Chemistry Operating Procedure C-200,Rev 11, Odcm.

ML17227A700
Person / Time
Site:	Saint Lucie
Issue date:	04/27/1982
From:	Boissy G, Wethy C FLORIDA POWER & LIGHT CO.
To:
Shared Package
ML17227A699	List: ML17227A698 ML17227A700 ML17309A692
References
C-200-01, C-200-1, NUDOCS 9302010203
Download: ML17227A700 (276)
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Text

Page 1 of 180 FLORIDA POWER & LiGHT COMPANY ST. LUCIE PLANT CHEMISTRY PROCEDURE NO, C-200 REVISION 11

1.0 TITLE

OFFSITE DOSE CALCULATIONMANUAL(ODCM) 2,0 REVIEW AND APPROVAL:

Reviewed by Facility Review Group A til 22 1982 App d p d.. Pl d IM p A ril 27 1982 Revision 11 Reviewed by F R G 19 Approved by G. J. Boiss Plant General Manager 19 THIS PROCEDURE HAS BEEN COMPLETELY REWRITTEN) PLEASE READ ENTIRE PROCEDURE BEFORE PROCEEDING. /R11 S OPS DATE DOCT PROCEDURE DOC N C-200 SYS COMP COMPLETED ITM 11 9302010Z03 V301ZZ PDR ADOCK 05000335 PDR I i

Page 2 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OfF SITE DOSE CALCULATION MANUAL ODCM INDEX PAGE INTRODUCTION .......,...,...., ~............,.......... ~...... 7 CONTROLS SECTION DEFINITIONS FOR CONTROLS SECTION ~ ~ ~ 9 1 1

~ ACTION ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ 9 1.3 CHANNEL FUNCTIONAL TEST......., .. 9

...,.... ~....,

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1.5 CHANNEL CALIBRATION . . ~ ~ ~ 9

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1.6 CHANNEL CHECK .. 9 1.10 DOSE EQUIVALENT I-131 10 1.13 FREQUENCY NOTATION,.........,...... .. 10 1.16 MEMBER(S) OF THE PUBLIC.............. .. 10 1.17 OFFSITE DOSE CALCULATIONMANUAL..... ., 10 1,18 OPERABLE - OPERABILITY,.....,,....... .; 11 1.19 OPERATIONAL MODE - MODE,.....,...... ., 11

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.1.23 PURGE- PURGING . ~ 11 1.25 RATED THERMAL POWER, ~... .. ~ ~ ~...... ,. 11 1.27 REPORTABLE EVENT .... .. 11 1.30 SITE BOUNDARY... .. 12 1.33 SOURCE CHECK ............ .,........

~ ~ . 12 1.35 THERMAL POWER...... ~....., ~......., .. 12 1.38 UNRESTRICTED AREA .. 12 1.39 VENTILATIONEXHAUST TREATMENT SYSTEM ,. 12 1.40 VENTING . ~ ~..........,..., . ~ ~........ .. 13 1.41 WASTE GAS HOLDUP SYSTEM .. ~..... ~... ,. 13

,3/4 CONTROLS AND SURVEILLANCE REQUIREMENTS . ~..., . ~..... 15 3/4.0 APPLICABILITY ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ 15 INSTRUMENTATION RADIOACTIVE LIQUID EFFLUENT MONITORING INSTRUMENTATION .... 16 RADIOACTIVEGASEOUS EFFLUENT MONITORING INSTRUMENTATION .. 21 3/4.11 RADIOACTIVE EFFLUENTS e

3/4.11,1 LIQUID EFFLUENTS CONCENTRATION .. 28 DOSE . .. 32 LIQUID RADWASTE TREATMENT..... ~ ~ ~

e ~ e

~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ . 33 I

Page 3 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM INDEX CONTROLS SECTION PAGE CONTROL AND SURVEILLANCE STATEMENTS FOR CONTROL SECTION 3/4.11 RADIOACTIVE EFFLUENTS (Continued) 3/4.11,2 GASEOUS EFFLUENTS DOSE RATE ~ ~ ~ ~" ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ .. 34 DOSE NOBLE GAS ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ .. 38 DOSE - IODINE-131, IODINE-133, TRITIUMS, AND RADIONUCLIDES IN PARTICULATE FORM .. 39 GASEOUS RADWASTE TREATMENT ............... .. 40 3/4.11.3 (NOT USED) 3/4.11.4 TOTAL DOSE . ~....,......... ~ . ~.............. ~ ~ ~ ~ ~ ~ 42 3/4.11.5 MAJOR CHANGES TO RADIOACTIVE LIQUID, GASEOUS AND SOLID WASTE TREATMENT SYSTEMS (ADMINISTRATIVECONTROL) ~ ~ ~ ~ ~ ~ 44 3/4.11,6 ANNUAL RADIOACTIVE EFFLUENT RELEASE REPORT TO THE COMMISSION (ADMINISTRATIVECONTROL) ~ ~ ~ ~ ~ ~ 45 3/4.12 RADIOLOGICALENVIRONMENTALMONITORING 3/4.12.1 MONITORING PROGRAM ........................ .. 48 3/4.12.2 LAND USE CENSUS ........... ~........ ~ ~ .. ~... . ~ 57 3/4.12,3 INTERLABORATORYCOMPARISON PROGRAM,....... .. 59 3/4.12.4 ANNUALRADIOLOGICAL ENVIRONMENTALOPERATING REPORT (ADMINISTRATIVECONTROL) ............. ~ ~ ~ ~ ~ ~ 60 BASES for CONTROLS SECTION 3/4.11 RADIOACTIVE EFFLUENTS 3/4.3.3.9 INSTRUMENTATION.......... ~..... . . 62

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3/4.11.1 LIQUID EFFLUENTS ~ .. 63 3/4.11.2 GASEOUS EFFLUENTS ... 65 3/4.11.3 (NOT USED) 3/4.11.4 TOTAL DOSE . ~............... ~ ~.... ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ 68 3/4.12 RADIOACTIVE ENVIRONMENTALMONITORING 3/4.12.1 MONITORING PROGRAM .. ~............ ~........... .. 70

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3/4.12.2 LAND USE CENSUS ~... .,... 70

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3/4.12,3 INTERLARORATORY COMPARISON PROGRAM 71

Page 4 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM INDEX CONTROLS SECTION PAGE LIST OF FIGURES for CONTROLS SECTION FIGURE 1-1 SITE AREA MAP & ENVIRONMENTALSAMPLE LOCATIONS,... 177 1-2 ENVIRONMENTALSAMPLE LOCATIONS (10 MILES) ..., . ~ ., .. 178 LIST OF TABLES for CONTROLS SECTION 1-1 FREQUENCY NOTATION 14 3,3-12 RADIOACTIVE LIQUID EFFLUENT MONITORING INSTRUMENTATION ... ~........... .. 17 3.3-13 RADIOACTIVE GASEOUS EFFLUENT MONITORING INSTRUMENTATION .............., ~ ~ 22 3,12-1 RADIOLOGICAI ENVIRONMENTALMONITORING PROGRAM .. ~ .. 50 3.12-2 REPORTING LEVELS FOR RADIOACTIVITYCONCENTRATIONS IN ENVIRONMENTALSAMPLES,........., ., ., 53 4.3-8 RADIOACTIVE LIQUID EFFLUENT MONITORING INSTRUMENTATION SURVEILLANCE REQUIREMENTS ., 19 4.3-9 RADIOACTIVE GASEOUS EFFLUENT MONITORING INSTRUMENTATION SURVEILLANCE REQUIREMENTS ., 25 4.11-1 RADIOACTIVE LIQUID WASTE SAMPLING AND ANALYSIS PROGRAM....... .. 29 4.11-2 RADIOACTIVEGASEOUS WASTE SAMPLING AND ANALYSIS PROGRAM .. 35 4.12-1 DETECTION CAPABILITIES FOR ENVIRONMENTALSAMPLE ANALYSIS LOWER LIMITOF DETECTION (LLD) ..... ~....., . .. 54

Page 5 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO, C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM INDEX METHODOLOGY SECTION PAGE Glossary for Methodology Section . ~ .,... ~ ~... ~.... ..,, .,......~ . ~ 73 1.0 LIQUID RELEASES METHODOLOGY . ~ .,,...,,..., .,....., . ~ . 76 1.1 Radioactive Liquid Effluen Model Assumptions .... ~ ~ ~ ~ ~ ~ ~ ~ 77 1.2 Determining'the Fraction (F) of 10 CFR Part 20 MPC Limits for a LIquid Release Source ........... ~ ~ ~ ~ ~ ~ ~ ~ 78 1.3 Determining Setpolnts for Radioactive Liquid Effluent Monitors ............................ ~ ~ ~ 81 1.4 Determining the Dose for Radioactive Liquid Releases . ~ ~ ~ 83 1.5 Projecting Dose for Radioactive Liquid Effluents...... ~ ~ o'7 2.0 Radioactive Releases of Gaseous Effluents ................, . ~ ~ ~ 88 2.1 Gaseous Effluent Model Assumptions . . ~ . 89 2.2 Determining the Whole Body and Skin Dose Rates for Noble Gas Releases and Establishing Setpolnts for Effluent Monitors.......................... ~ ~ ~ ~ ~ ~ ~ ~ 90 2.3 Determining the Radioiodine and Particulate Dose Rate to Any Organ From Gaseous Releases ..... ~ ~ ~ ~ ~ ~ ~ ~ 97 2.3.1 Inhalation .........., ~.......,.... ~ ~ ~ 99 2.3.2 Ground Plane .. ,. 101 2 3s3 Milk .. 102

~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~

2 .3.4 Tritium ~ .,. .. 104 2.3.5 Total Dose Rate by Release Source.............. , ~ 106 2.4 Determining the Gamma Air Dose for Radioactive Noble Gas Releases ... 106 2.5 Determining the Beta Air Dose for Radioactive Noble Gas Releases ..................-... ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ 1 10 2.6 Determining the Radioiodine and Particulate Dose to Any Organ From Cumulative Releases,..... ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ 1 12 DISCUSSION 2.6.1 .Inhalation ....... ~....... ~........ .. 115 2.6.2 Ground Plane .... ~...,... ~ .. '...... .. 116 2 6s3 Milk

~ ~ ~ ~ ~ ~ ~ ~ o ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ,. 117 2.6.4 Tritium (All pathways) .. 118

'..;............... ~ ~ ~ ~ ~ ~ ~ ~ ~

2,6.5 Total Organ Do'~r~ .. 119 2.7 Projecting Dose f<-. r".c."."'.;:!I.r i::;-:.-::,. f-fstusnl~: ~ ~ ~ ~ ~ ~ ~ ~ 120

Page 6 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM INDEX METHODOLOGY SECTION PAGE 3.0 40 CFR 190 Dose Evaluation.......................... ~.... 121 4.0 Annual'Report Format .............,...................... 122 Appendix A - MPC, Dose Factor and Historical Meteorological Tables ......................... ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ 1 38 Appendix B - Limited Analysis Dose Assessment for Liquid Radioactive Effluents .. ~... ~... ~........... . 165 Appendix C - Technical Bases for Effective Dose Factors ~.... . 167 Appendix D - Technical Bases for Eliminating Curie inventory Limit for Gaseous Waste Storage Tanks...... ~...... 171 Appendix E - Current R.E,M. Sample Point Locations ........ 173 Appendix F - Description of Meteorological Dispersion Formulas Utilized for Historical Data and Methodology for Determining Actual MET Data .. ~... ~... ~...... ~ . ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ 1 79

Page 7 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM INTRODUCTION The ODCM consists of the Controls Section followed by the Methodology Section.

The Controls Section provides the Control Statements, Limits, ACTION Statements, Surveillance Requirements, and BASES for ensuring that Radioactive Liquid and Gaseous Effluents released to UNRESTRICTED AREAS and/or the SITE BOUNDARY will be maintained within the requirements of 10 CFR Part 20, 40 CFR Part 190, 10 CFR 50.36.a, and 10 CFR Part 50 Appendix-I radioactive release criteria. All Control Statements and most Administrative Control Statements in the ODCM are directly tied to, and reference the Plant Technical Specification (TS) Administrative Section. The Administrative Control for Major Changes to Radioactive Liquid, Gaseous and Solid Treatment Systems is as per the guidance of NUREG-1301, April 1991, Supplement No. 1 to NRC Generic Letter 89-01. The numbering sequences of Control Statements also follow the guidance of NUREG-1301 as applicable, to minimize differences.

The Methodology Section uses the models suggested by NUREG-0133, November, 1978, and Regulatory Guide 1.109 to provide calculation methods and parameters for determining results in compliance with the Controls Section of the ODCM. Simplifying assumptions have been applied where applicable to provide a more workable document for implementing the

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Control requirements. Alternate calculation methods may be used from those presented as long as the overall methodology does not change or as long as most up-to-date revisions

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of. the Regulatory Guide 1.109 dose conversion factors and environmental transfer factors

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are substituted for those currently included and used in this document.

As per the Plant TS, all FRG approved changes to the ODCM, with required documentation of the changes, shall be submitted to the NRC in the Annual Effluent Release Report.

Procedures that directly implement, administer or supplement the requirements of the ODCM Controls and Surveillances are:

C-01 Schedule for Periodic Test C-02 Schedule for Test Calibrations C-70 Processing Aerated Liquid Waste C-72 Processing Gaseous Wastes C-201 Processing Meteorological Data for ODCM Applications The Radiological Environmental Monitoring Program is performed by the State of Florida as per FPL Juno Nuclear Operations Corporate Environmental Procedures.

Page 8 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM CONTROLS AND SURVEILLANCE REQUIREMENTS

"'.St; Lucie Plant ODCM Controls

Page 9 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM 1.0 DEFINITIONS for CONTROLS SECTION OF ODCM The defined terms of this section appear In capitalized type and are applicable throughout these Controls.

ACTION 1.1 ACTION shall be that part of a Control that prescribes remedial measures required under designated conditions, CHANNEL FUNCTIONAL TEST 1.3 A CHANNEL FUNCTIONALTEST shall be the injection of a simulated signal into the channel as close to the sensor as practicable to verify OPERABILITY of alarm, interlock and/or trip functions. The CHANNEL FUNCTIONAL TEST shall include adjustments, as

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necessary, of the alarm, interlock and/or Trip Setpoints such that the setpoints are within the required range and accuracy. ~

CHANNEL CALIBRATION 1.5 A CHANNEL CALIBRATIONshall be the adjustment, as necessary, of the channel output such that it responds with the necessary range and accuracy to known values of4he parameter which the channel monitors, The CHANNELCALIBRATIONshall encompass the entire channel including the sensor and alarm and/or trip functions, and shall include the CHANNEL FUNCTIONALTEST, The CHANNEL CALIBRATIONmay be performed by any series of sequential, overlapping, or total channel steps such that the entire channel is calibrated.

CHANNEL CHECK 1.6 A CHANNEL CHECK shall be the qualitative assessment of channel behavior during operation by observation. This determination shall include, where possible, comparison of the channel indication and/or status with other indications and/or status derived from independent instrument channels measuring the same parameter.

. -..""-> -~".~~Pi<':"'I-'lcr:t ODCM Controls

Page 10 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM 1.0 DEFINITIONS for CONTROLS SECTION OF ODCM DOSE EQUIVALENT I-131 1.10 DOSE EQUIVALENT I-131 shall be that concentration of l-131 (microCurie/gram) which alone would produce the same thyroid dose as the quantity and isotopic mixture of 1-131, l-132, l-133, l-134, and I-135 actually present. The thyroid dose conversion factors used for this calculation shall be those listed in [Table III of TID-14844, "Calculation of

'Distance Factors for Power and Test Reactor Sites" or Table E-7 of NRC Regulatory Guide 1.109, Revision 1, October 1977].

FREQUENCY NOTATION 1.13 The FREQUENCY NOTATION specified for the performance of Surveillance Requirements shall correspond to the intervals defined in Table 1.1.

MEMBER S OF THE PUBLIC 1.16 MEMBER (S) OF THE PUBLIC shall include all persons who are not occupationally

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associated with the plant. This category does not include employees of the licensee, its

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contractors, or vendors. Also excluded from this category are persons who enter the site

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to service equipment or to make deliveries. This category does include persons who use portions of the site for recreational, occupational, or other purposes not associated with the plant.

OFFSITE DOSE CALCULATION MANUAL 1.17 The OFFSITE DOSE CALCULATION MANUAL (ODCM) shall contain the methodology and parameters used in the calculation of offsite doses resulting from radioactive gaseous and liquid effluents, in the calculation of gaseous and liquid effluent monitoring Alarm/Trip Setpoints, and in the conduct of the Environmental Radiological Monitoring Program. The ODCM shall also contain (1) the Radioactive Effluent Controls and Radiological Environmental Monitoring Programs required by TS section 6.8.4g and (2) descriptions of the information that should be included in the Annual Radiological Environmental Operating and Annual Radioactive Effluent Release Reports required by TS 6.9.1.7 and 6.9.1.8.

St. Kg~i<,'@af<DCM Controls ~ >> ~ 0 , Mtg ~ ~ kg\

Page 11 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM 1.0 DEFINITIONS for CONTROLS SECTION OF ODCM OPERABLE - OPERABILITY 1.18 A system, subsystem, train, component or deVice shall be OPERABLE or have OPERABILITY when it is capable of performing its specified function(s), and when all necessaiy attendant instrumentation, controls, electrical power, cooling or seal water, lubrication or other auxiliary equipment that are required for the system, subsystem, train, component, or device to perform its function(s) are also capable of performing their related support function(s).

OPERATIONAL MODE - MODE 1.19 An OPERATIONAL MODE (l.eMODE) shall correspond to any one inclusive combination of core reactivity condition, power level, and average reactor coolant temperature specified in Table 1,2 of the St, Lucie Plant TS, PURGE - PURGING 1.23 PURGE or PURGING shall be any controlled process of discharging air or gas from a confinement to maintain temperature, pressure, humidity, concentration or other operating condition, in such a manner that replacement air or gas is required to purify the confinement.

RATED THERMAL POWER 1,25 RATED THERMAL POWER shall be a total reactor core heat transfer rate to the reactor coolant of 2700 MWt.

REPORTABLE EVENT 1.27 A REPORTABLE EVENT shall be any of those conditions specified in Section 50.73 of 10 CFR Part 50.

St. Lucie Plant ODCM Controls

Page 12 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM 1.0 DEFINITIONS for CONTROLS SECTION OF ODCM SITE BOUNDARY 1.30 The SITE BOUNDARY shall be that line beyond which the land is neither owned, nor leased, nor otherwise controlled by the licensee.

SOURCE CHECK 1.33 A SOURCE CHECK shall be the qualitative assessment of channel response when the channel sensor is exposed to a source of increased radioactivity.

THERMAL POWER 1.35 THERMAL POWER shall be the total reactor core heat transfer rate to the reactor

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coolant. ~

UNRESTRICTED AREA

.1.38 An UNRESTRICTED AREA shall be any area at or beyond the SITE BOUNDARY access to which is not controlled by the licensee for purposes of protection of individuals from exposure to radiation and radioactive materials, or any area within the SITE BOUNDARY used for residential quarters or for industrial, commercial, institutional, and/or recreational purposes.

VENTILATIONEXHAUST TREATMENT SYSTEM 1.39 A VENTILATIONEXHAUST TREATMENT SYSTEM shall be any system designed and installed to reduce gaseous radioiodine or radioactive. material in particulate form in eNuents by passing ventilation or vent exhaust gases through charcoal adsorbers and/or HEPA filters for the purpose of removing Iodines or particulates from the gaseous exhaust stream prior to the release to the environment. Such a system is not considered to have any effect on noble gas eNuents, Engineered Safety Features Atmospheric Cleanup Systems are not considered to be VENTILATION EXHAUST TREATMENT SYSTEM components.

St. Lucie Plant ODCM Controls

Page 13 of 180 ST, LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM 1.0 DEFINITIONS for CONTROLS SECTION OF ODCM VENTING 1.40 VENTING shall be the controlled process of discharging air or gas from a confinement to maintain temperature, pressure, humidity, concentration, or other operating condition, in such a manner that replacement air or gas is not provided or required during VENTING.

Vent, used in system names, does not imply a VENTING process.

WASTE GAS HOLDUP SYSTEM 1.41 A WASTE GAS HOLDUP SYSTEM shall be any system designed and installed to reduce radioactive gaseous effluents by collecting Reactor Coolant System offgases from the Reactor Coolant System and providing for delay or holdup for the purpose of reducing the total radioactivity prior to release to the environment.

St. Lucie Plant ODCM Controls

Page 14 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM TABLE 1.1 FRE UENCY NOTATION NOTATION FRE UENCY At least once per 12 hours1.388889e-4 days <br />0.00333 hours <br />1.984127e-5 weeks <br />4.566e-6 months <br />.

D At least once per 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br />.

W At least once per 7 days, 4/M* At least 4 per month at intervals of no greater than 9 days and minimum of 48 per year.

At least once per 31 days.

Q At lease once per 92 days.

SA At least once per 184 days.

At least once per 18 months.

Prior to each reactor startup.

N.A. Not Applicable.

P** Completed prior to each release

[~j

• For Radioactive Effluent Sampling

'* For Radioactive Batch Releases Only St. Lucie Plant ODCM Controls

Page 15 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM 3/4 CONTROLS AND SURVEILLANCE REQUIREMENTS 3/4.0 APPLICABILITY CONTROLS 3.0.1 Compliance with the Controls contained in the succeeding controls is required during the conditions specified therein; except that upon failure to meet the Control, the associated ACTION requirements shalt be met.

3.0.2 Noncompliance with a Control shall exist when the requirements of the Control and associated ACTION requirements are not met within the specified time intervals. If the Control is restored prior to expiration of the specified time intervals, completion of the ACTION requirements is not required.

SURVEILLANCE REQUIREMENTS 4.0.1 Surveillance Requirements shall be met during the conditions specified for individual Controls unless otherwise stated in an individual Surveillance Requirement.

4.0,2 Each Surveillance Requirement shall be performed within the specified time interval with:

a. A maximum allowable extension not to exceed 25% of the surveillance interval.

St. Lucie Plant ODCM Controls

Page 16 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM INSTRUMENTATION RADIOACTIVE LIQUID EFFLUENT MONITORING INSTRUMENTATION CONTROLS 3.3.3.9 In accordance with St. Lucie Plant TS 6.8.4.f.1), the radioactive liquid effluent monitoring instrumentation channels shown in Table 3.3-12 shall be OPERABLE with their Alarm/Trip Setpoints set to ensure that the limits of Control 3.11.1 1 are not exceeded. The

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Alarm/Trip Setpoints of these channels shall be determined and adjusted in accordance with the methodology and parameters in the OFFSITE DOSE CALCULATIONMANUAL(ODCM).

APPLICABILITY: At all times.

ACTION:

a. With a radioactive liquid effluent monitoring instrumentation channel Alarm/Trip Setpoint less conservative than required by the above control, immediately suspend the release of radioactive liquid effluents monitored by the affected channel, or declare the channel inoperable, or change the setpoint so it is acceptably conservative.

b. With less than the minimum number of radioactive liquid effluent monitoring instrumentation channels OPERABLE, take the ACTION shown in Table 3.3-12.

Restore the inoperable instrumentation to OPERABLE status within 30 days and, if unsuccessful, explain in the next Annual Radioactive Effluent Release Report why this inoperability was not corrected in a timely manner.

c. Report all deviations in the Annual Radioactive Effluent Release Report.

SURVEILLANCE REQUIREMENTS 4.3.3.9 Each radioactive liquid effluent monitoring instrumentation channel shall be demonstrated OPERABLE by performance of the CHANNEL CHECK, SOURCE CHECK, CHANNEL CALIBRATION,and CHANNEL FUNCTIONAL TEST at the frequencies shown in Table 4.3-8.

St. Lucie Plant ODCM Controls

Page 17 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM TABLE 3.3-12 RADIOACTIVE LI UID EFFLUENT MONITORING INSTRUMENTATION MINIMUM CHANNELS INSTRUMENT OPERABLE ACTION

1. Radioactivity Monitors Providing Alarm and Automatic Termination of Release a) Liquid Radwaste Effluen Line 35 b) Steam Generator Slowdown 1/SG 36 Effluent Line

2. Flow Rate Measurement Devices a) Liquid Radwaste Effluent Line N.A, 38 b) Discharge Canal N.A. 38 c) Steam Generator Blowdown N.A. 38 c~j Effluen Lines SG - Denotes Steam Generator St. Lucie Plant ODCM Controls

Page 18 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM TABLE 3.3-12 Continued ACTION STATEMENTS ACTION 35 - With the number of channels OPERABLE less than required by the Minimum Channels OPERABLE requirement, effluent releases may continue for up to 14 days provided that prior to initiating a release:

a. At least two independent samples are analyzed in accordance with the Surveillance Requirement for concentration limit of Control 4.11.1.1.1., and

b. At least two technically qualified members of the Facility Staff independently verify the release rate calculations and discharge line valving, Otherwise, suspend release of radioactive eNuents via this pathway.

ACTION 36 - With the number of channels OPERABLE less than required by the Minimum Channels OPERABLE requirement, eNuent releases via this pathway may continue for up to 30 days provided grab samples are analyzed for gross radioactivity (beta or gamma) at a limit of detection of at least 2.E-07 micro-Curie/ml:

a. At least once per 8 hours9.259259e-5 days <br />0.00222 hours <br />1.322751e-5 weeks <br />3.044e-6 months <br /> when the specific activity of the secondary coolant is greater than 0.01 micro-Curleslgram DOSE EQUIVALENT l-131, or

b. At least once per 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br /> when the specific activity of the secondary coolant is less than or equal to 0.01 micro-Curleslgram DOSE EQUIVALENT l-131.

ACTION 38 - Minimum system design flow of required running pumps shall be utilized for MPC calculations for discharge canal flow and maximum system design flow be utilized for MPC calculations for eNuent line flow.

St. Lucie Plant ODCM Controls

Page 19 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM TABLE 4.3-8 RADIOACTIVE LI UID EFFLUENT MONITORING INSTRUMENTATION SURVEILLANCE REQUIREMENTS CHANNEL CHANNEL SOURCE CHANNEL FUNCTIONAL INSTRUMENT CHECK CHECK CALIBRATION TEST

1. Radioactivity Monitors Providing Alarm and Automatic Termination of Release a) Liquid Radwaste Effluent R (2) Q (1)

Line b) Steam Generator R (2) Q (1)

Blowdown Effluent Line

2. Flow Rate Measurement Devices a) Liquid Radwaste Effluent D (3) N,A. Q Line b) Discharge Canal D (3) N.A. Q c) Steam Generator Q D (3) N.A.

Blowdown Effluent Line St. Lucie Plant ODCM Controls

Page 20 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM TABLE 4.3-8 Continued TABLE NOTATIONS (1) The CHANNEL FUNCTIONALTEST shall also demonstrate automatic isolation of this pathway and control room alarm annunciation occur if any of the following conditions exist:

1, Instrument indicates measured levels above the alarm/trip setpoint, or

2. Circuit failure, or

3. Instrument indicates a downscale failure, or

4. Instrument controls not set in operate mode.

(2) The initial CHANNEL CALIBRATION shall be performed using one or more of the reference standards traceable to the National Institute of Standards & Technology (NISQ or using standards that have been calibrated against standards certified by the NIST. These standards should permit calibrating the system over its intended range of energy and rate capabilities that are typical of normal plant operation, For subsequent CHANNEL CALIBRATION, button sources that have been related to the initial calibration may be used, (3) CHANNEL CHECK shall consist of verifying indication of flow during periods of release.

CHANNEL CHECK shall be made at least once per 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br /> on days on which continuous, periodic, or batch releases are made.

St. Lucie Plant ODCM Controls

Page 21 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM INSTRUMENTATION RADIOACTIVE GASEOUS EFFLUENT MONITORING INSTRUMENTATION CONTROLS 3.3.3.10 In accordance with St. Lucie Plant TS 6.8.4.f.1), the radioactive gaseous effluent monitoring instrumentation channels shown in Table 3.3-13 shall be OPERABLE with their Alarm/Trip Setpoints set to ensure that the limits of Control 3.11.2.1.are not exceeded.

The Alarm/Trip Setpoints of these channels shall be determined and adjusted in accordance with the methodology and parameters in the ODCM.

APPLICABILITY: As shown in Table 3.3-13 ACTION:

a. With a radioactive gaseous effluent monitoring instrumentation channel Alarm/Trip Setpoint less conservative than required by the above control, immediately suspend the release of radioactive gaseous effluents monitored by the affected channel, or declare the channel inoperable, or change the setpoint so it is acceptably conservative.

b. With less than the minimum number of radioactive gaseous effluent monitoring instrumentation channels OPERABLE, take the ACTION shown in Table 3.3-13.

Restore the inoperable instrumentation to OPERABLE status within 30 days and, if unsuccessful, explain in the next Annual Radioactive Effluent Release Report why this inoperability was not corrected in a timely manner.

\

c. Report all deviations in the Annual Radioactive Effluent Release Report.

SURVEILLANCE REQUIREMENTS 4.3.3.10 Each radioactive gaseous effluent monitoring instrumentation channel shall be demonstrated OPERABLE by performance of the CHANNEL CHECK, SOURCE CHECK, CHANNEL CALIBRATIONand CHANNEL FUNCTIONAL TEST at the frequencies shown in Table 4.3-9.

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St, Lucie Plant ODCM Controls

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N H

Page 22 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CAI CULATION MANUAL ODCM TABLE 3.3-13 RADIOACTIVE GASEOUS EFFLUENT MONITORING INSTRUMENTATION X

MINIMUM CHANNELS INSTRUMENT OPERABLE APPLICABILITY ACTION

1. Waste Gas Holdup System a) Noble Gas Activity Monitor-Providing Alarm and 1/Rx 45 Automatic Termination of Release

2. Condenser Evacuation System a) Noble Gas Activity Monitor 1/Rx 47 I<j l~~j

3. Plant Vent System a) Noble Gas Activity Monitor 1/Rx 47 (Low Range) b) Iodine Sampler 1/Rx 51 c) Particulate Sampler 1/Rx 51 d) Flow Rate Monitor N.A. 53 e) Sampler Flow Rate Monitor 1/Rx 46

4. Fuel Storage Area Ventilation System a) Noble Gas Activity Monitor 1/Rx 47 (Low Range) b) Iodine Sampler 1/Rx c) Particulate Sampler 1/Rx 51 d) Flow Rate Monitor N.A 53 e) Sampler Flow Rate Monitor 1/Rx 46 St. Lucie Plant ODCM Controls

Page 23 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM TABLE 3.3-13 Continued RADIOACTIVE GASEOUS EFFLUENT MONITORING INSTRUMENTATION MINIMUM CHANNELS INSTRUMENT OPERABLE APPLICABILITY ACTION

5. Laundry Area Ventilation System a) Noble Gas Activity Monitor 1/Rx 47 (Low Range) b) Iodine Sampler 1/Rx 51 c) Particulate Sampler 1/Rx 51 d) Flow Rate Monitor N.A. 53 e) Sampler Flow Rate Monitor 1/Rx 46

6. Steam Generator Blowdown Building Vent a) Noble Gas Activity Monitor 1/Rx 47 (Low Range) b) Iodine Sampler 1/Rx 51 c) Particulate Sampler 1/Rx d) Flow Rate Monitor 53 e) Sampler Flow Rate Monitor N.A.

46 (~j

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St. Lucie Plant ODCM Controls

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Page 24 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO, C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM TABLE 3.3-13 Continued TABLE NOTATIONS

- At all times while making releases via this pathway

- At all times when air ejector exhaust Is not directed to plant vent, Rx - Denotes reactor ACTION STATEMENTS ACTION 45 - With the number of channels OPERABLE less than required by the Minimum Channels OPERABLE requirement, the contents of the tank(s) may be released to the environment for up to 14 days provided that prior to initiating a release:

a. At least two independent samples of the tank's contents are analyzed, and

b. At least two technically qualified members of the facility staff independently verify the release rate calculations and discharge valve lineup.

Otherwise, suspend release of radioactive effluents via this pathway.

