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Rev. 0 1

i i

I 4

lo UNION ELECTRIC COMPANY CALLAWAY. PLANT OFFSITE DOSE CALCULATION MANUAL i

8303240311 830321 i

PDR ADOCK 05000403 PDR A

Rav. 0 Table of Contents 1.0 PURPOSE AND SCOPE Page 1

2.0 LIQUID EFFLUENTS 2

2.1 RADIOLOGICAL EFFLUENT TECHNICAL SPECIFICATION 3.3.3.9 2

2.2 LIQUID EFFLUENT MONITORS 2

2.2.1 Coatinuous Liquid Effluent Monitors 3

2.2.2 Radioactive Liquid Batch Release C1 Effluent Monitors 5

2.3 ODCM METHODOLOGY FOR THE DETERMIN-ATION OF LIQUID EFFLUENT MONITOR SETPOINTS 6

2.3.1 Development of ODCM Methodology for the Determination of Liquid Effluent Monitor Setpoints 6

2.3.2 Summary, Setpoint Determination Methodology for Liquid Effluent Monitors 11 2.4 LIQUID EFFLUENT CONCENTRATION MEASUREMENTS 12 2.4.1 Radiological Effluent Technical Specification 3.11.1.1 12 2.4.2 Description of Liquid Effluent Concentration Measurements 12 2.5 INDIVIDUAL DOSE DUE TO LIQUID EFFLUENTS 13 2.5.1 Radiological Effluent Technical Specification 3.11.1.2 13 2.5.2 The Maximum Exposed Individual 13 2.5.3 ODCM Methodology for Determining Dose Contributions from Liquid Effluents 13

-i-

, - ~

~-

Page 2.5.3.1 Calculation of Dose Contributions 13 2.5.3.2 Dose Factor Related to Liquid Effluents 15 2.5.4 Summary, Determination of Individ-ual Dose Due to Liquid Effluents 17 2.6 LIQUID RADWASTE TREATMENT SYSTEM 21 2.6.1 Radiological Effluent Technical Specification 3.11.1.3 21 2.6.2 De'scription of the Liquid Radwaste Treatment System 21 2.6.3 Operability of the L' quid Radwaste i

Treatment System 21 3.0 GASEOUS EFFLUENTS 22 3.1 RADIOLOGICAL EFFLUENT TECHNICAL SPECIFICATION 3.3.3.10 22 3.2 RADIOLOGICAL EFFLUENT TECHNICAL SPECIFICATION 3.11.2.1 22 3.3 GASEOUS EFFLUENT MONITORS 22 3.3.1 Continuous Release Gaseous Effluent Monitors 23

()

3.3.2 Batch Release Gaseous Monitors 25 3.4 ODCM METHODOLOGY FOR THE DETERMIN-l ATION OF GASEOUS EFFLUENT MONITOR SETPOINTS 26 3.4.1 Development of ODCM Methodology l

l for the Determination of Gaseous Effluent Monitor Setpoints 26 3.4.1.1 Whole Body Dose Rate Setpoint Calculations 28 3.4.1.2 Skin Dose Rate Setpoint Calculation 29 3.4.1.3 Gaseous Effluent Monitors Setpoint Determination 31

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Page 3.4.2 Summary, Gaseous Effluent Monitors Setpoint Determination 31 3.5 ODCM METHODOLOGY FOR DETERMINING

, DOSE CONTRIBUTIONS FROM GASEOUS EFFLUENTS 31 3.5.1 Determination of Dose Rate 31 3.5.1.1 Noble Gases 31 3.5.1.2 Radionuclides Other Than Noble Gases 32 3.5.2 Individual Dose Due to Noble Gases 36 3.5.2.1 Radiological Effluent Technical Specification 3.11.2.2 35 3.5.2.1.1 Noble Gases 35 3.5.2.2 Radiological Effluent Technical Specification 3.11.2.3 36 3.5.2.2.1 Radionuclides Other Than Noble Gases 37 3.6 GASEOUS RADWASTE TREATMENT SYSTEM 40 3.6.1 Radiological Effluent Technical Specification 3.11.2.4 40 O

3.6.2 Description of the Geseous Radwaste Treatment System 40 l

3.6.3 Operability of the Gaseous Radwaste Treatment System 40 l

4.0 DOSE AND DOSE COMMITMENT FROM URANIUM FUEL CYCLE SOURCES 41 4.1 RADIOLOGICAL EFFLUENT TECHNICAL l

SPECIFICATION 3.11.4 41 j

4.2 ODCM METHODOLOGY FOR DETERMINING i

DOSE AND DOSE COMMITMENT FROM URANIUM FUEL CYCLE SOURCES 41 i

4.2.1 Calculation of Total Dose 41 j

iii 1

y w-

,y-w--

w

--- 9

-g--

-y-

-w.

-y

=

.-+4w<r w

-.-w.

Rw. O Table of Contents (continued)

Page 4.2.1.1 Calculation of Total Dose from Noble Gases 41 4.2.1.2 Calculation of Total Dose from Radionuclides Other Than Noble Gases 42 4.2.1.3 Summary, Determination of Total Dose 42 5.0 RADIOLOGICAL ENVIRONMENTAL MONITORING 44 5.1 RADIOLOGICAL EFFLUENT TECHNICAL SPECIFICATION 3.12.1 44

==5.2 DESCRIPTION==

OF THE RADIOLOGICAL ENVIRONMENTAL MONITORING PROGRAM 44 6.0 METEOROLOGICAL DATA COLLECTION AND PROCESSING 52 6.1 METEOROLOGICAL DATA COLLECTION 52 6.2 METEOROLOGICAL DATA PROCESSING 52 7.0 SEMI-ANNUAL RADIOACTIVE EFFLUENT RELEASE REPORT 54 8.0 IMPLEMENTATION OF ODCM METHODOLOGY 55

==9.0 REFERENCES==

-iv-

Rev. 0 List of Figures Figure 5.lA Radiological Air Sampling Network Figure 5.lB Radiological Air Sampling Network i

Figure 5.2 Location of Aquatic Sampling Stations Figure 5.3 Groundwater Quality Monitoring Locations Figure 5.4 Food Products and Milk Sampling Locations Figure 5.5 Locations of Soil Sampling Stations O

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Li~st of Tables s

rable 1 Ingestion Dose Commitment Factor' (A ) for Adult Age Group-,

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R v. 0 1.0 PURPOSE AND SCOPE The Offsite Dose Calculation Manual (ODCM) describes the methodology and parameters used in the calculation of offsite doses and dose rates due to radioactive liquid and gaseous effluents and in the calculation of liquid and gaseous effluent monitoring instrumentation alarm / trip setpoints.

Changes in the calculational methodologies or parameters will be incorporated into the ODCM and documented in the Semi Annual

The ODCM does not L

replace any station implementing procedures.

Rnv. 0 2.0 LIQUID EFFLUENTS 2.1 Radiological Effluent Technical Specification 3.3.3.9 The radioactive liquid effluent monitoring instrumenta-tion channels shall be OPERABLE with their alarm / trip setpoints set to ensure that the limits of Radiological Effluent Technical Specification 3.11.1.1 are not exceeded.

The alarm / trip setpoint of these channels shall be determined in accordance with the methodology described in the ODCM.

2.2 Liquid Effluent Monitors Gross radioactivity monitors which provide for au-tomatic termination of liquid effluent releases are present on the liquid effluent lines.

Flow rate meas-urement devices are present on the liquid effluent lines and the discharge line (cooling tower blowdown).

s Setpoints, precautions and limitations applicable to the operation of the Callaway Plant liquid effluent monitors are provided in the appropriate Plant Procedures.

Setpoint values are calculated to assure that alarm and trip actions occur prior to exceeding the Maximum Permissible Concentration (MPC) limits in 10 CFR Part 20 at the release point to the unrestricted area.

The calculated alarm and trip action setpoints for the liquid effluent line monitors and flow measur-ing devices must satisfy'the following equation:

cf S

C

(_)

F+f (2.1)

C=

the liquid effluent concentration limit (MPC) implementing Radiological Effluent Technical Specification 3.11.1.1 for the site in (pCi/ml).

c=

The setpoint, in (pCi/ml), of the radioactiv-ity monitor measuring the radioactivity concentration in the effluent line prior to dilution and subsequent release; the setpoint, which is inversely proportional to the volumetric flow of the effluent line and -

 

Rev. 0 directly proportional to the volumetric flow of the dilution stream plus the effluent stream, represents a value, which, if ex-ceeded, would result in concentrations exceed-ing the limits of 10 CFR Part 20 in the unres-tricted area.

f=

The flow setpoint as measured at the radiation monitor location, in volume per unit time, but in the same units as F, below.

