Text

Update to Final Safety Analysis Report, Appendix I, 10CFR50, Appendix I Evaluation of Radioactive Releases from Point Beach Nuclear Plant (Historical) -
	ML21102A350
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Site:	Point Beach
Issue date:	04/02/2021
From:	; Point Beach
To:	; Office of Nuclear Reactor Regulation
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Appendix I Table of Contents FSAR (Historical)

APPENDIX I TABLE OF CONTENTS APPENDIX I 10CFR50, APPENDIX I EVALUATION OF RADIOACTIVE RELEASES FROM POINT BEACH NUCLEAR PLANT (Historical) - - - - - - - - - - - - - - - - - - - - - - - I.1-1 I.1 INTRODUCTION (Historical) - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - I.1-1 I.1.1 Liquid Radioactive Waste System (Historical) - - - - - - - - - - - - - - - - - - - - - - - - I.1-1 I.1.2 Gaseous Radioactive Waste System (Historical) - - - - - - - - - - - - - - - - - - - - - - - I.1-1 I.1.3 Secondary System Wastes (Historical) - - - - - - - - - - - - - - - - - - - - - - - - - - - - I.1-1 I.1.4 Chemical and Volume Control System (Historical) - - - - - - - - - - - - - - - - - - - - - - I.1-2 I.1.5 Plant Ventilation and Filtration Systems (Historical) - - - - - - - - - - - - - - - - - - - - - I.1-2 I.1.6 Previous Radioactive Waste System Modifications (Historical) - - - - - - - - - - - - - - - - I.1-2 I.1.7 Subsequent Changes to the Wastewater Effluent System (Historical) - - - - - - - - - - - - - - I.1-3 I.1.8 SUBSEQUENT CHANGES TO THE LIQUID RADIOACTIVE WASTE SYSTEM (Historical) - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - I.1-3 I.2 INFORMATION IN RESPONSE TO APPENDIX D OF DRAFT REGULATORY GUIDE 1.BB (Historical) - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - I.2-1 I.2.1 General (Historical) - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - I.2-1 I.2.2 Primary System (Historical) - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - I.2-2 I.2.3 Secondary System (Historical) - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - I.2-2 I.2.4 Liquid Waste Processing Systems (Historical) - - - - - - - - - - - - - - - - - - - - - - - - I.2-3 I.2.5 Gaseous Waste Processing System (Historical) - - - - - - - - - - - - - - - - - - - - - - - - I.2-4 I.2.6 Ventilation and Exhaust Systems (Historical) - - - - - - - - - - - - - - - - - - - - - - - - - I.2-6 I.2.7 References (Historical) - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - I.2-8 I.3 CALCULATED SOURCE TERMS AND RELEASES OF GASEOUS AND LIQUID EFFLUENTS (Historical)- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - I.3-1 I.3.1 Original Appendix I Evaluation (Historical) - - - - - - - - - - - - - - - - - - - - - - - - - I.3-1 I.3.2 Impact of Uprated Power Operations (Historical) - - - - - - - - - - - - - - - - - - - - - - - I.3-1 I.3.3 Reference (Historical)- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - I.3-1 I.4 METEOROLOGY (Historical) - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - I.4-1 I.4.1 Meteorological Program at Point Beach Nuclear Plant (Historical) - - - - - - - - - - - - - - - I.4-1 I.4.2 Description of X/Q and D/Q Modeling Procedures (Historical) - - - - - - - - - - - - - - - - I.4-4 I.4.3 Calculated X/Q and D/Q Values for Point Beach Nuclear Plant (Historical) - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - I.4-9 I.4.4 References (Historical) - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - I.4-9 UFSAR 2020 Page TOC - I-i of ii

Appendix I Table of Contents FSAR (Historical)

I.5.0 HYDROLOGY (Historical) - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - I.5-1 I.5.1 Description of Discharge (Historical) - - - - - - - - - - - - - - - - - - - - - - - - - - - - - I.5-1 I.5.2 Hydrological Model (Historical) - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - I.5-1 I.5.3 Input Data (Historical) - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - I.5-3 I.5.4 References (Historical) - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - I.5-3 I.6 SUPPLEMENTAL INFORMATION (Historical) - - - - - - - - - - - - - - - - - - - - - - - I.6-1 I.6.1 Enclosure 1 (Historical)- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - I.6-1 I.6.2 Enclosure 2 (Historical)- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - I.6-1 I.7 COMPARISONS OF REPORTED AND CALCULATED RELEASES OF RADIOACTIVITY (Historical) - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - I.7-1 I.7.1 Gaseous Releases (Historical) - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - I.7-1 I.7.2 Liquid Releases (Historical) - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - I.7-2 I.8 CALCULATIONS OF DOSES TO MAN (Historical) - - - - - - - - - - - - - - - - - - - - - I.8-1 I.8.1 Dose Models - Offsite Individuals (Historical) - - - - - - - - - - - - - - - - - - - - - - - - I.8-1 I.8.2 Dose Models - Onsite Individuals (Historical)- - - - - - - - - - - - - - - - - - - - - - - - - I.8-4 I.8.3 Calculated Doses (Historical) - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - I.8-5 I.8.4 References (Historical) - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - I.8-5 I.9

SUMMARY

(Historical) - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - I.9-1 I.9.1 Gaseous Releases (Historical) - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - I.9-1 I.9.2 Liquid Releases (Historical) - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - I.9-1 I.9.3 Impact of Uprated Power Operations (Historical) - - - - - - - - - - - - - - - - - - - - - - - I.9-2 I.9.4 Reference (Historical) - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - I.9-3 UFSAR 2020 Page TOC - I-ii of ii

Introduction FSAR Appendix I.1 (Historical)

I.1 10 CFR 50, APPENDIX I EVALUATION OF RADIOACTIVE RELEASES FROM POINT BEACH NUCLEAR PLANT I.1 INTRODUCTION Appendix I to 10 CFR Part 50 of the Nuclear Regulatory Commission (NRC) regulations, published in May, 1975, sets forth numerical guidelines for design objectives and limiting conditions for operation to maintain releases of radioactive materials from light water reactors as low as is reasonably achievable.Section V.B of Appendix I requires the holders of permits or licenses for operation of light water reactors to submit information necessary to evaluate the means employed to meet the objectives of Appendix I. This appendix contains information for the evaluation in response to guidelines provided by the Commission in February, 1976.

Radioactive waste system and related systems are described in the FSAR, Section 9.0 and Section 11.0. In the initial plant design provisions were made for processing of all radioactive liquid and gaseous wastes prior to release via monitored pathways to the environment. Brief descriptions of the various systems and operation are as follows.

I.1.1 LIQUID RADIOACTIVE WASTE SYSTEM (See Note 1)

All liquid radioactive wastes from controlled areas of the plant are collected in the liquid radioactive waste system waste holdup tank. These wastes are then processed by evaporation, as a minimum, and are released to the circulating water discharge on a batch basis. Each batch is analyzed prior to release. Filtration and demineralization equipment is available for further processing prior to release. Liquids are normally not recycled from this system.

I.1.2 GASEOUS RADIOACTIVE WASTE SYSTEM (See Note 1)

Initial plant design incorporated a compressed gas decay tank system supplying cover gas for tanks containing un-degassed reactor coolant. Cover gas (primarily nitrogen) displaced by filling tanks and gas from chemical and volume control system gas strippers is compressed and stored in gas decay tanks. This gas is reused as cover gas when tanks are drained by processing or transfer of liquids. Periodically, gas must be released. The release is on a batch basis following a minimum decay time specified by Technical Specifications. Each batch is analyzed prior to release.

I.1.3 SECONDARY SYSTEM WASTES (See Note 1)

Turbine building drains from both Units 1 and 2 are collected and routed to the effluent sump.

Potable Water System Reverse Osmosis unit concentrate discharge and filter backwash are drained into the plant effluent sump. The façade sumps are normally pumped to the effluent sump. Sanitary wastes from the plant are routed to the plant sewage treatment system, which also discharges to the effluent sump. The effluent sump is pumped to the retention pond. The retention pond overflow effluent is normally released to a pathway subject to monitoring via radiation monitor RE-230 to the circulating water system. Capability for further processing of these wastes is not provided.

Initial plant design incorporated a flash tank for pressure reduction and cooling of the steam generator blowdown for each unit. The vent from each flash tank is routed to a plant ventilation exhaust. Liquid from the flash tank is routed to the circulating water discharge. Provisions are UFSAR 2018 Page I.1-1 of 3

Introduction FSAR Appendix I.1 (Historical) also included for routing this liquid to the boric acid evaporators in the chemical and volume control system during periods of operation with significant primary-to-secondary leakage.

Processed liquids are normally not recycled from this system.

I.1.4 CHEMICAL AND VOLUME CONTROL SYSTEM (See Note 1)

The chemical and volume control system (CVCS) holdup tanks are shared between Units 1 and 2 and collect reactor coolant letdown for boron control and miscellaneous other reactor coolant drains. These liquids are then processed by ion exchange, gas stripping, filtration, and evaporation in the boron recovery portion of the CVCS. Boric acid evaporator condensate is collected and monitored on a batch basis prior to recycle to the reactor makeup water storage tank or release to the circulating water discharge. Concentrated boric acid is sent to the boric acid storage tanks or is solidified in cement and shipped offsite for burial. Evaporator condensate from this system is recycled as far as practicable for use as reactor makeup water.

I.1.5 PLANT VENTILATION AND FILTRATION SYSTEM (See Note 1)

Ventilation air from buildings normally containing radioactive materials and equipment is exhausted through HEPA and/or carbon adsorber equipment depending on the potential for significant releases. Turbine building ventilation is exhausted through roof exhausters with no treatment.

Containment ventilation systems include HEPA and carbon adsorber equipment in internal recirculation systems and purge systems.

I.1.6 PREVIOUS RADIOACTIVE WASTE SYSTEM MODIFICATIONS (See Note 1)

In 1971, Licensees completed conceptual designs of additional equipment to augment the initial plant systems and allow further reduction of radioactive releases from Point Beach Nuclear Plant.

This additional equipment included treatment of air ejector offgas, larger evaporation equipment, gas stripping and decay processes, and cryogenic adsorption equipment for removal of long-lived noble gases from waste gas prior to release.

The additional evaporation equipment is used to process radioactive liquid waste and can be used to process steam generator blowdown from either unit. The capability for recycle of processed blowdown is also incorporated in these modifications. In addition, steam generator blowdown tank vent condensers are used to minimize potential gaseous releases.

Air ejector offgas from Units 1 and 2 passes through a delay duct for decay of short-lived isotopes and can be processed by a carbon adsorber prior to release.

Gas stripper equipment is used to maintain reactor coolant gas concentrations at low levels by stripping the letdown from each unit. Stripped gas from the gas strippers is sent to charcoal decay tanks shared by Units 1 and 2. Effluent from the charcoal decay tanks is normally recycled to Unit 1 and Unit 2 volume control tanks in the CVCS to minimize gaseous releases. If stripped gas is released, it can be processed for krypton removal in the cryogenic adsorption equipment prior to release. The adsorbed krypton is then stored in a gas decay tank.

UFSAR 2018 Page I.1-2 of 3

Introduction FSAR Appendix I.1 (Historical)

I.1.7 SUBSEQUENT CHANGES TO THE WASTEWATER EFFLUENT SYSTEM In 2002, conveyor type filters replaced the Retention Pond. A modification installed two filtration conveyors capable of processing 300 gpm each through a roll of paper media. These new filtration conveyers were installed to process the turbine hall sumps and the water treatment wastewell to provide assurance of compliance with the WPDES permit for total suspended solids. After the installation of the conveyers the turbine hall sump was rerouted to the conveyers and isolated as an input to the effluent sump. As part of the retirement of the retention pond, the wastewater stream from the plant effluent sump discharge was rerouted back into the plant and joined the common discharge piping downstream of the new filters, but upstream of RE-230, Wastewater effluent process monitor. The effluent sump was routed downstream of the filters because the inputs to the sump (sewage treatment plant effluent and potable water RO unit filter backwash and reject), meet the WPDES permit for solids without further treatment. The inputs into the effluent sump are routed past RE-230 prior to discharge.

A third filtration conveyer was installed to process the facade sump drains. The façade sumps were rerouted to a 30-gpm conveyor, and the filter media is checked for contamination prior to disposal. This limits the spread of contamination and will prevent cross contamination of normally clean systems.

The Retention Pond was subsequently capped and abandoned.

I.1.8 SUBSEQUENT CHANGES TO THE LIQUID RADIOACTIVE WASTE SYSTEM A filtration/demineralization system has been added to the liquid radioactive waste system, and serves as the primar means of processing liquid radioactive waste. Wastes are processed and released to the circulating water discharge on a batch basis. Each batch is analyzed prior to release. If necessary, the processed liquid can be returned for reprocessing. The estimated liquid releases, based on use of the filtration/demineralization system, are listed in Table 11.1-3.

Note 1.Description reflects plant design information when the Appendix I evaluation was performed. See other FSAR sections as applicable for current system descriptions.

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Information In Response to Appendix D of Draft Regulatory Guide 1.BB FSAR Appendix I.2 (Historical)

I.2 INFORMATION IN RESPONSE TO APPENDIX D OF DRAFT REGULATORY GUIDE 1.BB The information in this section was provided in response to Draft Regulatory Guide 1.BB (Reference 1) and referenced the FSAR where appropriate. In many instances, plant operating data were used, rather than design data in the FSAR, because these data were representative of expected plant operation. Adjustments in the assumptions contained in Reference 1 also were included where appropriate to account for shared systems and structures at Point Beach Nuclear Plant.

The information and data provided in this response are part of the evaluation demonstrating compliance with 10 CFR 50, Appendix I governing design (dose) objectives for radioactive effluents. Updates or changes to individual parameters are not to be made in the remaining sections (i.e., 2.0 - 9.0) unless a complete re-evaluation is to be performed. However, design or procedural changes that impact the calculation results or conclusion of this evaluation are to be updated in the appropriate sections of the evaluation. PBNP effluents are controlled, quantified, and evaluated pursuant to the programs required by the PBNP Offsite Dose Calculation Manual.