ACTION 46 - With the number of channel OPERABLE less than required by the Minimum Channels OPERABLE requirement, effluen releases via this pathway may continue for up to 30 days provided the flow rate is estimated at least once per 4 hours4.62963e-5 days <br />0.00111 hours <br />6.613757e-6 weeks <br />1.522e-6 months <br />.

ACTION 47 - With the number of channel OPERABLE less than required by the Minimum Channels OPERABLE requirement, effluent releases via this pathway may continue for up to 30 days provided grab samples are taken at least once per 8 hours9.259259e-5 days <br />0.00222 hours <br />1.322751e-5 weeks <br />3.044e-6 months <br /> and these samples are analyzed for isotopic activity within 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br />.

ACTION 51 - With the number of channel OPERABLE less than required by the Minimum Channels OPERABLE requirement, effluent releases via the affected pathway may continue for up to 30 days provided samples are continuously collected with auxiliary sampling equipment as required in Table 4.11-2.

ACTION 53 - Maximum system flows shall be utilized in the determination of the instantaneous release monitor alarm setpoint.

St. Lucie Plant ODCM Controls

Page 25 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM TABLE 4.3-9 RADIOACTIVE GASEOUS EFFLUENT MONITORING INSTRUMENTATION SURVEILLANCE REQUIREMENTS Modes in CHANNEL which CHANNEL SOURCE CHANNEL FUNCTIONAL surveillance INSTRUMENT CHECK CHECK CALIBRATION TEST required 1 Waste Gas Holdup

~

System a) Noble Gas Activity Monitor - Providing Alarm and R (3) Q (1)

Automatic Termination of Release

2. Condenser Evacuation System a) Noble Gas Activity R (3) Q (2)

Monitor

3. Plant Vent System a) Noble Gas Activity R (3) Q (2)

Monitor b) Iodine Sampler W ~

N.A. N.A. N.A.

c) Particulate Sampler W N.A. N.A. N.A.

d) Flow Rate Monitor N.A. Q e) Sampler Flow Rate N.A. R N.A.

Monitor

4. Fuel Storage Area Ventilation System a) Noble Gas Activity R (3) Q (2)

Monitor b) Iodine Sampler W N.A. N.A. N.A.

c) Particulate Sampler W N.A. N.A. N.A.

d) Flow Rate Monitor N.A. Q e) Sampler Flow Rate N.A. N.A.

Monitor St. Lucie Plant ODCM Controls

Page 26 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM TABLE 4.3-9 Continued RADIOACTIVEGASEOUS EFFLUENT MONITORING INSTRUMENTATION SURVEILLANCE REQUIREMENTS Modes in CHANNEL which CHANNEL SOURCE CHANNEL FUNCTIONAL surveillance INSTRUMENT CHECK CHECK CALIBRATION TEST required

5. Laundry Area Ventilation System a) Noble Gas Activity R (3) Q (2)

Monitor b) Iodine Sampler W N.A. N,A. N.A.

c) Particulate Sampler W N.A. N,A. N.A.

d) Flow Rate Monitor N.A. Q e) Sampler Flow Rate N.A. N.A.

Monitor 6, Steam Generator Blowdown Building Vent a) Noble Gas Activity R (3) Q (2)

Monitor b) Iodine Sampler W N.A. N.A. N.A.

c) Particulate Sampler W N.A, N.A. N.A.

d) Flow Rate Monitor N,A. Q e) Sampler Flow Rate N.A. N.A.

Monitor St. Lucie Plant ODCM Controls

Page 27 of 180 ST, LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM TABLE 4.3-9 Continued TABLE NOTATIONS

• - At all times when making releases via this pathway.

• ' At all times when air ejector exhaust is not directed to plant vent.

(1) The CHANNEL FUNCTIONALTEST shall also demonstrate automatic isolation of this pathway and control room alarm annunciation occurs if any of the following conditions exist:

1. Instrument indicates measured levels above the alarm/trip setpoint, or

2. Circuit failure, or

3. Instrument indicates a downscale failure, or

4. Instrument controls not set In operate mode.

(2) The CHANNEL FUNCTIONAL TEST shall also demonstrate that control room alarm annunciation occurs if any of the following conditions exist:

1 ~ Instrument indicates measured levels above the alarm/trip setpoint, or

2. Circuit failure, or

3. Instrument indicates a downscale failure, or 4, Instrument controls not set in operate mode.

(3) The initial CHANNEL CALIBRATION shall be performed using one or more of the reference standards traceable to the National Institute of Standards & Technology (NIST) or using standards that have been calibrated against standards certified by the NIST, These standards should permit calibrating the system over its intended range of energy and rate capabilities that are typical of normal plant operation. For subsequent CHANNEL CALIBRATION, button sources that have been related to the initial calibration may be used.

St. Lucie Plant ODCM Controls

Page 28 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM 3/4.11 RADIOACTIVE EFFLUENTS 3/4.11.1 LIQUID EFFLUENTS CONCENTRATION CONTROLS 3.11.1.1 In accordance with the St. Lucie Plant TS 6.8.4.f.2) and 3), the concentration of radioactive material released in liquid effluents to UNRESTRICTED AREAS (see TS Figure 5,1-1) shall be limited to the concentrations specified in 10 CFR Part 20, Appendix B, Table II, Column 2 for radionuclides other than dissolved or entrained noble gases. For dissolved or entrained noble gases, the concentration shall be limited to 2.E-04 micro-Curie/ml total activity.

APPLICABILITY: At all times.

ACTION:

a. With the concentration of radioactive material released in liquid effluents to UNRESTRICTED AREAS exceeding the above limits, immediately restore the concentration to within the above limits.

SURVEILLANCE REQUIREMENTS 4.11.1.1.1 Radioactive liquid wastes shall be sampled and analyzed according to the sampling and analysis program of Table 4.11-1.

4.11.1,1.2 The results of the radioactivity analyses shall be used in accordance with the methodology and parameters in the ODCM to assure that the concentrations at the point of

.release are maintained within the limits of Control 3,11.1.1 ~

4,11.1.1.3 Post-release analyses of samples composited from batch releases shall be performed in accordance with Table 4.11-1, and results of the previous post-release analyses shall be used with the calculational methods In the ODCM to assure that the concentrations at the point of release were maintained within the limits of Control 3.11.1 1.

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St. Lucie Plant ODCM Controls

Page 29 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM TABLE 4.11-1 RADIOACTIVE LIQUID WASTE SAMPLING AND ANALYSIS PROGRAM Minimum Lower Limit of Uquld Release Sampling Type of Activity Analysis Detection Type Frequency Analysis Frequency LLD (1) (pCI/ml)

A. Batch Waste p P.G.E. (3) 5.E%7 Release Each Batch Each Batch I-131 1,E%6 Tanks (2)

Dissolved and p Entrained 1.E%5 One Batch/M Gases (Gamma Emlttera)

'p M H-3 1.E%5 Each Batch Composite (4) Gross Alpha 1.E%7 p Q Sr%9, Sr-90 5.E48 Each Batch Composite (4) Fe-55 1.E%6 B. Continuous Releases (5, 6)

Daily 4/M Composite P.G.E.(3)

I-131 5.E%7 1.E%6 X [iv]

Daily Grab Sample 4/M Composite Dissolved and Entrained Gases (Gamma Emlttere) 1.E-05 X (IIIj M H-3 1.E-05 Daily Composite Gross Alpha 1.E-07 j:~>l Q Sr%9, Sr-90 5.E-08 Daily Composite Fe-55 1.E46 C. Settling Basin W P.G.E. (3) 5.E%7 ri7]

W (7) Grab Sample 1-131 1.E%6 P,G.E. - Denotes Principal Gamma Emitter St. Lucie Plant ODCM Controls

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Page 30 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM TABLE 4.11-1 Continued TABLE NOTATION (1) The LLD is defined for purposes of these controls, as the smallest concentration of radioactive material in a sample that will yield a net count, above system background, that will be detected with 95% probability with only 5% probability of falsely concluding that a blank observation represents a 'real'ignal.

For a particular measurement system, which may include radiochemical separation:

4,66 S~

E ~ V~ 2.22E+06 ~ Y ~ exp (- X ~ 47)

Where; LLD the "a priori'ower limit of detection (micro-Curie per unit mass or volume),

the standard deviation of the background counting rate or of the counting rate of a blank sample as appropriate (counts per minute),

E = the counting efficiency (counts per disintegration),

V the sample size (units of mass or volume),

2.22E+06 = the number of disintegrations per minute per micro-Curie.,

Y the fractional radiochemical yield, when applicable, the radioactive decay constant for the particular radionuclide (sec'),

and the elapsed time between the midpoint of sample collection and the time of counting (sec).

Typical values of E, V, Y, and ririLT should be used in the calculation.

It should be recognized that the LLD is defined as an a priori (before the fact) limit representing the oapabiiity of a measurement system and not as an a gosteriori (after the fact) limit for a particular measurement.

Page 31 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM TABLE 4.11-1 Continued TABLE NOTATIONS Continued (2) A batch release is the discharge of liquid wastes of a discrete volume. Prior to sampling for analyses, each batch shall be isolated, and then thoroughly mixed by a method described in the ODCM to assure representative sampling.

(3) The principal gamma emitters for.which the LLD control applies include the following radionuclides: Mn-54, Fe-59, Co-58, Co-60, Zn-65, Mo-99, Cs-134, Cs-137, and Ce-141, and Ce-144. This list does not mean that only these nuclides are to be considered. Other gamma peaks that are identifiable, together with those of the above nuclides, shall also be analyzed and reported in'the Annual Radioactive Effluent Release Report pursuant to Control 3.11.2.6 in the format outlined in Regulatory Guide 1.21, Appendix B, Revision 1, June 1974.

(4) A composite sample is one in which the, quantity of liquid sampled is proportional to the quantity of liquid waste discharged and in which the method of sampling employed results in a specimen that is representative of the liquids released.

(5) A continuous release is the discharge of liquid wastes of a nondiscrete volume, e.g.,

from a volume of a system that has an input flow during the continuous release.

(6) If Component Cooling Water activity Is > 1.E-5 pCI/mi, perform a weekly gross activity on the Intake Cooling Water System outlet to ensure the activity level is less than or equal to 2.E-07 pCI/ml LLD limit. If ICW is >2.E-07 pCI/ml, perform analysis in accordance with a Plant Continuous Release on this Table, (7) Grab samples to be taken when there is confirmed primary to secondary system leakage indicated by the air ejector monitor indicating greater than or equal to 2x background,

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St. Lucie Plant ODCM Controls

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Page 32 of 180 ST, LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM RADIOACTIVE EFFLUENTS DOSE CONTROLS 3.11.1.2 In accordance with St. Lucie Plant TS 6.8.4,f.4) and 6.8.4.f,5), the dose or dose commitment to a MEMBER OF THE PUBLIC from radioactive materials In liquid eNuents released, from each unit, to UNRESTRICTED AREAS (see TS Figure 5,1-1) shall be limited:

a. During any calendar quarter to less than or equal to 1.5 mrems to the whole body and to less than or equal to 5 mrems to any organ, and

b. During any calendar year to less than or equal to 3 mrems to the whole body and to less than or equal to 10 mrems to any organ.

APPLICABILITY: At all times.

ACTION:

a. With the calculated dose from the release of radioactive materials in liquid effluents exceeding any of the above limits, prepare and submit to the Commission within 30 days, pursuant to Plant TS 6.9.2, a Special Report that Identifies the cause(s) for exceeding the limit(s) and defines the corrective actions that have been taken to reduce the releases and the proposed corrective actions to be taken to assure that subsequent releases will be in compliance with the above limits.

SURVEILLANCE REQUIREMENTS 4,11.1.2 Cumulative dose contributions from liquid effluents for the current calendar quarter and the current calendar year shall be determined in accordance with the methodology and parameters in the ODCM at least once per 31 days.

St. Lucie Plant ODCM Controls

Page 33 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM RADIOACTIVE EFFLUENTS LIQUID RADWASTE TREATMENT SYSTEM CONTROLS 3.11.1.3 In accordance with St. Lucie Plant TS 6.8.4.f.6), the Liquid Radwaste Treatment System shall be OPERABLE and appropriate portions of the system shall be used to reduce releases of radioactivity when the projected doses due to the liquid eNuent, from each unit, to UNRESTRICTED AREAS (see TS Figure 5.1-1) would exceed 0.06 mrem to the whole body or 0.2 mrem to any organ in a 31<ay period.

APPLICABILITY: At all times.

ACTION:

0 a. With radioactive liquid waste being discharged without treatment and in excess of the above limits and any portion of the Liquid Radwaste Treatment System not in operation, prepare and submit to the Commission within 30 days, pursuant to Plant TS 6.9.2, a Special Report that Includes the following information:

1.'xplanation of why liquid radwaste was being discharged without treatment, identification of any inoperable equipment or subsystems, and the reason for the inoperability,

2. Action(s) taken to restore the inoperable equipment to OPERABLE status, and

3. Summary description of action(s) taken to prevent a recurrence.

SURVEILLANCE REQUIREMENTS 4.11.1.3.1 Doses due to liquid releases from each unit to UNRESTRICTED AREAS shall be projected at least once per 31 days in accordance with the methodology and parameters in the ODCM when Liquid Radwaste Treatment Systems are not being fully utilized.

4.11.1.3.2 The installed Liquid Radwaste Treatment System shall be demonstrated OPERABLE by operating the liquid radwaste treatment system equipment for at least 30 minutes at least once per 92 days unless the liquid radwaste system has been utilized to process radioactive liquid effluents during the previous 92 days.

St. Lucie Plant ODCM Controls

e Page 34 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO, C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM RADIOACTIVE EFFLUENTS 3/4.11.2 GASEOUS EFFLUENTS DOSE RATE CONTROLS 3.11.2.1 In accordance with St. Lucie Plant TS 6.8.4.f.3), and 7), the dose rate in UNRESTRICTED AREAS due to radioactive materials released in gaseous eNuents from the site (see TS Figure 5.1-1) shall be limited to the following;

a. For noble gases: Less than or equal to 500 mremslyr to the whole body and less than or equal to 3000 mremslyr to the skin, and

b. For Iodine-131, for Iodine-133, for tritium, and for all radionuclides in particulate form with half-lives greater than 8 days: Less than or equal to 1500 mremslyr to any organ

~*>> 'A ACTION:

a. With the dose rate(s) exceeding the above limits, immediately restore the release rate to within the above limit(s).

SURVEILLANCE REQUIREMENTS 4,11.2.1.1 The dose rate due to noble gases in gaseous eNuents shall be determined to be within the above limits in accordance with the methodology and parameters in the ODCM.

4.11.2.1.2 The dose rate due to Iodine-131, Iodine-133, tritium, and all radionuclides in particulate form with half-lives greater than 8 days in gaseous effluents shall be determined to be within the above limits in accordance with,the methodology and parameters in the ODCM by obtaining representative samples and performing analyses in accordance with the sampling and analysis program specified in Table 4.11-2.

St. Lucie Plant ODCM Controls

Page 35 of 180 ST, LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM TABLE 4.11-2 RADIOACTIVE GASEOUS WASTE SAMPLING & ANALYSIS PROGRAM Gaseous Release Sampling Minimum Type of Activity Lower Limit of Type Frequency Analysis Analysis Detection Frequency (LLo) (1)

(pCVcc) 1, Waste Gas P P Noble Gas 1. &H Storage Tank Each Tank Each Tank P.G.E. (2)

Grab Sample

2. Containment P P Noble Gas Purge Each Purge (6) Each Purge (6) P.G.E, (2)

Grab Sample H-3 1.E-06

3. Vents:

a. Plant

b. Fuel Bldg 4/M Grab Sample Noble Gas P.G.E. (2) 1.E-04 (ttj (4 (6)

c. Laundry H-3

[ts].

1.E%6

d. S/G Blowdown Bldg.

4. All Release Continuous (3) 4/M l-131 1.E-12 Types as Charcoal listed in 3. Sample (4) above 4/M P.G.E. 1.E-11 Particulate Sample (4)

M Gross Alpha 1.E-11 Composite Particulate Sample Q Sr<9, Sr-90 1.E-11 Composite Particulate Sample Noble Gas Noble Gases 1.E-06 Monitor Gross Beta or Gamma P,G,E. - Denotes Principal Gamma Emitters

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St, Lucie Plant ODCM Controls

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Page 36 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO, C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM TABLE 4.11-2 Continued TABLE NOTATIONS (1) The LLD is defined for purposes of these controls, as the smallest concentration of radioactive material in a sample that will yield a net count, above system background, that will be detected with 95% probability with only 5% probability of falsely concluding that a blank observation represents a 'real'ignal ~

For a particular measurement system, which may include radiochemical separation:

4.66 S~

E ~ V ~ 2.22E%6 ~ Y ~ exp (- X ~ d 7)

Where:

LLD the "a priori'ower limit of detection (micro-Curie per unit mass or volume),

the standard deviation of the backgr'ound counting rate or of the counting rate of a blank sample as appropriate (counts per minute),

the counting efficiency (counts per disintegration),

V the sample size (units of mass or volume),

2.22E+06 = the number of disintegrations per minute per micro-Curie.,

Y the fractional radiochemical yield, when applicable, the radioactive decay constant for the particular radionuclide (sec'),

and the elapsed time between the midpoint of sample collection and the time of counting (sec) ~

Typical values of E, V, Y, and hT should be used in the calculation.

It should be recognized that the LLD is defined as an a priori (before the fact) limit representing the capability of a measurement system and not as an a gosteriori (after the fact) limit for a particular measurement.

St. Lucie Plant ODCM Controls

Page 37 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM TABLE 4.11-1 Continued I

TABLE NOTATIONS Continued (2) The principal gamma emitters for which the LLD control applies include the following radionuclides: Kr-87,Kr-88, Xe-133, Xe-133m, Xe-135, and Xe-138 in noble gas releases and Mn-54, Fe-59, Co-58, Co-60, Zn-65, Mo-99, l-131, Cs-134, Cs-137, Ce-141, and Ce-144 in Iodine and particulate releases. This list does not mean that only these nuclides are to be considered. Other gamma peaks that are identifiable, together with those of the above nuclides, shall also be analyzed and reported in the Annual Radioactive Effluent Release Report pursuant to Control 3.11.2.6 in the format outlined in Regulatory Guide 1.21, Appendix B, Revision 1, June 1974.

(3) The ratio of the sample flow rate to the sampled stream flow rate shall be known for the time period covered by each dose or dose rate calculation made in accordance with Controls 3.11.2.1, 3.11.2.2, and 3.11.2.3.

(4) Samples shall be changed at least four times per month and analyses shall be completed within 48 hours5.555556e-4 days <br />0.0133 hours <br />7.936508e-5 weeks <br />1.8264e-5 months <br /> after changing, or after removal from sampler. Sampling shall also be performed at least once per 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br /> for at least 7 days following each shutdown, startup, or THERMALPOWER change exceeding 15% of RATED THERMAL POWER within a 1-hour period and analyses shall be completed within 48 hours5.555556e-4 days <br />0.0133 hours <br />7.936508e-5 weeks <br />1.8264e-5 months <br /> of changing. When samples collected for 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br /> are analyzed, the corresponding LLDs may be increased by a factor of 10. This requirement does not apply if: (1) analysis shows that the DOSE EQUIVALENTI-131 concentration in the reactor coolant has not increased more than a factor of 3; and (2) the noble gas monitor shows that effluent activity has not increased by more than a factor of 3.

(5) Tritium grab samples shall be taken at least 4/M from the ventilation exhaust from the spent fuel pool area, whenever spent fuel is in the spent fuel pool.

(6) Sampling and analysis shall also be performed following shutdown, startup, or a THERMAL POWER change exceeding 15% of RATED THERMAL POWER within 1 hour1.157407e-5 days <br />2.777778e-4 hours <br />1.653439e-6 weeks <br />3.805e-7 months <br /> unless (1) analysis shows that the DOSE EQUIVALENT 1-131 concentration in the primary coolant has not increased more than a factor of 3; and (2) the noble gas activity monitor shows that effluent activity has not increased by more than a factor of 3.

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St. Lucie Plant ODCM Controls

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('t f F

Page 38 of 180 ST, LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM RADIOACTIVE EFFLUENTS DOSE - NOBLE GASES CONTROLS 3.11.2.2 In accordance with St, Lucie Plant TS 6.8.4.f.5), and 8), the air dose due to noble gases released in gaseous effluents, from each unit, to areas at and beyond the SITE BOUNDARY (see TS Figure 5.1-1) shall be limited to the following:

a. During any calendar quarter. Less than or equal to 5 mrads for gamma radiation and less than or equal to 10 mrads for beta radiation, and

b. During any calendar year. Less than or equal to 10 mrads for gamma radiation and less than or equal to 20 mrads for beta radiation.

APPLICABILITY: At all times.

ACTION:

a. With the calculated air dose from radioactive noble gases in gaseous eNuents exceeding any of the above limits, prepare and submit to the Commission within 30 days, pursuant to Plant TS 6.9.2, a Special Report that identifies the cause(s) for exceeding the limit(s) and defines the corrective actions that have been taken to assure that subsequent releases wilt be in compliance with the above limits.

SURVEILLANCE REQUIREMENTS 4.11.2.2 Cumulative dose contributions for the current calendar quarter and current calendar year for noble gases shall be determined in accordance with the methodology and parameters in the ODCM at least once per 31 days,

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St. Lucie Plant ODCM Controls

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Page 39 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE'CALCULATION MANUAL ODCM RADIOACTIVE EFFLUENTS DOSE - IODINE-131 IODINE-133 TRITIUM AND RADIOACTIVE MATERIAL IN PARTICULATE FORM CONTROLS 3.11.2.3 In accordance with St. Lucie Plant TS 6,8.4.f.5), and 9), the dose to a MEMBER OF THE PUBLIC from Iodine-131, Iodine-133, tritium, and all radionuclides in particulate form with half-lives greater than 8 days in gaseous eNuents released, from each unit, to areas at and beyond the SITE BOUNDARY (see TS Figure 5.1-1) shall be limited to the following:

a. During any calendar quarter, Less than or equal to 7.5 mrems to any organ and,

b. During any calendar year: Less than or equal to 15 mrems to any organ.

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APPLICABILITY: At all times. ~

ACTION:

a. With the calculated dose from the release of Iodine-131, Iodine-133, tritium, and radionuclides in particulate form with half-lives greater than 8 days, in gaseous eNuents exceeding any of the above limits, prepare and submit to the Commission within 30 days, pursuant to Plant TS 6.9.2, a Special Report that identifies the cause(s) for exceeding the limit(s) and defines the corrective actions that have been taken to assure that subsequent releases will be in compliance with the above limits.

SURVEILLANCE REQUIREMENTS 4.11.2.3 Cumulative dose contributions for the current calendar quarter and current calendar year for iodine-131, Iodine-133, tritium and radionuclides in particulate form with half-lives greater than 8 days shall be determined in accordance with the methodology and parameters in the ODCM at least once per 31 days.

St. Lucie Plant ODCM Controls

Page 40 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO, C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM RADIOACTIVE EFFLUENTS GASEOUS RADWASTE TREATMENT SYSTEM CONTROLS 3.11.2.4 In, accordance with St. Lucie Plant TS 6.8.4.f.6), the VENTILATIONEXHAUST Treatment System and the WASTE GAS HOLDUP SYSTEM shall be OPERABLE and appropriate portions of the system shall be used to reduce releases of radioactivity when the projected doses in 31 days due to gaseous effluent releases, from each unit, to areas at and [a60j beyond the SITE BOUNDARY (see TS Figure 5.1-1) would exceed:

a. 0,2 mrad to air from gamma radiation, or

b. 0.4 mrad to air from beta radiation, or

c. 0,3 mrem to any organ.

[as]

APPLICABILITY: At all times.

ACTION:

a. With radioactive gaseous waste being discharged without treatment and in excess of the above limits, prepare and submit to the Commission within 30 days, pursuant to Plant TS 6.9.2, a Special Report that includes the following information:

1. Identification of any inoperable equipment or subsystems, and the reason for the inoperability,

2. Action(s) taken to restore the inoperable equipment to OPERABLE status, and

3. Summary description of action(s) taken to prevent a recurrence.

St. Lucie Plant ODCM Controls

Page 41 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM RADIOACTIVE EFFLUENTS GASEOUS RADWASTE TREATMENT SYSTEM Continued SURVEILLANCE REQUIREMENTS 4.11,2.4.1 Doses due to gaseous releases from each unit to areas at and beyond the SITE BOUNDARY shall be projected at least once per 31 days in accordance with the methodology and parameters in the ODCM when Gaseous Radwaste Treatment Systems are not being fully utilized.

4.11.2.4.2 The installed VENTILATION EXHAUST TREATMENT SYSTEM and WASTE GAS HOLDUP SYSTEM shall be demonstrated OPERABLE by operating the WASTE GAS HOLDUP SYSTEM equipment and VENTILATION EXHAUST TREATMENT SYSTEM equipment for at least 30 minutes, at least once per 92 days unless the appropriate system has been utilized.to process radioactive gaseous effluents during the previous 92 days, St. Lucie Plant ODCM Controls

Page 42 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM RADIOACTIVE EFFLUENTS 3/4.11.4 TOTAL DOSE CONTROLS 3,11.4 In accordance with St. Lucie Plant TS 6.8.4.f.10), the annual (calendar year) dose or dose commitment to any MEMBER OF THE PUBLIC due to releases of radioactivity and to radiation from uranium fuel cycle sources shall be limited to less than or equal to 25 mrems to the whole body or any organ, except the thyroid, which shall be limited to less than or equal to 75 mrems.

APPLICABILITY: At all times.

ACTION:

a. With the calculated doses from the release of radioactive materials in liquid or gaseous effluents exceeding twice the limits of Control 3.11.1,2,a, 3.11.1.2.b, 3.11,2.2.a, 3.11.2.2.b, 3.11.2.3.a, or 3.11.2.3.b, calculations shall be made including direct radiation contributions from the units (including outside storage tanks etc.) to determine whether the above limits of Control 3.11.4 have been exceeded. If such is the case, prepare and submit to the Commission within 30 days, pursuant to Plant TS 6.9.2, a Special Report that defines the corrective action to be taken to reduce subsequent releases to prevent recurrence of exceeding the above limits and bj includes the schedule for achieving conformance with the above limits. This Special Report, as defined in 10 CFR 20,405 (c), shall include an analysis that estimates the radiation exposure (dose) to a MEMBER OF THE PUBLIC from uranium fuel cycle sources, including all effluent pathways and direct radiation, for the calendar year that includes the release(s) covered by this report. It shall also describe levels of radiation and concentrations of radioactive material involved, and the cause of the exposure levels or concentrations, If the estimated dose(s) exceeds the above limits, and if the release condition resulting in violation of 40 Part 190 has not already been corrected, the Special Report shall include a request for a variance in accordance with the provisions of 40 CFR Part 190. Submittal of the report is considered a timely request, and a variance is granted until staff action on the request is complete.

[~j St. Lucie Plant ODCM Controls

Page 43 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM RADIOACTIVE EFFLUENTS 3/4.11.4 TOTAL DOSE Continued SURVEILLANCE REQUIREMENTS 4.11.4.1 Cumulative dose contributions from liquid and gaseous effluents shall be determined in accordance with Controls 4.11.1.2, 4.11.2.2, and 4.11.2.3, and in accordance with the methodology and parameters in the ODCM.

4.11.4.2 Cumulative dose contributions from direct radiation from the units (Including outside storage tanks etc.) shall be determined in accordance with the methodology and parameters in the ODCM, This requirement is applicable only under conditions set forth in ACTION a. of Control 3.11.4.

St. Lucie Plant ODCM Controls

Page 44 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM RADIOACTIVE EFFLUENTS 3/4.11.5 MAJOR CHANGES TO RADIOACTIVELIQUID GASEOUS AND SOLID WASTE TREATMENT SYSTEMS*

ADMINISTRATIVECONTROLS 3.11,2,5 Licensee initiated major changes to the radioactive waste systems (liquid, gaseous, and solid):

1) Shall be reported to the Commission in the Annual Radioactive Effluent Release Report for the period in which the evaluation was reviewed by the Facility Review Group (FRG). The discussion of each shall contain:

a) A summary of the evaluation that led to the determination that the change could be made in accordance with 10 CFR 50.59.

b) Sufficient detailed information to totally support the reason for the change without benefit of additional or 'supplemental information; c) A detailed description of the equipment, components and processes involved and the interfaces with other plant systems; d) An evaluation of the change which shows the predicted releases of radioactive materials in liquid and gaseous effluents and/or quantity of solid waste that differ from those previously predicted in the license application and amendments thereto; e) An evaluation of the change which shows the expected maximum exposure to individuals in the UNRESTRICTED AREA and to the general population that differ from those previouslyestimated in the license application and amendments thereto; f) A comparison of the predicted releases of radioactive materials, in liquid and gaseous effluents and in solid waste, to the actual releases for the period when the changes are to be made; g) An estimate'of the exposure to plant operating personnel as a result of the change; and h) Documentation of the fact that the change was reviewed and found acceptable by the FRG..

2) Shall become effective upon review and acceptance by the FRG.

It

• Licensees may choose to submit the information called for in this Administrative Control as part of the annual FUSAR update.

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St. Lucie Plant ODCM Controls

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Page 45 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM RADIOACTIVE EFFLUENTS 3/4.11.6 ANNUAL RADIOACTIVE EFFLUENT RELEASE REPORT TO THE COMMISSION*

ADMINISTRATIVECONTROLS 3.11.2.6 As per Technical Specification 6.9.1.7, a Annual Radioactive Effluent Release Report covering the operation of each unit during the previous 12 months of operation shall be submitted within 60 days after January 1 of each year. The report shall include a summary of the quantities of radioactive liquid and gaseous effluents and solid waste released from each unit. The material provided shall be (1) consistent with the objectives outlined in by items a) through f) below, using the example report format in the ODCM, and (2) be in conformance with 10 CFR 50.36a and Section IV.B.1 of Appendix I to 10 CFR Part 50.

1

a. The Radioactive Effluent Release Reports shall include a summary of the quantities of radioactive liquid and gaseous effluents and solid waste released from the unit as outlined in Regulatory Guide 1.21, "Measuring, Evaluating, and Reporting Radioactivity in Solid Wastes and Releases of Radioactive Materials in Liquid and Gaseous Effluents from Light-Water-Cooled Nuclear Power Plants," Revision 1, June 1974, with data summarized on a quarterly basis following the format of Appendix B thereof.

b. The Radioactive Effluent Release Report to be submitted within 60 days after January 1 of each year shall include an annual summary of hourly meteorological data collected over the previous year. This annual summary may be either in the form of an hour-by-hour listing on magnetic tape of wind speed, wind direction, atmospheric stability, and precipitation (if measured), or in the form of joint frequency distributions of wind speed, wind direction, and atmospheric stability.**

This same report shall include an assessment of the radiation doses due to the radioactive liquid and gaseous effluents released from the unit or station during the

• - A single submittal may be made for a multiple unit station. The submittal should combine those sections that are common to all units at the station; however, for units with separate radwaste systems, the submittal shall specify the releases of radioactive material from each unit.

• • - In lieu of submission with the Radioactive Effluent Release Report, the licensee has the option of retaining this summary of required meteorological data on site in a file that shall be provided to the NRC upon request.

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St. Lucie Plant ODCM Controls

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I H I

1

Page 46 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM RADIOACTIVE EFFLUENTS 3/4;11.6 ANNUAL RADIOACTIVE EFFLUENT RELEASE REPORT TO THE COMMISSION Continued ADMINISTRATIVECONTROLS 3.11.2.6 (Contiriued)

b. (Continued) previous calendar year. This same report shall also include an assessment of the radiation doses from radioactive liquid and gaseous effluents to MEMBERS OF THE PUBLIC due to their activities inside the SITE BOUNDARY (see TS Figure 5.1-1) during the report period. All assumptions used in making these assessments, i.e., specific activity, exposure time and location, shall be included in these reports. The meteorological conditions concurrent with the time of release of radioactive materials in gaseous effluents, as determined by sampling frequency and measurement, shall be used for determining the gaseous pathway doses. The assessment of radiation doses shall be performed in accordance with the methodology and parameters in the ODCM.

c. Every 2 years using the previous 6 months release history for isotopes and historical meteorological data determine the controlling age group for both liquid and gaseous pathways, If changed from current submit change to ODCM to reflect new tables for these groups and use the new groups in subsequent dose calculations.

d. The Radioactive Effluent Release Report to be submitted 60 days after January 1 of each year shall also include an assessment of radiation doses to the likely most exposed MEMBER OF THE PUBLIC from reactor releases for the previous calendar year. Acceptable methods for calculating the dose contribution from liquid and gaseous effluents are given in Regulatory Guide 1.109 March 1976.