F=

The dilution water flow setpoint as measured prior to the release point, in volume per unit time.

{If (F) is large compared to (f), then F + f ~ F}.

The radioactive liquid waste stream is diluted by the Os plant discharge line prior to entry into the Missouri River.

Normally, the dilution flow is obtained from the cooling tower blowdown, but should this become unavailable, the plant water treatment facility sup-plies the necessary dilution flow via a bypass line.

({)

C(F + f)

(pCi/ml) c<

f (2.2) 2.2.1 Continuous Liquid Effluent Monitors The radiation detection monitors associated with conti-nous liquid effluent releases are:

Monitor I.D.

Description O-BM-RE-52 Steam Generator Blowdown Discharge Monitor 0-LE-RE-59 Turbine Building Drain Monitor - -

The steam generator blowdown discharge monitor conti-nuously monitors the blowdown discharge pump cutlet to detect radioactivity due to system demineralizer break through and to provide backup to the steam generator blowdown process radioactivity monitor to prevent dis-charge of radioactive fluid.

The sample point is located on the discharge of the pump in order to moni-tor discharge or recycled blowdown fluid and upstream of the discharge isolation valve to permit termination of the radioactive release prior to exceeding the in-stantaneous concentration limits of 10 CFR Part 20.

The high radioactivity alarm / trip setpoint initiates

control room alarm annunciation and automatic isolation of the blowdown isolation valves and the blowdown dis-charge valve.

The turbine building drain effluent monitor is provided to monitor turbine building liquid effluents prior to release to the environs.

The fixed-volume detector as-sembly continuously monitors the drain effluent line upstream of the drain line isolation valve.

The high radioactivity alarm / trip setpoint initiates control room annunciation and automatic isolation of the drain line isolation valve to prevent the release of radioac-tive fluids.

The sample location ensures that all potentially radioactive turbine building liquid ef-fluents are monitored prior to discharge.

O Each monitor channel is provided with a two level sys-tem which provides sequential alarms on increasing radioactivity levels.

These setpoints are designated as alert setpoints and alarm / trip setpoints.-

The alarm / trip setpoints are determined through the use of Equation (2.2) methodology to ensure that Radiologi-cal Effluent Technical Specification 3.11.1.1 limits are not exceeded at the site unrestricted area boundary.

The alert setpoints have been administra-tively established below the alarm / trip setpoints, thus providing an additional margin of safety.

7 Rev. 0 rate, and the' MPC for Cs-137 as the controlling isotope.

A portion of the total site allocation is provided for the value of the radiation monitor set-point,(c), based on local procedures and operating experience.

In the event the alarm / trip setpoint is reached, the radiation monitor setpoint (c),.will be reevaluated using the actual dilution flow rate (F),

the actual effluent stream flow rate (f), and the ac-tual isotopic analysis.

This evaluation will then be used to ensure that Radiological Effluent Technical Specification 3.11.1.1 limits were not exceeded.

2.2.2 Radioactive Liquid Batch Release Effluent Monitor The two radiation monitors which are associated with the liquid effluent batch release systems are:

MONITOR I.D.

Description O

O-HB-RE-18 Liquid Radwaste Discharge Monitor 0-HF-RE-45 Secondary Liquid Waste System Monitor' 4

The liquid radwaste radiation monitor continuously monitors the discharge of the liquid radwaste process-ing system to prevent the discharge of radioactive fluid to the environs.

The fixed-volume detector as-sembly continuously monitors the system discharge line upstream of the discharge valve.

The high radioactiv-ity alarm / trip setpoint initiates control room alarm annunciation and automatic isolation of the liquid rad-waste system discharge valve to terminate discharge.

O The sample point is located to ensure that all potenti-ally radioactive fluids from the liquid radwaste l

processing system are monitored prior to discharge.

The secondary liquid waste system discharge radioactiv-ity monitor continuously monitors secondary liquid waste system effluents prior to discharge to the environs.

The fixed-volume detector assembly monitors.

the discharge line upstream of the discharge isolation valve.

The high radioactivity alarm / trip setpoint ini-l tiates control room alarm annunciation and automatic isolation of the secondary liquid waste system dis-charge valve to prevent the discharge of radioactive fluid.. The sample location ensures that all potenti-l ally radioactive sources from the system are monitored prior to discharge.

, l 1

-. _.. ~, - -. - - -

Rev. 0 The setpoint for these monitors is determined according to the methodology described by Equation 2.2 and is a function of the dilution flow rate (F), the radioactive effluent line flow rate (f) and the tank liquid ef-fluent concentration, as determined by a pre-release isotopic analysis.

Based on these factors, a setpoint is calculated for the appropriate monitor to ensure that Radiological Effluent Technical Specification 3.11.1.1 limits are not exceeded at the site unres-tricted area boundary.

2.3 ODCM Methodology for the Determination of Liquid Effluent Monitor Setpoints The dependence of the setpoint (c), on the radionuclide distribution, yields, calibration, and monitor paramet-ers, requires that several variables be considered in setpoint calculations.

()

2.3.1 Development of ODCM Methodology for the Determination of Liquid Effluent Monitor Setpoints

~

2.3.1.1 The isotopic concentration of the release be-ing considered must be determined.

This is obtained from the sum of the measured concentrations as deter-mined by the analysis required per Radiological Ef-fluent Technical Specifications Table 4.11-1:

ICi=IC

+ C, + C

+C (2.3) gg s

t O

Where:

C. =

the concentration of each radionuclide i, as 1

the sum of the concentrations (C ) of each IC

99 measured gamma emitting nuclide 8bserved by gamma-ray spectroscopy of the waste sample.

the measured concentrations (C of alpha em-C**

itting nuclides observed by gr8s)s alpha analysis of the monthly composite sample..

the measured concentrations of Sr-89 and Sr-90 s

in liquid waste as determined by analysis of the quarterly composite sample.

the measured concentration of H-3 in liquid t

waste as determined by analysis of the monthly composite sample.

The C term is included in the analysis of each batch; 9

terms for alpha, strontium, and tritium are included as appropriate.

2.3.1.2 The measured radionuclide concentrations are O-used to calculate a Dilution Factor (F ), which is the g

ratio of total dilution flow rate to tank flow rate required to assure that the limiting concentrations of Radiological Effluent Technical Specification 3.11.1.1 are met at the point of discharge.

This is referred to as the required Dilution Factor and is determined ac-cording to:

Fd=I

+F (2.4) s 1

MPCi O

C C

C C

=I g

a

+

s

+

t

+F (2.5) 9 g

MPC MPC MPC MPC g

a s

t Where:

measured concentrations of C,

C, C and C C.

as defined in 2.3.1.1.

Term 2 C a will be included in the calculation as t

8 appropriate.

MPC. =

MPC MPC, MPC and MPC are limiting con 8e,ntrations 8f the appbopriate radionuclide 1

from 10CFR 20, Appendix B, Table II, Column 2..

Rev. O For dissolved or entrained noble gases the t

concentration shall be limited to 2x10 4 pCi/ml total activity.

the safety factor; a conservative factor used F

s to compensace for statistical fluctuations and errors of measurements.

(For example, 0.5 corresponds to a 100 percent F

g variation.)

Default value is F

= 0.9.

g 2.3.1.3 For the case Fd < 1, the monitor tank effluent concentration meets the limits of Radiological Effluent Technical Specification 3.11.1.1 without dilution and the effluent may be released at any desired flow rate.

If Fa > 1 then dilution is required to ensure com-pliaHee with Radiological Effluent Technical Specifica-tion 3.11.1.1 concentration limits.

If simultaneous releases are occuring or are anticipated, a modified dilution factor (Fd ), must be determined so that

()

available dilution 21ow may be apportioned among simultaneous discharge pathways.

Fdn = Fd+F (2.6) a Where:

F" =

the allocation factor which will modify the required dilution factor such that

/~)

simultaneous liquid releases may be made l

k-l without exceeding the limits of Radiological Effluent Technical Specification 3.11.1.1.