I.2.1 GENERAL

a. Maximum core thermal power is 1518.5 MWt as stated in the FSAR, Table 3.2-1, and Operating Licenses DPR-24 and DPR-27.

b. 1) The total calculated mass of uranium and plutonium in an equilibrium core is as follows:

Beginning Middle End Of Life Of Life Of Life Uranium (as 105,409 104,816 104,093 U), lbs.

Plutonium 425 583 711 (as Pu), lbs.

These values are based on an average burnup of 9300 MWD/MTU and operation at approximately 80 percent capacity factor.

2) Reload fuel is enriched to 3.1 weight percent uranium U235

3) There is no fissile plutonium in reload fuels at the present time.

c. 1) The assumed plant capacity factor is 80 percent.

2) The assumed fuel defect level is 0.12 percent. The fuel cladding is Zircaloy.

UFSAR 2018 Page I.2-1 of 8

Information In Response to Appendix D of Draft Regulatory Guide 1.BB FSAR Appendix I.2 (Historical)

3) Concentrations of fission, corrosion, and activation products in the primary and secondary coolant are given in Table I.3-2 and Table I.3-3, respectively, and are based on calculational methods recommended by Reference 1.

d. The quantity of tritium released in liquid and gaseous effluents is 610 and 610 curies per year, respectively, as calculated according to Reference 1 assumptions. Tritium quantities released in liquid and gaseous effluents based on plant operating data are 859 and 110 curies per year, respectively.

I.2.2 PRIMARY SYSTEM

a. The total calculated mass of primary coolant in the system (excluding the pressurizer and purification system) is 247,600 pounds per unit at full power. This value is based on volumes given in the FSAR, Table 4.1-1 and Table 4.1-3, with operation at Tavg of 570°F and a pressure of 2250 psig.

b. The average primary coolant letdown rate to the purification system is 40 gallons per minute (19,800 pounds per hour) for each unit, based on information in the FSAR, Table 9.3-2.

c. The average flow rate through the cation demineralizers in the purification system is zero.

Although initial design and operation included a cation demineralizer in series with a mixed bed demineralizer present plant operation normally utilizes only a single mixed bed demineralizer. Lithium control is accomplished with a mixed bed in H3BO3 form. This change was made necessary by the limited availability of lithium-7 hydroxide and lithium-7 form demineralizer resins.

d. The average flow rate to the CVCS holdup tanks is approximately 1.1 gallons per minute (564 pounds per hour) for each unit, based on plant operating data for 1974 and 1975.

I.2.3 SECONDARY SYSTEM

a. Each unit has two U-tube recirculating type steam generators. The carryover assumed in the evaluation is 0.20 percent for each steam generator based on plant measurements.

b. The steam flow is 6.62 x 106 pounds per hour (3.31 x 106 pounds per hour per steam generator) based on the FSAR, Table 4.1-4.

c. The mass of steam in each steam generator at full power is 5,230 pounds, based on the FSAR, Table 4.1-4, and steam conditions of 521°F and 821 psia.

d. The mass of liquid in each steam generator at full power is 80,240 pounds based on the FSAR, Table 4.1-4, and saturated conditions at 821 psia.

e. The total mass of coolant in the secondary system at full power is 197,600 pounds (excluding the steam generators and the condenser hotwells) based on calculations from plant measurements.

UFSAR 2018 Page I.2-2 of 8

Information In Response to Appendix D of Draft Regulatory Guide 1.BB FSAR Appendix I.2 (Historical)

f. The primary to secondary leak rate assumed in the evaluation is 100 pounds per day for each unit.

g. Each steam generator is provided with a blowdown connection located above the tubesheet. The blowdown is presently routed to a blowdown flash tank in each unit through throttling valves. The discharge from the flash tank is pumped through a filter to the plant circulating water discharge. Each blowdown flash tank is provided with a vent condenser cooled by service water. Modifications to the present system were made to allow heat recovery and processing of blowdown by the filtration/demineralization system if required prior to release.

During operation with significant primary to secondary leakage, steam generator blowdown can be processed at a reduced rate by routing the affected steam generator(s) blowdown to the waste holdup tank and the filtration/demineralization system; which is shared by Units 1 and 2. The steam generator blowdown system is further discussed in the FSAR, Section 10.1 and Section 11.1.

Steam generator blowdown rates are normally on the order of 25 gallons per minute (12,500 pounds per hour) per steam generator. This is the average value used in the evaluation.

h. Point Beach Nuclear Plant does not have provisions for condensate polishing demineralizers.

I.2.4 LIQUID WASTE PROCESSING SYSTEMS

a. Information on sources of radioactive liquid wastes, flow rates, and expected radioactivity concentrations is provided in Table I.2-1. These values are based on recommendations of Reference 1, where appropriate, and on plant operating data. All liquid waste sources are calculated assuming plant operation for 365 days per year except for steam generator blowdown which is adjusted for an 80 percent capacity factor.

Since Point Beach Nuclear Plant is a two-unit plant with many shared systems and structures, it is not appropriate in all cases to double the values for a single unit as recommended by Reference 1. In addition, because of the sharing, releases cannot be directly attributed to either Unit 1 or Unit 2 in most cases. Therefore, the information presented in Table I.2-1 represents the total for Point Beach Nuclear Plant.

Values provided in Reference 1, Table B-17, are used and are doubled for the two-unit plant except for the following items:

1) Laboratory drains are not doubled since there is a single laboratory for two units with drains directed to the liquid waste system.

2) Detergent wastes are not doubled since there is a single laundry for two units.

3) In addition to turbine building floor drains, additional secondary system waste is generated by continuous chemical analyzers in the secondary system. These have been added in addition to the turbine building floor drains value in Reference 1.

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Information In Response to Appendix D of Draft Regulatory Guide 1.BB FSAR Appendix I.2 (Historical)

4) Point Beach Nuclear Plant does not regenerate demineralizers in primary systems and no allowance is made for these wastes.

5) Evaporator condensate from the boric acid evaporators is recycled as reactor makeup water if the purity is within chemical specifications for makeup, however, releases from this source occur frequently. Table I.2-1 includes this source as a separate category.

Comparison of plant released for 1974 and 1975 with values derived from Table I.2-1 indicates good agreement. Table I.2-1 is therefore used in the evaluation of releases.

Capacities of tanks and processing equipment used in calculating holdup times and decon-tamination factors for each processing step are provided in Table I.2-2 and Figure I.2-1, respectively.

Calculated liquid source terms by isotope and waste category are provided in Table I.7-3.

Calculated holdup times for each waste category are provided in Table I.2-3. Observed operational liquid releases are provided in Table I.7-6.

b. Piping and instrument diagrams for radioactive waste systems and related systems are shown in the FSAR, Figure 9.3-1 through Figure 9.3-5, Figure 10.1-1, Figure 11.1-1 through Figure 11.1-3, and Figure 11.2-1 through Figure 11.2-4. Process flow diagrams for the liquid waste system and the CVCS are presented in Figure I.2-1 and Figure I.2-2, respectively.

I.2.5 GASEOUS WASTE PROCESSING SYSTEM

a. The volume of gas stripped from the primary coolant is approximately 78,000 cubic feet per year for each unit based upon a primary coolant hydrogen concentration of 35 cc per kilogram at standard conditions, a normal letdown flow of 40 gallons per minute, and two cold shutdowns per year for each unit.

b. During normal operation, the primary coolant letdown flow for purification is continuously stripped, with stripped gas being routed to the gaseous radioactive waste processing system. The purified hydrogen from the charcoal decay tanks in the gaseous radioactive waste system is recycled to the volume control tanks as described in the FSAR, Section 11.2.

Prior to a refueling shutdown or a cold shutdown requiring opening of the primary system, the primary system is stripped of dissolved gases. Under these conditions, the purified gas is routed to the volume control tank of the other unit.

The gaseous radioactive waste system incorporates a closed cover gas system with pressurized storage tanks which are used to store gas displaced during filling of the tanks in the CVCS and from operation of the gas strippers in the boron recovery portion of the CVCS. When tanks are emptied by processing, the stored gas is then recycled to fill the tank space. Periodically, gas inventory requires release of a portion of the stored gas.

Present operation of the system utilizes four gas decay tanks in the cover gas system. The fourth tank can be used for storage of krypton from the cryogenic absorption equipment.

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Information In Response to Appendix D of Draft Regulatory Guide 1.BB FSAR Appendix I.2 (Historical)

Each of the four usable gas decay tanks in the cover gas system has a volume of 525 cubic feet and a maximum operating pressure of 105 psig at ambient temperature. The total volume released from the tank at maximum pressure is approximately 3750 cubic feet at standard conditions. Plant radioactive release records indicate average release rates ranging from 2 to 15 cfm during batch releases.

c. During normal operation, cover gas is routed between the CVCS holdup tanks and the gas decay tanks with small quantities of gas being produced from the gas strippers in the CVCS. The major source of gas is that produced by filling a CVCS holdup tank with letdown from the primary system during plant startup, load-follow operation, or boron dilution near the end of core life and from draining of the fuel transfer canal in the spent fuel pool. Normally, one gas decay tank is held in reserve to accommodate filling of one holdup tank. Releases are made as required to allow one gas decay tank to be held in reserve.

Minimum holdup time prior to release of a gas decay tank is 7 days as specified in Technical Specifications. Actual holdup times are significantly longer, based on plant experience on the order of one release per month.

Fill times for gas decay tanks are not predictable due to the variety of operating conditions which result in filling a tank and to the reuse of gas as cover gas. During letdown to the hold up tanks, the fill time is controlled by the maximum letdown rate of 80 gallons per minute. Under these conditions, the fill time is approximately 6 hours6.944444e-5 days 0.00167 hours 9.920635e-6 weeks 2.283e-6 months . During fuel transfer canal draining, the fill time is controlled by gas compressor capacity of 40 cubic feet per minute. Under these conditions, the fill time is approximately 1.5 hours5.787037e-5 days 0.00139 hours 8.267196e-6 weeks 1.9025e-6 months .

Further discussion of the gaseous radioactive waste system is provided in the FSAR, Section 11.2.

d. HEPA filters are not provided downstream of the gas decay tanks.

e. Stripped gas from the continuously operating letdown gas strippers (one per unit) is routed to 3 charcoal decay tanks connected in series. These 3 tanks, common to both units, each contain approximately 1000 pounds of charcoal. Total volume of each tank is 46 cubic feet and normal operating pressure is 75 psig at ambient temperature. The dynamic absorption coefficients (K) for krypton and xenon are 77.7 and 1,386 cm3/gm, respectively, at an operating pressure of 75 psig at 77°F. The dew point is 40°F. From Section 2.5.a, the operational flow rate is calculated at 0.37 cubic feet per minute at standard conditions for both units.

Stripped gas, mainly hydrogen, is normally routed from the charcoal decay tanks back to the reactor coolant system. Optional routing is to the cryogenic system for krypton removal or to the gas decay tanks in the cover gas system. An additional route to the auxiliary building vent exists but is not normally used.

f. Piping and instrumentation diagrams for the gaseous radioactive waste system are given in the FSAR, Figure 11.2-1, Figure 11.2-2, and Figure 11.2-3. A process flow diagram is presented in Figure I.2-3.

UFSAR 2018 Page I.2-5 of 8

Information In Response to Appendix D of Draft Regulatory Guide 1.BB FSAR Appendix I.2 (Historical)

I.2.6 VENTILATION AND EXHAUST SYSTEMS

a. Areas of Point Beach Nuclear Plant which normally contain radioactive materials and which are provided with measures to reduce airborne radioactivity releases are shown in the FSAR, Figure 11.4-1 through Figure 11.4-8. Within these areas, the ventilation systems are designed so that flow is from areas of low potential for radioactive contamination to areas of higher potential. Piping and instrumentation diagrams for these ventilation systems are shown in Figure I.2-4 and Figure I.2-5. Areas of the plant which could contain low levels of radioactive contaminants with primary-to-secondary leakage, such as the turbine building, are not provided with HEPA or carbon adsorber equipment since releases from the areas are insignificant. A process flow diagram for all major ventilation systems is presented in Figure I.2-3. Ventilation and exhaust systems are as follows:

1) Containment Ventilation Each containment is provided with a containment purge system, an internal cleanup system, and a purge vent which exhausts above the containment facade. Purge exhaust (12,500 cubic feet per minute) is through roughing filters, HEPA filters, and carbon adsorbers. The internal cleanup system (5,000 cubic feet per minute) is provided with roughing filters, HEPA filters and carbon adsorbers. The cleanup system is not necessarily operated prior to each purge and therefore no credit is taken in the evaluation of releases via containment ventilation.

Pressure buildup in the containment as a result of instrument air leakage is vented continuously at a rate of approximately 10 cubic feet per minute via the containment air monitor. This effluent is routed to the containment purge filters prior to release via the purge vent.

The gas stripper building ventilation is routed to the Unit 2 purge vent at flow rates varying from 400 to 12,000 cubic feet per minute, depending on building air temperature.

Operational measurements indicate that only about 2 percent of the total plant noble gas release is via this pathway. Capability exists for routing this ventilation air through the Unit 2 containment purge filtration equipment.

2) Auxiliary Building Ventilation The auxiliary building ventilation includes ventilation air from service building controlled areas and is exhausted through the auxiliary building and the drumming area vents located above the Unit 1 containment facade.

The drumming area vent receives ventilation air from the drumming station in the auxiliary building, general areas of the auxiliary building above elevation 46' and spent fuel pool areas. Roughing and HEPA filters are provided for this exhaust.

The auxiliary building vent exhausts air from the service building, chemistry laboratory, general areas of the auxiliary building and cubicles containing radioactive equipment.

The chemistry laboratory exhausts to the auxiliary building vent through roughing filters, HEPA filters and carbon adsorbers. Service building ventilation and general areas and UFSAR 2018 Page I.2-6 of 8

Information In Response to Appendix D of Draft Regulatory Guide 1.BB FSAR Appendix I.2 (Historical) cubicles of the auxiliary building containing equipment with low potential for iodine releases are exhausted through roughing and HEPA filters. Areas of the auxiliary building with high potential for iodine releases are routed through roughing and HEPA filters to the auxiliary building vent with an optional route through carbon adsorbers and HEPA filters.