St. Lucie Plant ODCM Controls

li lt r'i I

I

Page 47 of 180 S T. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM RADIOACTIVE EFFLUENTS 3/4.11.6 ANNUAL RADIOACTIVE EFFLUENT RELEASE REPORT TO THE COMMISSION Continued ADMINISTRATIVECONTROLS 3.11.2.6 (Continued)

e. The Radioactive Effluent Release Reports shall include the following information for each class of solid waste (as defined by 10 CFR Part 61) shipped offsite during the report period; 1 ~ Volume

2. Total Curie quantity (specify whether determined by measurement or estimate)

3. Principal radionuclides (specify whether determined by measurement or estimate)

4. Type of waste (e.g,, dewatered spent resin, compacted dry waste, evaporator bottoms)

5. Type of container (e.g., LSA, Type A, Type B, Large Quantity), and

6. Solidification'gent or absorbent (e.g., cement, urea formaldehyde).

f. The Radioactive Effluent Release Reports shall include a list and description of unplanned releases from the site to UNRESTRICTED AREAS of radioactive materials in gaseous and liquid effluents made during the reporting period.

g. The Radioactive Effluent Release'Reports shall include any changes made during the reporting period to the PROCESS CONTROL PROGRAM (PCP) and to the OFFSITE DOSE CALCULATION MANUAL (ODCM), as well as a listing of new locations for dose calculations and/or environmental monitoring identified by the Land Use Census of ODCM Control 3.12.2.

h. The format for an Annual Radioactive Effluent Release Report is provided in ODCM Section 4.0. The information contained in an annual report shall not apply to any ODCM Control Dose Limit(s) since the methodology for the annual report is based on actual meteorological data, instead of historical conditions that the ODCM Controls and Control required calculations are based on.

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St. Lucie Plant ODCM Controls

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i' I'

Page 48 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM RADIOLOGICALENVIRONMENTALMONITORING 3/4.12.1 MONITORING PROGRAM CONTROLS 3.12.1 In accordance with St. Lucie Plant TS 6.8.4.g.1), the Radiological Environmental Monitoring Program shall be conducted as specified in Table 3,12-1, APPLICABILITY: At all times.

ACTION:

a. With the Radiological Environmental Monitoring Program not being conducted as specified in Table 3.12-1, prepare and submit to the Commission, in the Annual Radiological Environmental Operating Report required by Control 3.12.4, a description of the reasons for not conducting the program as required and the plans for preventing a recurrence.

b. With the confirmed'evel of radioactivity as the result of plant eNuents in an environmental sampling medium at a specNed location exceeding the reporting levels of Table 3.12-2 when averaged over any calendar quarter, prepare and submit to the Commission within 30 days, pursuant to Plant TS 6,9.2, a Special Report that identifies the cause(s) for exceeding the limit(s) and defines She corrective actions to be taken to reduce radioactive effluents so that the potential annual dose** to a MEMBER OF THE PUBLIC is less than the calendar year limit of Controls 3.11 1.2, 3.11.2.2, or 3.11.2.3.

~ When more than one of the radionuclides in Table 3.12-2 are detected in the sampling medium, this report shall be submitted if:

concentration (1) concentration (2) or 1 0 reportI'ng level (1) reporting level (2)

When radionuclides other than those in Table 3.12-2 are

• A confirmatory reanalysis of the original, a duplicate, or a new sample may be desirable, as appropriate. The results of the confirmatory analysis shall be completed at the earliest time consistent with the analysis but in any case within 30 days.

• • The methodology and parameters used to estimate the potential annual dose to a MEMBER OF THE PUBLIC shall be indicated in this report.

St. Lucie Plant ODCM Controls

Page 49 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM RADIOLOGICALENVIRONMENTALMONITORING 3/4.12.1 MONITORING PROGRAM Controls (Continued)

Action b. (Continued) detected and are the result of plant effluents, this report shall be submitted if the potential annual dose, to a MEMBER OF THE PUBLIC from all radionuclides is equal to or greater than the calendar year limits of Control 3.11.1.2, 3.11.2.2, or 3.11.2.3, This report is not required if the measured level of radioactivity was not the result of plant effluents; however, in such an event, the condition shall be reported and described in the Annual Radiological Environmental Operating Report required by Control 3.12.4.

c, With milk or broad leaf vegetation'samples unavailable from one or more of the sample locations required by Table 3.12-1, identify specific locations for obtaining replacement samples and add them within 30 days to the Radiological Environmental Monitoring Program given in the ODCM. The specific locations from which samples were unavailable may then be deleted from the monitoring program.

Pursuant to Control 3.11.2.6, submit in the next Annual Radioactive Effluent Release Report documentation for a change in the ODCM including a revised figure(s) and table for the ODCM reflecting the new location(s) with supporting information identifying the cause of'the unavailability of samples and justifying the selection of the new location(s) for obtaining samples.

SURVEILLANCE REQUIREMENTS 4.12.1 The radiological environmental monitoring samples shall be collected pursuant to Table 3.12-1 from the specific locations given in the table and figure(s) in the ODCM, and shall be analyzed pursuant to the requirements of Table 3.12-1 and the detection capabilities required by Table 4.12-1.

St. Lucie Plant ODCM Controls

r IJ

Page 50 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM TABLE 3.12-1 RADIOLOGICALENVIRONMENTALMONITORING PROGRAM'XPOSURE NUMBER OF REPRESENTATIVE PATHWAY SAMPLES AND SAMPLING AND TYPE AND and/or SAMPLE COLLECTION FREQUENCY " OF SAMPLE LOCATIONS i" FREQUENCY ANALYSIS

1. Direct Radiation',

27 Monitoring Gamma exposure rate-Locations monitoring with quarterly sample collection quarterly "

Airborne Continuous sampler Radioiodine filter.

Radioiodine and 5 Locations operation with l-131 analysis weekly Particulates sample collection Particulate Filter:

weekly, or more Gross beta radioactivity frequently if analysis 224 hours0.00259 days <br />0.0622 hours <br />3.703704e-4 weeks <br />8.5232e-5 months <br /> required by dust following a Alter loading change" Gamma of composite "

isotopld'nalysis (by location) quarterly

3. Waterborne a) Surface 1 Location Weekly Gamma isotopl &

Locations'ontinuous tritium analyses weekly 1 Location" Monthly Gamma Isotopl &

tritium analyses monthly b) Sediment from 2 Locations Semiannually Gamma isotopi shoreline analyses semiannually

4. Ingestion a) Fish and Invertebrates

1) Crustacea 2 Locations Semiannually Gamma isotopl analyses semiannually

2) Fish 2 Locations Semiannually Gamma Isotopic analyses semiannually b) Food Products

1) Broad leaf 3 Monthly when Gamma isotopi and vegetation available l-131 analyses monthly St. Lucie Plant ODCM Controls

Page 51 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM TABLE 3.12-1 Continued TABLE NOTATIONS 80 are permitted from the required sampling schedule if specimens are unobtainable due to hazardous. conditions, seasonal unavailability, malfunction of

'eviations automatic sampling equipment or other legitimate reasons. If specimens are unobtainable due to sampling equipment malfunction, corrective action shall be taken prior to the end of the next sampling period. All deviations from the sampling schedule shall be documented in the Annual Radiological Environmental Operating Report pursuant to Control 3.12.4.

b. Specific parameters of distance and direction sector from the centerline of one reactor, and additional description where pertinent, shall be provided for each sample location required by Table 3.12-1, In Appendix-E and applicable figures.

At times, it may not be possible or practicable to continue to obtain samples of the media of choice at the most desired location or time. In these instances suitable alternative media and locations may,be chosen for the particular pathway in question and appropriate substitutions made within 30 days in the radiological environmental monitoring program.

d. The following definition of frequencies shall apply to Table 3,12-1 only:

Weekly - Not less than once per calendar week. A maximum interval of 11 days is allowed between the collection of any two consecutive samples.

Semi-Monthly - Not less than 2 times per calendar month with an interval of not less than 7 days between sample collections. A maximum interval of 24 days is allowed between collection of any two consecutive samples.

Monthly- Not less than once per calendar month with an interval of not less than 10 days between sample collections.

Quarterly - Not less than once per calendar quarter.

Semiannually - One sample each between calendar dates (January 1 - June 30) and (July 1 - December 31) An interval of not less than 30 days will be

~

provided between sample collections.

The frequency of analyses is to be consistent with the sample collection frequency, St. Lucie Plant ODCM Controls

Page 52 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM TABLE 3.12-1 Continued TABLE NOTATIONS Continued

e. One or more instruments, such as a pressurized ion chamber, for measuring and recording dose rate continuously may be used in place of, or in addition to, integrating dosimeters. For purposes of this table, a thermoluminescent dosimeter (TLD) is considered to be one phosphor, two or more phosphors in a packet are considered as two or more dosimeters.

f. Refers to normal collection frequency. More frequent sample collection Is permitted when conditions warrant.

g. Airborne particulate sample filters are analyzed for gross beta radioactivity 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br /> or more after sampling to allow for radon and thoron daughter decay. In addition to the requirement for a gamma isotopic on a composite sample a gamma isotopic is also required for each sample having a gross beta radioactivity which is >1,0 pCi per. cubic meters and which is also >10 times that of the most recent control sample.

h. Gamma Isotopic analysis means the Identification and quantification of gamma-emitting radionuclides that may be attributabie to the effluents from the facility.

k. Discharges from the St, Lucie Plant do not influence drinking water or ground water pathways.

m. Atlantic Ocean, in the vicinity of the public beaches along the eastern shore of Hutchinson Island near the St. Lucie Plant (grab sample) n, Atlantic Ocean, at a location beyond Influence from plant effluents (grab sample).

p. Samples of broad leaf vegetation grown nearest each of two different offsite locations of highest predicted annual average ground level D/Q, and one sample of similar broad leaf vegetation at an available location 15-30 kilometers distant in the least prevalent wind direction based upon historical data in the ODCM.

[I, j, I (lower case), and o are not used on notation for clarity reasons]

St. Lucie Plant ODCM Controls

Page 53 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE'NO. C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM TABLE 3.12-2 REPORTING LEVELS FOR RADIOACTIVITYCONCENTRATIONS IN ENVIRONMENTALSAMPLES REPORTING LEVELS AIRBORNE FOOD PARTICULATE FISH MILK ANALYSIS PRODUCTS pCI/I OR GASES pCi/kg, wet pCI/I pCI/kg, wet H-3 30,000',000 Mn-54 30,000 pCVm'.9 Fe-59 10,000 Co-58 1,000 30,000 Co-60 10,000 Zn-65 20,000 Zr-La-140"'ATER Nb-95-'-131 211 Cs-134 30 10 1,000 60 1,000 Cs-137 50 20 2,000 70 2,000 Ba-200 I - as in pCM denotes liter

• - Since no drinking water pathway exists, a value of 30,000 pCI/I is used. For drinking water samples, a value of 20,000 pCi/I is used; this is 40 CFR Part 141 value.

'* - Applies to drinking water pathway exists, 2 pCi/I is the limit for drinking water.

An equilibrium mixture of the parent daughter isotopes which corresponds to the reporting value of the parent isotope.

St. Lucie Plant ODCM Controls

Page 54 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM TABLE 4.12-1 DETECTION CAPABILITIES FOR ENVIRONMENTALSAMPLE ANALYSIS' LOWER LIMITOF DETECTION LLD AIRBORNE FOOD WATER PARTICULATE FISH MILK SEDIMENT ANALYSIS PRODUCTS pCI/I OR GASES pCI/kg, wet pCI/I pCI/kg, dry pCi/kg, wet pCI/m'.01 Gross Beta H-3 3000'5 Mn-54 Fe-59 30 260 Co-58, 15 130 Co-60 Zn-65 30 260 Zr-95, Nb-95'" 15 l-131 0.07 60 Cs-134 15 0.05 130 15 60 150 Cs-137 18 0.06 150 18 80 180 Ba-140, La-140~'> 15 15 No drinking water pathway exists, a value of 2000 pCi/I is for drinking water.

• 'LD for, drinking water samples. If no drinking water pathway exists, the LLD of gamma isotopic analysis may be used.

St. Lucie Plant ODCM Controls

Page 55 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM TABLE 4.12-1 Continued TABLE NOTATIONS (1) This list does not mean that only these nuclides are to be considered. Other peaks that are identiTiable, together with those of the above nuclides, shall also be analyzed and reported in the Annual Radiological Environmental Operating Report pursuant to Control 3.12.4.

(2) Required detection capabilities for therm oluminescent dosimetere used for environmental measurements are given in Regulatory Guide 4.13.

(3) The LLD is defined for purposes of these controls, as the smallest concentration of radioactive material in a sample that will yield a net count, above system background, that will be detected with 95% probability with only 5% probability of falsely concluding that a blank observation represents a 'real" signal.

For a particular measurement system, which may include radiochemical separation:

4.66 S~

E ~ V~ 2.22 ~ Y ~ exp (- X ~ h7)

Where:

LLD= the 'a priori'ower limit of detection (pico-Curie per unit mass or volume),

Sb = the standard deviation of the background counting rate or of the counting rate of a blank sample as appropriate (counts per minute),

E = the counting efficiency (counts per disintegration),

V = the sample size (units of mass or volume),

2.22 = the number of disintegrations per minute per pico-Curie, Y = the fractional radiochemical yield, when applicable, the radioactive decay constant for the particular radionuclide (sec'), and hT = the elapsed time between the midpoint of sample collection and the time of counting (sec).

Typical values of E, V, Y, and dT should be used in the calculation.

St. Lucie Plant ODCM Controls

Page 56 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM TABLE 4.12-1 Continued TABLE NOTATIONS Continued It should be recognized that the LLD is defined as an a priori (before the fact) limit representing the capability of a measurement system and not as an a posteriori (after the fact) limit for a particular measurement. Analyses shall be performed in such a manner that the stated LLDs will be achieved under routine conditions. Occasionally background fluctuations, unavoidable small sample sizes, the presence of interfering nuclides, or other uncontrollable circumstances may render these LLDs unachievable.

In such cases, the contributing factors shall be Identified and described in the Annual Radiological Environmental Operating Report pursuant to Control 3.12.4.

(4) An equilibrium mixture of the parent and daughter isotopes which corresponds to 15 pCI/Liter of the parent isotope, St. Lucie Plant ODCM Controls

Page 57 of 180 t ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION OFFSITE DOSE CALCULATION MANUAL ODCM RADIOLOGICAL ENVIRONMENTALMONITORING 3/4.12.2 LAND USE CENSUS 11 CONTROLS 3.12.2 In accordance with St. Lucie Plant TS 6.8.4.g.2), a Land Use Census shall be conducted and shall identify within a distance of 8 km (5 miles) the location in each of the 16 meteorological sectors of the nearest milk animal, the nearest residence, and the nearest garden" of greater than 50 square meters (500 square feet) producing broad leaf vegetation.

APPLICABILITY: At all times.

ACTION:

a. With a Land Use Census identifying a location(s) that yields a calculated dose or dose commitment greater than the values currently being calculated in Control 4.11.2.3, pursuant to Control 3.11'.2.6, identify the new location(s) in the next Annual Radioactive Effluent Release Report.

b. With a Land Use Census identifying a location(s) that yields a calculated dose or dose commitment (via the same exposure pathway) 20% greater than at a location from which samples are currently being obtained in accordance with Control 3.12.1, add the new location(s) within 30 days to the Radiological Environmental Monitoring Program given in the ODCM. The sampling location(s), excluding the control station location, having the lowest calculated dose or dose commitment(s), via the same exposure pathway, may be deleted from this monitoring program after October 31 of the year in which this Land Use Census was conducted. Pursuant to TS 6.14, submit in the next Annual Radioactive Effluent Release Report documentation for a change in the ODCM including a revised figure(s) and table(s) for the ODCM reflecting the new location(s) with information supporting the change in sampling locations.

Broad leaf vegetation sampling may be performed at the SITE BOUNDARY in each of two different direction sectors with the highest predicted D/Qs in lieu of the garden census. Controls for broad leaf vegetation sampling in Table 3.12-1, Part 4.b., shall be followed, including analysis of control samples.

St. Lucie Plant ODCM Controls

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Page 58 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM RADIOLOGICALENVIRONMENTALMONITORING 3/4.12.2 LAND USE CENSUS Continued SURVEILLANCE REQUIREMENTS 4.12.2 The Land Use Census shall be conducted during the growing season at least once per 12 months using that information that will provide the best results, such as by a door-to-door survey, aerial survey, or by consulting local agriculture authorities. The results of the Land Use Census shall be included in the Annual Radiological Environmental Operating Report pursuant to Control 3.12.4.

St. Lucie Plant ODCM Controls

Page 59 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM RADIOLOGICAL ENVIRONMENTALMONITORING 3/4.12.3 INTERLABORATORYCOMPARISON PROGRAM CONTROLS 3.12.3 In accordance with St. Lucie Plant TS 6.8.4.g.3), analyses shall be performed on all radioactive materials, supplied as part of an lnterlaboratory Comparison Program that has been approved by the Commission', that correspond to samples required by Table 3.12-1 ~

APPLICABILITY: At all times.

ACTION:

a. With analyses not being performed as required above, report the corrective action taken to prevent a recurrence to the Commission in the Annual Radiological Environmental Operating Report pursuant to Control 3.12.4.

SURVEILLANCE REQUIREMENTS 4.12.3 A summary of the results obtained as part of the above required Interfaboratop Comparison Program shall be included in the Annual Radiological Environmental Operating Report pursuant to Control 3.12.4. If the Interiaboratory Comparison Program is other than the program conducted by the EPA, then the Interlaboratory Comparison Program shall be described in the ODCM.

This condition is satisfiedby participation in the Environmental Radioactivity Laboratory Intercomparison Studies Program conducted by the Environmental Protection Agency (EPA).

St. Lucie Plant ODCM Controls

Page 60 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO, C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM RADIOLOGICALENVIRONMENTALMONITORING 3/4.12.4 ANNUALRADIOLOGICALENVIRONMENTALOPERATING REPORT AREOR CONTROLS 'DMINISTRATIVE 3.12.4 In accordance with St, Lucie Plant TS 6.9.1,8, an Annual Radiological Environmental Operating Report covering the operation of the unit during the previous calendar year shall be submitted before May 1 of each year, The report shall include summaries, interpretations, and information based on trend analysis of the results of the Radiological Environmental Monitoring Program for the reporting period. The material provided in the AREOR shall be consistent with the objectives outlined below, and with Sections IV.B.2, IV.B.3, and IV.C of Appendix I to 10 CFR Part 50.

The Annual Radiological Environmental Operating Reports shall include summaries, Interpretations, and information based on trend analysis of the results of the radiological

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environmental surveillance activities for the report period, including a comparison, as

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appropriate, with preoperational studies, with operational controls and with previous environmental surveillance reports, and an assessment of the observed impacts of the plant operation on the environment. The reports shall also include the results of land use census

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required by Control 3.12.2, The Annual Radiological Environmental Operating Reports shall include the results of analysis of all radiological environmental samples and of all environmental radiation measurements taken during the period pursuant to the locations specified in the Table and Figures in the ODCM, as well as summarized and tabulated results of these analyses and measurements in the format of the table in the Radiological Assessment Branch Technical Position, Revision 1, November 1979. In the event that some individual results are not available for inclusion with the report, the report shall be submitted noting and explaining the reasons for the missing results. The missing data shall be submitted as soon as possible in a supplementary report, The reports shall also include the following: a summary description of the radiological environmental monitoring program; at least two legible maps'* covering all sampling locations keyed to a table giving distances and directions from the centerline of one reactor; the results of the Interlaboratory Comparison Program, required by Control 3,12,3; discussion of all deviations from the sampling schedule of Table 3.12-1; and discussion of all analyses in which the LLD required by Table 4.12-1 was not achievable.

A single submittal may be made for multiple unit station.

One map shall cover stations near the SITE BOUNDARY; a second shall include the more distant stations.

St. Lucie Plant ODCM Controls

Page 61 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM BASES for the CONTROLS AND SURVEILLANCE REQUIREMENTS MOTE The BASES contained in succeeding pages summarize the reasons for the Controls in Section 3.0 and 4.0, but are not part of these Controls.

St. Lucie Plant ODCM Controls - Bases

Page 62 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM INSTRUMENTATION BASES 3/4.3.3.10 RADIOACTIVE LIQUID EFFLUENT MONITORING INSTRUMENTATION The radioactive liquid effluent instrumentation is provided to monitor and control, as applicable, the releases of radioactive materials in liquid effluent during actual or potential releases of liquid effluents, The Alarm/Trip Setpoints for these instruments shall be calculated and adjusted in accordance with the methodology and parameters in the ODCM to ensure that the alarm/trip will occur prior to exceeding the limits of 10 CFR Part 20. The OPERABILITYand use of this instrumentation is consistent with the requirements of General Design Criteria 60, 63, and 64 of Appendix A to 10 CFR Part 50.

3/4.3.3.11 RADIOACTIVEGASEOUS EFFLUENT MONITORING INSTRUMENTATION The radioactive gaseous effluent instrumentation is provided to monitor and control, as

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applicable, the releases of radioactive materials in gaseous eNuent during actual or potential releases of gaseous eNuents. The Alarm/Trip Setpoints for these instruments shall be

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calculated and adjusted in accordance with the methodology and parameters in the ODCM to ensure that the alarm/trip will occur prior to exceeding the limits of 10 CFR Part 20. The OPERABILITYand use of this instrumentation is consistent with the requirements of General Design Criteria 60, 63, and 64 of Appendix A to 10 CFR Part 50.

St. Lucie Plant ODCM Controls - Bases

Page 63 of 180 ST, LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM 3/4.11 RADIOACTIVE EFFLUENTS BASES 3/4.11.1 LIQUID EFFLUENTS 3/4.11.1.1 CONCENTRATION This control is provided to ensure that the concentration of radioactive materials released in liquid waste effluents to UNRESTRICTED AREAS will be less than the concentration levels specified in 10 CFR Part 20, Appendix B, Table II, Column 2. This limitation provides additional assurance that the levels of radioactive materials in bodies of water in UNRESTRICTED AREAS will result in exposures within: (1) the Section II.A design objectives of Appendix I, 10 CFR Part 50, to a MEMBER OF THE PUBLIC, and (2) the limits of 10 CFR Part 20.106(e) to the population." The concentration limit for dissolved or entrained noble gases is based upon the assumption that Xe-135 is the controlling radioisotope and its MPC in air (submersion) was converted to an equivalent concentration in water using the methods described in International Commission on Radiological Protection (ICRP) Publication 2.

This control applies to the release of radioactive materials in liquid eNuents from all units at the site.

The required detection capabilities for radioactive materials in liquid waste samples are tabulated in terms of the lower limits of detection (LLDs). Detailed discussion of the LLD, and other detection limits can be found in Currie, L.A., 'Lower Limit of Detection: Definition and Elaboration of a Proposed Position for Radiological Effluent and Environmental Measurements,'UREG/CR<007 (September 1984), and in the HASL Procedures Manual, HAS L-300.

3/4.11.1.2 DOSE This control is provided to implement the requirements of Sections II.A, III,A, and IV.A of Appendix I, 10 CFR Part 50. The Control implements the guides set forth In Section II.A of Appendix I. The ACTION statements provide the required operating flexibilityand at the same time implement the guides set forth in Section IV,A of Appendix I to assure that the releases of radioactive material in liquid eNuents to UNRESTRICTED AREAS will be kept "as low as is reasonably achievable.'lso, for fresh water sites with drinking water supplies that can be potentially affected by plant operations, there is reasonable assurance that the operation of the facility will not result in radionuclide concentrations in the finished drinking water that are in excess of the requirements of 40 CFR Part 141. The dose calculation St. Lucie Plant ODCM Controls - Bases

Page 64 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM 3/4.11 RADIOACTIVE EFFLUENTS Continued BASES 3/4.11.1 LIQUID EFFLUENTS Continued 3/4.11.1.2 DOSE Continued methodology and parameters in the ODCM implement the requirements in Section III.A of Appendix I that conformance with the guides of Appendix I be shown by calcuiational procedures based on models and data, such that the actual exposure of a MEMBER OF THE PUBLIC through appropriate pathways Is unlikely to be substantially underestimated.

The equations specified in the ODCM for calculating the doses due to the actual release rates of radioactive materials in liquid effluents are consistent with the methodology provided in Regulatory Guide 1.109, 'Calculation of Annual Doses to Man from Routine Releases of Reactor Effluents for the Purpose of Evaluating Compliance with 10 CFR Part 50,

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Appendix I, 'Revision 1, October 1977 and Regulatory Guide 1.113, "Estimating Aquatic Dispersion of Effluents from Accidental and Routine Reactor Releases for the Purpose of Implementing Appendix I,'pril 1977.

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This control applies to the release of radioactive materials in liquid effluents from each unit at the site. For units with shared Radwaste Systems, the liquid effluents from the shared system are to be proportioned among the units sharing that system.

3/4.11.1.3 LI UID RADWASTE TREATMENT SYSTEM The OPERABILITYof the Liquid Radwaste Treatment System ensures that this system will be available for use whenever liquid eNuents require treatment prior to release to the environment. The requirement that the appropriate portions of this system be used when specified provides assurance that the releases of radioactive materials in liquid effluents will be kept 'as low as is reasonably achievable." This control implements the requirements of 10 CFR 50.36a, General Design Criterion 60 of Appendix A to 10 CFR Part 50 and the design objective given in Section II.D of Appendix I to 10 CFR Part 50. The specified limits governing the use of appropriate portions of the Liquid Radwaste Treatment System were specified as a suitable fraction of the dose design objectives set forth in Section II.A of Appendix I, 10 CFR Part 50 for liquid eNuents.

This control applies to the release of radioactive materials in liquid effluents from each unit at the site. For units with shared Radwaste Treatment Systems, the liquid effluents from the shared system are to be proportioned among the units sharing that system, St. Lucie Plant ODCM Controls - Bases

Page 65 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM RADIOACTIVE EFFLUENTS BASES 3/4.11.2 GASEOUS EFFLUENTS 3/4.11.2.1 DOSE RATE This control is provided to ensure that the dose at any time at and beyond the SITE BOUNDARY from gaseous effluents from all units on the site will be within the annual dose limits of 10 CFR Part 20 to UNRESTRICTED AREAS. The annual dose limits are the doses associated with the concentration of 10 CFR Part 20, Appendix B, Table II, Column I, These limits provide reasonable assurance that radioactive material discharged in gaseous eNuents will not result in the exposure of a MEMBER OF THE PUBLIC in an UNRESTRICTED AREA, either within or outside the SITE BOUNDARY, to an annual average concentration exceeding the limits specified in Appendix B, Table II of 10 CFR Part 20 (10 CFR Part 20.106(b)), For MEMBERS OF THE PUBLIC who may at times be within the SITE

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BOUNDARY, the occupancy of that MEMBER OF THE PUBLIC will usually be sufficiently low to compensate for any Increase in the atmospheric diffusion factor above that for the

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SITE BOUNDARY. The specified release rate limits restrict, at all times, the corresponding gamma and beta dose rates above background to a MEMBER OF THE PUBLIC at or beyond the SITE BOUNDARY to less than or equal to 500 mrems/year to the whole body or to less than or equal to 3000 mrem/year to the skin. These release rate limits also restrict, at all times, the corresponding thyroid dose rate above background to a child via4he inhalation pathway to less than or equal to 1500 mrems/year, This control applies to the release of radioactive materials in gaseous effluents from all units at the site.

The required detection capabilities for radioactive materials In gaseous waste samples are tabulated in terms of the lower limits of detection (LLDs), Detailed discussion of the LLD, and other detection limits can be found in Currie, L. A., 'Lower Limit of Detection:

Definition and Elaboration of a Proposed Position for Radiological Effluent and Environmental Measurements,'UREG/CR-4007 (September 1984), and in the HASL Procedures Manual, HASL-300.

St. Lucie Plant ODCM Controls - Bases

Page 66 of 180 ST, LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM RADIOACTIVE EFFLUENTS BASES 3/4.11.2.1 DOSE - NOBLE GASES This control is provided to implement the requirements of Sections II,B, III.Aand IV.A of Appendix I, 10 CFR Part 50. The control implements the guides set forth In Section I.B of Appendix I The ACTION statements provide the required operating flexibilityand at the

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same time implement the guides set forth in Section IV,A of Appendix I to assure that the releases of radioactive material in gaseous effluents to UNRESTRICTED AREAS will be kept "as low as is reasonably achievable." The Surveillance Requirements implement the requirements in Section III;Aof Appendix I that conformance with the guides of Appendix I be shown by calculational procedures based on models and data such that the actual exposure of a MEMBER OF THE PUBLIC through appropriate pathways is unlikely to be substantially underestimated. The dose calculation methodology-and parameters established in the ODCM for calculating the doses due to the actual release rates of

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radioactive noble gases in gaseous effluents are consistent with the methodology provided

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in Regulatory Guide 1 109, "Calculation of Annual Doses to Man from Routine Releases of

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Reactor Effluents for the Purpose of Evaluating Compliance with 10 CFR Part 50, "Appendix I, "Revision 1, October 1977 and Regulatory Guide 1.111, 'Methods for Estimating Atmospheric Transport and Dispersion of Gaseous Effluents in Routine Releases from Light-Water Cooled Reactors,'evision 1, July 1977. The ODCM equations provided for determining the air doses at and beyond the SITE BOUNDARY are based upon Ahe historical average atmospheric conditions.

This control applies to the release of radioactive materials in gaseous effluents from each unit at the site. For units with shared Radwaste Treatment Systems, the gaseous effluents from the shared system are to be proportioned among the units sharing that system.

3/4.11.2.3 DOSE - IODINE-131 IODINE-133 TRITIUM AND RADIOACTIVEMATERIAL IN PARTICULATE FORM This control is provided to implement the requirements of Sections II.C, III.Aand IV.A of Appendix I, 10 CFR Part 50. The Controls are the guides set forth in Section II.C of Appendix I. The ACTION statements provide the required operating flexibility and at the same time implement the guides set forth in Section IV.A of Appendix I to assure that the releases of radioactive material in gaseous effluents to UNRESTRICTED AREAS will be kept "as low as is reasonably achievable." The ODCM calcuiational methods specified in the St. Lucie Plant ODCM Controls - Bases

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Page 67 of 180 ST, LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM RADIOACTIVE EFFLUENTS BASES 3/4.11.2.1 DOSE - NOBLE GASES Continued 3/4.11.2.3 DOSE - IODINE-131 IODINE-133 TRITIUM AND RADIOACTIVEMATERIAL IN PARTICULATE FORM Continued Surveillance Requirements implement the requirements in Section III.A of Appendix I that conformance with the guides of Appendix I be shown by calculational procedures based on models and data such that the actual exposure of a MEMBER OF THE PUBLIC through appropriate pathways is unlikely to be substantially underestimated. The ODCM calculational methodology and parameters for calculating the doses due to the actual release

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rates of the subject material are consistent with the methodology provided In Regulatory Guide 1.109, ~'Calculation of Annual Doses to Man from Routine Releases of Reactor

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Effluents for the Purpose of Evalua'ting Compliance with 10 CFR Part 50, Apperidix I, "Revision 1, October 1977 and Regulatory Guide 1.111, "Methods for Estimating

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Atmospheric Transport and Dispersion of Gaseous Effluents in Routine Releases from Light-Water Cooled Reactors," Revision 1, July 1977, These equations also provide for determining the actual doses based upon the historical average atmospheric conditions.

The release rate controls for Iodine-131, Iodine-133, tritium, and radionuclides in particulate form with half-lives greater than 8 days are dependent upon the existing radionucIIde pathways to man in the areas at and beyond the SITE BOUNDARY. The pathways that were examined in the development of the calculations were: (1) individual inhalation of airborne radionuclldes, (2) deposition of radionuclides onto green leafy vegetation with subsequent consumption by man, (3) deposition onto grassy areas where milk animals and meat producing animals graze with consumption of the milk and meat by man, and (4) deposition on the ground with subsequent exposure of man.