F, = f (2.7) l f (

)

)

Where:

n=

the number of liquid discharge pathways for which Fa > 1 and which are planned for simultaMeous release.

However, this value for F may be unnecessarily res-trictive in that all rele$se pathways are apportioned the same fraction of the available dilution stream, regardless of the relative concentrations of each of the sources.

7-Therefore, F is necessarily defined as a flexible

(,)/

quantity wit 8 a default value of 1/n.

Prior to initi-ating a simultaneous release, a check must be made to assure that the sum of the allocation factors assigned to pathways for the simultaneous release is 1 1.

2.3.1.5 The calculated maximum permissable whste tank effluent flow rate, (f

, is based on the modified

) main)d the effective dilution flow dilution factor, (F rate, (F ff).

TheNEfectivedilutionflowrateis given by Feff = (0.9)F I2*0) e Where:

the cooling tower blowdown flow rate and/or bypass dilution flow.

A conservative value for F would be the minimum allow-able cooling tower blowdod of 5000gpm which is used as a default value.

2.3.1.6 Having established the values of F and F thecalculatedmaximumpermissiblewastetaNRflow95fe, can be calculated by:

i

*ff P~

*ff (f r fp << Feff)

(2.9) max g

g dn dn Where:

f

= the expected undiluted effluent flow rate.

p Thus the effluent flow rate is set at or below f"6Ee.

Even though the value of f actualeffluentpumpcapacEfy,maybelargerthanit does represent (f

the upper limit to the effluent fEo)w, rate whereby the s,/

requirements of Radiological Effluent Technical Specif-ication 3.11.1.1 may still be met.

If Fa < 1, the ef-fluent flow rate setpoint may be assigned any value since the waste tank effluent concentration meets the limits of Radiological Effluent Technical Specification 3.11.1.1 without dilution and the release may be made without regard to the setpoints for other release pathways.

For those discharge pathways selected to be secured during the release under consideration, the flow rate setpoint should be set at as low a value as practicable to detect any inadvertent release.

2.3.1.7 The liquid radiation monitor setpoint may now y

be determined based on the values of. C and f whichwerespecifiedtoprovidecomplianbe, withe 85, limits of Radiological Effluent Technical Specification

The monitor response is primarily to gamma {g g. tion, agia therefore, the actual setpoint is based on The calculated monitor setpoint concentration is determined as follows:

c=AIC pCi gg (Refer to Note)

(2.10)

A=

Adjustment factor which will allow the set-point to be established in a practical manner for convenience and to prevent spurious alarms.

A=Imax (Refer to Note)

(2.11) f Following) p If A > 1: Calculate c and determine the maximum value

()

for the actual monitor setpoint (pCi/ml).

If A < 1:No release may be made.

This condition must be flagged and the operator instructed to re-evaluate 2.3.1.3 and 2.3.1.5 (i.e., reduce ef-fluent flow rate or return radwaste for reprocessing).

NOTE If Fa < 1, no further dilution is required and the releMse may be made without regard to available dilu-tion or to other releases made simultaneously.

How-ever, it is necessary to estahlish a monitor setpoint which will provide alarm should the release concentra-tion inadvertently exceed Radiological Effluent Techni-(~N cal Specification 3.11.1.1 limits.

This can be accom-N/

plished by establishing the adjustment factor as follows:

1 A=F (2.12) d 2.3.2 Summary, Setpoint Calculation Methodology for Liquid Effluent Monitors The methodology described in 2.3.1 is used to determine setpoints for each of the radiation monitors assigned a d

Rav. O liquid process functi-on.

The limiting release concen-tration can be increased by reducing the discharge flow-rate and decreased by reducing the cooling tower blowdown flow-rate.

2.4 Liquid Effluent Concentration Measurements 2.4.1 Radiological Effluent Technical Specification 3.11.1.1 The concentration of radioactive material released from the site shall be limited to the concentrations speci-fied in 10 CFR Part 20, Appendix B, Table II, Column 2 for radionuclides other than dissolved or entrained no-ble gases.

For dissolved or entrained noble gases, the concentration shall be limited to 2.0 E-04 pC1/ml total activity.

2.4.2 Liquid Effluent Concentration Measurements

)

Liquid batch releases are discharged as a discrete volume and each release is authorized based upon the sample analysis and the dilution flow rate existing in the discharge line at time of release.

To assure re-presentative campling, each liquid monitor tank will be isolated and thoroughly mixed by recirculation of tank contents prior to sample collection.

The methods for mixing, sampling, and analyzing each batch are outlined in applicable plant procedures.

The allowable release rate limit is be calculated for each batch based upon the pre-release analysis, dilution flow-rate, and other procedural conditions, prior to authorization for release.

The radwaste liquid effluent discharge is monitored prior to entering the dilution discharge line and will automatically be terminated if the pre-()

tions are determined primarily from the gamma isotopic analysis of the liquid batch sample.

For alpha, Sr-89, Sr-90 and H-3, the measured concentration from the previous composite analysis is used.

Composite samples are collected for each batch release and monthly and quarterly analyses are performed in accordance with Table 4.11-1 of the Radiological Effluent Technical Specifications.

Dose contributions from liquids discharged as conti-nuous releases are determined by utilizing the last measured values of samples required in accordance with Radiological Effluent Technical Specifications Table 4.11-1.

) )

Rev. 0 2.5 Individual Dose Due to Liquid Effluents 2.5.1 Radiological Effluent Technical Specification 3.11.1.2 The dose or dose commitment to an individual from radi-oactive materials in liquid effluents released from the site shall be limited:

a.

During any calendar quarter to less than or equal to 1.5 mrem to the total body and less than or equal to 5 mrem to any organ, and L.

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

2.5.2 The Maximum Exposed Individual

()

The cumulative dose determination considers the dose contributions from the maximum exposed individual's consumption of fish and potable water, as appropriate.

The Callaway Plant's liquid effluents are discharged to the Missouri River.

As there are no potable water in-takes within 50 miles of the discharge point, this pathway does not require routine evaluation.

There-fore, the dose contribution from fish consumption is expected to account for more than 95% of the total man-rem dose from discharges to the Missouri River.

receiving 95% of the total dose from eating fish and 5%

l of the total dose from recreational activities.

t 2.5.3 ODCM Methodology for Determining Dose Contributions From Liquid Effluents l

2.5.3.1 Calculation of Dose Contributions The dose contributions for the total time period l

m IAtg 1=1 are calculated monthly (at least one each 31 days) and a cumulative summation of these total body and any or-gan dose is maintained for each calendar quarter.

'N.

m D =I [Ai7 g

ig F]

(2.13)

1 t=1 Where:

Dr=

the cumulative dose commitment to the whole

(])

body or any organ, t,

from the liquid ef-fluents for the total period m

t=1 in mrem.

Atg=

the length of the Ath time period over which and F are averaged for all liquid C.$ eases,E rd in hours.

Cig =

the average concentration of radionuclide, i, in undiluted liquid effluent during time period At from any liquid release, in pCi/ml.

()

the site related ingestion dose commitment A.

factor to the total body or any organ I for each identified principal gamma and beta emit-ter listed in Table 4.11-1, Radiological Ef-fluent Technical Specifications, (in mrem /hr) per (pCi/ml).

These factors are given in l

Table 1, as derived through the use of Equation (2.17).

the near field average dilution factor for CiE during any liquid effluent release.

Defined as the ratio of the maximum undiluted liquid waste flow during release to the product of l

the average flow from the site discharge structure to unrestricted receiving waters l

times 89.77.

(89.77 is the site specific ap-plicable factor for the mixing effect of the discharge structure.)

Rcv. O is the composite undiluted concentration The term C ofradioackkvematerialinliquidwasteatthecommon release point determined from the Radioactive Liquid Waste Sampling and Analysis Program, Table 4.11-1 in the Radiological Effluent Technical Specifications.

All dilution factors beyond the sample point (s) are in-cluded in the F term.

g 2.5.3.2 Dose Factor Related to Liquid Effluents Calculating dose contributions via Equation (2.13) requires the use of a dose factor A for each nuclide, i, which embodies the dose factors,ihathwaytransfer factors (e.g., bioaccumulation factors), pathiSay usage factors, and dilution factors for the points of pathway origin.