3) Turbine Building Ventilation Units 1 and 2 share a combined turbine building. Outside air is provided at all levels of the building and is exhausted through 19 turbine building roof exhausters evenly spaced along the length of the turbine building roof.

4) Condenser Air Ejectors Unit 1 and Unit 2 air ejectors discharge to a delay duct in the turbine building which provides a nominal one hour holdup prior to release via the auxiliary building vent. An optional route is through a carbon adsorber prior to the delay duct.

5) Radioactive Waste Gases Releases of cover gas from gas decay tanks are directly to the auxiliary building vent at a controlled rate.

Stripped gas from the Unit 1 and Unit 2 gas strippers is normally routed through the charcoal decay tanks and back to the CVCS volume control tank for each unit. This gas may also be released directly to the auxiliary building vent. An optional route is to pass the charcoal decay tank effluent through cryogenic adsorption equipment prior to release.

No credit for the cryogenic system is taken in calculating radioactive releases.

b. Decontamination factors of 10 for iodines through carbon adsorbers and 100 for particulates through HEPA filters are assumed for the evaluation, consistent with recommendations in Reference 1. All carbon adsorbers at Point Beach Nuclear Plant have a bed depth of 2 inches and a maximum face velocity of 40 feet per minute. Periodic testing of filtration equipment indicates decontamination factors at least equal to the above values. Credit is taken only for those filters which are normally in service.

c. Calculated gaseous release rates for Point Beach Nuclear Plant are provided in Table I.7 -1 and are based on methods recommended by Reference 1. Observed opera-tional gaseous releases for 1974 and 1975 are presented in Table I.7-4 and Table I.7-5.

d. Release point descriptions are provided in Table I.2-4. The release vents are the highest points of the plant. Where a range is given, the lower flow is assumed for the evaluation.

Each containment has a net free volume of 1,065,000 cubic feet. The containments are continuously vented to the containment purge filters via the containment monitoring system at a rate of approximately 10 cubic feet per minute.

Periodic venting of containment through the purge outlet valves with the unit at power was allowed during early plant operation. This practice is no longer allowed by plant Technical Specifications. However, for the purposes of the evaluation and based on plant UFSAR 2018 Page I.2-7 of 8

Information In Response to Appendix D of Draft Regulatory Guide 1.BB FSAR Appendix I.2 (Historical) operation during 1974 and 1975, an average of 10 purges per year per unit is assumed during power operation and four purges per year per unit are assumed during shutdown.

The average purge time is assumed to be 7 hours8.101852e-5 days 0.00194 hours 1.157407e-5 weeks 2.6635e-6 months at a flow of 12,500 cubic feet per minute.

Since the containment cleanup system is not necessarily operated prior to each purge, no credit is taken for the system in evaluating releases from Point Beach Nuclear Plant.

I.2.7 REFERENCE

1. Draft Regulatory Guide 1.BB, Calculation of Releases of Radioactive Materials in Liquid and Gaseous Effluents From Pressurized Water Reactors (PWR's),

Sept. 1975.

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Calculated Source Terms and Release of Gaseous and Liquid Effluents FSAR Appendix I.3 (Historical)

I.3 CALCULATED SOURCE TERMS AND RELEASES OF GASEOUS AND LIQUID EFFLUENTS I.3.1 ORIGINAL APPENDIX I EVALUATION The source terms (primary coolant and secondary side liquid and steam radioactivities) and the resulting radioactive releases (liquid and gaseous) are calculated using the basic assumptions and approaches recommended by NRC Draft Regulatory Guide 1.BB.

The procedures used in this evaluation provide essentially the same mathematical treatments as the PWR-GALE code used by the NRC staff. Values of plant parameters are based on Point Beach Nuclear Plant design and operating data.

The plant design and operating data, draft regulatory guide reference plant parameters, and applicable ranges are shown in Table I.3-1. Since the power level of 1518.5 MWt is outside the range given in Table I.3-1, the NRC references of plant coolant activities shown in Table B of Draft Regulatory Guide 1.BB have been adjusted. Table I.3-2 lists the resultant primary and secondary coolant radioactivity concentrations using these adjustment factors. Table I.3-3 lists the total primary and secondary liquid activities calculated in a similar manner.

I.3.2 IMPACT OF UPRATED POWER OPERATIONS The impact of a 17.6% power uprate (1811 MWT, including a 0.6% instrument uncertainty) on the annual liquid and gaseous releases were estimated in Reference 1, using methodology and assumptions from NUREG-0017. The evaluation indicated an approximate 17.6% increase in the liquid effluent release concentrations compared to pre-uprate operations, as this activity is based on RCS activity possessing long half-lives (which increases in proportion to the power uprate percentage) and on waste volumes (which are essentially independent of power level within the applicability range on NUREG-0017). Tritium releases in liquid effluents increased proportionately to the power uprate.

Similarly for the gaseous releases, the impact of uprated power on Kr-85 and tritium is limited to the increase in power level, 17.6%, taking into consideration a 0.6% uncertainty in the power level. Isotopes with shorter half-lives have increases slightly greater than the uprate percentage, estimated at 18.1 %. The other component of gaseous releases (i.e., iodines and particulates via the building ventilation systems), although increased, have a negligible impact on dose to the public. This is because the iodines and particulates category includes tritium, which is the controlling dose contributor.

I.3.3 REFERENCE

1. Shaw Calculation 129187-M-0104, Impact of EPU on Normal Operation Gaseous and Liquid Radioactive Effluent Releases, dated March 26, 2009.

UFSAR 2018 Page I.3-1 of 1

10 CFR 50 Appendix I Analysis FSAR Appendix I.4 (Historical)

I.4. METEOROLOGY I.4.1 METEOROLOGICAL PROGRAM AT POINT BEACH NUCLEAR PLANT The meteorological monitoring program at Point Beach Nuclear Plant was conducted in accordance with requirements in existence at the plant licensing stage. The data used in this evaluation was obtained during the 4/19/67 through 4/18/69 period. The meteorological tower is located approximately 2,000 feet south of the nearest reactor containment. Wind speed and wind direction at the 150-foot level (approximate height of the containments) were monitored by Belfort Type M wind instruments. The wind data were recorded on the Belfort recorder located in a shelter adjacent to the base of the tower and were reduced by visual (equal area) methods.

Atmospheric stability classes were determined by calculating hourly values of wind range, defined as the difference in azimuth between the maximum and minimum wind direction values during each hour. Hourly wind range values were then divided by a factor of 6, and a versus Pasquill Stability Class relationship, now referenced in Regulatory Guide 1.23 (Reference 1), was applied to establish the stability class. Hourly average values of wind speed, wind direction, and atmospheric stability class were used to compute hourly X/Q and D/Q values.

Wind direction was recorded to the nearest degree. Wind speed was measured to the nearest mile per hour, while calms were determined by a calculational or computer threshold wind speed of 0.7 miles per hour and assigned to the last valid wind direction.

In order to calculate plume rise, ambient dry-bulb temperature is required. Since this parameter was not monitored at the site, monthly normals (1931-1960) at Kewaunee, Wisconsin (12 miles north) were used for each hour of the month considered.

a. Point Beach Meteorological Data Table I.4-32 presents joint frequency distributions of wind speed and wind direction for each specific stability class, and all combined stability classes for the 4/19/67-4/18/69 onsite data period. Table I.4-33 presents similar distributions for each monthly period. A wind rose summary of Point Beach meteorology is presented in Table I.4-1.

b. Onsite Data Representativeness Data obtained during the meteorological monitoring program at Point Beach Nuclear Plant is compared to that obtained from a program conducted at Haven, Wisconsin (approximately 30 miles south on the shore of Lake Michigan), during 1973 and 1974 as summarized in Table I.4-28. The latter program was designed in accordance with the guidance in Regulatory Guide 1.23. Table I.4-22, Table I.4-23, and Table I.4-24 provide a comparison of Haven and Point Beach data with that obtained at Milwaukee, Wisconsin, for concurrent and long-term periods.

National Weather Service data for General Mitchell Field, Milwaukee, Wisconsin, is presented in Table I.4-29 through Table I.4-31. The similarities between Point Beach and Haven are as expected since both sites are similar in surrounding terrain and both are located on the shore of Lake Michigan.

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10 CFR 50 Appendix I Analysis FSAR Appendix I.4 (Historical)

The following comparisons can be made from Table I.4-22, Table I.4-23, and Table I.4-24:

Comparison A - Point Beach (1967-1969) to Haven (1973-1974)

Comparison B - Milwaukee (1967-1969) to Milwaukee (1973-1974)

Comparison C - Milwaukee (1967-1969) to Milwaukee (1956-1975)

Comparison A shows the similarities between Point Beach data and Haven data.

Comparison B shows the overall similarity of the meteorological conditions that occurred during the 4/19/67-1/18/69 period with those conditions occurring during the 6/1/73-5/31/74 period. Comparison C shows the long-term data representativeness with climatology, using the 1/1/56-12/31/75 Milwaukee data base. For the 1/1/65-12/31/75 period, only 3-hour observations were recorded by the National Weather Service, however, this has no significant bearing on the comparisons, since a large data sample is used.

Table I.4-22 shows stability class frequencies for the three sites and five data periods.

Comparison A shows excellent similarity. The large preponderance of E, F, and G stabilities directly reflects the lake breeze phenomenon of undercutting cold air replacing warmer surface air, thus causing shallow pseudo-inversions. This is not present in the Milwaukee data, since the STAR (Reference 2) methodology is based on gross parameterization of incoming solar radiation and wind speed. A stabilities at this latitude are rare, since a solar angle of at least 60 degrees is required. Also, E, F and G stabilities can only occur at night. Thus, Milwaukee data cannot reflect the effect of the daytime lake breeze on the stability classifications. Comparison B shows good similarity in the overall meteorology for both the Point Beach and Haven data periods. Similarly, Comparison C indicates that both the 4/19/67-4/18/69, and the 6/1/73-5/31/74 periods are representative of the long-term climatology.

Table I.4-23 shows the frequency distribution of wind direction by quadrant (and offshore/

onshore breakdown) for the three sites and five data periods. Comparison A shows small anomalies in the ESE-S and WNW-N sectors, while Comparison B shows minor differences in the NNE-E sectors. These anomalies reflect small synoptic-scale meteorological differences. For example, during the 4/19/67-4/18/69 period, Milwaukee had 22.0 percent WNW-N winds, while Haven had 27.2 percent. Those figures reflect the larger frequency of northerly component winds with an increase in latitude north from Milwaukee. Comparison C shows long-term representativeness of both the Point Beach and Haven data periods.

Table I.4-24 shows the average wind speed for each quadrant for the three sites and five data bases. Comparison A shows Point Beach somewhat windier than Haven, even though Comparison B indicates 6/1/73-5/31/74 to be the windier period. This is the result of the decreased friction of the earth's surface at the 150-foot Point Beach measurement, as opposed to the 10-meter Haven level, and the 20-foot Milwaukee level. Wind speed differences of this order can be found in year to year climatological variances. Comparison C shows overall similarity of both the Point Beach and Haven data periods with long-term climatology. Table I.4-22, Table I.4-23, and Table I.4-24 show general representativeness of the Point Beach data to long-term climatology data from Milwaukee. Table I.4-28 UFSAR 2018 Page I.4-2 of 9

10 CFR 50 Appendix I Analysis FSAR Appendix I.4 (Historical) through Table I.4-32 present wind speed - wind direction point frequency distributions of the data used in the representativeness analysis.

It is concluded that the 4/19/67-4/18/69 Point Beach data are representative of the actual meteorology occurring at Point Beach, and also of the long-term climatology of the area.

Since the present program produces representative meteorological data there is no basis for upgrading the program in accordance with Reference 1.

c. Wet Deposition Table I.4-25 and Table I.4-27 present precipitation-wind frequency distributions and intensity frequency distributions for National Weather Service Stations in the vicinity of Point Beach.

The onsite data period is represented by Green Bay (Austin Straubel Field), while the long-term climatology precipitation wind rose is represented by Milwaukee data. Table I.4-27 shows that 90 percent of all precipitation falls at a rate of 0.09 inch/hour or less, and shows the lack of a well-defined rainy period within the growing and grazing season. Table I.4-25 shows the precipitation to be generally well distributed with wind direction and wind speed.

Table I.4-26 shows that precipitation levels within a 50-mile vicinity of the site do not vary significantly. It is unlikely that significant wet deposition occurs near the Point Beach site.

Thus, the D/Q analysis reflects dry deposition only.

d. Airflow Trajectory Regimes of Importance and Topography in the Vicinity of Point Beach The Point Beach Nuclear Plant is situated near the shoreline of Lake Michigan in a relatively flat region of Wisconsin. Within a ten-mile radius of the plant, the scattered hills and knolls do not exceed 800 feet mean sea level (MSL) in any downwind sector. Plant grade is 606 feet MSL and major plant release points are at approximately 774 feet MSL.

Based on the low relief of the surrounding terrain, airflow trajectory reversals caused by topographic obstacles are unlikely and, if they occur, are relatively insignificant. General topography within a 10-mile radius is shown in Figure I.4-1. Maximum topographic elevation vs. distance by sector is illustrated in Figure I.4-2.

Thunderstorm activity, squall lines and frontal passages are relatively infrequent in the vicinity of Point Beach, therefore, air flow reversals caused by their presence are minimal.

These meteorological phenomena are generally short-lived and transitional and probably affect the overall local airflow less than one percent of the year. Based on the low frequency and short duration of these phenomena, as compared to an 8760-hour year, the overall effect on airflow reversals due to the phenomena are also relatively insignificant.

During the mid-spring to late-summer months (April through September), the lake is generally colder than the land. When the synoptic-scale meteorological conditions are weak and not very well established, a shallow flow from lake to land develops during the late morning to late afternoon hours. This airflow reversal phenomenon is called the lake breeze. The lake breeze, when well established, can penetrate as much as 25 miles inland.