This control applies to the release of radioactive materials in gaseous effluents from each unit at the site, For units witli shared Radwaste Treatment Systems, the gaseous effluents from the shared system are proportioned among the units sharing that system.

St. Lucie Plant ODCM Controls - Bases

Page 68 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM RADIOACTIVE EFFLUENTS BASES 3/4.11.2.4 GASEOUS RADWASTE TREATMENT SYSTEM The OPERABILITY of the WASTE GAS HOLDUP SYSTEM and the VENTILATION EXHAUST TREATMENT SYSTEM ensure that the systems will be available for use whenever gaseous effluents require treatment prior to release to the environment. The requirement that the appropriate portions of these systems be used, when specified, provides reasonable assurance that the releases of radioactive materials in gaseous eNuents will be kept 'as low as is reasonably achievable,'his control implements the requirements of 10 CFR 50.36a, General Design Criterion 60 of Appendix A to 10 CFR Part 50 and the design objective given in Section II.D of Appendix I to 10 CFR Part

50. The specified limits governing the use of appropriate portions of the systems were specified as a suitable fraction of the dose design objectives set forth in Section II.B and II.C-

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of Appendix I, 10 CFR Part 50 for gaseous effluents.

This control applies to the release of radioactive materials In gaseous eNuents from

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each unit at the site, For units with shared Radwaste Treatment Systems, the gaseous D

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effluents from the shared system are proportioned among the units sharing that system.

3/4.11.2.5 NOT USED 3/4.11.2.6 NOT USED 3/4.11.3 NOT USED 3/4.11.4 TOTAL DOSE This control is provided to meet the dose limitations of 10 CFR Part 190 that have been incorporated into 10 CFR Part 20 by 46 FR 18525, The control requires the preparation and submittal of a Special Report whenever the calculated doses due to releases of radioactivity and to radiation from uranium fuel cycle sources exceed 25 mrems to the whole body or any organ, except the thyroid, which shall be limited to less than or equal to 75 mrems. For sites containing up to four reactors, it is highly unlikely that the resultant dose to a MEMBER OF THE PUBLIC will exceed the dose limits of 40 CFR Part 190 if the individual reactors remain within twice the dose design objectives of Appendix I, and if direct radiation doses from the units (Including outside storage tanks, etc.) are kept small. The Special Report will describe a course of action that should result in the limitation St. Lucie Plant ODCM Controls - Bases

Page 69 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM RADIOACTIVE EFFLUENTS BASES 3/4.11.4 TOTAL DOSE Continued of the annual dose to a MEMBER OF THE PUBLIC to within the 40 CFR Part 190 limits.

For the purposes of the Special Report, it may be assumed that the dose commitment to the MEMBER OF THE PUBLIC from other uranium fuel cycle sources is negligible, with the exception that dose contributions from other nuclear fuel cycle facilities at the same site or within a radius of 8 kilometers must be considered. If the dose to any MEMBER OF THE PUBLIC is estimated to exceed the requirements of 40 CFR Part 190, the Special Report with a request for a variance (provided the release conditions resulting in violation of 40 CFR Part 190 have not already been corrected), in accordance with the provisions of 40 CFR 190.11 and 10 CFR 20.405c, is considered to be a timely request and fulfills the requirements of 40 CFR Part 190 until NRC staff action is completed, The variance only relates to the limits of 40 CFR Part 190, and does not apply in any way to the other requirements for dose limitation of 10 CFR Part 20, as addressed in Controls 3.11.1.1 and

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3.11.2.1 An individual is not considered a MEMBER OF THE PUBLIC during any period

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in which he/she is engaged in carrying out any operation that is part of the nuclear fuel

cycle, St. Lucie Plant ODCM Controls - Bases

Page 70 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM 3/4.12 RADIOLOGICALENVIRONMENTALMONITORING BASES 3/4.12.1 MONITORING PROGRAM The Radiological Environmental Monitoring Program required by this control provides representative measurements of radiation and of radioactive materials in those exposure pathways and for those radionuclides that lead to the highest potential radiation exposure of MEMBERS OF THE PUBLIC resulting from the plant operation. This monitoring program implementsSection IV.B,2 of Appendix I to 10 CFR Part 50 and thereby supplements the Radiological Effluent Monitoring Program by verifying that the measurable concentrations of radioactive materials and levels of radiation are not higher than expected on the basis of the effluen measurements and the modeling of the environmental exposure pathways.

Guidance for this monitoring program is provided by the Radiological Assessment Branch Technical Position on Environmental Monitoring, Revision 1, November 1979, The initially

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specified monitoring program will be effective for at least the first three years of commercial

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operation. Following this period, program changes may be initiated based on operational

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experience.

The required detection capabilities for environmental sample analyses are tabulated in terms of the lower limits of detection (LLDs). The LLDs required by Table 4.12-1 are considered optimum for routine environmental measurements in industrial laboratories. It should be recognized that the LLD ls defined as an a priori (before the fact) limit representtng the capablllty of a measurement system and not as an a gosterlorl (after the fact) limit for a particular measurement.

Detailed discussion of the LLD, and other detection limits can be found in Currie, L, A "Lower Limit of Detection: Definition and Elaboration of a Proposed Position for Radiological Effluent and Environmental Measurements,'UREG/CR<007 (September1984), and in the HASL Procedures Manual, HASL-300.

3/4.12.2 LAND USE CENSUS This control is provided to ensure that changes in the use of areas at and beyond the SITE BOUNDARY are identified and that modifications to the Radiological Environmental Monitoring Program given in the ODCM are made if required by the results of this census.

The best information from the door-to-door survey, from aerial survey or from consulting with local agricultural authorities shall be used.

St. Lucie Plant ODCM Controls - Bases

Page 71 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO, C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM .

RADIOLOGICAL ENVIRONMENTALMONITORING BASES 3/4.12.2 LAND USE CENSUS Continued This census satisfies the requirements of Section IV.B.3 of Appendix I to 10 CFR Part 50.

Restricting the census to gardens of greater than 50 square meters provides assurance that significant exposure pathways via leafy vegetables will be identified and monitored since a garden of this size is the minimum required to produce the quantity (26 kilograms/year) of leafy vegetables assumed in Regulatoiy Guide 1.109 for consumption by a child. To determine this minimum garden size, the following assumptions were made: (1) 20% of the garden was used for growing broad leaf vegetation (i.e., similar to lettuce and cabbage), and (2) a vegetation yield of 2 kilograms per square meter.

3/4.12.3 INTERLABORATORYCOMPARISON PROGRAM This requirement for participation in an approved Interiaboratory Comparison Program is provided to ensure that independent checks on the precision and accuracy of the measurements of radioactive materials in environmental sample matrices are performed as part of the quality assurance program for environmental monitoring in order to demonstrate that the results are valid for the purposes of Section IV.B.2 of Appendix I to 10 CFR Part 50.

St, Lucie Plant ODCM Controls - Bases

Page 72 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM METHODOLOGY SECTION METHODOLOGY for the CONTROLS AND SURVEILLANCE REQUIREMENTS

Page 73 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM METHODOLOGY SECTION GLOSSARY OF COMMONLY USED TERMS IN METHODOLOGY SECTION DB Dose from Beta Radiation CC or cc Cubic centimeter CI Curies - a unit of radioactivity see pCi C, Activity or concentration of a nuclide in the release source. Units of pCi, pCI/cc, or pCi/ml CFR Code of Federal Regulations Control(s) Regulations for operating, controlling, monitoring, and reporting radioactive effluen related activity as Indicated by the Controls Section of the ODCM.

Dose The exposure, in mrem or mrad, the organ or the individual receives from radioactive effluents Dose Factor Normally, a factor that converts the effect of ingesting radioactive material into the body, to dose to a specific organ. Body elimination, radioactive decay, and organ uptake are some of the factors that determine a dose factor for a given nuclide Dose Pathway - A specific path that radioactive material physically travels through prior to exposing an individual to radiation. The Grass-Cow-Milk-Infant is a dose pathway Dose Rate The dose received per unit time

'(D/Q) A long term D over Q - a factor with units of 1/m'hich describes the deposition of particulate matter from a plume at a point downrange from the source. It can be thought of as what part of the cloud is going to fallout and deposit over one square meter of ground. (See Appendix F).

FUSAR Final Updated Safety Analysis Report.

Page 74 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM METHODOLOGY SECTION GLOSSARY OF COMMONLY USED TERMS IN METHODOLOGY SECTION (continued)

A gamma photon - The dose from Gammas in air, etc.

Ground Plane Radioactive material deposited uniformly over the ground emits radiation that produces an exposure pathway when an individual is standing, sitting, etc., in the area. It is assumed that an adult receives the same exposure as an infant, regardless of the physical height differences. Only the whole body is considered for the ODCM.

H-3 Hydrogen-3, or Tritium, a weak Beta emitter I&8DP Radioiodines and particulates with half-lives greater than 8 days Ill Cubic Meters Square Meters MPC Maximum Permissible Concentration nuclide For the purposes of this manual, a radioactive isotope. Nuclide (i) signifies a specific nuclide, the 1st, 2nd, 3rd one under consideration. If nuclide (i) is l-131, then the Mi (dose factor) under consideration should be M,.>>, for example.

Organ For the ODCM either the bone, liver, thyroid, kidney, lung, GI-LLI, or the Whole Body. Whole Body is considered an organ for ease of writing the methodology in the ODCM.

pCi 1 pico-Curie = 1.E-12 Curies.

(Q Dot), (Q Dot), - Denotes a release rate in pCVsec for nuclide (i).

Q, Denotes p,CI of nuclide (i) released over a specified time interval.

Radiolodines Iodine-131 and Iodine I-133 for gaseous release pathways.

e Page 75 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM METHODOLOGY SECTION GLOSSARY OF COMMONLY USED TERMS IN METHODOLOGY SECTION (continued)

Receptor The individual receiving the exposure in a given location or who ingests food products from an animal for example. A receptor can receive dose from one or more pathways.

Release Source(s) - A subsystem, tank, or vent where radioactive material can be released independently of other radioactive release points.

TS The St, Lucie Plant Standard Technical Specifications Total Body Same as Whole Body in Control Statements

" micro Curies, 1 pCI =10~ Curies. The pCI is the standardunit of radioactivity for all dose calculations in the ODCM, A long term Chi over Q. It describes the physical dispersion (X/Q) characteristics of a semi-infinite cloud of noble gases as the cloud traverses downrange from the release point. Since Noble Gases are inert, they do not tend to settle out on the ground. (See Appendix F).

(X/Q)() A long term Depleted Chi over Q. It describes the physical dispersion characteristics of a semi-infinite cloud of radioactive lodines and particulates as the cloud travels downrange. Since lodines and particulates tend to settle out (fallout of the cloud) on the ground, the (X/Q), represents what physically remains of the cloud and its dispersion qualities at a given location downrange from the release point. (See Appendix F).

dt, ht, or delta t - A specific delta time interval that corresponds with the release interval data etc.

Page 76 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM METHODOLOGY SECTION 1.0 LI UID RELEASES METHODOLOGY

Page 77 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM METHODOLOGY SECTION 1 ~1 Radioactive Li uid Effluent Model Assum tions The FUSAR contains the official description of the site characteristics. The description that follows is a brief summary for dose calculation purposes:

The St. Lucie Plant is located on an island surrounded on two sides by the Atlantic Ocean and the Indian River, an estuary of the Atlantic Ocean.

Normally, all radioactive liquid releases enter the Atlantic Ocean where the Circulating Water Discharge Pipe terminates on the ocean floor at a point approximately 1200 feet offshore. No credit is taken for subsequent mixing of the discharge flume with the ocean. The diffusion of radioactive material into the ocean is dependent on the conditions of tide, wind, and some eddy currents caused by the Gulf Stream. The conditions are sufficiently random enough to distribute the discharges over a wide area and no concentrating effects are assumed.

There are no direct discharge paths for liquid effluents to either of the north or south private property boundary lines. The Big Mud Creek (part of the Indian River) does connect to a normally locked shut dam, that is intended to provide an emergency< supply of circulating water to the Intake Cooling Water Canal in the event a Hurricane causes blockage of the Intake Canal No radioactive

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water could be discharged directly into the Intake Cooling Water Canal because all plant piping is routed to the discharge canal and no back flow can occur. Consult the FUSAR for a detailed description of characteristics of the water bodies surrounding the plant site.

Only those nuclides that appear in the Liquid Dose Factor Tables will be considered for dose calculation.

Page 78 of 180 ST, LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM METHODOLOGY SECTION 1.2 Determinin the Fraction F of 10 CFR Part 20 MPC Limits for A Li uid Release Source Discussion - Control 3.11.1.1 requires that the sampling and analysis results of liquid waste (prior to discharge) be used with calculation methods in the in-plant procedures to assure that the concentration of liquid radioactive material in the unrestricted areas will not exceed the concentrations specified in 10 CFR Part 20, Appendix B, Table II. Chemistry Procedure C-70 'Processing Aerated Liquid.

Waste" provides instruction for ensuring batch release tanks will be sampled after adequate mixing. This section presents the calculation method to be used for this determination. This method only addresses the calculation for a specific release source. The in-plant procedures will provide instructions for determining that the summation of each release source's F values do not exceed the site's 10 CFR Part 20 MPC limit. The values for release rate, dilution rate, etc., will also have to be obtained from in-plant procedures. The basic equation is:

n F~ =

R D

Z C,

(MPC) /

/1 Where:

F the fraction of 10 CFR Part 20 MPC that would result if the release source was discharged under the conditions specified.

The undiluted release rate in gpm of the release source.

Liquid Rad Waste = 170 gpm Steam Generator = 125 gpm/Steam Generator The dilution flow in gpm of Intake Cooling Water or Circulating Water Pumps Intake Cooling flow is 14,500 gpm/pump Circulating Water flow is 121,000 gpm/pump C, The undiluted concentration of nuclide (i) in pCVml from sample assay (MPC), The maximum permissible concentration of nuclide (i) in IiCVml from Table L-1. For dissolved or entrained noble gases the MPC value is 2 X 10~ pCi/ml for the sum of all gases.

Page 79 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM METHODOLOGY SECTION 1.2 (continued)

The fraction of the 10 CFR Part 20 MPC limit may be determined by a nuclide-by-nuclide evaluation or for purposes of simplifying the calculation by a cumulative activity evaluation. If the simplified method is used, the value of 3 X 10~ pCi/ml (unidentified MPC value) should be substituted for (MPC), and the cumulative concentration (sum of all identified radionuclide concentrations) or the gross concentration should be substituted for C,, As long as the diluted concentration (C~ R/D) is less than 3 X 10~ pCVml, the nuclide-by-nuclide calculation is not required to demonstrate compliance with the 10 CFR Part 20 MPC limit. The following section provides a step-by-step procedure for determining the MPC fraction.

1, Calculation Process for Solids A. Obtain from the in-plant procedures, the release rate value (R) in gpm for the release source, B. Obtain from the in-plant procedures, the dilution rate (D) In gpm. No credit is taken for any dilution beyond the discharge canal flow.

C, Obtain (C,), the undiluted assay value of nuclide (i), in pCVml If the

~

simplified method is used, the cumulative concentration (Ctotai) Is used, D. From Table L-1, obtain the corresponding'(MPC) for nuclide (I) in pCVml ~

The value of 3 X 10~ pCVml should be used for the simplified method.

E. Divide C, by (MPC), and write down the quotient F. If the simplified method is used, proceed to the next step. If determining the MPC fraction by the nuclide-by-nuclide evaluation, repeat steps 1,2.1,C through 1.2.1.E for each nuclide reported in the assay, for H, from previous month composite, and for SR89/90 and Fe55 from previous quarter composite.

Page 80 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM METMODOLOGY SECTION 1.2 (continued) 1, (continued)

G. Add each C/(MPC) quotient from step 1.2.1.E and solve for Fas follows:

n F= R C,

Z

. D I 1 (MPC) i F, = a unit-less value where:

the value of Fcould be < or >1. The purpose of the calculation is to determine what the initial value of F is for a given set of release conditions, If F is >1, administrative steps are taken to ensure that the actual release conditions for dilution will ensure that F is <1 during the actual release. F is called the fraction of 10 CFR Part 20 MPC because it should never be allowed to be >1,

2. Calculation Process for Gases in Liquid A. Sum the pCi/ml of each noble gas activity reported in the release.

B. The values of R and D from 1.2.1 above shall be used in the calculations below:

(sum of 1,2,2.A) pCiml ~ R 0

.1 D C. F, shall be less than 2 X 10~ pCVml for the site for all releases in progress.

Each release point will be administratively controlled. Consult in-plant procedures for instructions.

Page 81 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM METHODOLOGY SECTION 1.3 Determinin Set pints for Radioactive Li uid Effluent Monitors Discussion - Control 3.3.3.10 requires that the liquid 'effluent monitoring instrumentation alarm/trip setpoints be set to initiate an alarm or trip so that the radioactivity concentration in water in the unrestricted area does not exceed the concentration of 10 CFR Part 20, Appendix B, Table II as a result of radioactivity in liquid effluents (Control 3.11.1.1). This section presents the method to be used for determining the instrumentation setpoints.

Gross cpm vs. total liquid activity curves are available for Liquid Effluent Monitors based on a composite of real release data. A direct correlation between gross cpm and the concentrations that would achieve 10 CFR Part 20 MPC levels in the discharge canal can be estimated. The 1978 liquid release data from annual reports was used to determine the average undiluted release concentration. These concentrations were then projected to a diluted concentration in the discharge canal assuming a 1 gpm release rate and a constant dilution flow of 121,000 gpm from 1 circ. water pump. This diluted activity,was divided by the nuclide's respective 10 CFR Part 20 MPC value (Table L-1) to obtain the Mi column on the table that follows:

Page 82 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM METHODOLOGY SECTION 1.3 (continued)

TABLE 1.3 NUCLIDE SYMBOL 1978 UNDILUTED pCVrnl M, (no units) l-131 4A3 E-5 1.22 E-3 l-132 2.23 E-7 2.30 E-7 1-133 3.17 EW 2.62 E-5 I-135 1.31 EW 2.71 EW Na-24 1.72 E-7 4.74 E-8 Cr-51 2.51 E.5 1.04 E-7 Mn-54 5.64 E4 4.66 E-7 Mn-56 1 ~ 11 E-9 9.17 E-11 Co-57 3.69 E-7 7.62 E-9 Co-58 1.51 EA 1.39 E-5 Fe-59 2.92 EW 4.83 E-7 Co+0 3.66 E-5 1.00 E-5 Zn-65 4.55 E-7 3.76 E-8 NIM 8.23 E-7 6.80 E-8 Ag-110 1.96 EW 5.40 E-7 Sn-113 5.75 E-7 5.94 E-8 Sb-122 2.15 EW 5.95 E-7 Sb-124 8AO EW 3.47 EW W-187 3.51 EW 4.83 E-7 Np-239 1.57 E.7 1.30 E-8 Br<2 3.64 E-7 7.52 E-8 Zr-95 2.82 E-5 3.88 E-6 Zr-97 4.05 EW 1.67 EW Mo-99 3.24 EW 6.70 E-7 Ru-103 3,84 E-8 4.00 E-9 Sb-125 2.26 EW 1.87 E-7 Cs-134 2.14 E-5 1.96 E-5 Cs-136 7.82 E-7 1.08 E-7 Cs-137 4.85 E-5 2.00 E-5 Ba-140 6A4 E-7 2.66 E-8 Ce-141 3.04 E-8 2.80 E.9 Ce-144 2.37 EW 1.96 EW 4.01 EW 1.33 E-3 (1) 1978 Undiluted Release Volume = 7 E 9 ml.

978 Undl'l Act Nuclide (I) gpm (release rate)

(2) > 1

< 1 MPC, (from Table L-1) 121000 gpm (dil rate)

Page 83 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM METHODOLOGY SECTION 1.3 (continued)

A<< is the total average pCi/ml concentration of the reference mixture and M<< is the fraction of the MPC of all nuclides for the release conditions specified. Dividing A<<by M<<yields to the MPC limit A,

for the which is the maximum total activity concentration equivalent nuclide distribution typical of radwaste discharges.

'" =

A~ = M1.33 '.302 EN pCkml The assumption that the mixture does not change is only used for calculational purposes.

1. The (C~ value in cpm should be obtained for the A (0.302 pCVml) from the release sources radioactive liquid effluent monitor curve of cpm vs. pCVml.

NOTE This setpoint is for a specified release of 1 gpm into 121000 gpm dilution flow.

2. For establishing the setpoint prior to liquid radwaste discharges, the (C~ will be adjusted as needed to account for actual release conditions (i.e., dilution flow rate, and the contribution of dissolved and entrained Nobles Gas Activity to the Monitor Activity Level).

1.4 Determinin the Dose for Radioactive Li uid Releases Discussion - Control 3.11.1.2 requires calculations be performed at least once per 31 days to verify that cumulative radioactive liquid effluents do not cause a dose in excess of 1.5 mrem to the whole body and 5 mrem to any organ during any calendar quarter and not in excess of 3 mrem to the whole body and 10 mrem to any organ during any calendar year. This section presents calculational method to be used for this verification.

This method is based on the methodology suggested by sections 4.3 and 4.3.1 of NUREG-0133 Revision 1, November, 1978. The dose factors are a composite of both the fish and shellfish pathways so that the fish-shellfish pathway is the only pathway for which dose will be calculated. For St. Lucie Plant, the adult is the most limiting age group, but the dose for child, and teenager can also be calculated by this method provided that their appropriate dose factors are available for the organ of interest. Only those nuclides that appear in the Tables of this manual will be considered.

Page 84 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM METHODOLOGY SECTION 1.4 (continued) 1 ~ This method provides for a dose calculation to the whole body or any organ for a given age group based on real release conditions during a specified time interval for radioactive liquid release sources. The equation is:

Arr dt~ Q (DF Where:

D, = dose commitment in mrem received by organ T of age group (to be specified) during the release time interval dt,.

A = the composite dose factor for the fish-shellfish pathway for nuclide (i) for organ T of age group (to be specified). The A~ values listed in the Tables in this manual are independent of any site specific information and have the units mrem-ml p,Cl-hr dt, = the number of hours that the release occurs.

Qg = The total quantity of nuclide (I) release during dt, (Ii,CI)

(DF), = The total volume of dilution that occurred during the release time period dt, (i.e the circulating water flow times time)

'he doses associated with each release may then be summed to provide the cumulative dose over a desired time period (e.g., sum all doses for release during a 31 day period, calendar quarter or a year).

Where:

DT = the total dose commitment to organ ~ due to all releases during the desired time interval (mrem)

Page 85 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION .

11 OFFSITE DOSE CALCULATION MANUAL ODCM,.

METHODOLOGY SECTION 1A (continued)

1. (continued)

Based on the.radionuclide distribution typical in radioactive effluents, the calculated doses to individuals are dominated by the radionuclides Fe-59, Co-58, Co-60, Zn-65, Nb-95, Cs-134 and Cs-137. These nuclides typically contribute over 95% of the whole body dose and over 90% of the Gl-LLI dose, which is the critical organ. Therefore, the dose commitment due to radioactivity in liquid effluents may be reasonably evaluated by limiting the dose calculation process to these radionuclides for the adult whole body and adult Gl-LLI. To allow for any unexpected variability in the radionuclide distribution, a conservatism factor of 0.6 is introduced into the, equation. After calculating the dose based on these 7 nuclides, the cumulative dose should be divided by 0.6, the conservatism factor. (i.e., D, = DQ0.6). Refer to Appendix B for a detailed, evaluation and explanation of this, limited analysis approach.

The methodology that follows is a,step-by-step breakdown to calculate doses based on the above equation. Refer to the in-plant procedures to determine the applicable organs, age groups, and pathway factors. If the limited analysis approach is used, the calculation should be limited to the Adult whole body dose and Adult Gl-LLI dose from the fish and shellfish pathways. Only the 7-previously specified radionuclides should be evaluated. For the dose calculations to be included in annual reports, the doses to the adult groups and all organs should be evaluated for. all radionuclides identified in the liquid effluents.

NOTE Table 1.4 provides a convenient form for compiling the dose accounting.

A, Determine the time interval dt, that the release took place. The in-plant procedures shall describe thelprocedure for calculating dt, for official release purposes.

B. Obtain (DF), for the time period dt, from Liquid Waste Management Records for the release source(s) of interest.

C. Obtain Q,l for nuclide (i) for the time period dt, from the Liquid Waste Management Records D. Obtain A~ from the appropriate Liquid Dose Factor Table

Page 86 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM METHODOLOGY SECTION 1.4 (continued)

1. (continued)

'~

TABLE 1.4 FISH AND SHELLFISH PATHWAY TIME/DATE START: TIME/DATE STOP: HOURS TOTAL DILUTION VOLUME:

AGE GROUP: -

ORGAN'ls DOSE FACTOR TABLE ¹:

NUCLIDE (i) C, (p,CI) DOSE (i) mrem Fe-59 Co-58

.. Co-60 Zn-65 Nb-95 Cs-134 Cs-137 OTHERS TOTAL DOSE T = mrem If based on limited analysis, divide by 0.6 mrem E. Solve for Dose (i)

~n df> A<

p ()

(DQ

Page 87 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM METHODOLOGY SECTION 1.4 (continued)

1. (continued)

K F. Repeat steps 1.4.1.C through 1.4.1.E for each nuclide reported and each organ required. If the limited analysis method is used, limit the radionuclides to Fe-59, Co-58, Co-60, Zn-65, Nb-95, Cs-134, and Cs-137 and determine the adult whole body dose and the adult Gl-LLI dose.

G, Sum the Dose (i) values to obtain the total dose to organ T from the fish-shellfish pathway. If the limited analysis method is being used, divide the cumulative dose by a conservatism factor of 0.6 to account for any unexpected variability in radionuclide distribution 1.5 Pro ectin Dose for Radioactive Li uid ENuents Discussion - Control 3.11.1.3 requires that appropriate subsystems of the liquid radwaste treatment system be used to reduce radioactive material In liquid eNuents when the projected doses due to the liquid eNuent, from each unit, to UNRESTRICTED AREAS (see TS Figure 5,1-1) would exceed 0.06 mrem to the whole body or 0.2 mrem to any organ in a 31 day period. The following calculation method is provided for performing this dose projection, The method is based on dose as calculated in section 1.4 with the adult as the bases for projecting.

1 ~ Obtain the latest result of the monthly calculation of the adult whole body dose and the adult's highest organ dose. These doses can be obtained from the

'n-plant records.

2. Divide each dose by the number of days the reactor plant was operational during the month.

3. Multiply the quotient of each dose by the number of days the reactor plant is projected to be operational during the next month. The products are the projected dose for the next month. These values should be adjusted as needed to account for any changes in failed fuel or other identifiable operating conditions that could significantly alter the actual releases.

4. If the projected dose is greater than 0.06 mrem to the whole body or greater than 0.2 mrem to the adults highest exposed organ, the liquid radwaste system shall be used.

Page 88 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM METHODOLOGY SECTION 2.0 GASEOUS RELEASES METHODOLOGY

Page 89 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM METHODOLOGY SECTION Gaseous Effluent Model Assum tions Descri tion of Site - (The FUSAR contains the official description of the site characteristics. The description that follows is a brief summary for dose calculation purposes only) The St. Lucie Plant'is located on an island surrounded on two

~

sides by the Atlantic Ocean and the Indian River, an estuary of the Atlantic Ocean.,

Private property adjoins the plant site in the north and south directions. A meteorological tower is located north of the plant near the site property line. There are 16 sectors, for dose calculation purposes, divided into 22.5'ach. The MET tower is calibrated such that a zero degree bearing coincides with TRUE NORTH.

A bearing of zero degrees dissects the north sector such that bearings of 348.75'nd 11.25'efine the boundaries of the north sector. The nearest distance to private property occurs in the north sector at approximately 0.97 miles. For ease of calculation, this 0.97 mile radius is assumed in all directions, although the real Unrestricted Area Boundary is defined in Figure 5.1-1 of the TS. Doses calculated over water areas do not apply to Controls or the annual report and may be listed as O.W. (over water) in lieu of performing calculations. The 0.97 mile range in the NW sector is O.W., but it was chosen as the worst sector for conservative dose calculations using the historical MET data.

Historical MET Data - MET data, between September 1, 1976 and August 31, 1978, from the St. Lucie MET Tower was analyzed by Dames & Moore of Washington, D.C. The methodology used by Dames 8 Moore was consistent with methods suggested by Regulatory Guide 1.111, Revision 1, Recirculation correction factors were also calculated for the St. Lucie Site and are incorporated into the historical MET tables (Tables M5, M6, and M7) in Appendix A of this manual. It was determined that these two years are representative data for this locale.

Dose Calculations - Dose calculations for Control dose limits are normally calculated using historical MET data and receptor location(s) which yield calculated doses no lower than the real location(s) experiencing the most exposure. Actual MET data factors are calculated and used in dose calculations for the annual reports.

Live MET data and hour-by-hour dose calculations are beyond the scope of this manual Historical information and conservative receptor locations, etc., are only

~

used for ease of Control dose limit calculations. Dose calculations for Control dose limits may be performed using actual MET data and real receptor locations. Any dose calculations performed with actual data should note the source of the data in the annual report. Actual MET data reduction should be performed in accordance with Regulatory Guide 1.111, Revision 1 and should incorporate Recirculation Correction Factors from Table M-4 of this manual.

Page 90 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM METHODOLOGY SECTION 2.1 (continued)

Dose Calculations - (continued)

The St. Lucie site uses the long term ground release model for all gaseous effluents. Only those radionuclides that appear in the gaseous effluent dose factor, tables will be considered in any dose calculations. Radioiodines are defined as Iodine-131 and I-133 for application to Controls. Other nuclides of Iodine may be included in dose calculations for ease of performing calculations, but their dose contribution does not have to be included in the Control requirements. Land Census information will apply to the calendar year following the year that the census was taken in to avoid splitting quarters, etc.

2.2 Determinin the Whole Bod and Skin Dose Rates for Noble Gas Releases And Establishin Set pints for Effluent Monitors Discussion - Control 3.11.2.1 limits the dose rate from noble gases in airborne

" releases to <500 mrem/yr - whole body and <3000 mrem/yr - skin. Control 3.3.3,11 requires that the gaseous radioactive effluent monitoring instrumentation be operable with alarm/trip setpoints set to ensure that these dose rate limits are not exceeded. The results of the sampling and analysis program of Control Table 4.11-2 are used to demonstrate compliance with these limits.

The following calculation method is provided for determining the dose rates to the whole body and skin from noble gases in airborne releases. The alarm/trip setpoints are based on the dose rate calculations. The Controls apply to all airborne releases on the site but all releases may be treated as if discharged from a single release point. Only those noble gases appearing in Table G-2 will be considered. The calculation methods are based on Sections 5.1 and 5.2 of NUREG-0133, November 1978. The equations are:

For WHOLE BODY Dose Rate:

n DR~ = Z K, (X/Q) (Q DO7)(

I For TOTAL SKIN Dose Rate:

n DR~= Z [L(+ 1.1 MJ (X/Q) (Q DO7),

I

Page 91 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM METHODOLOGY SECTION 2.2 (continued)

Where:

DR~ = whole body dose rate from noble gases in airborne releases (mrem/yr)

DR~= skin dose rate from noble gases in airborne releases (mrem/yr) a mathematical symbol to signify the operations to the right of the symbol are to be performed for each noble gas nuclide (i) through (n), and the individual nuclide doses are summed to arrive at the total dose rate for the release source.

the whole body dose factor due to gamma emissions for each noble gas nuclide reported in the release source. (mrem-m'/pCi-yr)

= the skin dose factor due to beta emissions for each noble gas nuclide (i) reported in the assay of the release source. (mrem-m'/pCi-yr)

M, the air dose factor due to gamma emissions for each noble gas nuclide (i) reported in the assay of the release source. The constant 1.1 converts mrad to mrem since the units of M, are in (mrad-m'/p,Ci-yr)

(X/Q) = for ground level, the highest calculated annual long term historic relative concentration for any of the 16 sectors, at or beyond the exclusion area boundary (sec/m')

(Q DOT), = The release rate of noble gas nuclide (i) in pCVsec from the release source of interest

1. Simplified Whole Body Dose Rate Calculation From an evaluation of past releases, an effective whole body dose factor (K,)

can be derived. This dose factor is in effect a weighted average whole body dose factor, i.e., weighted by the radionuclide distribution typical of past operation. (Refer to Appendix C for a detailed explanation and evaluation of K,). The value of ~ has been derived from the radioactive noble gas effluents for the years 1978, 1979, and 1980. The value is:

68 g1~ mrem-m',C/-yr

Page 92 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM METHODOLOGY SECTION 2.2 (continued)

1. (continued)

This value may be used in conjunction with the total noble gas release rate (Q DOT), to verify that the dose rate is within the allowable limits. To allow for any unexpected variability in the radionuclide distribution, a conservatism factor of 0.8 is introduced into the calculation. The simplified equation is:

DRwB =

08 j (9 DQ7) I

'o further simplify the determination, the historical annual average meteorological X/Q of 1.6 X 10~ sec/m'From Table M-1) may be substituted into the equation. Also, the dose limit of 500 mrem/yr may be substituted for DR~. Making these substitutions yields a single cumulative (or gross) noble gas release rate limit. This value is:

Noble gas release rate limit = 3.5 X 10'CI/sec As long as the noble gas release rates do not exceed this value (3.5 X no additional dose rate calculations are needed to verify compliance 10',CI/sec),

with Control 3.11.2.1.