The adult total body dose factor and the maxi-mum adult organ dose factor for each radionuclide will be used from Table E-11 of Regulatory Guide 1.109; thus r

the list contains critical organ dose factors for

(_3/

various organs.

The dose factor is calculated accord-ing to:

Aiz = k (U /D

+ U BF )DFi 3

composite dose parameter for the whole body or

critical organ of an adult for nuclide, i, for 1

all appropriate pathways, as (mrem /hr) per (pci/ml).

units conversion factor, derived according to:

g 1.14E05 = (1E06pCi/pCi x lE03ml/kg) + 8760 hr/yr.

adult fish consumption factor, equal to U

F 21kg/yr (Regulatory Guide 1.109, Table E-5).

BF. =

Bioaccumulation factor for nuclide, i, in fish 1

Dose conversion factor for nuclide, i, for DF. =

1 adults in pre-selected organ, t, as (mrem /pCi)

U" =

receptor individual's water consumption by age group as per Regulatory Guide 1.109, Table E-5.

For adults, U

= 730kg/yr.

y D" =

dilution factor from the near field area within one-quarter mile of the release point to the potable water intake for the adult water consumption.

approximately 78 miles downstream.

Therefore, it is not nycessary to e/aluate (U /D ) at this time, and Equation (2.14) simplies to:y y

O A

=k (U BF )DF it g

g (2.15)

A

= 1.14E05 (21BF )DF f7 i

f (2.16) s-or A

= 2.39E06 x BFf x DFf

~(2.17) f7 I.

Rav. 0 2.5.4 Summary, Determination of Individual Dose Due to Liquid Effluents The dose contribution for the total time period m

Iatt A=1 is determined by calculation for each monthly. period (at least once per 31 days) and a cumulative summation of these total body and organ doses is maintained for i

each calendar quarter.

The projected dose contribution l

from batch releases for which radionuclide concentra-tions are determined by periodic composite and grab sample analysis, as stated in Table 4.11-1 of the Radi-ological Effluent Technical Specifications, may be ap-proximated by using the last measured value.

: However, n

for reporting purposes, the calculated dose contribu-U tien from those radionuclides is based on actual composite / grab sample analysis.

Dose contributions are determined for all radionuclides identified in liquid effluents released to unrestricted areas.

Nuclides I

which are below the LLD for the analyses are reported as "less than" the nuclide's LLD, and are not' reported as being present at the LLD level for that nuclide.

O -

Rnv. O TABLE 1 INGESTION EOSE CCMMITMENT FACTOR (Air) FOR ADULT AGE GROUP (mrem /hr) per (uCi/ml) l I

I Total i

. 1 I

I Nuclidel Bone l

Liver Body i Thyroid i Kidney l Lung l GI-LLI l H-3 lNo Data l2.2EE-01 l2.26E-Oll2.26E-01 12,26E-Oll2.26E-Oll2.26E-Oll l C-14

!3,13E+0416.26E+03 16.26E+0336.26E*03 16.26E+0312.26E+0316.26E+031 i N -24 l4.07E+0214.07E+02 14.07E+0214.07E+02 14.07E+0214.07E+0214.07E+021 i P-32 i4.62E+0712.672+06 11.78E+06lNo Data lNo Data lNo Lata 15.19E+061 l CR-51 lNo Data INo Data

: 11. 27 E+0 0 ! 7. 62 E-01 13 81-01 11.69E+00l3.2-E+02i l HN-S4 lNo Data )4.38E+03 l8.35E+02lde Data ll.30E+03lNo Data ll.34E+041 l MN-56 luo Data ll.10E+02 11.95E+0llNe Data ll,40EtD2lNJ Data 13.52E+031

{s~wjFE-55 16.57E40214.54E+C2 II.05E+02lNo Data INo Data 12.53E+02l2.61E+02l FE-59 11.04E+0312.44E+03 19.34E+02lNo Data lNo Data l6.81E+02lG.13E+C3]

l CO-58 lNo Data 18.94E+01 12.00E+02lNo Data lNo Data lNo Data ll.81E+031 1 CO-60 luo Data 12.57E+02 15.66E+02lNo Data lNo Data lNo Data 14.82E+03l l NI-63 13.llE+04!2.15E+03 ll.04E+031No Data lNo Data lNo Data l4.49E+021 l N1-65 11.26E+02l1.64E+01 l7.48E+90lNo Data JNo Data lNo' Data 14.16E+021 l CU-64 INC Data l1.00E+01 14.69E+00lNo Data 12.52E+01lNo Data 18.52E+02l l ZN-65 12.32E+0417.38E+04 13.33E+04]No Data 14.93E+04lNo Data l4.65E+041 l ZN-69 14.93E+0119.44E+01 16.56E+00lNo Data 16.13E+0llNo Data l1.42E+0ll l BR-84 lNo Data INo Data 15.26E+01lNo Data lNo Data [No Data l4.13E-04l l RB-88 lNo Data 12.90E+02 ll.54E+02lNo Data INo Data lNo Data 14.00E-091 l RB-89 lNo Data l1.92E+02 11.35E+02lNo Data lNo Data lNo Data l1.12E-lli l SR-89 l2.21E+04lNo Data 16.35E+02lNo Data lNo Data lNo Data 13.55E+031 l SR-90 l5.44E+05lNo Data 11.34E+05lNo Data lNo Data INo Data ll.57E+041

(')lSR-92 SR-91 l4.07E+02lNo Data ll.64E+0llNo Data INo Data lNo Data ll.94E+031 ll.54E+02lNo Data l6.68E+00lNo Data lNo Data INo Data 13.06E+03l l Y-90 15.75E-OllNo Data l1.54E-02lNo Data INo Data lNo Data l6.10E+031 l Y-91M 15.44E-03lNo Data 12.10E-04lNo Data lNo Data INo Data ll.60E-021 l Y-91 18.43E+00lNo Data l2.25E-OllNo Data INo Data lNo Data 14.64E+03l l Y-92 15.05E-02lNo Data ll.48E-03lNo Data INo Data INo Data 18.85E+021 l ZR-95 l2.40E-Oll7.70E-02 15.21E-02lNo Data 11.21E-OllNo Data 12.44E+021 l ZR-97 l1.33E-02l2.68E-03 11.22E-03lNo Data 14.04E-03lNo Data 18.30E+021 l NB-95 14.47E+02l2.48E+02 11.34E+02lNo Data l2.46E+02lNo Data ll.51E+06l l MO-99 lNo Data 11.03E+02 l1.96E+0llNo Data 12.33E+02lNo Data 12.39E+021 l TC-99M18.87E-0312.51E-02 13.19E-OllNo Data 13.81E-Oll1.23E-0211.48E+011 l RU-10314.42E+00lNo Data ll.90E+00lNo Data ll.69E+0llNo Data 15.17E+02l l RU-105l3.68E-OllNo Data 11.45E-OllNo Data 14.76E+00lNo Data l2.25E+021 l RU-10616.57E+01lNo Data 18.32E+00lNo Data l1.27E+02lNo Data 14.25E+031 e

~'

l l

l Total l

l l

I"~

Nuclidel Bone Liver l

Body l Thyroid ! Kidney I Luna

! GI-LLI l TE-13212,41E+03tl.56E+03 l1.47E+0311.72E+03 l1.50Et04iNo Data 17.382+041 l I-130 12.71E+0ll8.01E+0] 13.16E+0il6:79E403 11.25E&O21No Data 16.89Etoil

! I-131 11.49E+0212.14E+02 11.22E+0217.00E+04 13,66E+02fNo Lata !5.64E4011 1 I-132 17.29E+00l1.95E+01 16.82E+00l6.82E+02 13.llE40llNo Data (3.66E+001 l I-133 15.10E+0118.87E+01 12. 70 E+0l i l. 30E +0 4 J1.55E+02iNo Data 17,97E+031

()I-134 13.81E+00ll.03E+01 l3.70E+0Ll1.79E+02 11.64E+0llNo Data 19.01E-03l l I-135 l1.59E+0114.16E+01 il.54E+01l2.75E+03 16.58Et0llNo Data 14.70E+011 lCS-134 12.98E+0517.09E+05 15.80E+05lNo Data 12.29E+0517.62E+0411.24E+04l lCS-136 13.12E+0411.23E+05 18.26E+04lNo Data 16.85E+04l9.39Et03)l.40E+04l