Conservatively assuming the lake breeze prevails six hours (1100LST - 1700LST) each day UFSAR 2018 Page I.4-3 of 9

10 CFR 50 Appendix I Analysis FSAR Appendix I.4 (Historical) during the early spring through late summer (April through September) period, approximately 10 percent of the annual period would be subject to these conditions.

In order to conservatively account for airflow trajectory reversals with the Gaussian single-line trajectory model, the terrain correction factor, shown in Figure 2 of Regulatory Guide 1.111 (Reference 3) was applied to all X/Q and D/Q calculations. This factor assumes that the same air is advected four times over the same receptor location at distances of 1200 meters or less from the plant and approaches unity at greater distances. The terrain correction factor was conservatively applied to all occurrences, onshore or offshore winds, summer or winter, and day or night conditions. The application of Figure 2 terrain correction factors more than adequately compensates for the level of air trajectory reversals that would be experienced at PBNP.

I.

4.2 DESCRIPTION

OF X/Q AND D/Q MODELING PROCEDURES In general, the methodology recommended by Reference 3 was used in the calculation of annual average and growing and grazing season average X/Q and D/Q values for the Point Beach site.

Since there are a variety of release modes for the major release points, X/Q and D/Q must be evaluated for each operating condition. Six categories of release modes are defined and evaluated as follows:

Release Mode IA This mode is the continuous exhaust of plant ventilation air through the auxiliary building vent.

Since the exit velocity is high, this release is considered to be an elevated release subject to the constraints discussed in this section.

Release Mode IB This mode is the periodic release of gas decay tank contents through the auxiliary building vent.

The X/Q and D/Q values are evaluated for the gas decay tank release intervals and frequencies.

Release Mode IIA This mode is the continuous release of 10 cubic feet per minute through each containment purge vent. Since exit velocities are negligible, the releases are considered ground level.

Release Model IIB This mode is the periodic purge of containment through the containment purge vent. The exit velocities are high and the release is elevated. The X/Q and D/Q values are evaluated for the purge intervals and frequencies.

Release Mode IIC This mode is the continuous release of gas stripper building ventilation through the Unit 2 containment purge vent. Exit velocities are variable and depend on building temperature; hence, the release is considered to be ground level.

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10 CFR 50 Appendix I Analysis FSAR Appendix I.4 (Historical)

Release Mode III This mode is the continuous release of turbine building ventilation through the roof exhausters.

The release is considered to be ground level.

A separate release mode was not defined for the drumming area vent, since the treatment assumed (HEPA) and the exit velocities and locations are essentially the same as that for the auxiliary building vent.

a. /Q Model The straight-line Gaussian diffusion model is used for X/Q calculations. Airflow reversals that are primarily caused by lake-breeze activity in the spring and summer months are conservatively accounted for by applying the correction factor ((x)) presented in Figure 2 of Regulatory Guide 1.111. The following equation is utilized for annual average and grazing season average /Q calculations:

he ( x ) 2 n1 ( 1 - E T ) exp - 1 --- -------------

X-

[ ]

Q (x) k1 2.032

= -------------

N j=1

[ ] [-

x k Et

( x -) -------------------------------------

u ( z2 ( x ) ) + -------b-ch 2 2 1

- z(x)

U 2 z

]

--- + ----------------------------------------------------------- (1)

The entrainment coefficient (ET)is a function of the ratio of exit velocity (Ue) to wind speed (u) for conditionally elevated release points. For stacks that are at least twice the height of a nearby structure, ET = 0. For vent released occurring below the level of a nearby structure, 100 percent downwash is conservatively assumed (ET = 1). For vent releases occurring between 1 and 2 times the height of a nearby structure, a conditionally elevated release is assumed, and the entrainment coefficient is defined as follows:

ET = 0.0 when Ue/û > 5.0 ET = 0.30-0.06 (Ue/û ) when 1.5 < Ue/û 5.0 (2)

ET = 2.58-1.58 (Ue/û ) when 1.0 < Ue/û 1.5 ET = 1.0 when Ue/û 1.0 The effective release height (he) is defined as:

he(x) = hr + h(x) - [ht(x) + ha] (3) where h is the plume rise.

g d To calculate plume rise, let S = --- (4)

T dz UFSAR 2018 Page I.4-5 of 9

10 CFR 50 Appendix I Analysis FSAR Appendix I.4 (Historical)

Then for A-D stabilities when x < 10 hr and for E-G stabilities when x < 2.4eq û/S1/2, plume rise is given by:

gQH 1 / 3 2 3 1.6- ----------------

h ( x ) = ------ [

-u Cp T- ( x )

p

] (5)

For A-D stabilities, when x 10 hr, plume rise is given by:

1.6 g Q H 1 / 3 h ( x ) = ------- ----------------- ( 10 h r ) 2 3 (6) u Cp p T For E-G stabilities when x 2.4 û/S1/2, plume rise is given by:

gQH 1 / 3 h ( x ) = 2.9 ----------------------- (7)

Cp p TuS The topographic height (ht(x)) is the actual height of the surface at the receptor point above plant grade. The aerodynamic downwash height correction (ha) is defined by:

h a = 3 ( 1.5 - U e u )d (8)

For cases where entrainment occurs, credit is taken for vertical plume expansion in the wake behind the release point building.

b. D/Q Model Deposition is calculated as follows:

n1 3 D

[ ]

( x )

Q k1

( x ) 2 N -1 x k 16 j=1 r Q Gk 1

nt i=1 Figure 7 of Reference 3 is used to determine ground release (entrained) relative deposition Q ik l

= ------------ ----------- n 1 ---- E t + ---- [ 1 - ( E t ) i ] n i1 ---- (9) values, while Figures 8 through 10 of this Regulatory Guide are used to determine [di(x)]j values as a function of release height. Inspection of rainfall rate distributions at Austin Straubel Field in Green Bay, Wisconsin, for the 4/19/67-4/18/69 data period indicates that 90 percent of the hours with precipitation had totals of 0.09 inches or less. Therefore, it is unlikely that significant wet deposition occurs at the Point Beach site.

Dry deposition is calculated for elemental radioiodines and particulates only. The deposition rate for noble gases, tritium, carbon-14, and non-elemental radioiodines is too slow to allow accumulation at the distances considered in this evaluation. Although deposition and plume depletion occur simultaneously, the X/Q values are not reduced in order to remain conservative.

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10 CFR 50 Appendix I Analysis FSAR Appendix I.4 (Historical)

c. Methodology Employed For Intermittent Releases The methodology employed in the calculation of intermittent release /Q's and D/Q's is as follows and reflects current Site Analysis Branch practices:

1. One-hour sector-averaged /Q values are calculated without terrain correction factors.

2. The 15% one-hour value is plotted at 1-hr. on log-log coordinates while the annual average value is plotted. At 8760 hours0.101 days 2.433 hours 0.0145 weeks 0.00333 months ; a straight line is drawn, connecting the two points.

3. Log-log interpolation based on total ground intermittent release hours versus annual hours yields /Q multiplier.

4. The multiplier is applied to annual average /Q and D/Q values to obtain intermittent

/Q and D/Q values.

d. List of Symbols

1. Indices and Subscripts i = index for elevated release stability group j = index for number of hours k = index for a particular receptor distance l = index for a particular 22.5x sector G = ground level b = building r = release b = building r = release e = effective, exit t = terrain a = aerodynamic downwash H = heat flux P = pressure UFSAR 2018 Page I.4-7 of 9

10 CFR 50 Appendix I Analysis FSAR Appendix I.4 (Historical)

2. Parameters

/Q= relative concentration D/Q= relative deposition rate x = downwind (receptor) distance (x)= terrain correction factor N = total number of valid data hours

û= average wind speed hb = building height he(x)= effective release height z(x)= vertical diffusion coefficient Ue = exit velocity hr = release height h(x)= plume rise ht = topographic impaction height ha = aerodynamic downwash correction height adjustment g = gravitational acceleration QH = heat flux Cp = specific heat at constant pressure

= density of ambient air T = ambient temperature Ts = stack temperature S = stability parameter d/dt= lapse rate of potential temperature d = inner stack diameter

= relative deposition n = number of valid data hours within a given sector UFSAR 2018 Page I.4-8 of 9

10 CFR 50 Appendix I Analysis FSAR Appendix I.4 (Historical)

I.4.3 CALCULATED /Q AND D/Q VALUE FOR POINT BEACH NUCLEAR PLANT Table I.4-2 presents the highest offsite sector D/Q and /Q values at the site boundary, nearest milk cow, milk goat, meat animal, resident, and vegetable garden. The annual period is represented by the 4/19/67-4/18/69 data period, while the grazing and/or growing season is approximated by the combination of the 4/19/67-10/18/67 and 4/19/68-10/18/68 periods. Table I.4-4 through Table I.4-13 list the /Q values for each of the above key receptors, the shoreline receptors (if any), the population distances to 50 miles, and selected distances out to three miles, since two of the six release modes are conditionally elevated. Table I.4-14 through Table I.4-21 presents D/Q values for the same receptors and locations. Because the three former onsite residences have either been demolished or abandoned, the annual and grazing season X/Q and D/Q values at these locations (WNW sector at 1250 meters, NNW sector at 1880 and 1980 meters) provided in Table I.4-3 are historical.

I.

4.4 REFERENCES

1. Regulatory Guide 1.23, Onsite Meteorological Programs, February 1972.

2. STAR is a computer program used by the National Climatic Center, Asheville, N.C., to determine the probability of simultaneous occurrences of a specified wind speed, direction and stability class. STAR uses hourly records of this data over a long period of time to establish a climatological frequency matrix of wind speed, direction and stability class for a given site.

3. Regulatory Guide 1.111, Methods of Estimating Atmospheric Transport and Dispersion of Gaseous Effluents in Routine Releases from Light-Water-Cooled Reactors, March 1976.

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10 CFR 50 Appendix I Analysis FSAR Appendix I.5 (Historical)

I.5 HYDROLOGY I.

5.1 DESCRIPTION

OF DISCHARGE The two Point Beach discharge flumes are each designed to accommodate discharge flows of 390,000 gpm. There is one flume for each unit. They are of similar design, one being the mirror image of the other.

Each flume is constructed of two rows of interlocked sheet pile sections. The shoreline (west) ends of the flumes are attached to the east pumphouse wall, perpendicular to the shoreline. Unit 1 flume extends into Lake Michigan in a SSE direction at an angle of 60 degrees to the shoreline.

Unit 2 flume extends at the same angle in a NNE direction. Each flume is 35 feet wide at the lake end, 17 feet wide at the pumphouse and is 228 feet long. The floor of each flume consists of tremie concrete approximately two feet thick. The bottom depth below mean water level varies between 19 feet and 17 feet-9 inches. The flumes are protected along their sides from wave and ice action by steel spreaders between the piling and rubble stone placed along the outside of each piling row.

The Unit 1 flume has a 35 foot by 19 foot platform on the lake end which had been open to the public for fishing.

I.5.2 HYDROLOGY MODEL The mathematical model used to calculate the lake dilution factor for Point Beach Nuclear Plant is based on methods suggested by Draft Regulatory Guide 1.EE (Reference 1). The plane source solution of the model can be obtained by integration of a point source solution over the source dimensions. For a steady point source discharge into a large lake of constant depth (d), a known steady longshore current (u), and straight shoreline the solution of the transport equation is:

W x = ---------------------- f ( z,z, z s, d) f ( y,y, y s) (1) 2 u y z

( 2 md + z s - z ) 2 ( 2 md - z s - z ) 2 f ( z,z, z s, d) = -

exp - ------------------------------------ -

+ exp - ------------------------------------

m = -

] 2 z2 ] [ 2 z2 [

( ys - y ) 2 ( ys + y )2 f ( y,y, y s) = exp - ------------------- -

+ exp - --------------------

]

2 y2 ] [ 2 y2 [

2 Ky X 2 Kz X y = _J------------

- , z = _J------------

u u Where:

UFSAR 2018 Page I.5-1 of 3

10 CFR 50 Appendix I Analysis FSAR Appendix I.5 (Historical) x is the non-decaying concentration Ky, Kz are the lateral and vertical turbulent diffusion coefficients W is source strength d is depth of the lake at the discharge point X is distance in horizontal direction h is the vertical depth of the discharge plume In deriving Equation (1), it is assumed that:

(1) the discharge is located at the point (0, Ys, Zs), i.e., at the origin of the x-axis and a distance Ys from the shoreline and Zs beneath the water surface; and, (2) the longitudinal diffusion and time dependence in the dissolved constituent transport equation are negligible.

The solution of a plane source can be obtained by integration of Equation (1) over the source dimensions. It is assumed that the plane source has a width of b (in the Y-axis) and a depth of h (in the Z-axis). Integrating f (s, z, zs, d) from zs to zs + h with respect to zs gives:

zs +h f ( s,z, z s, d) dz s = z J --

-A zs 2 m = -

Where:

( 2 md - z s - z ) ( 2 md + z s + h - z ) ( 2 md - z s - z ) ( 2 md + - z s - h - z )

A = - erf ---------------------------------- + erf ----------------------------------------- + erf ---------------------------------- - erf ------------------------------------------

2 z_t _t 2 z _t 2 z _t 2 z Integrating f(y,y,ys) from ys to ys + b with respect to ys gives:

( ys + b )

f ( y,y, y s) dy s = y J (3) y s B

Where:

( ys - y ) ( ys + b - y ) ( ys + y ) ( ys + b + y )

B = - erf ------------------ + erf --------------------------- - e rf ------------------ + erf ---------------------------

2 y _t 2 y _t 2 y_t 2 y _t Therefore:

z +h s y +b s

W x = ---------------------- f ( z,z, z s, d) dz s f ( y,y, y s) dy s 2 u y z zs ys UFSAR 2018 Page I.5-2 of 3

10 CFR 50 Appendix I Analysis FSAR Appendix I.5 (Historical)

W

= ------ A B (4) 4u m = -

Where W is source strength per unit area.

The dilution factor, DF, is given by: DF = W/(xQ) (5),

where Q is the volumetric discharge rate of the effluent.