Page 93 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM METHODOLOGY SECTION 2.2 (continued)

2. Setpoint Determination To comply with Control 3.3.3.11, the alarm/trip setpoints are established to ensure that the noble gas releases do not exceed the value of 3.5 X which corresponds to a whole body dose rate of 500 mrem/yr. The10'.CVsec, method that follows is a step-by-step procedure for establishing the setpoints.

To allow for multiple sources of releases from different or common release points, the allowable operating setpoints will be controlled administratively by allocating a percentage of the total allowable release to each of the release sources.

A. Determine (V) the maximum volume release rate potential from the in-plant procedures for the release source under consideration. The units of (V) are ft'/min.

B. Solve for A, the activity concentration in pCi/cc that would produce the Y control dose rate Limit.

3.5 X10'Ci X min X

5'3 X 60 sec sec (g ft'.8317 X 10'cc min A = pCVcc C. Refer to the pCi/cc vs. cpm curve for the Release Source's Gaseous Effluent Monitor cpm value (C), corresponding to the value of A above.

D. C is the 100% setpoint, assuming that there are no other release sources on the site.

E. Obtain the current % allocated to this release source from the gaseous waste management logs.

Page 94 of 180 ST, LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11

, OFFSITE DOSE CALCULATION MANUAL ODCM METHODOLOGY SECTION 2.2 (continued)

2. (continued)

F. The Operating setpoint SP gP c rn X l0 a//otted ~y in-Plant Procedures (P 100%

The whole body dose is more limiting than the calculated skin dose. (Refer to Appendix C for a detailed evaluation.) Therefore, the skin dose rate calculations are not required if the simplified dose rate calculation is used (i.e., use of K to determine release rate limits).

The calculation process of the following Section (2,2.3) is to be used if actual releases of noble gases exceed the above limit of 3.5 X 10',Ci/sec.

Under these conditions, a nuclide-by-nuclide evaluation is required to evaluate compliance with the dose rate limits of Control 3.11.2.1.

3. Whole Body and Skin Nuclide Specific Dose Rate Calculations The following outline provides a step-by-step explanation of how the whole body dose rate is calculated on a nuclide-by-nuclide basis to evaluate compliance with Control 3.11.2.1. This method is only used if the actual releases exceed the value of 3.5 X 10'.CI/sec.

A. The (X/Q) value = sec/m'nd is the most limiting sector at the exclusion area. (See Table M-1 for value and sector.)

B. Enter the release rate in ft'/min of the release source and convert it to:

min ft'0 X 2'8317 X 10 cc X cc/sec volume release rate min sec

Page 95 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM METHODOLOGY SECTION 2.2 (continued)

3. (continued)

C. Solve for(Q DOT), for nuclide (i) by obtaining the pCi/cc assay value of the release source and multiplying it by the product of 2.2.3.B above.

(Q DOT), = (nuclide [I])

(assay) p,Ci

< (2,2.3.B va/ue) cc CC sec (Q DOT), = p,Ci/sec for nuclide (i)

D. To evaluate the whole body dose rate obtain the K, value for nuclide (i) from Table G-2.

E. Solve for DR~

mrem-m' sec p.Ci OR /gg/Q) (Q pp7) m'ec g p,Ci-yr DR~ = mrem whole body dose from nuclide (i) for yr the specified release source F. To evaluate the skin dose rate, obtain the L, and M, values from Table G-2 for nuclide (i).

G. Solve for DR~,

DRIidrt i [Li + 1 1 M) (X/Q)(Q DOT)i DR , = mrem skin dose from nuciide 0) for the yr specitied release source

Page 96 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM METHODOLOGY SECTION 2.2 (continued)

3. (continued)

H. Repeat steps 2.2.3.D through 2,2.3.G for each noble gas nuclide (i) reported in the assay of the release source.

I. The Dose Rate to the Whole Body from radioactive noble gas gamma radiation from the specified release source is:

n DR~ = Z DR~

I J. The Dose Rate to the skin from noble gas radiation from the specified release source is:

The dose rate contribution of this release source shall be added to all other gaseous release sources that are in progress at the time of interest. Refer to in-plant procedures and logs to determine the Total Dose Rate to the Whole Body and Skin from noble gas effluents.

Page 97 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM METHODOLOGY SECTION 2,3 Determinin the Radioiodine 8 Particulate Dose Rate to An Or an From Gaseous Releases Discussion - Control 3.11.2.1 limits the dose rate from l-131, l-133, tritium and all radionuclides in particulate form with half lives >eight days to <1500 mrem/yr to any organ, The following calculation method is provided for determining the dose rate from radioiodines (see 2.1) and particulates and is based on Section 5.2.1 and 5.2,1.1 through 5.2:1,3 in NUREG-0133, November 1978. The Infant is the controlling age group in the inhalation, ground plane, and cow/goat milk pathways, which are the only pathways considered for releases. The long term (X/Q),

(depleted) and (D/Q) values are based on historical MET data prior to implementing Appendix I. Only those nuclides that appear on their respective table will be considered. The equations are:

For Inhalation Pathwa excludin H-3:

n R DR~~op Z (X/Q)0 (Q DO7)]

I For Ground Plane:

n DR~ggF, = Z ~

(D/Q)(Q D07),

I For Grass-Cow/Goat-Milk:

n DR = Z R ~

(D/Q)(Q DO7),

For Tritium Releases Inhalation 8 Grass-Cow/Goat-Milk:

DR~ = R~ 3 7 (XIQ)0 (Q DO7)~

Normally should be Pibut Ri~ values are the same, thus use Ri~ tables in Appendix A.

Page 98 of 180 ST, LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM METHODOLOGY SECTION 2.3 (continued)

For Total Dose Rate from I & 8DP and H-3 To An Infant Or an T:

Z DR~ = Z [DRuBDp + DR~)

Where:

The organ of interest for the infant age group The applicable pathways Dose Rate in mrem/yr to the organ T from iodines and 8 day I&8DPT particulates DRH = Dose Rate in mrem/yr to organ T from Tritium T

DR7 Total Dose Rate in mrem/yr to organ T from all pathways under consideration A mathematical symbol to signify the operations to the right of the symbol are to be performed for each nuclide (i) through (n),

and the individual nuclide dose rates are summed to arrive at the total dose rate from the pathway.

A mathematical symbol to indicate that the total dose rate D, to organ T is the sum of each of the pathways dose rates R, The dose factor for nuclide (i) for organ T for the pathway specified (units vary by pathway)

P, The dose factor for instantaneous ground plane pathway in units of mrem-m'ec p,Ci-yr

Page 99 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM METHODOLOGY SECTION 2.3 (continued)

From an evaluation of the radioactive releases and environmental pathways, the grass-cow/goat-milk pathway has been identified as the most limiting pathway with the infant's thyroid being the critical organ. This pathway typically contributes >90/o of the total dose received by the infant's thyroid and the radioiodine contribute essentially all of this dose. Therefore, it is possible to demonstrate compliance with the release rate limit of Control 3.11,2.1 for radioiodines and particulates by only evaluating the infant's thyroid dose for the release of radioiodines via the grass-cow/goat-milk pathway. The calculation method of Section 2.3.3 is used for this determination. If this limited analysis approach is used, the dose calculations for other radioactive particulate matter and other pathways need not be performed.

Only the calculations of Section 2.3.3 for the radioiodines need be performed to demonstrate compliance with the Control dose rate limit.

The calculations of Sections 2.3.1, 2.3.2, 2.3.4, and 2.3,5 may be omitted. The rate calculations as specified In these sections are included for completeness

" dose and are to be used only for evaluating unusual circumstances where releases of particulate materials other than radioiodines in airborne releases are abnormally high. The calculations of Sections 2.3.1, 2,3.2, 2.3.4, and 2.3,5 will typically be used to demonstrate compliance with the dose rate limit of Control 3.11,2.1 for radioiodines and particulates when the measured releases of particulate material (other than radioiodines and with half lives >8 days) are >10 times the measured releases of radioiodines.

1 ~ The Inhalation Dose Rate Method:

NOTE The H-3 dose ls calculated as per 2.3.4.

A. The controlling location is assumed to be an Infant locate'd in the sector at the mile range. The (X/Q)0 for this location is sec/m'. This value is common to all nuclides. (See Table M-2 for value, sector and range.)

B. Enter the release rate in ft'/min of the release source and convert to cc/sec.

X ' cc X m" cc/sec min 60 sec.

Page 100 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM METHODOLOGY SECTION 2.3 (continued)

1. (continued)

C. Solve for (Q DOT), for nuclide (i) by obtaining the pCi/cc assay value of the release source activity and multiplying it by the product of 2.3.1.B above.

(nuclide [i] assay) pCi X ( Value 2.3. 1 .8) cc (Q DQT)

CC ~

sec (Q DOT), = pCi/sec for nuclide (i)

D, Obtain the R, value from Table G-5 for the organ T.

E. Solve for DR, DR~ = R~ (X/Q)~ (Q DOT), = .' X X pCI-gf m3 sec DR~ = mrem The Dose Rate to organ T from nuclide (i) yr F. Repeat steps 2.3.1.C through 2.3.1.E for each nuclide (i) reported in the assay of the release source.

G. The Dose Rate to the Infants organ T from the Inhalation Pathway is:

DRI~f1 = DR, + DR, + + DR for all nuclides except H-3. This dose rate shall be added to the other pathways as per 2.3.6 - Total Organ Dose.

NOTE Steps 2.3.1.O through 2.3.1.G need to be completed for each organ T of the Infant.

Page 101 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM METHODOLOGY SECTION 2,3 (continued)

2. The Ground Plane Dose Rate Method:

NOTE Tritium dose via the ground plane is zero.

A. The controlling location is assumed to be an Infant located in the sector at the mile range. The (D/Q) for this location is 1/m'. This value is common to all nuclides. (See Table M-2 for sector, range and value.)

B, Enter the release rate in ft'/min of the release source and convert to cc/sec.

X 2.8317 f't3X10'<<X min = <</sec min 60 sec.

C. Solve for (Q DOT), for nuclide (I) by obtaining the pCi/cc assay value from the release source activity and multiplying it by the product of 2.3.2,B above.

(Q DO ) - (nuclide [i] assay) p.C/ X (Value 2.3.2.8) cc

<< sec (Q DOT), = pCI/sec for nuclide (i)

D, Obtain the P, value from Table G-3 E. Solve for DR,

=P (D/Q)(QDOT) mrem-m'- sec X,1 X pcl DR pCl yr m2 sec DR, = mrem The Dose Rate to organ T from nuclide (i) yr

Page 102 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM METHODOLOGY SECTION 2.3 (continued)

2. (continued)

F. Repeat steps 2.3.2.C through 2.3.2.E for each nuclide (i) reported in the assay of the release source.

G. The Dose Rate to the Infant's Whole Body from the Ground Plane Pathway Is:

DRG,P, = DR, + DR2+ + DR for all nuclides. This dose rate shall be added to the other pathways as per 2.3.5.

3. The Grass-Cow/Goat-Milk Dose Rate Method:

NOTE H-3 dose ls calculated as per 2.3.4.

A. The controlling animal was established as a located in the sector at miles. The (D/Q) for this location is 1/m'. This value iscommonto allnuclides. (See Table M-3 for sector, range, and value.)

B. Enter the anticipated release rate in ft'/min of the release source and convert to cc/sec.

~s min X 2.8317 X10'cc X min 60 sec.

C. Solve for (Q DOT), for nuclide (i) by obtaining the p,CI/cc assay value of the release source activity and multiplying it by the product of 2,3.3.B above.

(Q QQ7)

(nuclide [11 'a>>'aQ p,Ci X (value 2.3.3.8) cc CC sec (Q DOT), = p.CI/sec for nuclide (i)

Page 103 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM METHODOLOGY SECTION 2.3 (continued)

3. (continued)

D. Obtain the R, value from Table G-6(7) (whichever is the controlling animal, cow/goat, for infant).

If the limited analysis approach is being used, limit the calculation to the infant thyroid.

E. Solve for DR;T mrem-m'- sec p.CI DR = R (DIQ) (Q DOT) X 1 Ij,CI-/f m2 sec DRn = mrem the Dose Rate to organ T from nuclide (i) yr F. Repeat steps 2.3,3,C through 2,3.3.E for each nuclide (i) reported in the assay of the release source.

Only the radioiodines need to be included if the limited analysis approach is being used.

G. The Dose Rate to the Infant's organ T from Grass- -Milk pathway is:

DRgfaaa -Milkr = DR, + DR, + + DR for all nuclides; This dose rate shall be added to the other pathways as per 2.3.5 - Total Organ Dose.

NOTE Steps 2.3.3.O through 2.3.3.G need to be completed for each organ of the Infant. Limit the calculation to the infant thyroid if the limited analysis approach is being used.

Page 104 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM

. METHODOLOGY SECTION 2.3 (continued)

4. The H-3 Dose Rate Method:

A. The controlling locations and their (X/Q), values for each pathway are:

Inhalation - Infant at range in the sector.

(X/Q)o = sec/m'See Table M-2 for range, sector and value)

Ground Plane - Does not apply to H-3 Grass-Cow/Goat-Milk- located in the sector at miles with an Infant at the exclusion area in the sector drinking the milk. The (X/Q)~ for the location is (X/Q), = sec/m. (From Table M-6 at the range and sector corresponding to the location of the Milk Animal above.)

B. Enter the anticipated release rate in ft'/min of the release source and

~,

convert it to cc/sec.

< 2.8317 X 10'c < min min 60 sec.

cc/sec volume release rate C. Solve for (Q DOT)~ for Tritium, by obtaining the pCI/cc assay value of the release source, and multiplying it by the product of 2.3.4.B above.

(Q DOT)(H-3) pC~

X ' a'ue cc CC sec (Q DOT)~ = pCI/sec activity release rate D. Obtain the Tritium dose factor (R,) for Infant organ T from:

PATH TABLE 0 Inhalation G-5 Grass-Cow/Goat-Milk G-6(7)

Page 105 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM METHODOLOGY SECTION 2.3 (continued)

4. (continued)

E. Solve for D~ (Inhalation) using the (XIQ)~ for inhalation from 2.3.4.A and R~ (Inhalation) from 2.3.4.D.

DR~ = R<<(NQ)~ (Q DOT)<<

DR<< = mremlyr from H-3 Infant Inhalation for organ T My'.

Solve for D~ (Grass- -Milk) using the (X/Q)~ for Grass- -Milk from 2.3A.A and R~ (Grass- -Milk) from 2.3.4.D DR8~ R<<(XQ)0 (Q DOT)<<

DR<< = mremlyr from H-3 Infant G. Repeat steps 2.3.4.D through 2.3.4.F for each Infant organ T of interest, H. The individual organ dose rates from H-3 shall be added to the other organ pathway dose rates as per 2.3.5.

Page 106 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM METHODOLOGY SECTION 2.3 (continued)

5. Determinin the Total Or an Dose Rate from Iodines 8D-Particulates and H-3 from Release Source s A. The following table describes all the pathways that must be summed to arrive at the total dose rate to an organ T:

PATHWAY DOSE RATE STEP 4 REF.

Inhalation (I &8DP) 2,3.1.G Ground Plane (l&8DP) (Whole Body only) 2.3.2.6 Gr- Milk (l&8DP) 2.3.3.G Inhalation (H-3) 2.3.4.E Gr- -Milk (H-3) 2.3.4.F DR~ (sum of above)

B. Repeat the above summation for each Infant organ T.

C. The DR, above shall be added to all other release sources on the site that

'ill be in progress at any instant. Refer to in-plant procedures and logs to to each organ.

determine the Total DR, 2.4 Determinin the Gamma Air Dose for Radioactive Noble Gas Release Source s Discussion - Control 3.11.2.2 limits the air dose due to noble gases in gaseous effluents for gamma radiation to <5 mrads for the quarter and to <10 mrads in any calendar year. The following calculation method is provided for determining the noble gas gamma air dose and is based on section 5.3.1 of NUREG-0133, November 1978. The dose calculation is independent of any age group. The equation may be used for Control dose calculation, the dose calculation for the annual report or for projecting dose, provided that the appropriate value of (X/Q) is used as outlined in the detailed explanation that follows. The equation for gamma air dose is:

n D-air = Z 3.17 X 10" M, (XIQ) Q, I

Page 107 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM METHODOLOGY SECTION 2.4 (continued)

Where:

D-air gamma air dose in mrad from radioactive noble gases.

A mathematical symbol to signify the operations to the right side of the symbol are to be performed for each nuclide (i) through (n),

and summed to arrive at the total dose, from all nuclides reported during the interval No units apply.

~

3.17 X 10+ = the inverse of the number of seconds per year with units of year/sec.

M, the gamma air dose factor for radioactive noble gas nuclide (i) in units of mrad-m',CI-yr (X/Q) the long term atmospheric dispersion factor for ground level releases in units of sec/m'. The value of (X/Q) is the same for all nuclides (i) in the dose calculation, but the value of (X/Q) does vary depending on the Limiting Sector the Control is based on, etc.

Q, the number of micro-curies of nuclide (i) released (or projected) during the dose calculation exposure period. (e.g., month, quarter, or year)

Page 108 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM METHODOLOGY SECTION 2.4 (continued)

From an evaluation of past releases, a single effective gamma air dose factor (M,ff) has been derived, which is representative of the radionuclide abundances and corresponding dose contributions typical of past operation. (Refer to Appendix C for a detailed explanation and evaluation of M,) The value of M,has been

~

derived from the radioactive noble gas effluents for the years 1978, 1979, and 1980. The value is mead/Y~

74 X 1P2 p,Cilm'his value may be used in conjunction with the total noble gas releases ( Q,) to simplify the dose evaluation and to verify that the cumulative gamma air dose is within the limits of Control 3.11.2.2. To allow for any unexpected variability in the radionuclide distribution, a conservatism factor of 0.8 is introduced into the calculation. The simplified equation is Dg-Blf 3,17 X10 M X/Q~ QI P 8 eff j For purposes of calculations, the appropriate meteorological dispersion (X/Q) from Table M-1 should be used. Control 3.11.2.2 requires that the doses be evaluated once per 31 days, (i.e., monthly). The quarterly dose limit is 5 mrads, which corresponds to a monthly allotment of '1.7 mrads. If the 1.7 mrads is substituted for D.~a cumulative noble gas monthly release objective can be calculated. This value is 36,000 Ci/month, noble gases.

As long as this value is not exceeded in any month, no additional calculations are needed to verify compliance with the quarterly noble gas release limits of Control 3.11.2.2, Also', the gamma air dose is more limiting than the beta air dose.

Therefore, the beta air dose does not need to be calculated per Section 2.5 if the M ff dose factor is used to determine the gamma air dose. Refer to Appendix C for a detailed evaluation and explanation.

The calculations of Section 2.5 may be omitted when this limited analysis approach is used, but should be performed if the radionuclide specific dose analysis is performed. Also, the radionuclide specific calculations will be performed for inclusion in annual reports,

Page 10g of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM METHODOLOGY SECTION 2.4 (continued)

The following steps provide a detailed explanation of how the radionuclide specific dose is calculated. This method is used to evaluate quarterly doses in accordance with Control 3.11,2.2 if the releases of noble gases during any month of the quarter exceed 36,000 Ci.

1. To determine the applicable (X/Q) refer to Table M-1 to obtain the value for the type of dose calculation being performed. (i.e., Quarterly Control or Dose Projection for examples). This value of-(X/Q) applies to each nuclide (i).

2. Determine (M,) the gamma air dose factor for nuclide (i) from Table G-2.

3. Obtain the micro-Curies of nuclide (i) from the in-plant radioactive gaseous waste management logs for the sources under consideration during the time interval.

"4. Solve for D, as follows:

MI m~d-m yr + + (+a)m' sec IjC/-yr D~ mrad = the dose from nuclide (i)

5. Perform steps 2.4.2 through 2.4.4 for each nuclide (i) reported during the time interval in the source.

6. The total gamma air dose for the pathway is determined by summing the D, dose of each nuclide (i) to obtain D-air dose.

DY-air D1 + D2 + + Dn = mrad NOTE Compliance with a t/31 day Control, Quarterly Control, yearly or 12 consecutive months Control can be demonstrated by the limited analysis approach using M~. Using this method only requires that steps 2.4.2 through 2,4.5 be performed one time, remembering that the dose must be divided by 0.8, the conservatism factor.

7. Refer to in-plant procedures for comparing the calculated dose to any applicable limits that might apply.

Page 110 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM METHODOLOGY SECTiON 2.5 Determinin the Beta Air Dose for Radioactive Noble Gas Releases Discussion - Control 3.11.2,2 limits the quarterly air dose due to beta radiation from noble gases in gaseous effluents to <10 mrads in any calendar quarter and <20 mrads in any calendar year. The following calculation method is provided for determining the beta air dose and is based on Section 5.3.1 of NUREG-0133, November 1978. The dose calculation is independent. of any age group. The equation may be used for Control dose calculation, dose calculation for annual reports, or for projecting dose, provided that the appropriate value of (X/Q) is used as outlined in the detailed explanation that follows.

The equation for beta air dose is:

n Dg , Z = 3.17 X 10 N)X/Q) Q, I

"Where:

B-air beta air dose in mrad from radioactive noble gases.

a mathematical symbol to signify. the operations to the right side of the symbol are to be performed for each nuclide (i) through (n), and summed to arrive at the total dose, from all nuclides reported during the interval. No units apply.

3.17 X 10~ = the inverse of the number of seconds per year with units of year/sec.

the beta air dose factor for radioactive noble gas nuclide (i) in units of mrad-m',CI-yr (X/Q) the long term atmospheric dispersion factor for ground level releases in units of sec/m'. The value of (X/Q) is the same for all nuclides (I) in the dose calculation, but the value of (X/Q) does vary depending on the Limiting Sector the Control is based on, etc.

the number of micro-Curies of nuclide (i) released (or projected) during the dose calculation exposure period

Page 111 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM METHODOLOGY SECTION 2.5 (continued)

The beta air dose does not have to be evaluated if the noble gas gamma air dose is evaluated by the use of the effective gamma air dose factor (M,). However, if the nuclide specific dose calculation is used to evaluate compliance with the quarterly gamma air dose limits (Section 2.4), the beta air dose should also be evaluated as outlined below for the purpose of evaluating compliance with the quarterly beta air dose limits of Control 3.11.2.2. The following steps provide a detailed explanation of how the dose is calculated.

1, To determine the applicable (X/Q) refer to Table M-1 to obtain the value for the type of dose calculation being performed (i.e,, quarterly Control or Dose projection for examples). This value of (X/Q) applies to each nuclide (i).

2, Determine (N,) the beta air dose factor for nuclide (i) from Table G-2.

3. Obtain the micro-curies of nuclide (i) from the in-plant radioactive gaseous waste management logs for the source under consideration during the time interval.

4. Solve for D~ as follows:

3.17 X10 yr + ~, mradm + (

Di sec Ij,Ci-yr M' D, = mrad = the dose from nuclide (i)

5. Perform steps 2.5.2 through 2.5.4 for each nuclide (i) reported during the time interval in the release source.

6. The total beta air dose for the pathway is determined by summing the D, dose of each nuclide (i) to obtain D~, dose.

Df4ll D1 + D2 + D= mrad

7. Refer to in-plant procedures for comparing the calculated dose to any applicable limits that might apply.

Page 112 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM METHODOLOGY SECTION 2.6 Determinin the Radioiodine and Particulate Dose To An Or an From Cumulative Releases Discussion - Control 3.11.2.3 limits the dose to the whole body or any organ resulting from the release of l-131, l-133, tritium, and particulates with half-lives >8 days to <7.5 mrem during any calendar quarter and <15 mrem during any calendar year. The following calculation method is provided for determining the critical organ dose due to releases of radioiodines and particulates and is based on Section 5.3.1 of NUREG-0133, November 1978. The equation can be used for any age group provided that the appropriate dose factors are used and the total dose reflects only those pathways that are applicable to the age group. The (X/Q), symbol represents a DEPLETED-(X/Q) which is different from the Noble Gas (X/Q) in that (X/Q), takes into account the loss of l&8DP and H-3 from the plume as the semi-infinite cloud travels over a given distance. The (D/Q) dispersion factor represents the rate of fallout from the cloud that affects a square meter of ground at various distances from the site. The l&8DP and H-3 notations refer to l-131, l-133 Particulates having half-lives >8 days, and Tritium. For ease of calculations, dose from other Iodine "nuclides may be included (see 2.1). Tritium calculations are always based on (X/Q),. The first step is to calculate the l88DP and H-3 dose for each pathway that applies to a given age group. The total dose to an organ can then be determined by summing the pathways that apply to the receptor ln the sector.

The equations are:

For Inhalation Pathway (excluding H-3):

n DaBDP ~ 317 X10~R((X/ )D I I

For Ground Plane or Grass-Cow/Goat-Milk n

D~,~p = Z 3.17 X 10 R, (D/Q)Q(

i For each pathway above (excluding Ground Plane) For Tritium:

D 3.17 X 10 R~/X/Q)~Q(

Page 113 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM METHODOLOGY SECTION 2.6 (continued)

For Total Dose from Particulate Gaseous effluent to organ T of a specified age group:

= Z Dr Z [De~oi + ii~]

Where:

the organ of interest of a specified age group the applicable pathways for the age group of interest DIED P Dose in mrem to the organ T of a specified age group from radioiodines and 8D Particulates DH-3 Dose in mrem to the organ T of a specified age group from Tritium Total Dose in mrem to the organ T of a specified age group from Gaseous particulate ENuents A mathematical symbol to signify the operations to the right of the symbol are to be performed for each nuclide (i) through (n),

and the individual nuclide doses are summed to arrive at the total dose from the pathway of interest to organ T.

A mathematical symbol to indicate that the total dose D, to Z organ T is the sum of each of the pathway doses of l&8DP and H-3 from gaseous particulate effluents.

3.17 X 10 The inverse of the number of seconds per year with units of year/sec.

R, The dose factor for nuclide (i) (or H-3) for pathway Z to organ T of the specified age group. The units are either mrem-m'or pathways mrem-m' sec for pathways yr pCi using (XIQ)~ OR yr pCi using (DIQ)

Page 114 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM METHODOLOGY SECTION 2.6 (continued)

(X/Q)~ The depleted-(X/Q) value for a specific location where the receptor is located (see discussion). The units are sec/m'D/Q) the deposition value for a specific location where the receptor is located (see discussion) The units are 1/m'here m=meters.

~

Q, The number of micro-Curies of nuclide (i) released (or projected) during the dose calculation exposure period.

QH-3 the number of micro-Curies of H-3 released (or projected) during the dose calculation exposure period.

As discussed in Section 2,3, the grass-cow/goat-milk pathway has been identified as the most limiting pathway with the infant's thyroid being the critical organ. This pathway typically contributes >90% of the total dose received by the infant's thyroid and the radioiodine contributes essentially all of this dose. Therefore, it is possible to demonstrate compliance with the dose limit of Control 3.11.2.3 for radioiodines and particulates by only evaluating the infant's thyroid dose due to the release of radioiodines via the grass-cow/goat-milk pathway. The calculation method of Section 2.6.3 is used for this determination.

The dose determined by Section 2.6.3 should be divided by a conservatism factor of 0.8. This added conservatism provides assurance that the dose determined by this limited analysis approach will not be < the dose that would be determined by evaluating all radionuclides and all pathways, If this limited analysis approach is used, the dose calculations for other radioactive particulate matter and other pathways need not be performed. Only the calculations of Section 2.6.3 for the radioiodines are required to demonstrate compliance with the Control dose limit.

However, for the dose assessment included in Annual Reports, doses will be evaluated for the infant age groups and all organs via all designated pathways from radioiodines and particulates measured in the gaseous effluents according to the sampling and analyses required in Control Table 4.11-2. The following steps provide a detailed e'xplanation of how the dose is calculated for the given, pathways:

Page 115 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM METHODOLOGY SECTION 2.6 (continued)

1. The Inhalation Dose Pathwa Method:

NOTE The H-3 dose should be calculated as per 2.6.4.

A. Determine the applicable (X/Q)~ from Table M-2 for the location where the receptor is located. This value is common to each nuclide (i)

B. Determine the R, factor of nuclide (i) for the organ T and age group from Table G-5.

C. Obtain the micro-Curies (Q,) of nuclide (i) from the radioactive gas waste management logs for the release source(s) under consideration during the time interval.

D. Solve for D, Di 3 17 X 1 0 Rl(X/Q)pQi D(= mrem from nuclide (i)

E, Perform steps 2.6.1.B through 2.6.1.D for each nuclide (i) reported during the time interval for each organ.

F, The Inhalation dose to organ T of the specified age group is determined by summing the D, Dose of each nuclide (i)

Olnhalation mrem (Age Group)

Refer to 2.6.5 to determine the total dose to organ T from radioiodines &

SD Particulates

Page 116 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM METHODOLOGY SECTION 2.6 (continued)

2. The Ground Plane Dose Pathwa Method:

NOTE Tritium dose via the ground plane is zero. The Whole Body is the only organ considered for the Ground Plane pathway dose.

A. Determine the applicable (D/Q) from Table M-2 for the location where the receptor is located. This (D/Q) value is common to each nuclide (i)

B. Determine the Ri factor of nuclide (i) for the whole body from Table G-4.

The ground plane pathway dose is the same for all age groups.

C. Obtain the micro-Curies (Q,) of nuclide (i) from the radioactive gas waste management logs for the source under consideration.

D. Solve for D, DI = 3.17 X 10~RI (DIQ) QI D,= mrem for nuclide (i)

E. Perform steps 2.6.2.B through 2.6.2.D for each nuclide (i) reported during the time interval ~

F. The Ground Plane dose to the whole body is determined by summing the Di Dose of each nuclide (i) ar.PI.-WBody 1

+ 2 + + D= mrem Refer to step 2.6.6 to calculate total dose to the Whole Body.

Page 117 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM METHODOLOGY SECTION 2.6 (continued)

3. The Grass-Cow/Goat-Milk Dose Pathwa Method:

NOTE Tritium dose is calculated as per 2.6A.

A. A cow, or a goat, will be the controlling animal; (i.e., dose will not be the sum of each animal), as the human receptor is assumed to drink milk from only the most restrictive animal. Refer to Table M-3 to determine which animal is controlling based on its (D/Q).

B. Determine the dose factor R, for nuclide (i), for organ T, from

1. From Table G-6 for a cow, or,

2. From Table 6-7 for a goat.

If the limited analysis approach is being used, limit the calculation to the infant thyroid.

C. Obtain the micro-Curies (Q,) of nuclide (i) from the radioactive gas waste management logs for the release source under consideration during the time interval.