-lCS-137 13.82E+0515.22E+05 13.42E+05lNo Data l1.77E+0515.89E+0411.01E+04!

lCS-138 l2.64E+0215.22E+02 12.59E+02lNo Data

: 13. 84 E+0 213. 7 9E +0 l l 2. 23 E-0 31 IBA-139 19.29E-0116.62E-04 12.72E-02lNo Data 16.19E-0413.76E-04l1.65E+001 lBA-140 ll.94E+02l2.44E-01 il.27E+01lNo Data

: 18. 31E-02 l 1. 4 0 E-Ol l 4. 00 E+0 21 ILA-140 l1.50E-Oll7.53E-02 ll.99E -02 l No Data lNo Data lNo Data l5.53E+031 ICE-141 12.24E-02l1.51E-02 ll.72E-03lNo Data l7.03E-03lNo Data 15.78E+0ll lCE-143 l3.94E-0312.92E+00 13.23E-04lNo Data ll.28E-03lNo Data ll.09E+021 lCE-144 ll.17E+00l4.88E-01 16.26E-021No Data 12.89E-01lNo Data 13.94E+02l lPR-143 15.50E-0112.21E-01 12.73E-02lNo Data ll.27E-01lNo Data 12.41E+031 lND-147 13.76E-Oll4.35E-01 12.60E-02lNo Data 12.54E-OllNo Data 12.09E+031

(])W-187 12.96E+02l2.47E+02 18.64E+01lNo Data lNo Data lNo Data l8.09E+04l lNP-239 12.84E-0212.80E-03 ll.54E-03lNo Data l8.72E-03lNo Data 15.74E+02l Rnv. O TABLE 2 BIOACCUMULATION FACTOR (BF ) M D IN M E SENCE i

OF SITE-SPECIFIC DATA" (pCi/kg) per-(pCi/ liter)

BFf Element Fish (Freshwater)

H 9.0 E - 01 C

4.6 E + 03 Na 1.0 E + 02 P

1.0 E + 05 Cr 2.0 E + O2 Mn 4.0 E + 02 i

Fe 1.0 E & 02 Co 5.0 E + 01 Q'

Ni 1.0 E + O2 Cu 5.0 E + 01 2n 2.0 E + 03 Br 4.2 E + O2 Rb 2.0 E + 03 Sr 3.0 E 4 01 Y

2.3 E + 01 Zr 3.3 E + 00 Nb 3.0 E + 04 Mo 1.0 E + 01 Tc 1.5 E + 01 Ru 1.0 E + 01 Rh 1.0 E + 01 Te 4.0 E + 02 I

1.5 E + 01 Cs 2.0 E + 03 Ba 4.0 E + 00 O-La 2.5 E + 01 Ce 1.0 E + 00 Pr 2.5 E + 01 Nd 2.5 E + 01 W

l.2 E + 03 Np 1.0 E + 01 (a)

Values taken from Regulatory Guide 1.109, Rev 1, Table A-1.

R v. 0 2.6 Liquid Radwaste Treatment System 2.6.1 Radiological Effluent Technical Specification 3.11.1.3 The liquid radwaste treatment system shall be OPERABLE.

2.5.2 Description of the Liquid Radwaste Treatmen't System 2.6.3 Operability of the Liquid Radwaste Treatment _ System i

The liquid radwaste system is capable of varying treat-ment, depending on waste type and product desired.

It is capable of concentrating, gas stripping, and distil-lation of liquid wastes through the use of the evapora-tor system.

The demineralization system is capable of removing radioactive ions from solutions to be reused as makeup water.

Filtration is performed on certain liquid wastes and it may, in some cases, be the only required treatment prior to release.

The system has the ability to absorb halides through the use of char-coal filters prior to their release.

()

The operability of the liquid radwaste treatment system ensures this system will be available for.use when liquids require treatment prior to their release to the environment.

To determine operability requirements, doses due to liquid releases are projected once each 31 l

RSv. 0 3.0 GASEOUS EFFLUENTS 3.1 Radiological Effluent Technical Specification 3.3.3.10 The radioactive gaseous effluent monitoring instrumen-tation channels shall be OPERABLE with their alarm / trip setpoints set to ensure that the limits of Radiological Effluent Technical Specification 3.11.2.1 are not exceeded.

The alarm / trip setpoints of these channels shall be determined in accordance with the ODCM.

3.2 Radiological Effluent Technical Specification

()

a.

For noble gases:

Less than or equal to 500 mrem /yr to the total body and less than or equal to 3000 mrem /yr to the skin, and b.

For all radioiodines and for all radioactive materials in particulate form and radionuclides (other than noble gases) with half lives greater than 8 days:

Less than or equal to 1500 mrem /yr to any organ from the inhalation pathway only.

3.3 Gaseous Effluent Monitors Noble gas activity monitors, iodine monitors, and par-ticulate monitors are present on the containment build-ing ventilation system, plant unit ventilation system, and radwaste building ventilation system.

Each monitor channel is provided with a two level sys-tem which provides sequential alarms on increasing radioactivity levels.

These setpoints are designated i

as alert setpoints and alarm / trip setpoints.

The radiation monitor alarm / trip setpoints for each release point are based on the radioactive noble gases in gaseous effluents.

It is not considered practicable to apply instantaneous alarm / trip setpoints to inte-grating radiation monitors sensitive to radioiodines,.

R5v. O radioactive materials in particulate form and radionu-clides other than noble gases.

Conservative assump-tions may be necessary in establishing setpoints to ac-count for system variables, such as the measurement system efficiency and detection capabilities during normal, anticipated, and unusual operating conditions, the variability in release flow and principal radionu-clides, and the time lag between alarm / trip action and the final isolation of the radioactive effluent.

3.3.1 Continuogs Release Gaceous Effluent Monitors The radiation detection monitors associated with conti-nucus gaseous affluent releases are:

A)

Monitor I.D.

Description t,_

0-GT-RE-21 Unit Vent 0-GH-RE-lO Radwaste Building Vent The Unit Vent reanitor continuously monitors the ef-fluent from the unit vent for particulate, iodine (halogen), and gaseous radioactivity.

The unit vent, via ventilation exhaust systems, continuously purges various tanks and sumps normally containing low-level radioactive aerated liquids that can potentially gener-ate airborne activity.

The exhaust systems which supply air to the unit vent are from the fuel building, auxiliary building, the ac-gx cess control area, the containment purge, and the con-denser air discharge.

All of these systems are filtered before they exhaust to the unit vent.

The unit vent monitor measures ac-tual plant effluents and not inplant concentrations.

Thus, the system continuously monitors downstream of the last point of potential radioactivity entry.

The monitoring system consists of an off-line, three-way airborne radioactivity monitor.

An isokinetic sampling probe is located downstream of the last point of poten-tial radioactivity entry for sample collection.

The sample extracted by the isokinetic nozzle is passed through the fixed filter (particulate), charcoal filter (iodine), and fixed-volume (gaseous) detector assem-blies and then through the pumping system for discharge back to the unit vent.

Indication is provided on the.

The Radwaste Building Ventilation effluent monitor con-tinuously monitors for particulate, halogen, and gaseous radioactivity in the effluent duct downstream of the exhaust filter and fans.

The sample point is located downstream of the last possible point of radi-oactive influent, including the waste gas decay tank discharge line.

The flow path provides ventilation ex-haust for all' parts of the building structure and com-ponents within the building and provides a discharge path for the waste gas decay tank release line.

These components represent potentiel sources for the release of gaseous and air particulate and iodine activities in addition to the drainsge sumps, tanks, and equipmenu purged by the vaste processing system.

4 The monitoring system consists of a fixed filter par-ticulate monitor, an iodine monitor, and gaseous activ-ity monitor.

The sample is extracted through an iso %inetic nozzle to t

ensure that a representative sample of the air is ob-tained prior to release to the environment.

After passino through the fixed filter (particulate), char-coal filter (halegen), and fixed-volume (noble gas) detector assemblies and the pumping system, the sample is discharged back to the exhau'st duct.

Indication is provided on the radiation monitoring system CRT in the control room.

4 This monitor will isolate the waste gas decay tank dis-charge line if the radioactivity release rate is above the present limit when the waste gas' discharge valve

(])

has been deliberately or inadvertently opened.

Since there are two continuous gaseous effluent release points, a fraction of the total MPC will be allocated to each release point.