I.5.3 INPUT DATA Based on a paper by Paddock et. al. (Reference 2) the width of the plane source is estimated to be 1000 feet and the plane source is discharging 1000 feet offshore into a 0.4 feet per second current.

The lateral and vertical mixing coefficients are 900 cm2/sec (0.97 ft2/sec) and 2 cm2/sec (0.0022 ft2/sec), respectively. (Reference 3) From Equations (4) and (5), the centerline dilution factor 12 miles downstream at the Two Rivers, Wisconsin potable water intake is approximately 10 for a discharge rate of 644 cubic feet per second.

Field observations of flow patterns at Point Beach show the presence of reversing currents.

(Reference 3, Reference 4) As indicated in Reference 1, when the directional distribution of currents is approximately bimodal, long-term dilution factors would be about twice those calculated from Equation (4). It is also noted that the dilution calculated by the above model is for a far field. Additional dilution arising from initial mixing in the near field (an additional dilution factor of 5) is also applied. The total dilution factor at the nearest water intake at Two Rivers, Wisconsin, is then calculated to be 100.

I.

5.4 REFERENCES

1. Draft Regulatory Guide 1.EE (Working Paper), Methods for Estimating Aquatic Dispersion of Liquid Effluents from Routine Reactor Releases for the purpose of Implementing Appendix I, February, 1976.

2. Paddock, R. A., Policastro, A. J., Dunn, W. E., and Kyser, J. M., Application of Prominent Near-Field Models for Heated Surface Discharge to Prototype Field Data on Lake Michigan, Energy and Envir. Systems Div., Argonne National Laboratory, paper presented at U.S. - Japan Seminar on Engineering and Environmental Aspects of Waste Heat Disposal, April 15-19, 1974, Tokyo, Japan.

3. Point Beach Nuclear Plant, Non-Radiological Environmental Surveillance Program, Wisconsin Electric Power Company and Wisconsin Michigan Power Company, Annual Report No. 1, September 1972 through November 1973.

4. Point Beach Nuclear Plant, Non-Radiological Environmental Surveillance Program, Wisconsin Electric Power Company and Wisconsin Michigan Power Company, Annual Report Nos. 2 and 3, November 1973 through October 1975.

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10 CFR 50 Appendix I Analysis FSAR Appendix I.6 (Historical)

I.6 SUPPLEMENTAL INFORMATION By Enclosures 1 and 2 to a letter dated February 17, 1976, the Nuclear Regulatory Commission requests that certain specific information be provided as part of the Appendix I evaluation.

Requested information not provided elsewhere in the evaluation is presented in this section.

I.6.1 ENCLOSURE 1 Guidance to Holders of Permits to Construct or Licenses to Operate Light-Water-Cooled Reactors for Which Application was Filed Prior to January 2, 1971, to Meet the Requirements of Appendix I to 10 CFR Part 50.

a. Radioactive source terms used in the evaluation are consistent with the parameters and methodology set forth in Regulatory Guide 1.BB to the extent practicable. Any deviations from the Reg. Guide are noted. Descriptions of the applicable plant parameters and source term are provided in Section I.2 and Section I.3, respectively.

b. Meteorological and Hydrological parameters used in the calculation of doses are consistent with Regulatory Guides 1.DD and 1.EE to the extent practicable. Meteorology and hydrology are discussed in further detail in Section I.4. and Section I.5, respectively.

c. Dose calculations are consistent with Regulatory Guide 1.109 to the extent practicable.

Any deviations from Regulatory Guide 1.109 are noted in the detailed discussion presented in Section I.8.

d. Operational liquid effluent release data is presented on an annual basis for 1974 and 1975 in Table I.7-6. All liquid discharges are released through the discharge flumes via the circulat-ing water system. Operational gaseous effluent release data is presented on an annual basis for 1974 and 1975 in Table I.7-4. Operational gaseous effluent release data is presented on a monthly basis for 1974 and 1975 by release point in Table I.7-5. A brief description of operating condition of each unit is noted for each month.

e. Information requested in Enclosure 2 is provided in Section 6.2.

f. Proposed Technical Specifications reflecting the requirements of Appendix I to 10 CFR Part 50 have been provided under separate cover.

I.6.2 ENCLOSURE 2 Additional Information Needed from Holders of Permits or Licenses to Construct or Operate Light-Water-Cooled Reactors for Which Application was Filed Prior to January 2, 1971.

a. The information requested in Appendix D of Regulatory Guide 1.BB is provided asSection I.2.

b. Distances to the nearest site boundary are provided in Table I.6-1. Distances to the nearest residence and nearest vegetable garden are presented in Table I.6-2. Distances to the nearest milk cow, milk goat, and meat animal are given in Table I.6-3.

In deriving these distances, it is assumed that every residence (farm or non-farm) has the UFSAR 2018 Page I.6-1 of 2

10 CFR 50 Appendix I Analysis FSAR Appendix I.6 (Historical) potential for having a vegetable garden. Since the land use in the vicinity of Point Beach Nuclear Plant is predominantly agricultural, the distance to the nearest milk or meat producing animal is assumed to be the distance to the nearest practicing farm having dwelling and a barn. However, it is assumed that land surrounding the site, owned by the Licensee and leased to local farmers, is unlikely to be used for pasture. Consistent with these assumptions, Figure I.6-1 shows the locations of all farms and non-farm residences out to a distance of 3 miles for each radial sector.

c. Based on considerations in Draft Regulatory Guide 1.DD, estimates of relative concentration (X/Q) and deposition (D/Q) appropriate for locations determined in item 2, above, are presented in Table I.4-4 through Table I.4-21.

d. A complete description of the meteorological program, data, models, and parameters is presented in Section 4.0.

e. Regulatory Guide 1.23 did not exist during the design and licensing stages of Point Beach Nuclear Plant. The meteorological program and data are discussed in detail in Section I.4.1.

f. Meteorological data for the Point Beach site, discussion of representativeness, and description of meteorological monitoring instrumentation is presented in Section I.4..

Since the present program produces representative meteorological data as discussed in Section I.4.1., there is no basis for upgrading the program in accordance with Regulatory Guide 1.23.

g. The lake breeze phenomenon is the only airflow trajectory regime of importance in the vicinity of Point Beach Nuclear Plant. A detailed discussion is presented in Section I.4.1.

h. A map showing detailed topographic features within a 10-mile radius of the plant is given in Figure I.4-1. Plots of maximum topographic elevation versus distance for each sector are given in Figure I.4-2.

i. Intermittent gaseous releases at Point Beach Nuclear Plant occur from containment purges and gas decay tank releases. A summary of containment purge experience from January 1, 1974, to February 29, 1976, is presented in Table I.6-4. Gas decay tank releases are summarized in Table I.6-5.

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10 CFR 50 Appendix I Analysis FSAR Appendix I.7 (Historical)

I.7 COMPARISONS OF REPORTED AND CALCULATED RELEASES OF RADIOACTIVITY I.7.1 GASEOUS RELEASES Calculated annual gaseous releases are provided in Table I.7 -1 and are based on the methods and assumptions in Draft Regulatory Guide 1.BB. Reported Point Beach Nuclear Plant gaseous releases are provided for 1974 and 1975 by month in Table I.7-5 and by year in Table I.7-4.

a. Noble Gases The calculated annual release of noble gases for the two-unit plant is 690 Curies per year.

Comparing this value to the reported annual average releases of 27,000 Curies per year indicates disagreement by a factor of approximately 40. This disagreement is believed to be caused by a combination of radiation monitoring system background interference and assumptions in the model recommended by Draft Regulatory Guide 1.BB for calculation of releases.

The major release point for reported noble gas releases at Point Beach Nuclear Plant is the auxiliary building vent. This release point is monitored by a scintillation detector in the vent stack. The recorded output of this monitor is used to calculate total noble gas releases for the vent. The detector is shielded so small increases in ambient external background radiation levels will not increase the reported noble gas releases. Internal stack contamination or large increases in background radiation may increase the reported amount. Plant practice has been to account for these background changes where the duration and effects can be quantified, however, this cannot be done in all instances. As a result, reported releases of noble gases are conservatively high.

Also, as a backup, a SPING pallet continuously draws samples off the vent stack.

The model recommended by Draft Regulatory Guide 1.BB accounts for noble gas releases from system leakage only via the leakage of undegassed liquids. Plant experience indicates that small leaks can occur from systems containing radioactive gases, such as the cover gas system. The radioactivity of these gases may be several orders of magnitude higher on a per volume basis than the noble gas radioactivity of undegassed liquids; hence a very small gaseous leak can result in significant noble gas releases. Since the model does not consider this potential the releases predicted by the model may not be compared to our experiences. A gaseous leak term for the model would be difficult to quantify since in most cases the volumetric leak rates of gaseous systems are so small that measurement is impracticable. Nevertheless, some allowance should be made for gaseous leaks to avoid setting design or operating objectives based on a release model which may not include all normal operating occurrences.

The reported releases are conservatively high because of the inclusion of a portion of radiation monitor background in determining noble gas releases while the calculated releases based on the model may be low because of the inability of the model to account for small gaseous leaks.

Further refinements in both areas should result in calculated releases approaching actual plant releases.

Reference to Table I.8-5 indicates that the dose based on calculated noble gas releases is approximately 0.03 millirems per year to the total body of an offsite individual. Adjusting this to the reported releases would result in a calculated dose on the order of 1 millirem per year. Both calculated doses are well within the design objective of 5 millirem per year.

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10 CFR 50 Appendix I Analysis FSAR Appendix I.7 (Historical)

b. Iodines The calculated annual release of radioactive iodine for the plant is 0.3 Curies per year. This value compares favorably with reported iodine releases of 0.14 Curies per year on an annual average basis. The disagreement by a factor of 2 is not significant and may be the result of the lower fuel defect level during actual operation.

c. Particulates The calculated annual release of particulate material for the plant is approximately 0.007 Curies per year while the reported releases for the plant are approximately 0.03 Curies per year on an annual average basis. The disagreement by a factor of approximately 4 arises primarily from higher than normal Cesium-138 during one month in the 1974 - 1975 period. Cesium-138 is a short-lived isotope not predicted by the model in Draft Regulatory Guide 1.BB. Cesium-138 is of negligible dose significance and the factor of 4 disagreement is not significant.

d. Tritium Calculated tritium releases based on Draft Regulatory Guide 1.BB are 610 Curies per year via gaseous pathways compared to reported releases of 110 Curies per year on an annual average basis. The disagreement by a factor of 6 is due to the assumption in Draft Regulatory Guide 1.BB that half the tritium produced is released in gaseous effluents. The difference is not significant since the dose significance of tritium is small.

I.7.2 LIQUID RELEASES

a. Gross Radioactivity (excluding tritium)

Calculated annual liquid releases are provided in Table I.7-2 and Table I.7-3. Reported Point Beach Nuclear Plant releases for 1974 and 1975 are provided in Table I.7-6.

The calculated releases from Point Beach Nuclear Plant, excluding tritium and dissolved noble gases, are 3.2 Curies per year for the two unit plant, while the reported annual average is approximately 1 Curie per year for 1974 and 1975. The disagreement by approximately a factor of 3 is the result of the higher fuel defect assumptions and the 0.3 Curies for anticipated operational occurrences in the model recommended by Draft Regulatory Guide 1.BB.

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10 CFR 50 Appendix I Analysis FSAR Appendix I.8 (Historical)

I.8 CALCULATIONS OF DOSES TO MAN I.8.1 DOSE MODELS - OFFSITE INDIVIDUALS Doses are calculated using the dose models contained in Regulatory Guide 1.109 (Reference 1) in the evaluation of potential doses to individuals in the vicinity of Point Beach Nuclear Plant.

Pathways not considered in Reference 1 or methods differing from Reference 1 are described in the dose models and assumptions presented below.

Included in this evaluation are dose assessments of three pathway categories: 1) pathways associated with releases of liquid effluents to Lake Michigan, 2) the direct exposure from releases of noble gases to the atmosphere, and 3) pathways associated with radioiodines, particulates, carbon-14, and tritium releases to the atmosphere.

1. Liquid Effluents A condenser circulating water flow rate of 644 cubic feet per second (290,000 gallons per minute) for the release streams is used in the calculation of all doses due to liquid effluents and is based on plant operating records for 1974 and 1975. All usage factors are taken from Table A-2 of Reference 1 unless otherwise noted.

1. Swimming and Boating For boating and swimming, the COHORT-II Monte Carlo Radiation Transport Code (Reference 2) has been used to calculate dose rates to boaters and swimmers. The gamma energy spectrum is based on the eighteen-group of the DLC-23/CASK library (Reference 3). The source radioactivity used for boating and swimming is the radioactivity in the discharge diluted by a factor of 5 to account for near-field dilution in the mixing zone.

The boating model assumes a disc source 50 feet in diameter with a thickness of 3 feet.

Dose rates are calculated at points 1, 2, and 3 feet above the water to approximate the location of boaters. Attenuation by the boat is neglected.

The calculated dose rate is nearly constant at the three receptor points considered, indicating that the source model is essentially semi-infinite in this analysis. These dose rate levels are approximately half the submerged dose rates calculated for swimmers.

Usage factors for boating of 52 hours6.018519e-4 days 0.0144 hours 8.597884e-5 weeks 1.9786e-5 months per year for teen and adult age groups and 29 hours3.356481e-4 days 0.00806 hours 4.794974e-5 weeks 1.10345e-5 months per year for child are used as suggested by Reference 1.

The Monte Carlo program is used to calculate the dose rate for swimming. A cylindrical source 10 feet in diameter is enclosed in an annular mass of water 20 feet in diameter. The source region was limited to the 10 feet diameter cylinder. The 20 feet diameter outer cylinder is added to include backscattering into the source region in the Monte Carlo analysis. A receptor point 2 feet below the surface is used. The calculated submerged dose rate is approximately twice the dose rate above the surface of the water.

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10 CFR 50 Appendix I Analysis FSAR Appendix I.8 (Historical)

The swimming pathway is not considered in Reference 1. A usage factor of 100 hours0.00116 days 0.0278 hours 1.653439e-4 weeks 3.805e-5 months per year is used for the adult and teen age groups. A usage factor of 56 hours6.481481e-4 days 0.0156 hours 9.259259e-5 weeks 2.1308e-5 months per year is used for the child age group.

