil less pump at approximately 56 LPM using a charcoal filter cartridge.

Charcoal cartridges are installed downstream of the particulate filters and are used to collect airborne radioiodine.

The results of the weekly analysis 18  

of the charcoal cartridges are presented in Table 8-3.All results were below the lower level of detection of 0.07 pCi/m with no positive activity detected.C.Direct Radiation-Thermoluminescent Dosimeters Thermoluminescent dosimeters (TLDs)measure external radiation exposure from several sources including naturally occurring radionuclides in the air and soil, radiation from cosmic origin, fallout from atomic weapons testing, potential radioactive airborne releases from the power station and direct radiation from the power station.The TLDs record exposure from all of these potential sources.The TLDs are deployed quarterly at 27 locations in the environs surrounding the D.C.Cook Nuclear Plant.The average value of the four areas of each dosimeter (calibrated individually after each field exposure period for response to a known exposure and for transit exposure)are presented in Table B-4.Those exposure rates are quite typical of observed ra'tes at many other locations in the country.The average annual measurement, for the control samples was 4.34 mR/standard month with a range of 3.0 to 6,6 mR/standard month.The annual accumulation of indicator samples had a measurement of 4.17 mR/standard month with a range of 2.8 to 6.6 mR/standard month.The 1996 annual average in the environs of the Donald C.Cook Nuclear Plant is at the low range of the exposure rat~~(1.0 to 2.0 mR/week)measured during the preoperational period.The results of the indicator and control TLDs are in good agreement and are plotted in Trending Graph 2.D.Surface Water A 125 milliliter surface water sample is collected from the intake forebay and from two shoreline locations, all within 0.3 mile of the two reactors and were composited daily over a monthly period.The thirty samples were analyzed for iodine-131 by the radiochemical technique described on page 73.All results were less than the lower limit of detection of 1 pCi/l.'I'he quarterly composite was analyzed for 19 J

tritium by liquid scintillation method described on page 70.Results are presented in Table B-5.Tritium was detected in 2 of the 10 samples analyzed with an average concentration of 520 pCi/liter and a range of 130 to 910 pCi/liter.

Trending Graph-3 TRITIUM IN GROUNDWATER 1980 1982 1984 1986 1988 1990 1992 1994 4/95 10/95 4/96 10/96

Trending Graph-3 (Cont.)TRITIUVi IN GROUNDWATER 10000 8000!CL 0 M 0 6000 CI I 0)0 CL C M C 4000 2000 1980 1982 1984 1986 1988 1990 1992 1994 4/95 10/95 4/96 10/96 Well-4 W:II-5 Well-6 Well-7  

'l6000 (6 CL O CL O 0 0 V O I U CL 0)12000 8000 4000 0 1/92 1/93'/94 1/95 1/96 Well 14 added to the program in 1993.No sample collected January 1994.Well 8~Well 9 M Well 10~Well 11 M Well 12 M Well 13~Well 14 Daily samples are collected at the intake of the purification plants for St.Joseph and Lake Township.The 500 ml daily samples at each location are composited and analyzed for gross beta, iodine-131, and gamma emitters.On a quarterly basis the daily samples are composited and analyzed for tritium.The results of analyses of drinking water samples are shown in Table 3-7.Gross beta activity was measured in all twenty-six samples from the Lake Township intake with an average concentration of 3.41 pCi/liter and a range from 2.1 to 5.1 pCi/liter.

No gamma emitting isotopes or iodine-131 were detected.Tritium was not measured in any of the four samples from either location.Tritium (or LLD values)in drinking water are plotted in Trending Graph 4.There were no drinking water analyses performed in the preoperational program.G.~edimen i S.dtment samples are cnllected semiannually along the shoreline of Lake Michigan at the same two locations as the surface water samples.Two liters of lake sediment are collected using a small dredge in an area covered part time by wave action.The sediment samples are analyzed by gamma ray spectroscopy, the results of which are shown in Table B-8.In April and October one sample was collected from location SL-2 and SL-3.Gamma ray spectroscop de etected naturally occurring potassium-40 in all four samples.The ray spec roscopy average potassium-40 concentration was 4695 pCi/kg (dry weight)with a range from 3420 to 6510 pCi/kg (dry weight).Thorium-228, also naturally occurring was measured in all samples with an average concentration of 443 pCi/kg (dry weight)with a range from 91.8 to 846 pCi/kg (dry weight).Radium-226 was measured in two samples 25 Trending Graph-4 TRITIUM IN DRINKING WATER 2000 CL 1500 0 CL O 0 O O 1000 L 500 0 a4" 4 4 p)+<<+r.<<~.<<~.<<~.<<~.<<~<<.~<<.+<<<<~'"qy'<<<<~<<<<<<t"'~,~'i'01/89 07/89 01/90 07/90 01/91 10/91 4/92 10/92 4/93 10/93 4/94 10/94 4/95 10/95 4/96 10/96~~~~"4~~~~~Lake Township St.Joseph

with an average activity of 667 pCi/kg and a range of 440 to 894 pCi/kg (dry weight).All other gamma emitters were below the lower limits of detection.

IV.CONCLUSIONS The results of the 1996 Radiological Environmental Monitoring Program for the Donald C., Cook Nuclear Plant have be.n presented.

The results were as expected for normal environmental samples.Naturally occurring radioactivity was observed in sample media in the expected activity ranges.J Occasional samples of a few media showed the presence of man-made isotopes.These have been discussed individually in the text.Observed activities were at very low concentrations and had no significant dose consequence.