Neglecting the batch releases, i

the plant Unit Vent monitor has been allocated 0.7 MPC and the Radwaste Building Vent monitor has been allo-I cated 0.3 MPC.

These will be changed as required, but limited to 1 MPC of Xe-133.

Therefore, a particular monitor reaching the fractional MPC setpoint would not necessarily mean the MPC limit at the site boundary is being exceeded; the alarm only indicates that the spe-cific release point is contributing a greater fraction of the MPC limit than was allocated to the associated monitor and will constitute an evaluation of both systems.

f -

Rpv. 0 3.3.2 Batch Release Gaseous Monitors i

Monitor I.D.

Description 0-GT-RE-22 Containment Purge System Monitors 0-GT-RE-33 0-GT-RE-31 Containment Atmosphere Radioactivity 0-GT-RE-32 Monitors 0-GH-RE-10 Radwasta Building Vent l

The Containment Purge System continuously monitors the containment purge-exhaust duct during purge cperations for particulate, iodine, and gaseous radioactivity.

w The purpose of these monitors is to isolate the con-s) tainment purge systen on high gaseous activity via the ESFAS.

These monitors also serve as backup indication for personnel protection and reactor coolant pressure boundary leakage detection for the containment at-mosphere radioactivity monitors.

1 The sample points are located outside the containment i

between the containment isolation dampers and the con-tainment purge filter adsorber unit.

Each monitor is provided with two isokinetic nozzles to l

ensure that representative samples are obtained for both normal purge and minipurge flow rates.

The sample is extracted through the selected nozzle and then passed through the selector valve, the fixed filter (particulate), charcoal filter (iodine), and

fixed-volume gaseous detectors.

The sample then passes through the pumping system and is discharged back to the duct.

The Containment Atmosphere Radioactivity monitors, con-tinuously monitor the containment atmosphere ~for par-ticulate, iodine, and gaseous radioactivity.

They isolate the containment purge system on high gaseous activity via the ESFAS.

These monitors also serve for reactor coolant pressure boundary leakage detection and for personnel protection.

The containment atmosphere radioactivity monitors provide backup indication for the containment purge monitors. _

Rnv. 0 Samples are extracted from the operating deck level (El 2047'-6") through sample lines which penetrate the containment.

The monitors are located as close as possible to the containment penetrations to minimize the length of the sample tubing and the effects of sam-ple plate out.

The sample points are located in areas which ensure that representative samples are obtained.

Indication is provided for each monitor on individual indicators on the radioactivity monitoring nyctea con-trol panel and, through isolated signals, on the radio-activity monitoring system CRT in the control room.

The Radwaste Building Vent nonitors are described'in

Section 3.3.1.

l A pre-release isotopic analysis will be performed for each batch release to determine the identity and quan-tity of the principal radionuclides.

The alarm / trip setpoint(s) will be adjusted accordingly to ensure that the limits of Radiological Effluent Technical Specifi-cation 3.11.2.1 are not exceeded.

3.4 ODCM Methodology for the Determination of Gaseous Effluent Monitor Setpoints 3.4.1 Development of ODCM Methodology for the Determi-nation of Gaseous Effluent Monitor Setpoints The alarm / trip setpoint for gaseous effluent monitors l

is determined based on the lesser of the whole body dose rate and skin dose rate, as calculated for the un-restricted site boundary.

3.4.1.1 Whole Body Dose Rate Setpoint Calculations To ensure that the limits of Radiological Effluent Technical Specification 3.11.2.1 are met, the alarm / trip setpoint based on the whole body dose rate is calculated according to:.

R.v. O Swb < Dwb wb s,

(3.1)

R FF Where:

Swb =

the response of the gaseous effluent noble gas monitor at the alarm / trip setpoint based on the whole dose rate.

Dwb =

Radiological Effluents Technical Specification 3.11.2.1 limit of 500 mrem /yr, conservatively interpreted as a continuous release over a one year period.

the safety factor; a conservative factor used F

8 to compensate for statistical fluctuations and errors of measurement.

(For example, F

= 0.5 corresponds to a 100% variation.)

Defa61t e

value is F, = 1.0.

the allocation factor which will modify the F

8 required dilution factor such that simultaneous gaseous releases may be made without exceeding the limits of Radiological Effluent Technical Specification 3.11.2.1.

(pCi/cc) per (mrem /yr) to the whole body,

Ryg=C+ [(X/Q) I K Qg)

(3.2) g 1

Where:

monitor reading of a noble gas monitor cor-C=

responding to the sample radionuclide concen-trations for the batch to be released.  

~

s R;v. 0 5-4 s i Concentrations are determined in accordance with Table 4.11-2 of the Radiological Effluent Technical Specifications.

The mixture of radionuclides determined via grab sampling of the effluent stream or source is correlated to a calibration factor to determine monitor response.

The monitor response is based on concentrations, not release rate, and is in units of (pCi/cc).

J R79=

the highest calculated annual average relative concentration for any area at or beyogd the unrestricted area boundary,-in (sec/m ).

the whole body dose factor dd'e' to gamma emis-1 sionsforeachidentifiednogle clide, is (mrem /yr per pCi/m.).' gas radionu-

(Table 3)

()

\\'Q.=

rate of release of noble gas radionuclide, i, 1

in (pCi/sec)

_us x

t 3.4.1.2ssSkin Dose Rate Setpoint Calculation st --

Technien1 Specification 3.11.2.1 are met, the

alarm / trip setpoint based on the skin dose rate is cal-culated,aceording to:

: SgiDRFF, (3.3) sss C)

~

and Fa.are as previously defined.

~

the response of the gaseous effluent noble gas S

g

' monitor at the. alarm / trip setpoint based on the skin dose rate.

Radiological Efiluents Technical Specification D

s 3.11.2.1 limit of 3000 mrem /yr, conservatively int.erpreted as a continuous release over a one year period.

R:v. O (pCi/cc) per (mrem /yr) to the skin, determined R

s according to:

R, = C + [(X/Q) I (Li + 1.1M ) Qg]

(3.4) g 1

the skin dose factor due to beta emissions for 1

each identified noblg)gase radionuclide, in (mrem /yr) per (pci/m

, Table 3)

)

1.1 =

conversion factor:

1 mrad air dose = 1.1 mrem skin dose.

the air dose factor due to gamma emissions for 1

each identified noblg) gas radionuclide, in (mrad /yr) per (pCi/m (Table 3)

C, (X/Q) and Qi are as previously defined.

3.4.1.3 Gaseous Effluent Monitors Setpoint Determination The results of Equation (3.1) and Equation (3.3) are compared.

The setpoint is then selected as the lesser

(])

. l I

O O

TABLE 3 DOSE FACTORS FOR EXPOSURE TO A SEMI-INFINITE CLOUD OF NOBLE GASES" Whole Body Gamma Air Beta Air Dose Factor Skin Dose Factor Dose Factor Dose Factor K

L M

N Radionuclide (mrem /yr)iper (pci/m ) (mrem /yr)pbr(pci/m3) (mrad /yr) per (pCi/m3)

(mrad /yr)peb(pci/m3) i a

1.93 E+01 2.88 E+02 Kr-83m 7.56 E-02 Kr-85m 1.17 E+03 1.46 E+03 1.23 E+03 1.97 E+03 Kr-85 1.61 E+01 1.34 E+03 1.72 E+01 1.95 E+03 Kr-87 5.92 E+03 9.73 E+03 6.17 E+03 1.03 E+04 Kr-88 1.47 E+04 2.37 E+03 1.52 E+04 2.93 E+03 Kr-89 1.66 E+04 1.01 E+04 1.73 E+04 1.06 E+04 Kr-90 1.56 E+04 7.29 E+03 1.63 E+04 7.83 E+03 Xe-131m 9.15 E+01 4.76 E+02 1.56 E+02 1.11 E+03 Xe-133m 2.51 E+02 9.94 E+02 3.27 E+02 1.48 E+03 3

i Xe-133 2.94 E+02 3.06 E+02 3.53 E+02 1.05 E+03 Xe-135m 3.12 E+03 7.11 E+02 3.36 E+03 7.39 E+03 i

Xe-135 1.81 E+03 1.86 E+03 1.92 E+03 2.46 E+03 w

Xe-137 1.42 E+03 1.22 E+04 1.51 E+03 1.27 E+04 Xe-138 8.83 E+03 4.13 E+03 9.21 E+03 4.75 E+03 Ar-41 8.84 E+03 2.69 E+03 9.30 E+03 3.28 E+03 (a)

The listed dose factors are derived from Table B-1 in Reg. Guide 1.109 and are for detected in gaseous effluents.