D. Solve for D, DI = 3.17 X 10 RI(D/Q)QI D, = mrem from nuclide (i)

E. Perform steps 2.6.3.B through 2.6.3.D for each nuclide (i) reported during the time interval. Only the radioiodines need to be included if the limited analysis approach is used.

Page 118 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM METHODOLOGY SECTION 2.6 (continued)

3. (continued)

F. The Grass-Cow-Milk (or Grass-Goat-Milk) pathway dose to organ T is determined by summing the Di dose of each nuclide(i).

De~(or D<<) = D, + D, + + D= mrem The dose to each organ should be calculated in the same manner with steps 2.6.3.B through 2.6.3.F. Refer to step 2.6.5 to determine the total dose to organ T from radioiodines &8D Particulates. If the limited analysis approach is being used the infant thyroid dose via the grasswow(goat)-milk pathway is the only dose that needs to be determined. Section 2.6.5 can be omitted.

4, The Gaseous Tritium Dose Each Pathwa Method:

A. The controlling locations for the pathway(s) has already been determined by: Inhalation - as per 2.6.1.A Ground Plane - not applicable for H-3 Grass-Cow/Goat-Milk - as per 2,6.3.A B. Tritium dose calculations use the depleted (X/Q), instead of (D/Q). Table M-2 describes where the (X/Q)0 value should be obtained from.

C. Determine the Pathway Tritium dose factor (R<<) for the organ T of interest from the Table specified below:

MILK AGE INHALATION COW GOAT Infant G-5 G-6 G-7 D. Obtain the micro-Curies (Q) of Tritium from the radioactive gas waste management logs (for projected doses - the micro-Curies of nuclide-(i) to be projected) for the release source(s) under consideration during the time interval. The dose can be calculated from a single release source, but the total dose for Control limits or quarterly reports shall be from all gaseous release sources.

Page 119 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM METHODOLOGY SECTION 2,6 (continued)

4. (continued)

E. Solve for D~

D~ =. 3,17 X 10 RH4(NQ)oQ D~ = mrem from Tritium in the specified pathway for organ T of the specified age group

5. Determinin the Total Or an Dose From lodines 8D-Particulates andH-3 From Cumulative Gaseous Releases NOTE Control dose limits for l88DP shall consider dose from all release sources from the reactor unit of interest.

A. The following pathways shall be summed to arrive at the total dose to organ T from a release source, or if applicable to Control, from all release sources:

PATHWAY DOSE (mrem) STEP 0 REF.

Inhalation (Ia 8DP) 2.6.1.F Ground Plane (l&8DP) (Whole Body only) 2.6.2.F Grass- Milk (i&SOP) 2.6.3.F Inhalation (H-3) 2.6.4.E Grass- -Mllk (H-3) 2.6.4.E Dose = (sum of above)

B. The dose to each of the INFANT'S ORGANS shall be calculated:

BONE, LIVER, THYROID, KIDNEY, LUNG, WHOLE BODY, & Gl-LLI The INFANT organ receiving the highest exposure relative to its Control Limit is the most critical organ for the radioiodine & 8D Particulates gaseous effluents.

Page 120 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM METHODOLOGY SECTION 2.7 Pro'ectin Dose for Radioactive Gaseous ENuents Discussion - Control 3.11.2.4 requires that the waste gas holdup system be used to reduce releases of radioactivity when the projected doses in 31 days due to gaseous eNuent releases, from each unit, to areas at and beyond the SITE BOUNDARY (see TS Figure 5-1-1) would exceed 0.2 mrad for gamma radiation and 0.4 mrad for beta radiation, The following calculation method is provided for determining the projected doses. This method is based on using the results of the calculations performed in Sections 2.4 and 2.5.

1, Obtain the latest results of the monthly calculations of the gamma air dose (Section 2.4) and the beta air dose if performed (Section 2.5). These doses can be obtained from the in-plant records.

2. Divide these doses by the number of days the plant was operational during the month.

3. Multiply the quotient by the number of days the plant is projected to be operational during the next month. The product is the projected dose for the next month. The value should be adjusted as needed to account for any changes in failed-fuel or other identifiable operating conditions that could significantly alter the actual releases.

4. If the projected doses are >0.2 mrads gamma air dose or > 0.4 mrads beta air dose, the appropriate subsystems of the waste gas holdup system shall be Used.

~g ~

Page 121 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM METHODOLOGY SECTION 3.0 40 CFR 190 Dose Evaluation Discussion - Dose or dose commitment to a real individual from all uranium fuel cycle sources be limited to <25 mrem to the whole body or any organ (except thyroid, which is limited to <75 mrem) over a period of 12 consecutive months. The following approach should be used to demonstrate compliance with these dose limits. This approach is based on NUREG-0133, Section 3.8.

3.1 Evaluation Bases Dose evaluations to demonstrate compliance with the above dose limits need only be performed if the quarterly doses calculated in Sections 1.4, 2.4 and 2.6 exceed twice the dose limits of Controls 3.11.1.2.a, 3.11.1.2.b, 3.11.2.2a, 3.1.2.2b, 3.11,2.3a, and 3.11.2.3b respectively; i.e., quarterly doses exceeding 3 mrem to the whole body (liquid releases), 10 mrem to any organ (liquid releases), 10 mrads gamma air dose, 20 mrads beta air dose, or 15 mrem to the thyroid or any organ from radioiodines and particulates (atmospheric releases). Otherwise, no evaluations are required and the remainder of this section can be omitted.

3.2 Doses From Li uid Releases For the evaluation of doses to real individuals from liquid releases, the same calculation method as employed in Section 1.4 will be used. However, more realistic assumptions will be made concerning the dilution and ingestion of fish and shellfish by individuals who live and fish in the area. Also, the results of the Radiological Environmental Monitoring program will be included in determining more realistic dose to these real people by providing data on actual measured levels of plant related radionuclides in the environment.

3.3 Doses From Atmos heric Releases For the evaluation of doses to real individuals from the atmospheric releases, the same calculation methods as employed in Section 2.4 and 2.6 will be used.

In Section 2.4, the whole body dose factor (K) should be substituted for the gamma air dose factor (M,) to determine the whole body dose. Otherwise the same calculation sequence applies. However, more realistic assumptions will be made concerning the actual location of real individuals, the meteorological conditions, and the consumption of food (e.g., milk). Data obtained from the latest land use census (Control 3.12,2) should be used to determine locations for evaluating doses. Also, the results of the Radiological Environmental Monitoring program will be included in determining more realistic doses to these real people by providing data on actual measured levels of radioactivity and radiation at locations of interest.

'.s4 y>>

Page 122 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM METHODOLOGY SECTION 4.0 Annual Radioactive Effluent Re ort Discussion - The information contained in a annual report shall not apply to any Control The reported values are based on actual release conditions instead of

~

historical conditions that the Control dose calculations are based on. The Control dose limits are therefore included in item 1 of the report, for information only. The MPC's in item 2 of the report shall be those listed in Tables L-1 and 6-1 of this manual. The average energy in item 3 of the report is not applicable to the St. Lucie Plant, The format, order of nuclides, and any values shown as an example in Tables 3.3 through 3.8 are samples only. Other formats are acceptable if they contain equivalent information. A table of contents should also accompany the report. The following format should be used:

RADIOACTIVE EFFLUENTS - SUPPLEMENTAL INFORMATION

1. Regulatory Limits:

1.1 For Radioactive liquid waste effluents:

a. The concentration of radioactive material released from the site (see Figure 5.1-1 in TS-A) shall be limited to the concentrations specified in 10 CFR Part 20, Appendix B, Table II, Column 2 for radionuclides other than dissolved or entrained noble gases. For dissolved or entrained noble gases, the concentration shall be limited to 2 X 10~ p,CI/ml total activity.

b. The dose or dose commitment to a MEMBER OF THE PUBLIC from radioactive materials in liquid effluents released from each reactor unit to unrestricted areas (See Fig. 5.1-1 in TS-A) shall be limited during any calendar quarter to <1.5 mrem to the whole body and to <5 mrem to any organ and <3 mrem to the whole body and <10 mrem to any organ during any calendar year.

1,2 For Radioactive Gaseous Waste Effluents:

a. The dose rate in unrestricted areas (see Fig. 5.1-1 in the TS-A) due to radioactive materials released in gaseous effluents from the site shall be limited to the following values:

The dose rate limit for noble gases shall be <500 mrem/yr to the whole body and <3000 mrem/yr to the skin, and The dose rate limit from I;131, l-133, Tritium, and particulates with half-lives >8 days shall be <1500 mrem/yr to any organ.

Page 123 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM METHODOLOGY SECTION 4.0 (continued)

1. (continued) 1.2 (continued) b, The air dose (see Figure 5,1-1 in the TS-A) due to noble gases released in gaseous eNuents, from each reactor unit, to areas at and beyond the SITE BOUNDARY shall be limited to the following:

During any calendar quarter, to <5 mrad for gamma radiation and <10 mrad for beta radiation and during any calendar year to <10 mrad for gamma radiation and c20 mrad for beta radiation

c. The dose to a MEMBER OF THE PUBLIC from l-131, 1-133, Tritium, and all radionuclide in particulate form, with half-lives >8 days in gaseous eNuents released from each reactor unit to areas at and beyond the SITE BOUNDARY (see Figure 5.1-1 In the TS-A) shall be limited to the following:

During any calendar quarter to <7.5 mrem to any organ, and during any calendar year to <15 mrem to any organ.

2. Maximum Permissible Concentrations:

Air - as per attached Table G-1 Water - as per attached Table L-1

3. Average energy of fission and activation gases in gaseous eNuents is not applicable to the St. Lucie Plant.

Page 124 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM

- METHODOLOGY SECTION 4.0 (continued)

4. Measurements and Approximations of Total Radioactivity:

A summary of liquid effluent accounting methods is described in Table 3.1.

A summand of gaseous effluent accounting methods is described in Table 3.2.

Estimate of Errors:

LIQUID GASEOUS Error Topic Avg.% Max.% Avg,% Max.%

Release Point Mixing 2 5 NA NA Sampling 1 5 2 5 Sample Preparation 1 5 1 5 Sample Analysis 3 10 3 10 Release Volume 2 5 4 15 Total % 9 30 10 35 (above values are examples only)

The predictability of error for radioactive releases can only be applied to nuclides that are predominant in sample spectrums. Nuclides that are near background relative to the predominant nuclides in a given sample could easily have errors greater than the above listed maximums.

Page 125 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM METHODOLOGY SECTION 4.0 (continued)

4. (continued)

TABLE 3.1 RADIOACTIVE LIQUID EFFLUENT SAMPLING AND ANALYSIS LIQUID METHOD OF FREQUENCY TYPE OF ANALYSIS SOURCE ANALYSIS EACH BATCH PRINCIPAL GAMMA EMITTERS p.h.a.

RELEASES'AMPLING MONITOR TRITIUM L.S.

TANK MONTHLYCOMPOSITE GROSS ALPHA G.F.P.

QUARTERLY COMPOSITE Sr%9, Sr-90, Fe-55 C.S. & L.S.

FOUR PER MONTH PRINCIPAL GAMMA EMITTERS p.h.a.

STEAM AND DISSOLVED GASES GENERATOR TRITIUM L,S.

BLOWDOWN MONTHLYCOMPOSITE GROSS ALPHA G.F.P.

RELEASES QUARTERLY COMPOSITE Sr%9, Sr-90, Fe-55 C.S. & L.S.

TABLE NOTATION:

Boric Acid Evaporator condensate is normally recovered to the Primary Water Storage Tank for recycling into the reactor coolant system and normally does.

not contribute to liquid waste effluent totals.

p.h.a, gamma spectrum pulse height analysis using Lithium Germanium detectors, AII peaks are identified and quantified.

L.S, Liquid Scintillation counting C.S. Chemical Separation G.F.P. Gas Flow Proportional Counting

Page 126 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM METHODOLOGY SECTION 4.0 (continued) 4, (continued)

TABLE 3.2 RADIOACTIVE GASEOUS WASTE SAMPLING AND ANAlYSIS GASEOUS METHOD OF SAMPLING FREQUENCY TYPE OF ANALYSIS SOURCE ANALYSIS Waste Gas Each Tank Principal Gamma Emitters G, p.h.a.

Decay Tank Releases Containment Each Purge Principal Gamma Emitters G, p.h.a.

Purge H-3 L.S.

Releases Four per Month Principal Gamma Emitters (G, C, P) - p.h.a.

H-3 L.S.

Monthly Composite Gross P - G. F. P.

Plant Vent (Particulates) Alpha Quarterly Composite Sr-90 C.S. &

(Particulates) Sr%9 L.S.

G Gaseous Grab Sample C Charcoal Filter Sample Particulate Filter Sample L.S. Liquid Scintillation Counting C.S. Chemical Separation p.h.a. Gamma spectrum pulse height analysis using Lithium Germanium detectors. All peaks are identified and quantified.

G.F.P. Gas Flow Proportional Counting

Page 127 of 180 ST, LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM METHODOLOGY SECTION 4.0 (continued)

5. Batch Releases A. Liquid

1. Number of batch releases:

2. Total time period of batch releases: minutes

3. Maximum time period for a batch release: minutes

4. Average time period for a batch release: minutes

5. Minimum time period for a batch release: minutes

6. Average dilution stream flow during the period (see Note 1 on Table 3.3): GPM All liquid releases are summarized in tables B. Gaseous

1. Number of batch releases:

2, Total time period for batch releases: minutes

3. Maximum time period for a batch release: minutes

4. Average time period for batch releases: minutes

5. Minimum time period for a batch release: minutes All gaseous waste releases are summarized in tables

Page 128 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM METHODOLOGY SECTION 4.0 (continued)

6. Unplanned Releases A. Liquid

1. Number of releases:

2. Total activity releases: Curies

8. Gaseous

1. Number of releases:

2. Total activity released: Curies C. See attachments (if applicable) for:

1. A description of the event and equipment involved.

2. Cause(s) for the unplanned release.

3. Actions taken to prevent a recurrence

4. Consequences of the unplanned release

7. Description of dose assessment of radiation dose from radioactive effluents to the general public due to their activities inside the site are reported on the January annual report.

8. Offsite dose calculation manual revisions initiated during this reporting period.

See Control 3.11.2.6 for required attachments to the Annual Report.

9. Solid waste and irradiated fuel shipments as per requirements of Control 3.11.2.6.

Page 129 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM METHODOLOGY SECTION 4.0 (continued)

10. Process Control Program (PCP) revisions as per requirements of TS 6,13.

11. Major changes to Radioactive Liquid, Gaseous and Solid Waste Treatment Systems as per requirements of Control 3.11.2.5.

Page 130 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM METHODOLOGY SECTION FLORIDA POWER & LIGHT COMPANY ST. LUCIE UNIT ¹ ANNUAL REPORT - ~~ THROUGH ~~

TABLE 3.3: LIQUID EFFLUENTS - SUMMATION OF ALL RELEASES UNIT QUARTER ¹ QUARTER ¹ A, Fission and Activation Products Total Release - (Not including Tritium, Gases, Alpha) Ci C

2. Average Diluted Concentration During Period p,CI/ML B. Tritium

1. Total Release Ci

2. Average Diluted Concentration During Period p,CI/ML'i C. Dissolved and Entrained Gases

1. Total Release

2. Average Diluted Concentration During Period p,Ci/ML .

D. Gross Alpha Radioactivity

1. Total Release Ci

Page 131 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM METHODOLOGY SECTION TABLE 3.3: LIQUID EFFLUENTS - SUMMATION OF ALL RELEASES (continued)

I QUA QU E. Volume of Waste Released (Prior to Dilution) LITERS F. Volume of Dilution Water Used During Period' LITERS 1 - The volume reported should be for the entire interval of the reporting period, not just during release intervals. This volume should also be used to calculate average dilution stream flow during the period.

Page 132 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM METHODOLOGY SECTION FLORIDA POWER 8t. LIGHT COMPANY ST. LUCIE UNIT ¹ ANNUAL REPORT - ~~ THROUGH ~~

TABLE 3A; LIQUID EFFLUENTS (EXAMPLE FORMAT)

CONTINUOUS MODE BATCH MODE NUCLIDES RELEASED'-131 UNIT QUARTER ¹ QUARTER ¹ QUARTER ¹ QUARTER ¹ CI I-133 CI E l-135 CI NA-24 CI CR-51 CI MN-54 CI CO-57 CI CO-58 CI FE-59 CI CO-60 CI ZN-65 CI Nl-65 CI AG-1 10 CI SN-113 CI SB-122 CI SB-124 CI W-187 CI NP-239 CI ZR-95 CI MO-99 CI RU-1 03 CI CS-134 CI CS-136 CI CS-137 CI BA-140 CI CE-141 CI BR-82 CI ZR-97 CI SB-125 CI

• All nuclides that were detected should be added to the partial list of the example format.

Page 133 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM METHODOLOGY SECTION TABLE 3.4: LIQUID EFFLUENTS (EXAMPLE FORMAT)

(continued)

CONTINUOUS MODE BATCH MODE NUCLIDES RELEASED UNIT QUARTER ¹ QUARTER ¹ QUARTER ¹ QUARTER ¹ CE-144 CI SR-89 CI SR-90 CI UNIDENTIFIED CI TOTAL FOR PERIOD (ABOVE) CI AR<1 CI KR-85 CI XE-131M CI XE-133 CI XE-133M CI XE-135 CI

Page 134 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM METHODOLOGY SECTION FLORIDA POWER & LIGHT COMPANY ST. LUCIE UNIT ¹ TABLE 3.5 LIQUID EFFLUENTS - DOSE SUMMATION Age Group; Adult Location; Any Adult Exposure Interval: From Through CALENDAR YEAR DOSE Fish & Shellfish Pathway to Organ (mrem)

BONE LIVER THYROID KIDNEY LUNG Gl-LLI WHOLE BODY

Page 135 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM METHODOLOGY SECTION FLORIDA POWER 8t. LIGHT COMPANY ST. LUCIE UNIT ¹ ANNUAL REPORT - ~~ THROUGH ~~

TABLE 3.6: GASEOUS EFFLUENTS - SUMMATION OF ALL RELEASES UNIT QUARTER ¹ QUARTER ¹ A. Fission and Activation Gases

1. Total Release Ci E

2. Average Release Rate For Period pCi/SEC I

B. Iodines

1. Total Iodine-131 Ci

2. Average Release Rate for Period pCi/SEC C. Particulates Particulates T-1/2 > 8 Days Ci

2. Average Release Rate for Period pCi/SEC

3. Gross Alpha Radioactivity Ci D. Tritium

1. Total Release Ci I

2, Average Release Rate for Period pCI/SEC

Page 136 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM METHODOLOGY SECTION FLORIDA POWER 8L LIGHT COMPANY ST. LUCIE UNIT 0 ANNUAL REPORT - ~~ THROUGH TABLE 3.7 GASEOUS EFFLUENTS - GROUND LEVEL RELEASES

~~

(EXAMPLE FORMAT)

CONTINUOUS MODE BATCH MODE NUCLIDES RELEASED UNIT QUARTER ¹ QUARTER ¹ QUARTER ¹ QUARTER ¹

1. FIssIon Gases AR-41 CI KR-85 CI KR-85M CI KR-87 CI KR-88 CI XE-131M CI E XE-133 CI XE-133M CI XE-135 CI XE-135M CI XE-138 CI UNIDENTIFIED CI II E

TOTAL FOR PERIOD (ABOVE) CI E

2. Iodines I-131 CI 'E I-133 CI I-135 CI 'E TOTAL FOR PERIOD (ABOVE) CI

3. ParticuIates CO-58 CI SR-89 CI SR-90 CI ,E All nuclides that were detected should be added to the partial list of the example format.

Page 137 of 180 ST. LUCIE T CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM METHODOLOGY SECTION FLORIDA POWER 8c LIGHT COMPANY ST. LUCIE UNIT ¹ TABLE 3.8 GASEOUS EFFLUENTS - DOSE SUMMATION - CALENDAR YEAR AGE GROUP: INFANT EXPOSURE INTERVAL: FROM THROUGH BONE LIVER THYROID KIDNEY LUNG Gl-LLI WHOLE BODY PATHWAY (mrem) (mrem) (mrem) (mrem) (mrem (mrem) (mrem)

Ground Plane (A)

Grass- -Milk(B)

.Inhalation (A)

TOTAL (A) SECTOR: RANGE: miles (B) COW/ GOAT SECTOR: RANGE: miles NOBLE GASES CALENDAR YEAR (mrad)

Gamma Air Dose Beta Air Dose Sector. Range: 0.97 miles NOTE The dose values above were calculated using actual meteorological data during the specified time interval with MET data reduced as per Reg. Guide 1.111, March 1976.

Page 138 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM APPENDIX A MPC, DOSE FACTOR AND HISTORICAL METEOROLOGICAL TABLES

Page 139 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM TABLE L-1 MAXIMUMPERMISSIBLE CONCENTRATIONS IN WATER IN UNRESTRICTED AREAS Nuclide MPC (pCi/ml) Nuclide MPG (pCVml) Nuclide MPC (pCi/ml)

H-3 3 E-3 Y-90 2 E-5 Te-129 8 EA Na-24 3 E-5 Y-91m 3 E-3 Te-131m 4 E-5 P-32 2 E-5 Y-91 3 E-5 Te-131 None Cr-51 2 EN Y-92 6 E-5 Te-132 2 E-5 Mn-54 1 EA Y-93 3 E-5 1-130 3 E-6 Mn-56 1 EA Zr-95 6 E-5 I-131 3 E-7 Fe-55 8 EA Zr-97 2 E-5 I-132 8 E-6 Fe-59 5 E-5 Nb-95 1 EA I-133 1 E-6 Co-57 4 EA Nb-97 9 EA I-134 2 E-5 Co-58 9 E-5 Mo-99 4 E-5 l-135 4 E-6 Co-60 3 E-5 Tc-99m 3 E-3 Gs-134 9 E-6 Nl-65 1 EA Tc-101 None Cs-136 6 E-5 Gu-64 2 EA Ru-103 8 E-5 Gs-137 2 E-5 ~

Zn-65 1 EA Ru-105 1 EA Cs-138 None Zn-69 2 E-3 Ru-106 1 E-5 Ba-139 None Br-82 4 E-5 Ag-110 3 E-5 Ba-140 2 E-5 Br-83 3 E-6 Sn-113 8 E-5 Ba-141 None Br-84 None I-113m 1 E-3 Ba-142 None Br-85 None Sb-122 3 E-5 La-140 2 E-5 Rb-86 2 E-5 Sb-124 2 E-5 La-142 None Rb-88 None Sb-125 1 EA Ce-141 9 E-5 Rb-89 None Te-125m 1 EA Ce-143 4 E-5 Sr-89 3 E-6 Te-127m 5 E-5 Ge-144 1 E-5 Sr-90 3 E-7 Te-127 2 EA Pr-144 None Sr-91 5 E-5 Te-129m 2 E-5 W-187 6 E-5 Sr-92 6 E-5 Np-239 1 EA If a nuclide ls not listed, refer to 10 CFR Part 20, Appendix B, and use the most conservative insoluble/soluble MPC where they are given in Table II, Column 2.

None - (As per 10 CFR Part 20, Appendix B) "No MPC limit for any single radlonuclide not listed above with decay mode other than alpha emission or spontaneous fission and with radioactive half-life less than 2 hours2.314815e-5 days <br />5.555556e-4 hours <br />3.306878e-6 weeks <br />7.61e-7 months <br />."

Page 140 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CAL'CULATION MANUAL ODCM TABLE L-2 ENVIRONMENTAL PATHWAY-DOSE CONVERSION FACTORS FOR LIQUID DISCHARGES PATHWAY- SALT WATER FISH AND SHELLFISH AGE GROUP - ADULT ORGAN DOSE FACTOR (MREM/HR PER pCI/ML)

GI-Lu WHOLE NUCUDE BONE LIVER THYROID KIDNEY LUNG BODY H-3 0. 3.60E-01 3.60E%1 3.60E-01 3.60E%1 3.60E<1 3.60E-01 NA-24 6.08E-01 6.08E-01 6.08E<1 6.08E<1 6.08E+1 6.08E<1 6.08E-01 P-32 1.67E+07 1.05E+06 0. 0. 0. 1.88E+06 6.47E+05 CR-51 0. 0. 1.23E+00 7.42E+00 1A1E+03 5.59E+00 MN-54 0., 7.07E+03 0. 2.10E+03 0. 2.17E+04 1.35E+03 MN-56 0. 1.78E+02 0. 226 E+02 0. 5.68E+03 3.17E+01 FE-55 1.15E+05 5.19E+05 0. 0. 6.01E+05 2.03E+05 1.36E+05 FE-59 8.08E+04 1.92E+05 0. 0. 5.32E+04 6.33E+05 729 E+04 CO-57 0. 1.42E+02 0. 0. 0. 3.60E+03 2.36E+02

0. 6.05E+02 0. 0. 0. 1ME+04 1.35E+03

0. 1.74E+03 0. 0. 0. 326 E+04 3.83E+03 Nl<5 2.63E+01 0. 0. 0. 6.65E+02 '1 DOE+01 CU-64 0. 2.15E+02 0. 5.41E+02 0. 1.83E+04 1.01E+02 1.62E+05 5.13E+05 0. 3;43E+05 0. 323 E+05 2.32E+05 3.43E+02 6.60E+02 0. 4.27E+02 0. 9.87E+01 4.57E+01 Based on 1 pCi/sec release rate of each isotope in discharge flow of 1 cc/sec with no additional dilution

Page 141 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM TABLE L-2, ENVIRONMENTALPATHWAY-DOSE CONVERSION FACTORS FOR UQUID DISCHARGES PATHWAY<<SALT WATER FISH AND SHELLFISH AGE GROUP - ADULT ORGAN DOSE FACTOR (MREM/HR PER pCI/ML)

WHOLE NUCLIDE BONE LIVER THYROID KIDNEY LUNG GI-LLI BODY BR-82 0. 0. 0. 0. 0. 4.68E+00 4.08E+00 BR-83 0. 0. 0. 0. 0. 1.05E<1 7Z6E%2 BR-84 0. 0. 0. 0. 0. 7.38E-07 9.42E-02 BR-85 0. 0. 0. 0. 0. 0. 3.86E~

RB-86 0. 6.25E+02 0. 0. 0. 1Z3E+02 2.91E+02 RB-88 0. 1.79E+00 0. 0. 0. 0. 9.50E-01 RB-89 1.19E+00 0. 0. 0. 0. 8.38E<1 SR-89 5.01E+03 0. 0. 0. 0. 8.01E+02 1A4E+02 SR-90 1Z3E+05 0. 0. 0. 1.65E+03 SR-91 9A3E+01 0. 0. 0. 0. 4.75E+02 4.15E+00 SR-92 3.50E+01 0. 0. 0. 0. 6.91E+02 1.51E+00 Y-90 6.07E+00 0. 0. 0. 0. 6A3E+04 '1.63E-01 Y-91M 5.74E%2 0. 0. 0. 0. 1.68E-01 2Z3E-03 Y-91 8.89E+01 0. 0. 0. 4.89E+04 2.38E+00 Y-92 5.34E-01 0. 0. 0. 0. 9.33E+03 1.56E%2 Based on 1 pCi/sec release rate of each isotope in discharge flow of 1 cc/sec with no additional dilution

Page 142 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CAL'CULATIONMANUAL ODCM TABLE L-2 ENVIRONMENTALPATHWAYWOSE CONVERSION FACTORS FOR LlQUID DISCHARGES.

PATHWAY- SALT WATER FISH AND SHELLFISH AGE GROUP - ADULT'RGAN DOSE FACTOR (MREM/HR PER pCI/ML)

NUCLIDE BONE LIVER THYROID KIDNEY LUNG GI-LLI WHOLE BODY Y-93 1.69E+00 0. 0. 0. 0. 5.36E+04 4.67E-02 ZR-95 1.60E+01 5.13E+00 0. 8.09E+00 0. 1.59E+04 3.47E+00 ZR-97 8.82E-01 1.78E-01 0. 2.69E-01 0. 5.51E+04 8.19E-02 NB-95 4.48E+02 2.49E+02 0. 2.47E+02 0. 1.51E+06 9.79E+01 NB-97 3.76E+00 9.50E-01 0. 1.11E+00 0. 3.51E+03 3.47E-01 MO-99 0. 128E+02 0. 2.90E+02 0. 2.97E+02 2.43E+01 TC-99M 1.30E<2 3.67E-02 0. 5.57E<1 1.80E-02 2.17E+01 4.67E%1 TC-101 1.33E-02 1.93E%2 0. 3.47E-01 9.82E~ 0. 1.89E1 RU-103 1.07E+02 0. 0. 4.09E+02 0. 1ME+04 4.61E+01 RU-105 8.90E+00 0. 0. 1.15E+02 0. 5A4E+03 3.51E+00 RU-106 1.59E+03 0. 0. 3.08E+03 0. 1.03E+05 2.01E+02 AG-110 1.57E+03 1.45E+03 0. 2.85E+03 0. 5.92E+05 8.62E+02 SB-124 2.78E+02 5Z3E+00 6.71E-01 0. 2.15E+02 7.85E+03 1.10E+02 SB-125 2.20E+02 2.37E+00 1.96E%1 0. 2.30E+04 1.95E+03 4.42E+01 TE-125M 2.17E+02 7.89E+01 6.54E+01 8.83E+02 0. 8.67E+02 2.91E+01 Based on 1 pCi/sec release rate of each isotope in discharge flow of 1 cc/sec with no additional dilution

Page 143 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM TABLE L-2 ENVIRONMENTALPATHWAY-DOSE CONVERSION FACTORS FOR LlQUID DISCHARGES PATHWAY- SALT WATER FISH AND SHELLFISH AGE GROUP - ADULT ORGAN DOSE FACTOR (MREM/HR PER pCI/ML)

NUCLIDE BONE UVER THYROID LUNG Gl-LLI WHOLE BODY TE-127M 5.50E+02 1.92E+02 1.40E+02 2Z3E+03 0. 1.84E+03 6.70E+01 TE-127 8.92E+00 3MEAS 6.61E+00 3.63EW1 0. 7.04E+02 1.93E+00 TE-129M 9.32E+02 3.49E+02 320 E+02 3.89E+03 0. 4.69E+03 1.48E+02 TE-129 2.55E+00 9.65E-01 1.95E+00 1.07E+01 0. 1.92E+00 621&)1 TE-131M 1.41E+02 6.87E+01 1.09E+02 6.95E+02 0. 6.81E+03 5.72E+01 TE-131 1.60E+00 6.68E1 1.31E+00 7.00E+00 0. 2.39E<1 5.04E-01 TE-132 2.05E+03 1.33E+02 1.46E+02 128 E+03 0. 625 E+03 1Z4E+02 I-130 3.98E+01 1.18E+02 1.50E+04 1.83Et02 0. 1.01E+02 4.63E+01 I-131 2.18E+02 3.13E+02 1.02E+05 5.36E+02 0. 824 E+01 1.79E+02 I-132 1.07E+01 2.85E+01 3.76E+03 4.55E+01 0. 5.36E+00 1.01E+01 I-133 7.51 E+01 1.30E+02 2.51E+04 227 E+02 0. 1.15E+02 3.98E+01 l-134 5.57E+00 1.51E+01 1.96E+03 2.41E+01 0. 1.32E+2 5.41E+00 I-135 2.33E+01 6.14E+01 8.03E+03 9.77E+01 0. 6.88E+01 225 E+01 CS-134 .6.85E+03 1.63E+04 0. 529 E+03 1.75E+03 2.85E+02 1.33E+04 CS-136 7.17E+02 2.83E+03 0. 1.58E+03 2.16E+02 322 E+02 2.04E+03 Based on 1 pCi/sec release rate of each isotope in discharge flow of 1 cc/sec with no additional dilution

Page 144 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM TABLE L-2 ENVIRONMENTALPATHWAY-DOSE CONVERSION FACTORS FOR LIQUID DISCHARGES PATHWAY - SALT WATER FISH AND SHELLFISH AGE GROUP - ADULT ORGAN DOSE FACTOR (MREM/HR PER pCi/ML)

NUCLIDE BONE LIVER THYROID KIDNEY LUNG GI-LLI WHOLE BODY CS-137 8.79E+03 1.20E+04 0. 4.09E+03 1.36E+03 2.31E+02 7.88E+03 CS-138 6.08E+00 1.20E+01 0. 8.84E+00 8.73E-01 5.12E-05 5.96E+00 BA-139 7.87E+00 5.61E~ 0. 5Z4E-03 3.18E-03 1.39E+01 2.30E-01 BA-140 1.65E+03 2.07E+00 0. 7.04E-01 1.18E+00 3.39E+03 1.09E+02 BA-141 0. 2.89E~ 0. 2.68E-03 1.64E-03 1.80E-09 1.29E-01 BA-142 1.73E+00 1.78E-03 0. 1.50E-03 1.01E-03 0. 1.09E-01 LA-140 1.58E+00 7.95E-01 0. 0. 0. 5.83E+04 2.11E-01 LA-142 8.07E-02 3.67E%2 0. 0. 0. 2.68E+02 9.15E-03 CE-141 3.43E+00 2.32E+00 0. 1.08E+00 0. 8.87E+03 2.63E-01 CE-143 6.05E-01 4.47E+02 0. 1.97E-01 0. 1.67E+04 4.95E-02 CE-144 1.79E+02 7.48E+01 0. 4.43E+01 0. 6.05E+04 9.60E+00 PR-144 1.91E-02 7.88E%3 0. 4.45E~ 0. 2.73E-09 9.65E-04 W-187 9.17E+00 7.68E+00 0. 0. 0. 2.51E+03 2.69E+00 NP-239 3.56E-02 3.50E-03 0.. 1.08E-02 0. 7.12E+02 1.92E-03 Based on 1 pCi/sec release rate of each isotope in discharge flow of 1 cc/sec with no additional dilution

Page 145 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM TABLE 6-1 MAXIMUMPERMISSIBLE'CONCENTRATIONS IN AIR IN UNRESTRICTED AREAS Nuclide MPG (pCVcc) Nuclide MPG (pCVcc)

Ar<1 4 E-8 Y-91 1 E-9 Kr-83m 3 E-8 Zr-95 1 E-9 Kr-85m 1 E-7 Nb-95 3 E-9 Kr-85 3 E-7 Ru-103 3 E-9 Kr<7 2 EW Ru-106 2 E-10 Kr-88 2 E-8 Ag-110 3 E-10 Kr-89 3 EW Sn-113 2 E-9 Kr-90 3 EW In-113m 2 E-7 Xe-131m 4 E-7 Sn-123 1 E-10 Xe-133m 3 E-7 Sn-126 1 E-10 Xe-133 3 E-7 Sb-124 7 E-10 Xe-135m 3 E-8 Sb-125 9 E-10 Xe-135 1 E-7 Te-125m 4 E-9 Xe-137 3 E-8 Te-127m- 1 E-9 Xe-138 3 E-8 Te-129m 1 E-9 H-3 2 E-7 I-130 1 E-10 P-32 2 E-9 I-131 1 E-10 Cr-51 8 E-8 I-132 3 E-9 Mn-54 1 E-9 I-133 4 E-10 Fe-59 2 E-9 I-134 6 E-9 Co-57 6 E-9 l-135 1 E-9 Co-58 2 E-9 Cs-134 4 E-10 Go-60 3 E-10 Gs-136 6 E-9 Zn-65 2 E-9 Cs-137 5 E-10 Rb-86 2 E-9 Ba-140 1 E-9 Sr-89 3 E-10 La-140 4 E-9 Sr-90 3 E-11 Ce-141 5 E-9 Rb-88 3 E-8 Ce-144 2 E-10

'f a nuclide is not listed, refer to 10 CFR Part 20, Appendix B, and use the most conservative insoluble/soluble MPC where they are given in Table II, Column 1.