2. Ingestion of Potable Water The Green Bay, Wisconsin, potable water intake is located in Lake Michigan approximately 13 miles north of the Point Beach site and the Two Rivers, Wisconsin, potable water intake is located approximately 12 miles south of the site. As part of intensive non-radiological environmental surveillance programs(4) the lake current characteristics have been determined in the vicinity of the site. These studies indicate highly variable lake current direction; therefore, dilution factors at both intakes were evaluated and found to be approximately equal. Since the Two Rivers, Wisconsin, intake is nearest the site, this intake is considered in the evaluation; however, calculated ingestion doses would also be applicable to any individual using Green Bay, Wisconsin, potable water.

The calculational methods for determining lake dilution factors are described in Section 5.

A far-field dilution factor of 10 is calculated at the Two Rivers intake. Using a near-field dilution factor of 5 and a factor of 2 to account for variable current direction, the total dilution factor at the Two Rivers intake is 100. In addition to this dilution, a decay time of 44 hours5.092593e-4 days 0.0122 hours 7.275132e-5 weeks 1.6742e-5 months is assumed (based on lake current measurements) and an additional 12 hours1.388889e-4 days 0.00333 hours 1.984127e-5 weeks 4.566e-6 months decay is assumed during transport of water through the purification plant. No credit is taken for removal of radioactivity by water treatment processes.

Ingestion of potable water is assumed to be 730 liters per year for adults and 510 liters per year for all other age groups.

3. Ingestion of Fish For the maximum individual case, fish are assumed to be caught at the edge of the initial mixing zone. The appropriate mixing zone dilution factor is 5, as suggested by Reference 1. A holdup time of 24 hours2.777778e-4 days 0.00667 hours 3.968254e-5 weeks 9.132e-6 months between catching and eating fish is assumed. The consumption of fish is assumed to be 21, 16, and 6.9 kilograms per year for an adult, teen and child, respectively.

4. Shoreline Recreation A point 1500 meters south is the closest point to the site at which this pathway exists. A decay time of 3.4 hours4.62963e-5 days 0.00111 hours 6.613757e-6 weeks 1.522e-6 months is assumed and a total dilution factor of 878 at the shoreline is calculated in accordance with the models presented in Section 5. Usage factors of 12, 67, and 14 hours1.62037e-4 days 0.00389 hours 2.314815e-5 weeks 5.327e-6 months per year are used for an adult, teen, and child, respectively. The shore width factor is assumed to be 0.

5. Ingestion of Invertebrates Doses for ingestion of invertebrates are not calculated for Point Beach Nuclear Plant.

There is no known fishery in the area for invertebrates.

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10 CFR 50 Appendix I Analysis FSAR Appendix I.8 (Historical)

6. Ingestion of Leafy Vegetables For the maximum individual case, leafy vegetables are assumed to be irrigated from the potable water supply of the City of Two Rivers. The dilution factor is 100 and the consumption is 64, 42 and 26 kilograms per year for the adult, teen, and child, respectively.

A holdup time of 24 hours2.777778e-4 days 0.00667 hours 3.968254e-5 weeks 9.132e-6 months is assumed between harvesting and eating leafy vegetables.

7. Ingestion of Stored Vegetables For the maximum individual case, non-leafy stored vegetables are assumed to be irrigated from the Two Rivers potable water supply with a dilution factor of 100. The consumption is assumed to be 520, 630, and 520 kilograms per year for the adult, teen, and child, respectively. A holdup time of 60 days is assumed between harvesting and consumption.

8. Ingestion of Cow's Milk For the maximum individual case, cow's milk is assumed to be produced at a farm which gets drinking and irrigation water from the potable water supply of the City of Two Rivers.

A dilution factor of 100 is assumed. Consumption of cow's milk is assumed to be 310, 400, 330, and 330 liters per year for the adult, teen, child, and infant, respectively. A hold up time of 2 days is used between production and consumption.

9) Ingestion of Meat Meat for the maximum individual is assumed to be produced from an animal at a farm which gets drinking and irrigation water from the potable water supply of Two Rivers. A dilution factor of 100 is assumed. The consumption is 110, 65, and 41 kilograms per year for the adult, teen, and child, respectively. A holdup time of 20 days is used between slaughter and consumption.

b. Gaseous Effluents All dose pathways from gaseous releases are calculated using the methods and parameters described in Reference 1. The following pathways are considered:

1. Noble Gas Releases The maximum individual is assumed to be at the nearest residence in the south-southwest direction at a distance of 1460 meters for total body and beta skin doses. For gamma and beta air doses, the maximum individual is assumed to be at the site boundary in the south direction at a distance of 1270 meters. Annual average X/Q values are used.

2. Inhalation The maximum individual is assumed to be at the nearest residence at a distance of 1460 meters in the south-southwest direction. Annual average X/Q values are applied for this location. Breathing rates of 7300, 5100, 2700, and 1900 m3/yr are assumed for the adult, teen, child, and infant, respectively.

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10 CFR 50 Appendix I Analysis FSAR Appendix I.8 (Historical)

3. Ingestion of Leafy Vegetables For doses from ingestion of leafy vegetables, a garden is assumed to be at the nearest residence in the south-southwest direction at a distance of 1460 meters. Growing season X/Q's and deposition rates are applied based on a growing season of 6 months.

Concentrations of tritium and carbon-14 in the vegetables are calculated using X/Q values as recommended in Reference 1. The consumption is assumed to be the same as for the liquid pathway.

4. Ingestion of Stored Vegetables Stored vegetables are grown at the same location as leafy vegetables and use the same X/Q's and deposition rates. Consumption of stored vegetables is assumed to be the same as for the liquid pathway.

5. Ingestion of Cow's Milk A cow is assumed to be at the site boundary in the SSE direction at a distance of 1300 meters. A six month grazing season is assumed. Growing season X/Q's and deposition rates are applied. Concentrations of tritium and carbon-14 in the vegetation which the animal consumes are calculated using X/Q values as recommended in Reference 1. The consumption of cow's milk is assumed to be the same as for the liquid pathway.

6. Ingestion of Goat's Milk A milk goat is assumed to be at the same location as the milk cow. The X/Q's and deposition rates for the cow's milk pathway are used for this pathway. Consumption of goat's milk is assumed to be 310, 400, 330, and 330 liters per year for the adult, teen, child, and infant, respectively.

7. Ingestion of Meat A meat animal is assumed to be at the same location as the milk cow. The X/Q's and deposition rates for the cow's milk pathway are used for this pathway. A six month grazing season is assumed. Consumption of meat is assumed to be the same as for the liquid pathways.

8. Standing on Contaminated Ground The maximum individual is assumed to be in the south-southwest direction at a distance of 1460 meters. Annual deposition rates are applied for this location, and an occupancy and shielding factor of 0.7 is assumed.

I.8.2 DOSE MODELS - ONSITE INDIVIDUALS Note: The following is historical because there are no longer any occupied residences within the site boundary.

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10 CFR 50 Appendix I Analysis FSAR Appendix I.8 (Historical)

Three occupied residences exist within the Point Beach Nuclear Plant site boundary which are owned by the Licensees and which are occupied only by families of plant employees. Since some (but not all) pathways exist for potential exposure of these individuals to releases from the plant, hypothetical doses have been calculated for onsite individuals in all age groups at the maximum location. No calculations are performed for ingestion of fresh or stored vegetables (liquid release pathway only), ingestion of cow or goat milk, and ingestion of meat since these pathways either cannot exist or are known not to exist for these individuals.

For the remainder of the potential pathways, the calculated doses are for individuals in the WNW sector at a distance of 1250 meters from the plant. Calculated doses for recreational activities such as fishing, swimming, and boating are identical to those for offsite individuals. Dose models for appropriate pathways are identical to those for offsite individuals except as modified by distance from release points.

I.8.3 CALCULATED DOSES Calculated doses to offsite individuals are provided in Table I.8-1 through Table I.8-4 for radioiodine and particulates in gaseous effluents. Calculated doses to offsite individuals from liquid effluents are provided in Table I.8-6 through Table I.8-9. Calculated doses to offsite and onsite individuals from noble gas releases are provided in Table I.8-5.

Calculated doses to onsite individuals for radioiodine and particulates in gaseous releases are provided in Table I.8-10 through Table I.8-13. Calculated doses to onsite individuals from liquid effluents can be obtained from Table I.8-6 through Table I.8-9 by summing the fish ingestion, swimming, boating and shoreline pathways.

The replacement of the Retention Pond by the conveyor-type filtration units does not have an adverse effect upon the calculated doses. Only the path has changed, with the function of the Retention Pond as a settling basin replaced by active filtration through the new equipment.

I.

8.4 REFERENCES

1. 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, Appendix I, March, 1976, U. S. Nuclear Regulatory Commission, Washington, D.C.

2. L. Soffer and L. Clemons, Jr., COHORT-II-A Monte Carlo General Purpose Shielding Computer Code, CCC-198, Union Carbide Corporation, April, 1971.

3. G. W. Morrison, E. A. Straker, and R. H. Obegaarden, A Coupled Neutron and Gamma-Ray Multigroup Cross Section Library For Use In Shielding Calculations, Trans. American Nuclear Society, 15, 535, 1972.

4. Point Beach Nuclear Plant Non-Radiological Environmental Surveillance Program, Wisconsin Electric Power Company and Wisconsin Michigan Power Company, Annual Reports 1, 2 and 3 covering the period from November, 1972 through October, 1975.

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Summary FSAR Appendix I.9 (Historical)

I.9

SUMMARY

Calculations of radioactive releases and potential doses to individuals have been performed in accordance with models in Nuclear Regulatory Commission Regulatory Guides. The potential doses are calculated for each pathway through which exposure might be realized for various individuals. These pathways are then combined, as appropriate, to estimate the potential dose to a hypothetical individual exposed to all pathways. A comparison of calculated doses with the design objectives is given in Table I.9-1 for offsite individuals and for onsite individuals. All calculated doses are within the design objectives and are as low as reasonably achievable.

I.9.1 GASEOUS RELEASES Calculated gamma and beta air doses at the site boundary are 0.06 and 0.07 millirads per year, respectively, and are a small fraction of the design objectives of 10 and 20 millirads per year for gamma and beta dose rates.

Calculated total body and skin doses to an offsite individual are 0.03 and 0.06 millirems per year, respectively. These doses are a small fraction of the design objectives of 5 and 15 millirems per year to the total body and skin, respectively. Corresponding calculated doses to an onsite resident are 0.02 millirems per year total body, and 0.04 millirems per year to the skin. These calculated doses are also well within the design objectives.

The maximum calculated dose to any organ of an offsite individual from all pathways for radioiodine and particulates is 15 millirem per year to the thyroid and is equal to the design objective of 15 millirem per year. The maximum hypothetical individual for this case is an offsite infant residing at a distance of 1,460 meters in the south-southwest sector and ingesting 330 liters per year of goat's milk in addition to being exposed to radioactivity in air and on the ground. The calculated dose for the same infant ingesting an equivalent volume of cow's milk is 12 millirems per year. In either case, the design objective is met.

The calculated dose to any organ of an onsite resident is 0.82 millirems per year to the child thyroid. This calculated dose is well within the design objective of 15 millirems per year. Since all conservatively calculated doses from gaseous releases are within the design objectives it is concluded that gaseous waste processing systems and ventilation system filtration equipment at Point Beach Nuclear Plant will continue to maintain releases as low as reasonably achievable and further augmentation is not required.

I.9.2 LIQUID RELEASES

a. Calculated Doses The highest calculated total body dose is 0.19 millirem per year for a hypothetical adult.

Essentially all of this dose is calculated to be from eating fish living at the edge of the initial mixing zone in the surface plume near the plant. The calculated doses are well within the design objective of 5 millirem per year.

The highest calculated dose to any organ from liquid pathways is 0.26 millirem per year to the liver of an offsite teenage individual. The major portion of this dose is calculated to be from the same fish pathway as for the adult. This calculated dose is well within the design objective of 5 millirems per year.

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Summary FSAR Appendix I.9 (Historical)

b. Calculated Releases Actual plant liquid releases for 1974 and 1975 average approximately 1 Curie per year and calculated releases are 3.2 Curies per year. These releases are well within the design objective of 5 Curies per year per reactor (10 Curies per year for the plant).

Because the doses and Curie releases via liquid pathways are much less than the design objectives there is no need to further augment liquid waste systems to continue to maintain releases as low as is reasonably achievable.

I.9.3 IMPACT OF UPRATED POWER OPERATIONS Scaling techniques, based on NUREG-0017, Revision 1 methodology, were used to assess the impact of core power uprate on radioactive gaseous and liquid effluents at PBNP.

As described in Reference 1, the conservatively performed power uprate analysis used the plant core power operating history during the years 2002 to 2006, the reported liquid effluent and dose data during that period, NUREG-0017 equations and assumptions, and conservative methodology, to estimate the impact of operation at the analyzed uprate core power level of 1811 MWt on radio-active gaseous and liquid effluents, and normal operation off-site doses.

The licensed reactor core power level prior to 2003 was 1518.5 MWt. The core power was increased to 1540 MWt at the end of 2002. For the uprate condition, the system parameters used in the power uprate analysis reflected the flow rates and coolant masses at an analyzed core power level of 1811 MWt. For the pre-uprate condition, the evaluation used offsite doses based on an average 5 year set of organ and whole body doses calculated using data presented in the PBNP Annual Radioactive Effluent Release Reports for the years 2002 through 2006, taking into consideration the associated average annual core power level, extrapolated to 100 percent avail-ability at the licensed power level.

Using the methodology and equations found in NUREG-0017, Revision 1, and based on a comparison of the change in power level and in plant coolant system parameters (e.g., reactor coolant mass, steam generator liquid mass, steam flow rate, reactor coolant letdown flow rate, flow rate to the cation demineralizer, letdown flow rate for boron control, steam generator blowdown flow rate, steam generator moisture carryover, etc.) for both pre-uprate and uprate conditions, the maximum potential percentage increase in coolant activity levels due to the uprate for each chemical group identified in NUREG-0017 was estimated.