Rav. 0 3.4.2 Summary, Gaseous Effluent Monitors Setpoint Determination The gaseous effluent monitors setpoints are calculated as described in Section 3.4.

However, it should be noted that a batch release will alter the flow rate characteristics at the Unit Vent and therefore the concentration as sensed by the monitor.

For example, in the case of a mini-purge, the setpoint for the Unit Vent monitor must be re-calculated to include both the continuous and batch sources.

3.5 ODCM Methodology for Determining Dose Contributions From Gaseous Effluents Dose rate calculations are performed for gaseous ef-fluents to ensure compliance with Radiological Effluent Technical Specification 3.11.2.1 as stated in Section 3.2.

3.5.1 Determination of Dose Rate The following methodology is applicable to the location (unrestricted area or beyond) characterized by the values of the parameter (X/Q) which results in the max-imum whole body or skin dose rate.

In the event that the analysis indicates a different location for the whole body and skin dose limitations, the location selected for consideration is that which minimizes the allowable release values.

The factors K, L and M. relate the radionuclide air-borneconcentbatibn,stovkriousdoserates,assuminga semi-infinite cloud model, and are tabulated in Table 3.

s 3.5.1.1 Noble Gases The release rate limit for noble gases is determined according to the general relationships delineated as l

follows:

l (K ((X/Q)Q )] < 500 mrem /yr (3.5)

i 1

l l

l.

Rsv. O D, = { [(Li 1.1 M )((X/Q)Q )] < 3000 mrem /yr (3.6)

1 Where:

Dwb =

Whole body dose rate, conservatively averaged over a period of one year.

Whole body dose factor due to gamma emissions 1

for each identified goble gas radionuclide, in (mrem /yr) per (uCi/m ).

(Table 3)

(R7Q) =

The highest calculated annual average relative

(])

concentration for any area at or beyond the unrestricted area boundary.

I Q. =

The release rate of radionuclides, i, in 1

gaseous effluents, from all vent releases in (pci/sec).

Skin dose rate, conservatively averaged over a D

s period of one year.

Skin dose factor due to beta emissions for 1

each identified noble gas radionuclide, in (mrem /yr) per (pci/m3) (Table 3).

1.1 =

Units conversion factor; 1 mrad air dose = 1.1 mrem skin dose.

()

M. =

Air dose factor due to gamma emissions for 1

each identified noble gas radionuclide, in (mrad /yr) per (pci/m3) (Table 3).

3.5.1.2 Radionuclides Other Than Noble Gases The release rate limit for all radionuclides and radi-oactive materials in particulate form and radionuclides other than noble gases is determined according to:

i[(X/Q)Q ] < 1500 mrem /yr (3.7)

g 1

R;v. O l

Where:

=

Dose rate to any critical organ, in (mrem /yr).

o P. =

Dose parameter for radionuclides other than 1

noble gases for the inhalation pathway for the child, based on the critical organ, in (mrem /yr) per (pci/m ).

(Table 4) a (X/Q) and Qi are as previously defined.

The dose parameter (P ) includes the internal dosimetry of radionuclide, i,akdthereceptor'sbreathingrate, which are functions of the receptor's age.

Therefore o

the child age group has been selected as the limiting age group.

For the child exposure, separate values of P lated in Table 4 for the inhalation pathway.i are tabu-These values were calculated according to:

Pi = K' (BR) DFA:

O where:

~

K' =

Units conversion factor: 1pCi = 1E06pCi.

BR=

The breathing rate of the child age group, in (m3/yr).

(Regulatory Guide 1.109, Table E-5).

DFA. =

The maximum organ inhalation dose factor for 1

the child age group for the ith radionuclide, in (mrem /pci).

The whole body is considered as an organ in the selection of DFA.

(Regulatory Guide 1.109, Table E-9)g Note:

All radiciodines are assumed to be released in elemental form.

l Rnv. 0 TABLE 4 Dose Parameter (P ) For Radionuclides Other Than Noble Gases" f

P i b

RADIONUCLIDE (mrem /yr) per (pC1 H-3 1.12 E + 03 C-14 3.59 E + 04 Cr-51 1.70 E + 04 Mn-54 1.58 E + 06 Fe-59 1.27 E + 06 Co-58 1.11 E + 06 Co-60 7.07 E + 06 Zn-65 9.95 E + 05 Sr-89 2.16 E + 06 O

Sr-90 1.01 E + 08 v

Zr-95 2.23 E + 06 Mo-99 1.35 E + 05 I-131 1.62 E + 07 I-133 3.85 E + 06 I-135 7.92 E + 05 Cs-134 1.01 E + 06 Cs-136 1.71 E + 05 Cs-137 9.06 E + 05 Ba-140 1.74 E + 06 La-140 2.26 E + 05 Ce-141 5.44 E + 05 Ce-144 1.20 E + 07 (a) dose parameters listed are for radionuclides that may be detected in gaseous effluents.

Additional h<,

dose parameters not listed may be determined using methodology described in NUREG-0133.

Guide 1.109, Rev. 1, 1977 -,

R;v. 0 3.5.2 Individual Dose Due To Gaseous Effluents 3.5.2.1 Radiological Effluent Technical Specification 3.11.2.2 The air dose due to noble gases released in gaseous ef-fluents from-the site shall be limited to the following:

a.

During any calendar quarter:

Less than or equal to 5 mrad for gamma radiation and less than or equal to 10 mrad for beta radiation and, b.

During any calendar year:

Less than or equal to 10 mrad for gamma radiation and less than or equal to 20 mrad for beta radiation.

3.5.2.1.1 Noble Gases

()

The air dose in unrestricted areas due to noble gases released from the site is determined according to the following methodology:

D

= 3.17 x 10 s? [Mi {(X/Q) Qi + (X/q) qi}] 15 mrad (3.9) g 1

During any calendar quarter, for beta radiation:

(

8 D3 = 3.17 x 10 3 [Ni {(X/Q) Qi + (X/q) qi}] 1 10 mrad (3.10) 1 During any calendar year, for gamma radiation:-

= 3.17 x 1083 [Mi [(X/Q) Qi + (X/q) qi}] 1 10 mrad (3.11) g 1

Db = 3.17 x 10 s? [Ni {(X/Q) Qi + (X/q) gi}] 1 20 mrad (3.12) 1 l l l

Air dose from gamma radiation due to noble D

9 gases released in gaseous effluent.

Db=

Air dose from beta radiation due to noble gases released in gaseous effluents.

(X/q) =

The relative concentration for areas at or beyond the unrestricted area boundary for short term releases (equal to or less than 500 hrs / year).

: q. =

The average release of noble gas radionu-1 clides, i, in gaseous effluents from all vent O

releases for short-term releases (equal to or less than 500 hrs / year), in (pci).

Releases are cumulative over the calendar quarter or year, as appropriate.

N. =

The air dose factor due to beta emissions for 1

Q. =

The average release of noble gas radionu-1 clides, i, in gaseous effluents from all vent releases for long-term releases (greater than 500 hrs / year), in (pci).

Releases are cumula-tive over the calendar quarter or year, as appropriate.

O (X/Q) =

The highest calculated annual average relative concentration for areas at or beyond the unrestricted area boundary for long-term releases (greater than 500 hrs /yr).

M is as previously defined. (Refer to Section 3.4.1.2) i 3.5.2.2 Radiological Effluent Technical Specification 3.11.2.3 The dose to an individual from radionuclides and radi-oactive materials in particulate form, and radionu-clides (other than noble gases) with half-lives greater than 8 days in gaseous effluents released from the site shall be limited to the following:  

\\

Rnv. O a.

During any calendar quarter:

Less than or equal to 7.5 mrem to any organ and, b.

During any calendar year:

Less than or equal to 15 mrem to any organ.

3.5.2.2.1 Radionuclides Other Than Noble Gases The dose to an individual from radioiodines, radioac-tive materials in particulate form, and radionuclides other than noble gases with half-lives greater than 8 days in gaseous effluents released to unrestricted areas is determined by the following expressions:

O During eny ce1 ender querter:

i 3.17E-08 { Ri [W Qi + w qi] 1 7.5 mrem (3.13)

1 During any calendar year:

i 3.17E-08 { Ri [W Qi + w qi] i 15 mrem (3.14)

1 Where:

D. =

Dose to an individual from radionuclides other 1

(])

than noble gases.