146 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM TABLE G-2 GASES'age DOSE FACTORS FOR NOBLE WHOLE BODY SKIN DOSE FACTOR GAMMAAIR BETA AIR DOSE FACTOR L DOSE FACTOR DOSE FACTOR RADIONUCLIDE K, M, N, (mrem/yr per pCI/m') (mrem/yr per pCi/m') (mrad/yr per pCi/m') (mrad/yr per pCi/m')

Kr-83m 7.56E-02" 1.93E+01 2.88E+02 Kr-85m 1.17E+03 1.46E+03 1Z3E+03 1.97E+03 Kr-85 1.61E+01 1.34E+03 1.72E+01 1.95E+03 Kr-87 5.92E+03 9.73E+03 6.17E+03 1.03E+04 Kr-88 1.47E+04 2.37E+03 1.52E+04 2.93E+03 Kr<9 1.66E+04 1.01E+04 1.73E+04 1.06E+04 Kr-90 1.56E+04 7.29E+03 1.63E+04 7.83E+03 Xe-131m 9.15E+01 4.76E+02 1.56E+02 1.11E+03 Xe-133m 2.51E+02 9.94E+02 327 E+02 1.48E+03 Xe-133 2.94E+02 3.06E+02 3.53E+02 1.05E+03 Xe-135m 3.12E+03 7.11E+02 3.36E+03 7.39E+02 Xe-135 1.81E+03 1.86E+03 1.92E+03 2.46E+03 Xe-137 1.42E+03 1.22E+04 1.51E+03 1Z7E+04 Xe-138 8.83E+03 4.13E+03 9Z1E+03 4.75E+03 Ar<1 8.84E+03 2.69E+03 9.30E+03 3.28E+03 The listed dose factors are for radionuclides that may be detected in gaseous eNuents.

7.56E-02 = 7.56 X 10

Page 147 of 180 ST. LUCIE PLANT CHEMISTRY OPERATIN

G. PROCEDURE

NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM TABLE G-3 ENVIRONMENTALPATHWAY-DOSE CONVERSION FACTORS P I FOR GASEOUS DISCHARGES PATHWAY- GROUND PLANE DEPOSmON AGE GROUP - INFANT ORGAN DOSE FACTOR (SQ. METER - MREM/YR PER pCI/Sec)

NUCLIDE WHOLE BODY H-3 0.

CR-51 6.68E+06 1.10E+09 FE-59 3.92E+08 CO-57 1.64E+08 5Z7E+08 4.40E+09 6.87E~

RB-86 129E+07 SR%9 3.07E+04 SR-90 5.94E+05 Y-91 1.53E+06 ZR-95 6.94E+08 NB-95 1.95E+08 RU-103 1.57E+08 RU-106 2.99E+08 AG-110 3.18E+09 Based on 1 pCI/sec release rate of each isotope in and a Value of 1. for X/Q, depleted X/Q and Relative Deposition

Page 148 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM TABLE G-3 ENVIRONMENTALPATHWAY-DOSE CONVERSION FACTORS P I FOR GASEOUS DISCHARGES PATHWAY- GROUND PLANE DEPOSmON AGE GROUP - INFANT ORGAN DOSE FACTOR -

(SQ. METER MREM/YR PER pCI/Sec)

NUCLIDE WHOLE BODY SN-126 SB-124 8.42E+08 SB-125 7.56E+08 TE-125M 2.19E+06 TE-127M 1.15E+06 TE-129M 5.49E+07 1-130 7.90E+06 W31 2.46E+07 I-132 1.78E+06 I-133 3.54E~

I-134 6.43E+05 l-135 3.66E+06 CS-134 2.82E+09 CS-136 2.13E+08 CS-137 1.15E+09 BA-140 2.39E+08 CE-141 1.95E+07 CE-144 9.52E+07 Based on 1 pCi/sec release rate of each isotope t in and a Value of 1. for X/Q, depleted X/Q and Relative Deposition

Page 149 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM TABLE GQ ENVIRONMENTALPATHWAY-DOSE CONVERSION FACTORS R I FOR GASEOUS DISCHARGES PATHWAY - GROUND PLANE DEPOSION AGE GROUP - CHILD - TEEN-ADULT & INFANT ORGAN DOSE FACTOR (SQ. METER - MREM/YR PER pCI/Sec)

NUCLIDE WHOLE BODY H-3 CR-51 4.68E+06 MN-54 1.38E+09 FE-59 2.75E+08 CO-57 1.89E+08 CO-58 3.80E+08 CO-60 2.15E+10 7A3E+08 RB-86 9.01E+06 SR-89 2.17E+04 SR-90 5.35E+06 Y-91 1.08E+06 ZR-95 5.01E+08 NB-95 1.36E+08 RU-103 1.10E+08 RU-106 4.19E+08 AG-110 3.58E+09 Based on 1 pCi/sec release rate of each isotope in and a Value of 1. for X/Q, depleted X/Q and Relative Deposition

Page 150 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM TABLE G-4 ENVIRONMENTALPATHWAY-DOSE CONVERSION FACTORS R I FOR GASEOUS DISCHARGES PATHWAY - GROUND PLANE DEPOSITION AGE GROUP - CHILD - TEEN-ADULT & INFANT ORGAN DOSE FACTOR (SQ. METER - MREM/YR PER pCI/Sec)

NUCLIDE WHOLE BODY SN-126 5.16E+10 SB-124 5.98E+08 SB-125 2.30E+09 TE-125M 1.55E+06 TE-127M 8.79E+05 TE-129M 3.85E+07 I-130 I-131 1.72E+07 I-132 125E+06 I-133- 2.48E~

I-134 4.50E+05 I-135 2.56E+06 CS-134 6.99E+09 CS-136 1.49E+08 CS-137 1.03E+10 BA-140 1.68E+08 CE-141 1.37E+07 CE-144 1.13E+08 Based on 1 pCi/sec release rate of each isotope t in and a Value of 1. for X/Q, depleted X/Q and Relative Deposition

Page 151 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM TABLE G-5 ENVIRONMENTALPATHWAY-DOSE CONVERSION FACTORS R I I FOR GASEOUS DISCHARGES PATHWAY INHALATION AGE GROUP - INFANT ORGAN DOSE FACTOR (MREIteYR PER pCi/Cu Meter)

NUCLIDE BONE UVER THYROID KIDNEY LUNG GI-LLI WHOLE BODY H-3 0. 4.30E+02 4.30E+02 1.88E+02 4.30E+02 4.30E+02 4.30EW2 P-32 2.31E+05 1.35E+04 0. 0. 0. 1.51E+04 8.78E+03 CR-51 0. 0. 1.40E+01 3.99E+00 2.52E+03 5.81E+02 1.75E+01 MN-54 0. 6.93E+03. 0. 1.72E+03 2.45E+05 1.35E+04 1.10E+03 FE-59 2.06E+03 4.86E+06 0. 0. 1.78E+05 3.29E+04 1.85E+03 CO-57 0. 1Z1E+02 0. 0. 6.47E+04 5.50E+03 1.18E+02

0. 1.18E+02 0. 0. 8.79E+05 1Z1E+04 1.68E+02

0. 8.40E+02 0. 0. 5.57E+06 3.28E+04 1.17E+03 ZN-65 5.67E+03 1.81E+04 0. 1.21E+04 1.53E+05 9.35E+03 8.15E+03 RB-86 2.37E+04 0. 0. 0. 2.91E+03 1.03E+04 SR-89 4.31 E+04 0. 0. 0. 2.31E+06 6.80E+04 1.24E+03 SR-90 1.32E+07 0. 0. 0. 1.53E+07 1.39E+05 8.06E+05 Y-91 5.98E+04 0. 0. 0. 2.63E+06 7.17E+04 '1.60E+03 ZR-95 1.08E+04 2.73E+03 0. 9.48E+03 1.81E+06 1.41E+04 1.95E+03 NB-95 1Z8E+03 5.75E+02 0. 1.35E+03 4.77E+05 1Z1E+04 3.37E+02 RU-103 1.69E+02 0. 0. 1.02E+03 5.66E+05 1$ 8E+04 5.85E+01 RU-106 9.31E+03 0. 0: 2.34E+04 1.50E+07 1.76E+05 1.14E+03 AG-110 1.89E+03 1.75E+03 0. 3A4E+03 8.12E+05 5ME+04 1.04E+03 Based on 1 pCi/sec release rate of each isotope t in and a Value of 1. for X/Q, depleted X/Q and Relative Deposition

Page 152 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM TABLE G-5 ENVIRONMENTALPATHWAY-DOSE CONVERSION FACTORS R I I FOR GASEOUS DISCHARGES PATHWAY- INHALATION AGE GROUP - INFANT ORGAN DOSE FACTOR (MREM/YR PER pCI/Cu Meter)

NUCLIDE BONE LIVER THYROID KIDNEY LUNG Gl-LLI WHOLE BODY SN-123 3.11E+04 6.45E+02 6.45E+02 0. 3.61E+06 5.99E+04 1.02E+03 SN-126 2Z1E+05 5.85E+03 1.72E+03 0. 1.64E+06 2Z3E+04 8.40E+03 SB-124 5.46E+03 1 03E+02 1.32E+01 0. 4.34E+05 7.11E+04 2.17E+03 SB-125 1.16E+04 1ME+02 1.03E+01 0. 3.85E+05 1.76E+04 2.32E+03 TE-125M 4.54E+02 1.95E+02 1.53E+02 2.17E+03 4.96E+05 1.36E+04 6.16E+01 TE-127M 2.21E+03 9.83E+02 5.75E+02 8.01E+03 1.68E+05 2.62E+04 2.74E+02 TE-129M 1.32E+03 5.80E+02 5.08E+02 6.40E+03 1.83E+06 7.32E+04 2.06E+02 I-130 8.02E+02 2.35E+03 3.05E+05 3.65E+03 0. 1.35E+03 925 E+02 I-131 3.63E+04 427 E+04 1.41E+07 1.07E+04 0. 1.07E+03 2.51E+04 I-132 2.03E+02 5.70E+02 7.67E+04 9.09EW2 0. 7.11E+01 2.03E+02 I-133 1.34E+04 1.93E+04 4.66E+06 4.55E+03 0. 228 E+03 5.87E+03 I-134 1.13E+02 3.02E+02 4.02E+04 4.82E+02 1.76E%1 1.08E+02 I-135 4.TOE+02 1.22E+03 1.64E+05 1.95E+03 0. 9.18E+02 4.51E+02 CS-134 4.80E+05 825 E+05 0. 5.04E+04 1.01E+05 1.37E+03 7.32E+04 CS-136 6.85E+03 2.56E+04 0. 1.50E+04 2.10E+03 2.04E+03 1.95E+04 CS-137 6.86E+05 7.31E+05 0. 3.89E+04 9.45E+04 1.32E+03 4.41 E+04 BA-140 5.70E+03 4Z7E+00 0. 2.93E+00 1.64E+06- 2.95E+02 CE-141 2.52E+03 1.55E+03 0. 1.10E+03 5.24E+05 2.06E+04 1.81E+02 CE-144 4.68E+05 1.82E+05 0. 1.48E+05 1.27E+07 1.61E+05 2.49E+04 Based on 1 pCi/sec release rate of each isotope in and a Value of 1. for X/Q, depleted X/Q and Relative Deposition

e Page 153 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM TABLE GW ENVIRONMENTALPATHWAY-DOSE CONVERSION FACTORS R I I FOR GASEOUS DISCHARGES PATHWAY- COWS MILK(CONTAMINATEDFORAGE) AGE GROUP - INFANT ORGAN DOSE FACTOR (SQ. METER - MREM/YR PER pCi/Sec)

NUCLIDE BONE LIVER THYROID KIDNEY LUNG GI-LLI WHOLE BODY H-3 0. 2.37E+03 2.37E+03 1.04E+03 2.37E+03 2.37E+03 2.37E+03 PQ2 1.82E+10 1.14E+09 0. 0. 0. 2.05E+09 7.05E+08 CR-51 0. 0. 1.82E+04 6.72E+03 4.04E+04 7.66E+06 3.05E+04 MN-54 0. 8.96E+06 0. 2.67E+06 0. 2.74E+07 1.71E+06 FE-59 3.17E+07 7.52E+07 0. 0. 2.09E+07 2.48E+08 2.86E+07 CO-57 0. 1.36E+06 0. 0. 0. 3.46E+07 2.27E+06

0. 2.55E+07 0. 0. 0. 6.60E+07 6.24E+07 CO-60 0. 8.73E+07 0. 0. 0. 2.16E+08 2.09E+08 1.46E+09 4.65E+09 0. 3.11E+09 0. 2.93E+09 2.10E+09 RB-86 0. 2.77E+09 0. 0. 5.45E+08 1Z9E+09 SR-89 1.47E+10 0. 0. 0. 0. 2.75E+08 4ME+08 SR-90 1.65E+11 0. 0. 0. 0. 1.61E+09 4Z1E+10 Y-91 8.12E+04 0. 0. 0. 0. 5.37E+06 2.16E+03 ZR-95 2.12E+05 9.41E+04 0. 1.86E+04 0. 7.47E+07 5.56E+04 NB-95 5.49E+05 2.47E+05 0. 4.84E+04 0. 1.98E+08 1.45E+05 RU-103 8.30E+03 0. 0. 4.16E+03 0. 1.04E+05 2.86E+03 RU-106 2.01E+05 0. 0. 420 E+04 0. 1.56E+06 2.46E+04 AG-110 621 E+07 5.75E+07 0. 1.13E+08 0. 2.35E+10 3.42E+07 Based on 1 pCi/sec release rate of each isotope in and a Value of 1. for X/Q, depleted X/Q and Relative Deposition Note: The units for C-14 and H-3 are (MREM/YR Per pCi/Cu. Meter)

Page 154 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING, PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM TABLE GW ENVIRONMENTALPATHWAYNOSE CONVERSION FACTORS R I I FOR GASEOUS DISCHARGES PATHWAY- COWS MILK(CONTAMINATEDFORAGE) AGE GROUP - INFANT ORGAN DOSE FACTOR (SQ. METER - MRElteYR PER pCi/Sec)

NUCLIDE BONE LIVER THYROID KIDNEY LUNG GI-LLI WHOLE BODY SN-126 1.75E+09 3ASE+07 1.01E+07 0. 4.97E+06 1.16E+09 5.25E+07 SB-124 2.75E+07 5.19E+05 6.64E+04 0. 2.13E+07 7.78E+08 1.09E+07 SB-125 3.59E+07 3.27E+06 2.93E+06 3.96E+06 2.83E+09 2A3E+08 6.62E+06 TE-125M 1.57E+08 5.30E+07 5.18E+07 7.05E+07 0. 7.57E+07 2.10E+07 TE-127M 5.54E+07 1.93E+07 1.79E+07 2.00E+08 0. 324 E+08 7.38E+06 TE-129M 5.87E+08 2.02E+08 2.21E+08 2.70E+08 0. 3.54E+08 8.95E+07 I-130 4.54E+05 1.35E+06 1.71E+08 2.09E+06 0. 1.15E+06 5.29E+05 I-131 2.59E+09 3.09E+09 9.94E+11 7Z4E+08 0. 1.16E+08 1.81 E+09 I-132 1.78E%1 4.76E-01 6Z6E+01 7.58E%1 0. 8.93E-02 1.69E-01 l-133 3.75E+07 5ASE+07 1.30E+10 129E+07 0. 9.74E+06 1.66E+07 I-134 0. 0. 1.06E<9 0. 0. 0.

I-135 1.49E+04 3.94E+04 5.15E+06 6Z6E~ 8.07E<2 4.41E+04 1A4E+04 CS-134 4A3E+10 7.97E+10 0. 4.65E+09 9.12E+09 1.90E+08 6.75E+09 CS-136 2.78E~ 1.10E+09 0. 6.11Et08 8.37E+07 1 USE+08 7.90E+08 CS-137 6A4E+10 7.21E+10 0. 3.66E+09 8.69E+09 1.86E+08 4.14E+09 BA-140 2.45E+08 2.47E+05 0. 122E+04 1.51E+05 8.13E+06 1.27E+07 CE-141 2.65E+05 1.62E+05 0. 9.72E+03 0. 7.87E+07 1.90E+04 CE-144 2.10E+07 8.29E+06 0. 5.67E+05 0. 8.66E+08 1.13E+06 Based on 1 pCi/sec release rate of each isotope in and a value of 1 ~ for X/Q, depleted X/Q and relative deposition.

Note: The units for C-14 and H-3 are (MREM/YR Per pCi/Cu. Meter)

Page 155 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM TABLE G-7 ENVIRONMENTALPATHWAY-DOSE CONVERSION FACTORS R I I FOR GASEOUS DISCHARGES PATHWAY GOATS MILK(CONTAMINATEDFORAGE) AGE GROUP - INFANT ORGAN DOSE FACTOR -

(SQ. METER MREM/YR PER pCI/Sec)

NUCLIDE BONE UVER THYROID KIDNEY LUNG GI-LLI WHOLE BODY H-3 0. 4.84E+03 4.84E+03 2.11E+03 4.84E+03 4.84E+03 4.84E+03 P2 2.19E+10 1.37E+09 0. 0. 2.46E+09 8.46E+08 CR-51 0. 0. 2.19E+03 8.07E+02 4.85E+03 9.19E+05 3.66E+03 MN-54 0. 1.08E+06 0. 3.20E+05 0. 329 E+06 2.05E+05 FE-59 4.12E+05 9.78E+05 0. 0. 2.72E+05 3.23E+06 3.72E+05 CO-57 0. 1.64E+05 0. 0. 0. 4.15E+06 2.72E+05

0. 3.06E+06 0. 0. 0. 7.92E+06 7.49E+06

0. 1.05E+07 0. 0. 0. 2.59E+07 2.51 E+07 ZN-65 1.76E+08 5.57E+08 0. 3.73E+08 0. 3.51E+08 2.52E+08 RB-86 0. 3.32E+08 0. 0. 0. 6.54E+07 1.55E+08 SR-89 3.09E+10 0. 0. 0. 0. 5.77E+08 8.87E+08 SR-90 3.46E+11 0. 0. 0. 0. 3.35E+09 8.83E+10 Y-91 9.74E+03 0. 0. 0. 0. 6.45E+05 2.60E+02 ZR-95 2.54E+04 1.13E+04 223 E&3 0. 8.95E+06 6.67E+03 NB-95 6.59E+04 2.97E+04 0. 5.81E+03 0. 2.37E+07 1.75E+04 RU-103 9.96E+02 0. 0. 4.99E+02 0. 1Z4E+04 3.43E+02 RU-106 2.41E+04 0. 5.04E+03 0. 1.87E+05 2.96E+03 AG-110 7.45E+06 6.90E+06 0. 1.36E+07 0. 2.81E+09 4.10E+06 Based on 1 pCi/sec release rate of each isotope t in and a Value of 1. for X/Q, depleted X/Q and Relative Deposition Note: The units for C-14 and H-3 are 1MREM/Yr per pCi/Cu meter.

Page 156 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM TABLE G-7 ENVIRONMENTALPATHWAY-DOSE CONVERSION FACTORS R I I FOR GASEOUS DISCHARGES PATHWAY GOATS MILK(CONTAMINATEDFORAGE) AGE GROUP - INFANT ORGAN DOSE FACTOR -

(SQ. METER MREM/YR PER pCI/Sec)

NUCUDE BONE LIVER THYROID KIDNEY LUNG Gl-LLI WHOLE BODY SN-126 2.10E+08 4.17E+06 1ME+06 0. 5.97E+05 1.40E+08 6.30E+06 SB-124 3.30E+06 622 E+04 7.97E+03 0. 2.56E+06 9.33E+07 1.30E+06 SB-125 4.31 E+06 3.92E+05 3.52E+05 4.76E+05 3.40E+08 2.92E+07 7.94E+05 TE-125M 1.89E+07 6.36E+06 6.21E+06 8.46E+06 0. 9.09E+06 2.52E+06 TE-127M 6.64E+06 2.31E+06 2.15E+06 2.40E+07 0. 3.88E+07 8.85E+05 TE-129M 7.05E+07 2.42E+07 2.66E+07 323E+07 0. 425 E+07 1.07E+07 I-130 5.45E+05 1.61E+06 2.05E+08 2.51E+06 0. 1.38E+06 6.35E+05 I-131 3.11E+09 3.70E+09 1.19E+12 9Z8E+08 0. 1.39E+08 2.17E+09 I-132 2.13M)1 5.71E%1 7.51E+01 9.10E-01 0. 1.07E+1 2.03E-01 I-133 4.50E+07 6.57E+07 1.55E+10 1.55E+07 0. 1.17E+07 1.99E+07 1-134 0. 0. 1>7E-09 0. 0. 0. 0.

I-135 1.79E+04 4.72E+04 6.18E+06 7.51E+04 2.42E-01 SME+04 1.73E+04 CS-134 1.33E+11 2.39E+11 0. 1.39E+10 2.74E+10 5.69E+08 2.02E+10 CS-136 8.34E+08 329 E+09 0. 1.83E+09 2.51E+08 3.74E+08 2.37E+09 CS-137 1.93E+11 2.16E+11 0. 1.10E+10 2.61E+10 5.59E+08 1Z4E+10 BA-140 2.95E+07 2.96E+04 0. 1.47E+03 1.81E+04 9.76E+05 1.52E+06 CE-141 3.17E+04 1.95E+04 0. 1.17E+03 0. 9A4+06 2.28E+03 CE-144 2.52E+06 9.95E+05 0. 6.80E+04 0. 1.04E+08 1.36E+05 Based on 1 pCi/sec release rate of each isotope t in and a value of 1. for X/Q, depleted X/Q and relative deposition.

Note: The units for C-14 and H-3 are 1MREM/Yr per pCi/Cu meter.

Page 157 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM TABLE M-1 Selecting the Appropriate Long Term (X/Q) for Dose Calculations Involving Noble Gases for:

(1) Whole Body dose from instantaneous releases (2) Skin dose from instantaneous releases (3) Gamma air dose (cumulative)

(4) Beta air dose (cumulative)

TYPE OF DOSE ~

LIMITING LIMITING (X/Q) VALUE CALCULATION RANGE (miles) Sector sec/m Instantaneous 0.97 NW 1.6 X 10 1/31 days 0.97

1. Normally (X/Q) = 1.6 X 10'ec/m'.

Quarterly 0.97 Yearly May use option of actual 12 Consecutive 0.97 meteorological data for time of months concern.

Annual Report 0.97 N/A Note-1 NOTE 1 The (X/Q) has to be calculated based on actual meteorological data that occurred during the period of interest. The sector of interest is N/A because the limiting (X/Q) will be determined from the actual meteorological data and may occur in any sector.

0.97 miles Corresponds to the minimum site boundary distance in the north direction 0.97 miles was chosen for all other sectors for ease of calculations

'nd when the averaging is done for quarterly reports.

Page 158 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM TABLE M-2 Selecting the Appropriate Long Term (X/Q)o or (D/Q) for Dose Calculations Involving Radioiodines 8 8 D Particulates for:

(1) Inhalation (2) Tritium(AII gas pathways) (3) Ground Plane TYPE OF DOSE LIMITING LIMITINGSECTOR (X/Q)~ seo/m' (D/Q) 1/m~

CALCULATION RANGE (miles) (OL)

NW Instantaneous 0.97 1.3 X 10 WNW 8.2 X Quarterly for 0.97 A,B Annual Reports 0.97 10'.2 1/31 days, B 0.97 NW Qtr. yearly, 1.3 X 10~

Annual Total Dose 0.97 WNW X 10'OL)

Over land areas only (A) To be determined by reduction of actual met data occurring during each quarter (B) For Tritium in the Milk Animal Pathway, the (X/Q)o value should be that of the respective controlling sector and range where the Milk Animal is located as per Table M-3. Example: If a cow was located at 4.25 miles in NW sector, use the (X/Q)o for 4.25 miles NW.

Page 159 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM TABLE M-3 Selecting the Appropriate Long Term (D/Q) for Dose Calculations Involving Radioiodines and 8D Particulates for Grass-Cow-Milk or Grass-Goat-Milk:

TYPE OF DOSE (D/Q) Value LIMITINGRANGE LIMITINGSECTOR CALCULATION Release Rate 1/m'.

1/31 Days Quarterly - Yearly Annual (Calendar Year)

Annual Report The worst cow or goat as per locations from land census. If no milk animal in any sector, assume a cow at 4.25 miles in the highest (D/Q) sector over land.

B. The historical (D/Q) of all land sectors with the worst cow or goat from each sector as reported in the Land Census. A 4.25 mile cow should be assumed in the worst sector over land when no milk animal is reported.

C. The highest (D/Q) at a milk animal location of all milk animals reported in the Land Census Report. (If no milk animals within 5 miles a 4.25 mile cow should be assumed in the sector having the highest (D/Q) at 4.25 miles over land). Actual Met Data should be used for the selection of the worst case milk animal and for the dose calculations. If both goat and milk animals are reported inside 5 miles, dose calculations should be performed on each animal and the higher dose animal contribution should be used.

The historical wind frequency fractions for e'ach sector are listed in Table M-8.