Specific examples of sample media with positive analysis results are discussed below.Air particulate gross beta concentrations of all the indicator locations for 1996 appear to follow the gross beta concentrations at the control locations.

The concentration levels are actually lower than during the preoperational period.Gamma isotopic analysis of the particulate samples identified the gamma emitting isotopes as natural products (beryllium-7 and potassium-40).

No man-made activity was found in the particulate media during 1996.No iodine-131 was detected in charcoal filters in 1996.Thermoluminescent dosimeters (TLDs)measure external gamma radiation from naturally occurring radionuclides in the air and soil, radiation from cosmi~~rigin and fallout from atmospheric nuclear weapons testing, and radioactive airborne releases and direct radiation from the power plant.The average annual TLD results were at normal background exposure levels.Surface water samples are collected daily from the intake forebay and two locations in Lake Michigan.The samples are analyzed quarterly for tritium.and monthly for gamma emitting isotopes.No gamma emitters were detected during 1996.Tritium was measured and the concentrations were at normal background levels.Groundwater samples were collected quarterly at fourteen wells, all within 4300 feet of the reactors.The three wells within-500 feet had measurable tritium which is attributed to the operation of the plant.The highest concentration measured in 1996 was 14000 pCi/liter while the 30 0

The increased tritium concentration is attributed to draining portions of the Component Cooling Water (CCW)system to the turbine room sump which discharges into the onsite absorption pond.Well W-14 is adjacent to the pond and monitors the aquifer at this location.Potassium-40, a naturally occurring nuclide was not observed during 1996.No other gamma emitting isotopes were detected.Samples are'collected daily at the intakes of the drinking purification plants for St.Joseph and Lake Township.Samples composited daily over a two week period are analyzed for iodine-131, gross beta, and measured for gamma emitting isotopes.Samples are also analyzed quarterly for tritium.No iodine-131 or gamma emitting isotopes were detected.Gross beta was measured in all fifty-two samples at normal background concentrations.

Tritium was not measured in any of the eight quarterly composite samples collected during 1996.Sediment samples can be a sensitive indicator of discharges from-nuclear power stations.Sediment samples are collected semiannually along the shoreline of Lake Michigan at two locations in close proximity of the reactors.The samples were analyzed by gamma ray spectroscopy and only naturally occurring gamma emitters were detected.There is no evidence of station discharges affecting Lake Michigan, either in the sediments or in the water.as previously discussed.

M ilk samples were not analyzed during 1996 due to lack of participants in the program.Broadleaf sampling was performed in lieu of milk collection in 1996.Cesium-137 was measured in 7 of 31 broadleaf samples.No other gamma emitting isotopes were measured in broadleaf samples in 1996.Fish samples collected in Lake Michigan in the vicinity of the nuclear plant.were analyzed by gamma ray spectroscopy.

The only gamma emitting isotope measured was cesium-137 which was found in low concentrations in five samples.31 Food products, consisting of grapes, and broadleaf vegetation were collected and analyzed by gamma ray spectroscopy.

Based on the evidence of the Radiological Environmental Monitoring Program the Donald C.Cook Nuclear Plant is operating within regulatory limits.Tritium in seven on-site wells appears to be the only radionuclide which can be directly correlated with the plant.However the associated groundwater does not provide a direct dose pathway to man.32 V.REFERENCES 33

and Reporting Radioactivity in Solid Wastes and Releases of Radioactive Materials in Liquid and Gaseous Effluents from Light-Water-Cooled Nuclear Power Plants, April 1974.6.United States Nuclear Regulatory Commission, Regulatory Guide 1.4"Programs for Monitoring Radioactivity in the Enilrons of Nuclear Power Plants", April 1975.7.USNRC Branch Technical Position,"Acceptable Radiological Environmental Monitoring Program", Rev.1, November 1979.34 APPENDIX A RADIOLOGICAL ENVIRONMENTAL MONITORING PROGRAM  

35 RADIOLOGICAL ENVIRONMENTAL MONITORING PROGRAM  

INDIANA MICHIGAN POWER COMPANY-DONALD C.COOK NUCLEAR PLANT DOCKET NO.50-3I5/50-31,6 I!El<RIEN COUNlY JANUAI<Y I to DECEMBER 31.1996 MEDIUM OR PATIIWAY SAMPLF.D tUNIT OF MEASUREMENTI ANA Y.AND TOTAL NUMIIER OF ANALYSES PERFORMED.I FAN Ia/I>I.IANGE I WITI I I N NAME MEAN DISTANCE AND D)RECTION RANGE NUMI3ER OF COlrfROL LOCATION NONROUTINE MEAN REPORI'ED RANGE MEASUREMENTS Alr Iodlnc (p C I/rr I3)1-131 525-(0/:3 I:I)-(0/2 13)Airborne Particulates (I E.03 pCI/nr3)Gross ficta 524 (Weekly)19.13(313/313)

ONS-I Orrslle 1945 ft.20.9(53/53) 19.7(212/212)

(7.2-36)(8.6-36)(7.0-33)Gamma Bc-7 40 139(24/24)

(74.7-195)QNS.6 Onslte 1917 ft.152(4/4),'104-195)128(16/16)

(88.3-I 54)K-40 40 5.0.9(7/24)

('3.95-9.39)ONS-2-Onsllc 2338 ft.7.06(2/4)(4.72-9.39)-