Q. =

The releases of radionuclides, radioactive 1

materials in particulate form, and radionu-clides other than noble gases, i, in gaseous effluents, for all vent releases for long-term releases (greater than 500 hrs /yr), in (pci).

: q. =

The releases of radionuclides, radioactive 1

in (pCi).

Releases are cumulative over the calendar quarter or year as appropriate.

R v. O i

R. =

The dose factor for each identified radionu-1 clide, i, in m2(mrem /yr) per (pci/sec) or (mrem /yr) per (pci/m ). (Table 5) a W=

The dispersion parameter for estimating the dose to an individual at the controlling loca-tion for long-term releases (greater than 500 hrs /yr):

W = (X7Q) for the inhalation pathway, in(sec/m ),

a W = (D7Q) for the food and grounc plane pathways, in(meters 2),

w=

The dispersion parameter for estimating the es dose to an individual at the controlling loca-(s/

tion for short-term releases (equal to or less than 500 hrs /yr):

(D/Q) =

the average relative deposition of the ef-fluent at the unrestricted area boundary, con-sidering depletion of the plume during trans-port, for long term releases (greater than

(])

500 hrs /yr), in (meters 2).

(D/q) =

the relative deposition of the effluent at the unrestricted area boundary, considering deple-tion of the plume during transport, for short term releases (less than or equal to 500 hrs /yr), in (meters 2),

Note:

For the direction sectors with existing pathways within 5 miles from the site, the appropriate R. values are used.

If no real pathway exists within 5 miles from the center of the building complex, the cow-milk R. value is used, and it is assumed that this pathway ekists at the 4.5 to 5.0 mile distance in the limiting-case sector.

If the R.

for an existing pathway within l

5 miles is less than a cow-milk Rg at 4.5 to 5.0 miles, then the value of the cow-milk Ri at 4.5 to 5.0 miles is used..-

( \\

I) w-x_-

TABLE 5 PATHWAY DOSE FACTORS (R ), FOR RADIONUCLIDES OTHER THAN NOBLE GASES g

Inhalation Ground Plane Grass-Cow-Milk Meat Vegetation Pathway Pathway Pathway Pathway Pathway

"# "/Y#)

("2 "#*"/Y#)

("2 *#**/Y#)

("2 "# */Y#)

("2 per (pCi/m )

per (pCi/sec) per (pCi/sec) per (pCi/sec) per (pC1/sec)

Radionuclide Infant Child Whole Skin Infant Child Child Child Body H-3 (X /Q) 6.47E+02 1.12E+03 2.38E+03 1.57E+03 2.34E+02 4.01E+03 C-14 2.65E+04 3.59E+04 2.34E+09 1.20E+09 3.84E+08 8.91E+08 Cr-51 1.28E+04 1.70E+04 4.65E+06 5.50E+06 4.69E+06 5.39E+06 3.26E+05 6.21E+06 Mn-54 1.00E406 1.58E+06

: 1. 39E+06 1.63E+09 3.89E+07 2.09E+07 8.02E+06 6.65E+08 Fe-59 1.02E+06 1.27E+06 2.72E+08 3.20E+08 3.93E+08 2.03E+08 4.46E+08 6.68E+08 Co-58 7.77E+05 1.11E+06 3.79E+08 4.44E+08 6.05E+07 7.07E+07 9.59E+07 3.77E+08 Co-60 4.51 E406 7.07E+06 2.15E+10 2.53E+10 2.10E+08 2.40E+08 3.84E+08 2.09E+09 Zn-65 6.47E+05 9.95E+05 7.47E+08 8.59E+08 1.90E+10 1.10E+10 9.99E+08 2.16E+09 Sr-89 2.03E+06 2.16E+06 2.16E+04 2.51E+04 1.26E+10 6.62E+09 4.82E+08 3.60E+10 Sr-90 4.09E+07 1.01E+08 1.22E+11 1.12E+11 1.04E+10 1.24E+12 Zr-95 1.75E+06 2.23E+06 2.45E408 2.84E+08 8.27E+05 8.80E+05 6.12E+08 8.85E+08 I-131 1.48E+07 1.62E+07 1.72E+07 2.09E+07 1.05E+12 4.34E+11 5.58E+09 4.76E+10 I-133 3.56E+06 3.85E406 2.45E+06 2.98E+06 9.63E+09 3.78E+09 8.75E+01 8.27E+08 I-135 6.96E+05 7.92E+05 2.51E+06 2.93E+06 1.97E+07 8.49E+06 1.05E+07 Cs-134 7.03E405 1.01E406 6.86E209 8.00E+09 6.81E+10 3.72E+10 1.51E+09 2.63E+10 Cs-136 1.35E+05 1.71E+05 1.53E+08 1.74E+08 5.80E+09 2.77E+09 4.42E+07 2.24E+08 Cs-137 6.12E+05

: 9. 06E+05 1.03E+10 1.20E+10 6.04E+10 3.23E+10 1.34E+09 2.39E+10 Ba-140 1.6P6+06 1.74E+06 2.05E+07 2.35E+07 2.42E+08 1.18E+08 4.43E+07 2.79E+08 La-140 1.68E+05 2.26E+05 1.92E+07 2.18E+07 1.88E+05 1.90E+05 5.52E+02 3.20E+07 Ce-141 5.17E405 5.44E+05 1.37E+07 1.54E+07 1.37E+07 1.36E+07 1.38E+07 4.08E+08 Cc-144 9.84E+06 1.20E+07

: 6. 96E+0 7 8.04E+07 1.33E+08 1.32E+08 1.89E+08 1.04E+10

% 09 1.15F40 5

: 1. 3 5E I O S 3.98E406

: 4. 62E4 06 3.10E408 1.74E408 2.44E+05 1.65E+07 _ _ _ _ _

3.6 Gaseous Radwaste Treatment System 3.6.1 Radiological Effluent Technical Specification 3.11.2.4 The-Gaseous Radwaste Treatment System and the Ventila-tion Exhaust Treatment System shall be OPERABLE.

The appropriate portions of the gaseous radwaste treatment system shall be used to reduce radioactive materials in gaseous waste prior to their discharge when.the projected gaseous effluent air dose due to gaseous ef-fluent releases from the site when averaged over the calendar quarter, would exceed 0.6 mrad for gamma radi-r~

ation and 1.2 mrad for beta radiation.

The appropriate portions of the ventilation exhaust treatment system shall be used to reduce radioactive materials in gaseous waste prior to their discharge when the projected doses due to gaseous effluent releases from the site when averaged over the calendar quarter would exceed 0.9 mrem to any organ.

3.6.2 Description of the Gaseous Radwaste Treatment System The gaseous radwaste treatment system and the ventila-tion exhaust system are available for use whenever gaseous effluents require treatment prior to being released to the environment.

The gaseous radwaste 4

treatment system is designed to allow for the retention of all gaseous fission products to be discharged from

(])

the reactor coolant system.

The retention system con-sists of eight (8) gas decay storage tanks, six (6) for use during normal operations and two (2) for use during shutdown conditions.

These systems will provide reas-onable assurance that the releases of radioactive materials in gaseous effluents will be kept ALARA.

3.6.3 Operability of the Gaseous Radwaste Treatment System The operability of the gaseous radwaste treatment sys-tem ensures this system will be available for use when gases require treatment prior to their release to the environment.

To determine operability requirements, doses due to gas release are projected once each 31 days in accordance with the methodology described in Section 3.5.2.. _.

R3v. 0 4.0 DOSE AND DOSE COMMITMENT FROM URANIUM FUEL CYCLE SOURCES 4.1 Radiological Effluent Technical Specification 3.11.4 The dose or dose commitment to any member of the public from uranium fuel cycle sources shall be limited to less than or equal to 25 mrem to the total body or any organ (except the thyroid, which shall be limited to less than or equal to 75 mrem) over 12 consecutive months.

4.2 ODCM Methodology for Determining Dose and Dese Commitment from Uranium Fuel Cycle Sources For the purpose of calculating the annual population-integrated dose within a 50 mile radius of the site, O