Page 160 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM TABLE M-4 TERRAIN CORRECTION FACTORS Florida Power & Light Company St. Lucie Unit 1 Terrain Correction Factors (PUFF / STRAIGHT LINE)

Hutchinson Island, Florida Period of Record: 8/29/77 to 8/31/78 Dames and Moore Job No: 4598-112 Base Distance in Miles/Kilometers DESIGN AFFECTED DISTANCE 25 .75 1.25 1.75 2.25 2.75 325 3.75 4.25 4.75 SECTOR MILES .40 1.21 2.01 2.82 3.62 4.42 523 6.03 6.84 7.64 NNE 0. 1.906 1.576 1.465 1.404 1.318 1.334 1.386 1.346 1.338 1.887 1.581 1.461 1.391 1.310 1259 1.164 1;128 1.101 1.116 ENE 0. 1.452 1230 1.122 1.081 1.047 1.033 .941 .906 .902

0. 1.662 1.425 1.277 1.193 1.151 1.097 1.121 1.123 1.122 ESE 0. 1.690 1.483 1.328 1.246 1.190 1.134 1.094 1.032 .968 SE 0. 1.818 1.691 1.470 1.427 1A35 1.361 1.366 1.331 1.279 1Z39 SSE 0. 1.812 1.586 1.370 1.302 1.270 1263 1.229 1.193 1.171 1.151

0. 1.398 1.321 1.125 1.108 1.127 1.073 1.063 1.047 1.024 SSW 0. 1.534 1.411 1.192 1Z05 1.132 1.135 1.116 1.077 1.060 SW 0. 1.685 1.492 1.222 1.160 1.160 1.198 1.196 WSW 0. 1.620 1.333 1Z10 1.173 1.257'.123 1.082 1.091 1.099 1.056 1.034 1.004 W 0. 1.651 1.415 1Z18 1.154 1.099 1.081 1.067 1.093 1.083 WNW 0. 1.720 1.430 1X67 1.185 1.150 1.133 1.125 1.033 1.045 NW 0. 1.681 1A07 1257 1.173 1.119 1.078 1.063 .995 .998 .978 NNW 0. 1.739 1.488 1.316 1Z12 1.172 1.122 1.135 1.080 1.099 1.091

0. 1.816 1.524 1.389 1.285 1.263 1.285 1267 1.231 1.213 Note 1: Any interpolations between stated mileages will be done by Iog-log

Page 161 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM TABLE MW, HISTORICAL LONG TERM - 0 Fre uenc corrected Terrain / Recirculation Adjusted Program ANNXOQ9 Version - 11/18/76 Florida Power 8 Light Company St. Lucie Unit 1 Average Annual Relative Concentration (sec/cubic meter)

Hutchinson Island, Florida Period of Record: 9/1/76 to 8/31/78 Dames and Moore Job No: 1.4598- 112 Base Distance in Miles/Kilometers DESIGN AFFECTED DISTANCE .75 1Z5 1.75 2.25 2.75 325 3.75 425 4.75 SECTOR MILES 1.21 2.01 2.82 3.62 4.42 523 6.03 6.84 7.64 NNE 0. 1.1E45 1.7E46 7.BE<7 4.5E<7 3.1E%7 2.2E+7 1.7&)7 1.5E<7 1.2E%7 1.0E<7 NE 1.3E+5 2.1&06 8.9E+7 5.1E<7 3.4E<7 2.4E%7 1.7E%7 1.4E-07 1.1E+7 9.8E~

ENE 0. 9.3E~ 1.4E~ 62E%7 37E<7 2.5E<7 1.9E%7 1.3E<7 1.1 E-07 8.8E~ 7.5E~

0. 9.8E-06 1.6E~ 6.5E%7 3.7E%7 2.5E<7 1.8E%7 1.4E<7 12E47 9.9E48 8.4E-08 ESE 0. 1.2E~ 1.9E46 8.1E<7 4.8E<7 32E+7 2.4E<7 1.8E<7 1.4E+7 1.1E%7 9.0E~

SE 0. 1.4E~ 2.4E~ 9.7E47 5.7E47 4.0E<7 2.9E%7 2.3E7 1.9E7 1.4E<7 1.2E<7

0. 1.1E~ 1.7E46 7.3E<7 4.3E47 2.9E<7 2.1&)7 1.6E<7 1.3&)7 1.1E+7 9.1E~

62E~ 1.0E~ 42E47 2.5E%7 1.SEE 1.4E<7 1.0E<7 8.0E~ 6.6E~ 5.5E-08 SSW 0. 5.7E~ 9.0E+7 4.0E%7 2.3E+7 1.6E<7 1.1E<7 8.9E-08 7.0&M 5.7E48 4.8E-08 SW 6.1E~ 9.4E%7 3.9E+7 2.2E<7 1.6E<7 1.1E%7 7.0E-08 6.0E~ 5.1E~

WSW 0. 7.3E~ 1.1E~ 4.6E%7 2.7E%7 1.7E47 1.3E%7 1.0E+7 6.5E~ 5.4E~

W 7.6E~ 1.2E-06 52EW7 2.9E%7 2.0E%7 1.3E<7 1.0E%7 8.4E-08 7.2E~ 6.1E-08 WNW 0. 1.4E-05 2.1E~ 9.1E47 5.2E-07 3.4E<7 2.6E%7 2.0E<7 1.5E<7 1.2E<7 1.0E<7 1.6E~ 2.4&% 1.0E~ 5.9E<7 3.9E-07 2.BE+7 2.1E-07 1.7E-07 1.4E%7 1.2E%7 NNW 0. 1.5E%5 2.2E-06 9.6E<7 5.5E+7 3.6E47 2.6E%7 2.0E+7 1.6E-07 1.3E<7 1.2E7

0. 9.1E~ 1.4E~ 6.3E-07 3.6E%7 2.4E%7 1.8E47 1.4E%7 12E<7 9.4E48 7.9E%8 Number of Valid Observations = 17135 Number of Calms Lower Level = 95 Number of Invalid Observations = 385 Number of Calms Upper Level = 0 Note 1 - Any interpolations between stated mileages will be done by log-log

Page 162 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM TABLE MW HISTORICAL LONG TERM DEPLETED - Q Fr uenc corrected Terrain / Recirculation Adjusted Program ANNXOQ9 Version - 11/18/76 Florida Power & Light Company St. Lucie Unit 1 Average Annual Relative Concentration Depleted (sec/cubic meter)

Hutchinson Island, Florida Period of Record: 9/1/76 to 8/31/78 Dames and Moore Job No: 4598-112 Base Distance in Miles/Kilometers DESIGN AFFECTED DISTANCE .25 .75 1.25 1.75 2.25 2.75 3.25 3.75 4.25 4.75 SECTOR MILES Ao 1.21 2.01 2.82 3.62 4.42 5.23 6.03 6.84 7.64 NNE 0. 1.1E45 1.6E46 6.6E<7 3.BE+7 2.4 EAT 1.TENT 1.3E<7 1.1E47 92E48 7.6EM NE 12E+5 1.7&Xi 7.6 EAT 4.3E<7 2.BE+7 1.9 EAT 1.4E<7 1.1E-OT 8.6E~ 7.4E-OB ENE 0. 8.9E46 1.2E46 5.3 EAT 3.0 EAT 2.0 EAT 1.4E+7 1.0 EAT 8.4E-OB 6.6E~ 5.6E~

0. 9.1E46 1.3E~ 5.6EQT 3.1E<7 2.1 E+7 1.5E+7 1.1E<7 9.1E-OS 7.5E~ 6.3E~

ESE 0. 12E~ 1.6E~ 6.9E<7 3.9E<7 2.6E<7 1.9 EAT 1.4ERT 1.1&07 8.5E~ 6.7E~

SE 0. 1.3E%5 2.0E~ 8.2E+7 4.TENT 3.3 EAT 2.3E<7 1.BEAT 1.3E47 1.1E<7 9.0E-OB

0. 1.1E<5 1.6E~ 6.3E<7 3.5E+7 2.4E<7 1.BENT 1.4E<7 1.0 EAT 8.2E~ 6.8E~

0. 5.9E46 9.1E47 3.6E-OT 2.1E<7 1.4E<7 1.1E<7 T.TE~ 62E-08 5.0E~ 4.1E-OS SSW 0. 5.4E~ B.0E47 3.4E+7 1.9 EAT 1.3EWT 8.9E~ 6.9E48 5.5E-OB 4.3E~ 3.6E~

SW 5.7E46 8.4 EAT 3.4E<7 1.BE<7 12&)7 92E~ 6.7E~ 5.3E-OB - 4.6E~ 3.8E-OB WSW 0. 9.6E+7 4.0 EAT 2.2E+7 1.4E<7 1.0E+7 B.0E~ 6.1 E-08 5.0E~ 4.0E~

W 1.1E~ 4.4E+7 2.4E7 1.6EQT 1.1E<7 8.2E~ 6.4E~ 5.5E~ 4.4E-OB

0. 1.3E<5 7.9 EAT 4.4E-07 2.9E<7 -

2.0EAT 1.6EAT 1.2E+7 9.3EM 7.8E-OB NW 1.5E%5 8.9 EAT 4.9E<7 3.1 EAT 2.3E<7 1.TENT 1.3E-07 1.0E<7 8.5E-OB NNW 1.4&)5 8.3E<7 4.5E<7 2.9E<7 2.0 EAT 1.6 EAT 1.2EWT 1.0E<7 8.6E-OB

0. 8.7E46 1.3E46 5.4E-07 3.0E<7 2.0EQT 1.4EOT 1.1E+7 8.9E-OS 7.0E48 Number of Valid Observations = 17135 Number of Calms Lower Level = 95 Number of Invalid Observations = 385 Number of Calms Upper Level = 0 Note 1 - Any interpolations between stated mileages will be done by log-log

Page 163 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM TABLE M-7 HISTORICAL LONG TERM - 0/Q Fr uenc corrected TERRAIN / RECIRCULATION ADJUSTED PROGRAM ANNXOQ9 VERSION - 11/18/76 Florida Power & Light Company St. Lucie Unit 1 Average Annual Relative Deposition Rate (square meter - 1)

Hutchinson Island, Florida Period of Record: 9/1/76 to 8/31/78 Dames and Moore Job No: 4598 - 112 Base Distance in Miles/Kilometers DESIGN AFFECTED DISTANCE .75 125 1.75 2.25 2.75 325 3.75 4.25 4.75 SECTOR MILES 1.21 2.01 2.82 3.62 4.42 523 6.03 6.84 7.64 NNE 0. 6.5E~ 9.3E~ 3.7E~ 2.1E~ 9.0E-10 6.8E-10 5.5E-10 4.3E-10 3.5E-10 NE 6.0E48 8.9E~ 3.5E49 1.9E49 8.1E-10 5.6E-10 4.3E-10 3.3E-10 2.8E-10 ENE 0. 1.9E~ 1.0E~ 6.6E-10 4.6E-10 3.2E-10 2.4E-10 1.9E-10 1.5E-10

0. 3.0E48 4.6E~ 1.8E49 9.5E-10 6.0E-10 42E-10 3.1E-10 2.5E-10 2.0E-10 1.6E-10 ESE 0. 3.7E~ 5.8E~ 2.3E~ 1.2E~ 8.0E-10 5.4E-10 3.9E-10 3.0E-10 22E-10 1.7E-10 SE 0. 1.0E48 4.0E~ 2.1E~ 1.4'ZE~

9.7E-10 72E-10 5.6E-10 4.3E-10 3.5E-10

0. 62E~ 9.5E~ 3.6E~ 2.0E~ 8.7E-10 6.4E-10 4.9E-10 3.9E-10 3.1E-10

0. 42E~ 7.0E~ 2.6E~ 1.4E~ 9.5E-10 6.9E-10 4.9E-10 3.8E-10 3.0E-10 2.5E-10 SSW 0. 3.4E~ 5.4E~ 2.2E~ 1.1E~ 7.5E-10 5.0E-10 3.7E-10 2.9E-10 2.3E-10 1.8E-10 SW 7.0E-09 2.6E~ 1.5E~ 9.0E-10 6.6E-10 4.6E-10 3.6E-10 3.0E-10 2.5E-10 WSW 0. 5.3E48 7.TED 3.0E49 1.0E~ 7.3E-10 5.5E-10 4.1E-10 3.3E-10 2.6E-10

0. 5.0E-08 7$ E~ 1.6E~

1.6'.0E49 9.8E-10 6.7E-10 5.0E-10 3.8E-10 3.2E-10 2.6E-10

0. 8.8E~ 1.3E~ 4.9E~ 2.6E~ 1.7E49 1.1E-09 8.7E-10 6.6E-10 5.1E-10 4.2E-10 82E~ 4.7E49 2.5E~ 1.1E~ 7.9E-10 5.8E-10 4.7E-10 3.8E-10

0. 8.2E-08 1Z&N 4.6E49 2.4E~ 1.5E~ 1.1E%9 8.1E-10 5.9E-10 4.8E-10 4.0E-10

0. 5.1 E-08 7.3E~ 2.9E49 1.5E49 9.8E-10 7.1E-10 5.4E-10 42E-10 3.2E-10 2.7E-10 Number of Valid Observations = 17135 Number of Calms Lower Level = 95 Number of Invalid Observations = 385 Number of Calms Upper Level = 0 Note 1 - Any interpolations between stated mileages will be done by log-log

Page 164 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM TABLE M-8 Joint Wind Frequency Distribution Data Period: September 1, 1976 - August 31, 1978 All Winds St. Lucie Unit 2 Data Source: On-Site Hutchinson Island, Florida Wind Sensor Height 10,00 Meters Florida Power & Light Co.

Table Generated: 12/05/78. 07.42.18. Dames and Moore Job No: 4598 - 112 - 27 Wind Speed Categories (Meters per Second)

WIND 0.0- 1.5- 3.0- 5.0- 7.5-SECTOR 1.5 3.0 5.0 7.5 10.0 <<10.0 TOTAL'EAN SPEED 71 206 318 3 0 NNE 1.25 1.92 02 0.00 4.05 62 292 385 128 0 0 887

.38 1.77 2.33 .77 0.00 0.00 5.25 505 0 0 1057 ENE 3.51

.36 3.06 0.00 0.00 6AO 69 355 510 76 0 0 1010 3.25

.42 2.15 3.09 .46 0.00 0.00 6.11 115 744 72 1 0 1616 ESE 0.00 9.78 304

.70 4.14 4.50 .01 183 660 749 28 0 0 1620 SE 3.99 4.53 17 0.00 0.00 9.81 1 ~ 11 ~

129 579 656 93 1 0 1458 SSE O'I 3.10

.78 3.50 3.97 .56 0.00 8.82 72 310 407 8 1 897 1.88 2A6 05 01 5A3 372 105 SSW 2.25 2.70 .20

.51

'129 14 0 1025 SW 3.10

.78 08 0.00 6.20 155 320 188 29 0 695 WSW 2.59

.94 1.94 1.13 ~ 18 0.00 4.21 174 267 119 37 2 0 599 W 1.05 1.62 .72 01 0.00 3.63 203 172 17 0 0 696 WNW .10 0.00 0.00 4.21 1.23 1.04 143 518 424 50 0 0 1135 NW 2.85

.87 3.14 2.57 .30 0.00 0.00 6.87 85 379 535 70 1 0 1070 NNW .42 0.00 6.46

.51 2.29 3.24 01 91 194 531 0 969 3.69

.55 1.17 3.21 0.00 5.88 95 95 CALM CALM .57

.57 1920 6214 7023 1287 73 16522 TOTAL 3.10 11.62 37.61 42.51 7.79 100.00 NUMBER OF VALIDOBSERVATIONS 16522 94.30 PCT. Key XXX Number of Occurrences NUMBER OF INVALIDOBSERVATIONS 988 5.70 PCT. XXX Percent Occurrences TOTAL NUMBER OF OBSERVATIONS 17520 100.00 PCT.

' Totals below are given in hours 8 percent for wind frequency by sectors

Page 165 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM APPENDIX B LIMITED ANALYSIS DOSE ASSESSMENT FOR LIQUID RADIOACTIVE EFFLUENTS The radioactive liquid effluents for the years 1978, 1979, and 1980 were evaluated to determine the dose contribution of the radionuclide distribution. This analysis was performed to evaluate the use of a limited dose analysis for determining environmental doses. Limiting the dose calculation to a few selected radionuclides that contribute the majority of the dose provides a simplified method of determining compliance with the dose limits of Control 3.11.1.2, Tables B-1 and B-2 present the results of this evaluation. Table B-1 presents the fraction of the adult whole body dose contributed by the major radionuclldes. Table B-2 presents the same data for the adult Gl-LLI dose. The adult whole body and adult Gl-LLI were determined to be the limiting doses based on an evaluation of all age groups (adult, teenager, child, and infant) and all organs (bone, liver, kidney, lung, and Gl-LLI). As the data in the tables show, the radionuclides Fe-59, Co-58, Co-60, Zn-65, Cs-134, and Cs-137 dominate the whole body dose; the radlonuclides, Fe-59, Co-58, Co-60, Zn-65, and Nb-95 dominate the Gl-LLI dose. In all but one case (1979-fish, Gl-LLI dose) these

~

~

radionuclides contribute 90% or more of the total dose, If for 1979 the fish and shellfish

~

~

pathways are combined as Is done to determine the total dose, the contribution from these nuclides is 84%" of the total Gl-LLI dose.

Therefore, the dose comm0iment due to radioactive material in liquid effluents can be reasonably estimated by limiting the dose calculation to the radionuclides, Fe-59, Co-58, Co-60, Zn-65, Nb-95, Cs-134, and Cs-137, which cumulatively contribute the majority of the total dose calculated by using all radionuclides detected. This limited analysis dose assessment method is a simplified calculation that provides a reasonable evaluation of doses due to liquid radioactive effluents and allows for an estimate of Fe-55 contribution to dose.

Tritium is not included in the limited analysis dose assessment for liquid releases because the potential dose resulting from normal reactor releases is negligible and is essentially independent of radwaste system operation. The amount of tritium releases annually is about 300 curies. At St, Lucie, 300 CVpr released to the Atlantic Ocean produces a calculated whole body dose of 5 X 10 mrem/yr via the fish and shellfish pathways. This amounts to less than 0.001% of the design objective dose of 3 mrem/yr.

Furthermore, the release of tritium is a function of operating time and power level and is essentially unrelated to radwaste system operation.

The dose due to Iron -55 made it necessary to change the conservatism factor from 0.8 to 0.6, which was done on Revision 7 to the ODCM, based on early 1986 data.

Page 166 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM TABLE B-1 ADULT WHOLE BODY DOSE CONTRIBUTIONS FRACTION OF TOTAL 1978 1979 1980 RADIONUCLIDE FISH SHELLFISH FISH SHELLFISH FISH SHELLFISH Co-58 0.08 0.27 0.06 0.28 0.02 0.05 Co+0 0.05 0.19 0.03 0.15 0.20 OA4 Fe-59 0.10 0.25 0.04 0.13 0.15 0.22 Zn-65 0.01 0.10 0.02 0.19 0,04 0.20 Cs-134 0.31 OA6 0.14 0.27 0.04 0.07'.10 Gs-137 0.42 0.38 0.11 0.30 0.04 TOTAL 0.97 0.98 0.99 1.00 0.98 0.99 TABLE B-2 ADULT Gl-LLI DOSE CONTRIBUTION FRACTION OF TOTAL 1978 1979 1980 RADIONUCLIDE SHELLFISH FISH SHELLFISH FISH SHELLFISH Go-58 0.03 0.36 0.25 OA4 0.01 0.07 Co+0 0.02 0.23 0.12 0.22 0.05 0.57 Fe-59 0.03 0.31 0.16 0.19 0.04 0.29 Zn-65 0.01 0.02 0.01 0.05 0.01 0.04 Nb-95 0.89 0.01 0.21 0.01 0.88 0.01 TOTAL 0.98 0.92 0.75 0.90 0.97 0.97

Page 167 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM APPENDIX C TECHNICAL BASES FOR EFFECTIVE DOSE FACTORS Overview The evaluation of doses due to releases of radioactive material to the atmosphere can be simplified by the use of effective dose transfer factors instead of using dose factors which are radionuclide specific. These effective factors, which are based on the typical radionuclide distribution in the releases, can be applied to the total radioactivity released to approximate the dose in the environment, i.e., instead of having to sum the isotopic distribution multiplied by the isotope specific dose factor only a single multiplication (K,,

M,, or N~) times the total quantity of radioactive material released would be needed.

This approach provides a reasonable estimate of the actual dose while eliminating the need for a detailed calculational technique.

Determination of Effective Dose Factors The effective dose transfer factors are based on past operating data. The radioactive effluent distribution for the past years can be used to derive single effective factors by the following equations:

K>>= Z( K,~f, (C-1)

Where; the effective whole body dose factor due to gamma emissions from all noble gases released the whole body dose factor due to gamma emissions from each noble gas radionuclide i released the fractional abundance of noble gas radionuclide i is of the total noble gas radionuclides

Page 168 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO, C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM APPENDIX C TECHNICAL BASES FOR EFFECTIVE DOSE FACTORS (continued)

(L + 1.1 M),>> = f (L( + 1.1 M) ~ f, (C-2)

Where:

(L+1.1 M),= the effective skin dose factor due to beta and gamma emissions from all noble gases released (L, + 1 ~ 1 M,) = the skin dose factor due to beta and gamma emissions from each noble gas radionuclide i released M>>= Z( M, ~

f( '(C-3)

Where:

M ff the effective air dose factor due to gamma emlssions from all noble gases released the air dose factor due to gamma emissions from each noble gas radionuclide i released Z N,'

N,>>= ( f( (C<)

Where:

Neff the effective air dose factor due to beta emissions from all noble gases released N, the air dose factor due to beta emissions from each noble gas radionuclide i

Page 169 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM APPENDIX C TECHNICAL BASES FOR EFFECTIVE DOSE FACTORS (continued)

To determine the appropriate effective factors to be used and to evaluate the degree of variability, the atmospheric radioactive effluents for the past 3 years have been evaluated. Tables C-1 and C-2 present the results of this evaluation.

As can be seen from Tables C-1 and C-2, the effective dose transfer factors varies little from year to year. The maximum observed variability from the average value is 18%.

This variability is minor considering other areas of uncertainty and conservatism inherent in the environmental dose calculation models.

To provide an additional degree of conservatism, a factor of 0.8 is introduced Into the dose calculation process when the effective dose transfer factor is used. This added conservatism provides additional assurance that the evaluation of doses by the use of a single effective factor will not significantly underestimate any actual doses in the environment.

Reevaluation The doses due to the gaseous effluents are evaluated by the more detailed calculation methods (i.e., use of nuclide specific dose factors) on a yearly basis. At this time a comparison can be made between the simplified method and the detailed method to-assure the overall reasonableness of this limited analysis approach. If this comparison indicates that the radionuclide distribution has changed significantly causing the simplified method to underestimate the doses by more than 20%, the value of the effective factors will need to be reexamined to assure the overall acceptability of this approach. However, this reexamination will only be needed if the doses as calculated by the detailed analysis exceed 50% of the design bases doses (i.e., greater than 5 mrads gamma air dose or 10 mrads beta air dose),

In any case, the appropriateness of the A value will be periodically evaluated to assume the applicability of a single effective dose factor for evaluating environmental doses.

Page 170 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM r

TABLE C-1 EFFECTIVE DOSE FACTORS NOBLE GASES-WHOLE BODY AND SKIN DOSES WHOLE BODY EFFECTIVE SKIN EFFECTIVE DOSE FACTOR DOSE FACTOR YEAR K>> (L+1.1M)~

mrem-m'i- mrem-m'i-r r 1978 73X1 1.4 X 10 1979 7.4 X 1 1.4X1 1980 5,6 X 1 1,2 X 10 AVERAGE 6.8 X 10 1.3 X 10 TABLE C-2 EFFECTIVE DOSE FACTORS NOBLE GASES - AIR DOSES GAMMAAIR EFFECTIVE 'ETA AIR EFFECTIVE DOSE FACTOR DOSE FACTOR YEAR Man N, mrad-m'i- mrad-m'i-r r 1978 80 X 10 1.2 X 10 1979 8,O X1O 1.2 X 10 1980 62 X 1 1.2 X 10 AVERAGE 7.4 X 10 1.2 X 10

Page 171 of 180 ST, LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM APPENDIX D TECHNICAL BASES FOR ELIMINATINGCURIE INVENTORY LIMIT FOR GASEOUS WASTE STORAGE TANKS The NRC Standard Technical Specifications include a limit for the amount of radioactivity that can be stored in a single waste gas storage tank. This curie inventory limit is established to assure that in the event of a tank failure releasing the radioactivity to the environment the resulting whole body dose at the site boundary would not exceed 0.5 rem.

For St. Lucie, the inventory limit in the waste gas storage tank has been determined to be approximately 285,000 curies (Xe-133, equivalent). An allowable primary coolant

'adioactivity concentration is established by the Appendix A Technical Specifications which limits the primary coolant radioactivity concentrations to 100/E with E being the average energy of the radioactivity in Mev. This equation yields an upper primary coolant gross activity limit of about 160 pCVml. By applying this activity concentration limit to the total liquid volume of the primary system, a total activity limit can be determined, For St. Lucie the primary system volume is about 70,000 gallons, which

~

~

yields a limiting total inventory of approximately 43,000 Ci.

By assuming a typical radionuclide distribution an equivalent Xe-133 inventory can be determined. Table D-1 provides the typical radionuclide (noble gases) distribution and the Xe-133 equivalent concentration. The equivalent concentration is determined by multiplying the radionucllde concentration by the ratio of the nuclide whole body dose-factor to the Xe-133 whole body dose factor. Summing all the individual radionucllde equivalent concentrations provides the overall reactor coolant Xe-133 equivalent concentration. The data show that the equivalent concentration is a factor of 2 larger than the gross concentration (i.e., 24 pCVgm total versus 47 pCVgm equivalent). The resulting Xe-133 equivalent curie inventory of the reactor coolant system is approximately 86,000 Ci.

Therefore, even if the total primary system at the maximum Tech. Spec, allowable concentration was degassed to a single waste gas decay tank, the tank curie inventory would be well below the 285,000 Cl limit. Based on this evaluation, the curie inventory limit on a single waste gas storage tank cannot exceed the Technical Specification requirement.

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Page 172 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM TABLE D-1 REACTOR COOLANT - XE-133 EFFECTIVE CONCENTRATION REG. GUIDE 1.109 Xe-133 REACTOR WHOLE BODY DF RATIO EFFECTIVE COOLANT'ONCENTRATION

~mrei~r TB OF CONCENTRATION RADIONUCLIDE (pCI/gm) (pCI/ml) Xe 133 OF (pCI/gm)

Kr-85m 0.19 1.2 X 10 4.1 0.78 Kr-85 0.83 1.6 X 10 0.06 0.05 Kr-87 0.16 5.9 X 10 20. 3.2 Kr-88 0.31 1.5 X 10 52. 16.

Xe-131m 8.8 92 X 10 0.32 2.8 Xe-133m 0.20 2.5 X 10 0.86 0.17 Xe-133 12. 2.9 X 10 1.0 12.

Xe-135m 0.11 3.1 X 10 1.2 Xe-135 1.2 1.8 X 10 6.2 7.4 Xe-137 0.02 1.4 X 10 4.8 0.1 Xe-138 0.12 8.8 X 10 3.6 TOTALS 24. 47.

• Data adapted from the NRC GALE Code

Page 173 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM APPENDIX E RADIOLOGICALENVIRONMENTALSURVEILLANCE ST. LUCIE PLANT Key to Sample Locations SAMPLE APPROXIMATE SAMPLES DIRECTION PATHWAY LOCATION DESCRIPTION COLLECTION DISTANCE COLLFCTED SFCTOR FREQUENCY (miles)

Direct Radiation North of Blind Creek Quarterly N Direct Radiation NNW-5 South of Pete Stone Creek Quarterly NNW Direct Radiation NNW-10 C. G. Station TLD Quarterly NNW Direct Radiation NW-5 Indian River Drive at Rio Vista Drive Quarteriy 6 NW Direct Radiation NW-10 Intersection of SR 68 and SR 607 TLD Quarterly 10 NW Direct Radiation WNW-2 Cemetery South of 7107 Indian River Drive Quarterly WNW Direct Radiation WNW-5 US-1 at SR 712 Quarteriy WNW Di(ect Radiation WNW-10 SR 70, West of Turnpike TLD Quarterly 10 WNW Direct Radiation W-2 7609 Indian River Drive Quarterly W Direct Radiation W-5 Oleander and Sager Streets Quarterly W Direct Radiation W-10 I-95 and SR 709 Quarteriy W Direct Radiation WSW-2 8503 Indian River Drive Quarterly 2 WSW Direct Radiation WSW-5 Prima Vista Blvd. at Yacht Club Quarterly '0 WSW Direct Radiation WSW-10 Del Rio and Davis Streets Quarterly WSW Direct Radiation SW-2 9207 Indian River Drive Quarterly SW Direct Radiation SW-5 US 1 and Village Green Drive Quarterly SW Direct Radiation SW-10 Port St. Lucie Blvd. and Cairo Road Quarterly 10 SW Direct Radiation ~ SSW-2 10307 Indian River Drive Quarteriy SSW

Page 174 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM APPENDIX E RADIOLOGICALENVIRONMENTALSURVEILLANCE (continued)

ST. LUCIE PLANT Key to Sample Locations SAMPLE APPROXIMATE SAMPLES DIRECTION PATHWAY LOCATION DESCRIPTION COLLECTION DISTANCE COLLECTED SECTOR FREQUENCY (miles)

Direct Radiation SSW-5 Port St. Lucie Blvd. and US 1 TLD Quarterly SSW Direct Radiation SSW-10 Pine Valley and Westmoreland Roads Quarterly SSW Direct Radiation 13179 Indian River Drive Quarterly Direct Radiation S-10 US1 and SR 714 Quarterly 10 Direct Radiation S/SSE-10 Indian River Drive and Quail Run Lane Quarterly 10 SSE Direct Radiation SSE-5 Entrance of Nettles Island Quarterly SSE Direct Radiation Airborne SSE-10 Elliot Museum Quarterly 10 SSE Direct Radiation SE-1 South of Cooling Canal Quarterly SE Airborne Direct Radiation 'H-32 U. of Florida - 1FAS Entomology Lab Vero Beach Quarterly 19 NNW Radioiodine &

FPL Substation - Weatherby Road Weekly WNW Particulates Airborne Radioiodine &

~ 'H12 FPL Substation - SR 76, Stuart Weekly 12 Particulates Radioiodine &

Airborne H14 Onsite - near south property line Weekly SE Particulates Radioiodine &

H30 Power Line - 7609 Indian River Drive Weekly W Particulates

'Denotes Control Sample

Page 175 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CAL'CULATIONMANUAL ODCM APPENDIX E RADIOLOGICALENVIRONMENTALSURVEILLANCE (continued)

ST. LUCIE PLANT Key to Sample Locations SAMPLE APPROXIMATE SAMPLES DIRECTION PATHWAY LOCATION DESCRIPTION COLLECTION DISTANCE COLLECTED SECTOR FREQUENCY (miles)

Radioiodine 8 Airborne H34 Onsite - At Meteorological Tower Weekly 0.5 .

Waterborne Particulates Surface Water Weekly Atlantic Ocean vicinity of public beaches east side (ocean)

H15 ENE/E/ESE of Route A1A Sediment from Semi-Annually shoreline Surface Water Monthly (ocean) 10-20 Waterborne H59 Near south end of Hutchinson Island S/SSE Sediment from Semi-Annually shoreline Crustacea Semi-Annually Food Products H15 Ocean side vicinity of St. Lucie Plant (NOTE 1) ENE/E/ESE Fish Semi-Annually Broad Leaf Monthly Food Products H51 Offsite near north property line vegetation (when N/NNW (mangrove) available)

Denotes control sample

Page 176 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM APPENDIX E RADIOLOGICALENVIRONMENTALSURVEILLANCE (continued)

ST. LUCIE PLANT Key to Sample Locations SAMPLE APPROXIMATE SAMPLES DIRECTION PATHWAY LOCATION DESCRIPTION COLLECTION DISTANCE COLLECTED SECTOR FREQUENCY (miles)

Broad leaf Monthly Food Products H52 Offsite near south property line vegetation (when S/SSE (mangrove) available)

Crustacea Semi-Annually Fish Semi-Annually Food Products H59 Near south end of Hutchinson Island Broad leaf Monthly 10-20 S/SSE vegetation (mangrove)

'Denotes control sample It is the policy of Florida Power & Light Company (FPL) that the St. Lucie 1 & 2 Radiological Environmental Monitoring Programs are conducted by the State of Florida Department of Health and Rehabilitative Services (DHRS), pursuant to an Agreement between FPL and DHRS and; that coordination of the Radiological Environmental Monitoring Programs with DHRS and compliance with the Radiological Environmental Monitoring Program Controls are the responsibility of the Nuclear Energy Services Department.

NOTE 1 These samples may be collected from or supplemented by samples collected from the plant intake canal if the required analyses are unable to be performed due to unavailability or inadequate quantity of sample from the ocean side location.

Page 177 of 180 ST, LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATIONMANUAL ODCM FIGURE 1-1 SITE AREA MAP & ENVIRONMENTALSAMPLE LOCATIONS t4~A QT ~~ - H61Ãnd Creelt LC LU

. 0 K

WNW-2 Z H16 EXCLIJSION AREA (0.07 ml)

ANO LOW UNIT 1 W.2 POPULATION 2ONE (1 ml)

NOTES:

+ UNIT 2

1) L4lqrdd ahhraste Release Point

2) Due to the soale oI the SE-1 Recure the Exduslon Area RarÃus (OAl7 m6e) and the Low Population Zone (1 mme) area shown aa being the same stze.

P5" w Ts~7 H14 '~)

H62 Ar 1

(C-2%4. WPG)

SCALE IN MILES

Page 178 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM FIGURE 1-2 ENVIRONMENTALSAMPLE LOCATIONS 10 MILES NV-10 WNW.10 4'

ygsW

+>>

M y EOF W.1 Fp g +44 WSW4 WSW-1 SW.10

. R.k SSW.10 H12

Page 179 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM APPENDIX F METEOROLOGICAL DISPERSION FORMULAS'For XI 2.032 EQ (1)

(u)O (oz+ )

2e032 g/Q

+ "(.)o EQ (2)

Where:

C =.5 V = 207.5 ft. (63.2 meters)

(u) = a name for one term X/Q was calculated using each of the above EQ's for each hour. The highest X/Q from EQ (1) or EQ (2) was selected. The total integrated relative concentration at each sector and distance was then divided by the total number of hours in the data base.

• Terrain correction factors given by Table MA were also applied to Dispersion Formulas

/

/

Page 180 of 180 ST. LUCIE PLANT CHEMISTRY OPERATING PROCEDURE NO. C-200, REVISION 11 OFFSITE DOSE CALCULATION MANUAL ODCM APPENDIX F METEOROLOGICAL DISPERSION FORMULAS'continued)

~de (X/Q)~ = (X/Q) X (Depletion factor of Figure 2 of R.G. 1.111-R1)

For De osition D/Q:

D/Q = RDep/(2 sin [11,25] X) X (Freq. distribution)

Where:

D/Q Ground deposition rate X Calculation distance RDep = Relative ground deposition rate from Figure 6 of R.G. 1.111, R1

e Document No. C-200 i

Rev. 11 ADDENDUM INSTRUCTION SHEET FOR DOCUMENT COMPLETION

. NOTE TO WORD PROCESSING'rawings in DrawPerfect e NUCLEAR RECORDS, ITEMS MUST BE XEROXED ON THE FOLLOWING PAGES BEFORE DISTRIBUTION'/A Verified by Vault Custodian

• 1 I

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qJ