To estimate an upper bound impact on off-site doses, the highest factor found for any chemical group pertinent to the release pathway was applied to the average doses previously determined as representative of operation at pre-uprate conditions. This approach was utilized to estimate the maximum potential increase in effluent doses due to the uprate, and demonstrate that the estimated off-site doses following the uprate, although increased, will continue to remain below the regulatory limits set by 10 CFR 50, Appendix I. Reference 1 shows that based on operating history, the maximum estimated dose due to gaseous liquid radwaste effluents following power uprate will continue to remain significantly below the annual design objectives for gaseous and liquid radwaste effluents set by 10 CFR 50 Appendix I.

It is noted that actual gaseous and liquid effluent isotopic release and dose information are provided in the PBNP Annual Radioactive Effluent Release Reports.

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Summary FSAR Appendix I.9 (Historical)

I.9.4 REFERENCE

1. Shaw Calculation 129187-M-0104, Impact of EPU on Normal Operation Gaseous and Liquid Radioactive Effluent Releases, dated March 26, 2009.

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FSAR Appendix I Tables and Figures (Historical)

Table I.2-1 SOURCES AND EXPECTED RADIOACTIVITY OF LIQUID WASTES AT POINT BEACH NUCLEAR PLANT EXPECTED FRACTION (2)

OF PRIMARY COOLANT EXPECTED FRACTION TO SOURCE RATE TOTAL (1) RADIOACTIVITY BE RELEASED (gal/day) (gal/yr)

Primary System Waste Containment Sumps 80 29,200 1.0 1.0 Auxiliary Building Drains 400 146,000 0.1 1.0 Laboratory Drains 400 146,000 0.002 1.0 Sampling Drains 70 25,550 1.0 1.0 Detergent Wastes 450 164,250 < 0.0001 Ci/yr 1.0 Miscellaneous 1,400 511,000 0.01 1.0 Anticipated Occurrences - 4,000 0.30 Ci/yr 1.0 Total 2,800 1,026,000 Secondary System Waste Turbine Building Floor Drains 14,400 5,250,000 Steam Condensate 1.0 Secondary System Sampling 5,000 1,820,000 Steam Condensate 1.0 Steam Generator Blowdown 144,000 42,050,000 0.1 x Steam Generator Blowdown 1.0 Total 163,400 49,120,000 Other Letdown to CVCS Holdup Tanks 3,290 1,200,000 1.0 0.53 (1) Assumes 365 days per year for both Unit 1 and Unit 2 except for steam generator blowdown which is adjusted for 80 percent capacity factor.

(2) All fractions for primary system waste are related to degassed primary coolant concentrations and are prior to processing in radioactive liquid waste systems and related systems.

UFSAR 2018 Page 1 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.2-2 CAPACITIES USED IN CALCULATING HOLDUP TIMES FOR RADIOACTIVE LIQUIDS WASTE SOURCE COMPONENT TOTAL PROCESS RATE OR VOLUME RATE OR VOLUME USED Primary System Waste Waste Holdup Tank 21,000 gal. 8,400 gal.

Waste Evaporator 35 gal./min. 35 gal./min.

Waste Condensate Tanks 10,000 gal. each 8,000 gal.

Waste Condensate Pumps 75 gal./min. each 150 gal./min.

Other Letdown to CVCS Holdup Tanks 58,000 gal. each 69,600 (1)

Holdup Tanks Boric Acid Evaporator 12.5 gal./min. 12.5 gal./min.

Monitor Tanks 10,000 gal. each 8,000 gal.

Monitor Tank Pumps 60 gal./min. each 120 gal./min.

(1) Based on sharing of three tanks by Units 1 and 2.

UFSAR 2018 Page 2 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.2-3 CALCULATED HOLDUP TIMES FOR COLLECTION, PROCESSING AND RELEASE SOURCE CALCULATED HOLDUP TIME (1)

(Days)

Primary System Containment Sumps 3.2 Auxiliary Building Drains 3.2 Laboratory Drains 3.2 Sampling Drains 3.2 Detergent Wastes 3.2 Miscellaneous 3.2 Anticipated Operational Occurrences Not Applicable Secondary System Turbine Building Floor Drains 30 Secondary System Sampling 30 Steam Generator Blowdown Negligible Other Letdown to CVCS Holdup Tanks 46.2 (2)

(1) Calculated holdup times are based on methods recommended by Draft Regulatory Guide 1.BB.

(2) Based on sharing of three holdup tanks by Units 1 and 2.

UFSAR 2018 Page 3 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.2-4 POINT BEACH NUCLEAR PLANT RELEASE POINT DESCRIPTIONS Sheet 1 of 3 Outside Design Temperature: -15°F (Winter) and 95°F (Summer)

1. UNIT 1 PURGE VENT Diameter = 36 Flow = 12,500 to 25,000 cfm for purging and 10 cfm for continuous venting.

Exit Velocity = 20.1 to 40.2 miles per hour for purging.

Elevation = 168 0 Height = 142 0 above finished grade 26 0 Location = NE corner of Unit 1 facade Facade Elevation = 161 6 Design Temperatures:

Operating = 105°F (Winter) and 105°F (Summer)

Shutdown = 50°F (Winter) and 105°F (Summer)

Adjacent Structures:

N - Aux. Bldg. (el. 111 9) and Unit 2 facade (el. 161 6)

E - Service Bldg. and Turbine Bldg. (el. 111 9)

S - None W - None

2. UNIT 2 PURGE VENT Diameter = 36 Flow = 12,500 to 25,000 cfm for purging, 400 to 12,000 cfm for gas stripper bldg. ventilation, and 10 cfm for continuous venting.

Exit Velocity = 20.1 to 40.2 miles per hour for purging and 0.6 to 19.3 miles per hour for gas stripper bldg. ventilation.

Elevation = 168 0 Height = 142 0 above finished grade 26 0 Location = SE corner of Unit 2 facade Facade Elevation = 161 6 Design Temperatures:

Operating = 105°F (Winter) and 105°F (Summer)

Shutdown = 50°F (Winter) and 105°F (Summer)

Adjacent Structures:

N - None E - Service Bldg. and Turbine Bldg. (el. 111 9)

S - Aux. Bldg. (el. 111 9) and Unit 1 facade (el. 161 6)

W - None UFSAR 2018 Page 4 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.2-4 POINT BEACH NUCLEAR PLANT RELEASE POINT DESCRIPTIONS Sheet 2 of 3

3. DRUMMING AREA VENT Diameter = 46 Flow = 43,100 cfm Exit Velocity = 42.4 miles per hour Elevation = 168 0 Height = 142 0 above finished grade 26 0 Location = NW corner of Unit 1 facade Facade Elevation = 161 6 Design Temperatures: = 65°F (Winter) and 85°F (Summer)

Adjacent Structures:

N - Aux. Bldg. (el. 111 9) and Unit 2 facade (el. 161 6)

E - Service Bldg. and Turbine Bldg. (el. 111 9)

S - None W - None

4. AUXILIARY BUILDING VENT Diameter = 54 Flow = 61,400 cfm Exit Velocity = 43.9 miles per hour Elevation = 168 0 Height = 142 0 above finished grade of 26 0 Location = SE corner of Unit 1 facade Facade Elevation = 161 6 Design Temperatures: = 65°F (Winter) and 85°F (Summer)

Adjacent Structures:

N - Aux. Bldg. (el. 111 9) and Unit 2 facade (el. 161 6)

E - Service Bldg. and Turbine Bldg. (el. 111 9)

S - None W - None UFSAR 2018 Page 5 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.2-4 POINT BEACH NUCLEAR PLANT RELEASE POINT DESCRIPTIONS Sheet 3 of 3

5. TURBINE BUILDING ROOF EXHAUSTERS (19)

Diameter = NA no credit taken for elevated Flow = 47,000 cfm each -- release; ground release Exit Velocity = NA assumed Elevation = Approximately 110 (elevation of turbine building roof)

Height = Approximately 84 above finished grade of 26 0 Location = Evenly spaced along a north-south line atop the turbine building Design Temperatures: = 65°F (Winter) and 115°F (Summer)

Adjacent Structures:

N - None E - None S - None W - Facade Structures (el. 161 6)

UFSAR 2018 Page 6 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.3-1 COMPARISONS WITH PARAMETERS USED TO DESCRIBE THE REFERENCE PRESSURIZED WATER REACTOR WITH U-TUBE STEAM GENERATORS NOMINAL RANGE PBNP PARAMETER SYMBOL UNITS VALUE MAXIMUM MINIMUM VALUE Thermal Power P MWt 3400 3800 3000 1518.5 Steam Flow Rate FS lbs/hr 1.5(7) 1.7(7) 1.3(7) 6.62(6)

Weight of water in reactor coolant system SP lbs 5.5(5) 6.0(5) 5.0(5) 2.75(5)

Weight of water in all steam generators WS lbs 4.5(5) 5.0(5) 4.0(5) 1.60(5)

Reactor coolant letdown flow (purification) FD - lbs/hr 3.7(4) 4.2(4) 3.2(4) 1.98(4)

Reactor coolant letdown flow (yearly average for boron control) FB lbs/hr 500 1000 250 564 Steam Generator blowdown flow (total) FBD lbs/hr Volatile 75,000 100,000 50,000 25,000 Fraction of radioactivity in blowdown stream which is not returned to the secondary coolant system NBD - 1.0 1.0 0.9 1.0 Flow through the purification system cation demineralizer FA lbs/hr 3700 7500 0.0 0.0 Ratio of condensate demin eralizer flow rate to the total steam flow rate NC -

Volatile 0.65 0.75 0.55 0.0 Ratio of the total amount of noble gases routed to gaseous radwaste from the purification system to the total amount of noble gases routed from the primary coolant system to the purification system (not including the boron 0.0 Kr-85 recovery system) Y - 0.0 0.01 0.0 1.0 All Others UFSAR 2018 Page 7 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.3-2 POINT BEACH NUCLEAR PLANT CALCULATED SOURCE TERM CONCENTRATIONS (Ci/gm)

Sheet 1 of 3 Reactor Coolant Steam Generator Steam Generator Isotope (Ci/gm) Liquid (Ci/gm) Steam (Ci/gm)

NOBLE GASES Kr-83m 1.7E-02 0.0 1.1E-08 Kr-85m 7.2E-02 0.0 4.6E-08 Kr-85 5.9E-02 0.0 3.8E-08 Kr-87 5.2E-02 0.0 3.1E-08 Kr-88 1.5E-01 0.0 9.3E-08 Kr-89 4.9E-03 0.0 3.1E-09 Xe-131m 4.3E-03 0.0 2.7E-09 Xe-133m 3.2E-02 0.0 2.0E-08 Xe-133 1.3E+00 0.0 8.2E-07 Xe-135m 1.3E-02 0.0 7.9E-09 Xe-135 1.7E-01 0.0 1.1E-07 Xe-137 8.9E-03 0.0 5.6E-09 Xe-138 4.3E-02 0.0 2.6E-08 HALOGENS Br-83 4.6E-03 2.2E-07 2.2E-09 Br-84 2.6E-03 2.5E-08 3.5E-10 Br-85 3.0E-04 5.6E-10 5.6E-12 I-130 1.9E-03 1.9E-07 1.9E-09 I-131 2.3E-01 2.7E-05 2.7E-07 I-132 9.6E-02 5.8E-06 5.8E-08 I-133 3.3E-01 3.8E-05 3.8E-07 I-134 4.6E-02 1.0E-06 1.0E-08 I-135 1.8E-01 1.4E-05 1.4E-07 UFSAR 2018 Page 8 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.3-2 POINT BEACH NUCLEAR PLANT CALCULATED SOURCE TERM CONCENTRATIONS (Ci/gm)

Sheet 2 of 3 CS, RB Rb-86 7.6E-05 1.2E-08 1.2E-11 Rb-88 2.0E-01 1.7E-06 1.7E-09 Cs-134 2.2E-02 3.2E-06 3.2E-09 Cs-136 1.2E-02 1.8E-06 1.8E-09 Cs-137 1.6E-02 2.6E-06 2.6E-09 WATER ACTIVATION PRODUCTS N-16 4.0E+01 2.8E-06 2.8E-06 TRITIUM H-3 1.0E+00 1.0E-03 1.0E-03 OTHER NUCLIDES Cr-51 1.6E-03 2.5E-07 2.5E-10 Mn-54 2.6E-04 5.6E-08 5.6E-11 Fe-55 1.3E-03 2.3E-07 2.3E-10 Fe-59 8.3E-04 1.7E-07 1.7E-10 Co-58 1.3E-02 2.3E-06 2.3E-09 Co-60 1.7E-03 2.5E-07 2.5E-10 Sr-89 2.9E-04 5.7E-08 5.7E-12 Sr-90 8.3E-06 1.1E-09 1.1E-12 Sr-91 5.9E-04 1.5E-08 1.5E-11 Y-90 1.4E-05 1.1E-09 1.1E-12 Y-91m 3.7E-04 8.5E-09 8.5E-12 Y-91 1.7E-03 2.5E-07 2.5E-10 Y-93 1.2E-01 5.9E-09 5.9E-12 Zr-95 5.0E-05 1.1E-08 1.1E-11 Nb-95 4.1E-05 1.1E-08 1.1E-11 Mo-99 3.8E-01 2.0E-05 2.0E-08 UFSAR 2018 Page 9 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.3-2 POINT BEACH NUCLEAR PLANT CALCULATED SOURCE TERM CONCENTRATIONS (Ci/gm)

Sheet 3 of 3 Tc-99m 3.5E-01 1.8E-05 1.8E-08 Ru-103 3.7E-05 5.7E-09 5.7E-12 Ru-106 8.3E-06 1.1E-09 1.1E-12 Rh-103m 4.4E-05 5.7E-09 5.7E-12 Rh-106 9.9E-06 1.1E-09 1.1E-09 Te-125m 2.4E-05 1.7E-09 1.7E-12 Te-127m 2.3E-04 2.8E-08 2.8E-11 Te-127 7.7E-04 8.8E-08 8.8E-11 Te-129m 1.2E-03 1.7E-07 1.7E-10 Te-129 1.6E-03 1.7E-07 1.7E-10 Te-131m 2.2E-03 2.9E-07 2.9E-10 Te-131 1.1E-03 5.6E-08 5.6E-11 Te-132 2.3E-02 2.9E-06 2.9E-09 Ba-137m 1.6E-02 2.5E-06 2.5E-09 Ba-140 1.8E-04 2.8E-08 2.8E-11 La-140 1.3E-04 2.0E-08 2.0E-11 Ce-141 5.8E-05 1.1E-08 1.1E-11 Ce-143 3.5E-05 2.9E-09 2.9E-12 Ce-144 2.7E-05 5.6E-09 5.6E-12 Pr-143 4.2E-05 5.7E-09 5.7E-12 Pr-144 3.3E-05 5.6E-09 5.6E-12 Np-239 1.0E-03 1.7E-07 1.7E-10 UFSAR 2018 Page 10 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.3-3 POINT BEACH NUCLEAR PLANT CALCULATED SOURCE TERM ACTIVITIES (Ci)

Sheet 1 of 3 Reactor Steam Generators Isotope Coolant (Ci) Liquid (Ci)

NOBLE GASES Kr-83m 1.9E+00 0.0 Kr-85m 8.1E+00 0.0 Kr-85 6.7E+00 0.0 Kr-87 5.8E+00 0.0 Kr-88 1.7E+01 0.0 Kr-89 5.5E-01 0.0 Xe-131m 4.8E-01 0.0 Xe-133m 3.6E+00 0.0 Xe-133 1.5E+02 0.0 Xe-135m 1.4E+00 0.0 Xe-135 1.9E+01 0.0 Xe-137 1.0E+00 0.0 Xe-138 4.8E+00 0.0 HALOGENS Br-83 5.2E-01 1.6E-05 Br-84 2.9E-01 2.5E-06 Br-85 3.3E-02 4.1E-08 I-130 2.1E-01 1.4E-05 I-131 2.5E+01 2.0E-03 I-132 1.1E+01 4.3E-04 I-133 3.8E+01 2.8E-03 I-134 5.2E+00 7.5E-05 I-135 2.0E+01 1.0E-03 CS, RB Rb-86 8.6E-03 8.9E-07 Rb-88 2.2E+01 1.3E-04 Cs-134 2.5E+00 2.3E-04 UFSAR 2018 Page 11 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.3-3 POINT BEACH NUCLEAR PLANT CALCULATED SOURCE TERM ACTIVITIES (Ci)

Sheet 2 of 3 Reactor Steam Generators Isotope Coolant (Ci) Liquid (Ci)

CS, RB Cs-136 1.3E+00 1.3E-04 Cs-137 1.8E+00 1.9E-04 WATER ACTIVATION PRODUCTS N-16 4.5E+03 2.0E-04 TRITIUM H-3 1.1E-02 7.3E-02 OTHER NUCLIDES Cr-51 1.8E-01 1.9E-05 Mn-54 2.9E-02 4.1E-06 Fe-55 1.5E-01 1.6E-05 Fe-59 9.3E-02 1.2E-05 Co-58 1.5E+00 1.6E-04 Co-60 1.9E-01 1.9E-05 Sr-89 3.3E-02 4.1E-06 Sr-90 9.3E-04 8.2E-08 Sr-91 6.6E-02 1.1E-06 Y-90 1.6E-03 8.3E-08 Y-91m 4.2E-02 6.2E-07 Y-91 1.9E-01 1.9E-05 Y-93 1.3E-02 4.3E-07 Zr-95 5.6E-03 8.2E-07 Nb-95 4.7E-03 8.2E-07 Mo-99 4.3E+01 1.5E-03 Tc-99m 4.0E+01 1.3E-03 Ru-103 4.2E-03 4.1E-07 UFSAR 2018 Page 12 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.3-3 POINT BEACH NUCLEAR PLANT CALCULATED SOURCE TERM ACTIVITIES (Ci)

Sheet 3 of 3 Reactor Steam Generators Isotope Coolant (Ci) Liquid (Ci)

OTHER NUCLIDES Ru-106 9.3E-04 8.2E-08 Rh-103m 5.0E-03 4.2E-07 Rh-106 1.1E-03 8.1E-08 Te-125m 2.7E-03 1.2E-07 Te-127m 2.6E-02 2.1E-06 Te-127 8.7E-02 6.4E-06 Te-129m 1.3E-01 1.2E-05 Te-129 1.8E-01 1.3E-05 Te-131m 2.4E-01 2.1E-05 Te-131 1.2E-01 4.1E-06 Te-132 2.6E+00 2.1E-04 Ba-137m 1.8E+00 1.8E-04 Ba-140 2.1E-02 2.1E-06 La-140 1.4E-02 1.5E-06 Ce-141 6.5E-03 8.2E-07 Ce-143 3.9E-03 2.1E-07 Ce-144 3.1E-03 4.1E-07 Pr-143 4.7E-03 4.1E-07 Pr-144 3.7E-03 4.1E-07 Np-239 1.1E-01 1.3E-05 UFSAR 2018 Page 13 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.4-1 POINT BEACH NUCLEAR PLANT ON-SITE WIND ROSE FOR 4/19/67 TO 4/18/69 (FREQUENCY PERCENT)

WIND SPEED CLASSIFICATIONS (MPH)

WINDS BLOWING FROM 1-3 4-7 8 - 12 13 - 18 19 - 24 25 TOTAL N 0.56 1.42 2.93 3.16 1.11 0.66 9.84 NNE 0.31 0.85 1.89 1.77 0.94 0.72 6.49 NE 0.36 1.02 1.28 1.28 0.47 0.29 4.71 ENE 0.40 0.66 0.51 0.44 0.27 0.12 2.40 E 0.62 0.79 0.44 0.33 0.13 0.16 2.46 ESE 0.52 0.66 0.44 0.17 0.20 0.05 2.05 SE 0.51 1.02 0.81 0.61 0.31 0.27 3.52 SSE 0.37 0.83 1.37 0.82 0.57 0.25 4.21 S 0.48 1.25 2.63 2.13 1.04 0.53 8.06 SSW 0.40 1.30 4.27 4.45 1.73 0.39 12.54 SW 0.44 1.50 3.47 2.27 0.46 0.12 8.24 WSW 0.26 0.83 1.78 1.30 0.38 0.13 4.69 W 0.42 1.14 2.23 2.40 0.91 0.60 7.70 WNW 0.32 1.13 2.88 3.52 1.37 0.43 9.65 NW 0.29 1.05 2.72 2.47 0.45 0.15 7.13 NNW 0.19 0.76 2.12 1.60 0.59 0.14 5.40 Total Observations = 14,647 Percentage of Calms = 0.91 UFSAR 2018 Page 14 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.4-2 POINT BEACH NUCLEAR PLANT

SUMMARY

OF ANNUAL AND GRAZING SEASON /Qs AND D/Qs FOR HIGHEST OFFSITE SECTORS Highest Sector for Nearest Resident Highest Sectors for Site Boundary & Animal Locations & Vegetable Garden Location Release Mode S Sector (1,270m) SSE Sector (1,300m) SSW Sector (1,460m)

Location Type /Q D/Q /Q D/Q /Q D/Q x 107 x 109 x 107 x 109 x 107 x 109 IA Auxiliary Building Continuous Conditionally A 4.01 13.3 A 3.11 20.1 A 2.86 5.90 Vent elevated GS 2.75 6.78 GS 2.08 11.7 GS 3.57 7.08 IB Auxiliary Building Intermittent Conditionally A 9.43 31.3 A 9.36 60.5 A 8.05 16.6 Vent (during gas elevated GS 7.34 18.1 GS 8.44 47.5 GS 9.00 17.8 decay tank releases IIA Unit 1 and Unit 2 Continuous Ground Level A 60.7 47.9 A 19.5 24.6 A 23.9 21.8 Purge Vent 10 cfm Vent GS 51.9 34.1 GS 13.1 14.7 GS 28.0 26.3 IIB Unit 1 and 2 Purge Intermittent Conditionally A 27.0 47.6 A 16.7 50.0 A 19.1 29.1 Vent (purge) elevated GS 22.1 33.2 GS 12.4 37.9 GS 20.7 30.1 IIC Gas Stripper Continuous Ground Level A 60.7 47.9 A 19.5 24.6 A 23.9 21.8 Building (through GS 51.9 34.1 GS 13.1 14.7 GS 28.0 26.3 Unit 2 Purge Vent)

III Turbine Building Continuous Ground Level A 70.4 47.9 A 21.0 24.6 A 26.6 21.8 Roof Exhausters GS 60.8 34.1 GS 14.1 14.7 GS 31.4 26.3 Notes: A = Annual Average; GS = Grazing or Growing Season, /Q in sec/m3; D/Q in m-2 UFSAR 2018 Page 15 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.4-3

POINT BEACH NUCLEAR PLANT ANNUAL GROWING SEASON /Qs AND D/Qs FOR ONSITE RESIDENTS Release Mode WNW Sector NNW Sector NNW Sector (1,250 meters) (1,880 meters) (1,980 meters)

Location Type /Q D/Q /Q D/Q /Q D/Q x 107 x 109 x 107 x 109 x 107 x 109 IA Auxiliary Building Continuous Conditionally A 0.732 3.91 A 1.49 3.90 A 1.40 3.39 Vent elevated GS 0.857 5.37 GS 1.89 4.31 GS 1.78 3.75 IB Auxiliary Building Intermittent Conditionally A 4.05 21.7 A 6.55 17.1 A 6.25 15.1 Vent (during gas elevated GS 4.31 27.2 GS 7.45 17.0 GS 7.11 15.0 decay tank releases IIA Unit 1 and Unit 2 Continuous Ground Level A 28.6 11.0 A 9.59 7.28 A 8.52 6.37 Purge Vent 10 cfm Vent GS 36.3 14.1 GS 13.1 9.18 GS 11.6 8.04 IIB Unit 1 and 2 Purge Intermittent Conditionally A 11.9 23.9 A 9.82 15.7 A 9.19 14.0 Vent (purge) elevated GS 12.8 28.8 GS 10.7 15.6 GS 10.1 14.0 IIC Gas Stripper Continuous Ground Level A 28.6 11.0 A 9.59 7.28 A 8.52 6.37 Building (through GS 36.3 14.1 GS 13.1 9.18 GS 11.6 8.04 Unit 2 Purge Vent)

III Turbine Building Continuous Ground Level A 32.4 11.0 A 10.6 7.28 A 9.38 6.37 Roof Exhausters GS 40.9 14.1 GS 14.6 9.18 GS 12.9 8.07 Notes: A = Annual Average; GS = Growing Season, /Q in sec/m3; D/Q in m-2

This table is historical because onsite residences have either been demolished or abandoned.

UFSAR 2018 Page 16 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.4-4 POINT BEACH NUCLEAR PLANT AUXILIARY BUILDING VENT, CONTINUOUS ELEVATED RELEASE (IA)

DATA PERIOD: 4/19/67 - 4/18/69

/Q (Sec/M3) at Various Receptor Distances (M)

Downwind Shoreline Site Nearest Nearest Sector Boundary Boundary Residence Farm 805 1,700 1,980 2,415 2,800 3,200 3,600 4,025 4,830 5,635 7,245 12,070 24,140 40,235 56,330 72,425 Order E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-08 E-08 E-08 E-09 E-09 E-09 SSE 3.37 3.11 1.84 3.11 3.74 2.19 1.78 1.34 1.08 0.896 0.754 0.640 0.483 0.380 2.53 1.16 0.464 2.41 1.56 1.12 S N/A 4.01 1.67 4.01 5.90 2.88 2.47 2.02 1.74 1.52 1.35 1.19 1.01 0.882 6.41 3.40 1.60 9.13 6.26 4.71 SSW N/A 3.17 2.86 2.22 4.09 2.65 2.46 2.12 1.78 1.52 1.31 1.13 0.869 0.697 4.87 2.22 1.02 5.55 3.69 2.72 SW N/A 2.43 2.16 2.39 2.61 2.15 2.16 1.95 1.70 1.47 1.30 1.14 0.791 0.582 3.62 1.67 0.818 4.35 2.86 2.09 WSW N/A 1.12 0.922 1.12 1.14 0.974 0.980 0.901 0.746 0.755 0.693 0.638 0.504 0.411 2.46 1.18 0.589 3.19 2.12 1.56 W N/A 0.885 0.844 0.885 1.06 0.907 0.902 0.841 0.834 0.815 0.784 0.740 0.581 0.473 2.64 1.49 0.765 4.06 2.67 1.95 WNW N/A 0.676 0.775 0.768 0.691 0.715 0.884 0.766 0.805 0.819 0.830 0.817 0.585 0.443 3.56 1.77 0.922 4.98 3.30 2.43 NW N/A 1.03 0.884 0.915 1.78 1.15 1.05 0.910 0.906 0.890 0.876 0.857 0.830 0.788 5.35 2.01 1.01 5.43 3.61 2.65 NNW 2.96 1.37 1.09 1.37 2.81 1.69 1.40 1.13 1.02 0.961 0.913 0.861 0.792 0.725 4.82 2.16 0.863 4.56 2.99 2.18 N 12.0 0.938 0.836 N/A 4.97 2.94 2.41 1.84 1.49 1.23 1.04 0.944 0.828 0.745 5.86 3.05 1.17 6.00 3.87 2.79 NNE 55.4 N/A N/A N/A 7.61 3.78 3.12 2.43 2.01 1.69 1.45 1.26 0.985 0.802 5.72 2.93 1.30 7.21 4.87 3.62 NE 47.7 N/A N/A N/A 4.22 1.81 1.52 1.23 1.06 0.924 0.820 0.732 0.605 0.513 3.90 2.22 1.09 6.40 4.45 3.38 ENE 23.3 N/A N/A N/A 2.58 1.27 1.06 0.831 0.696 0.593 0.515 0.450 0.360 0.298 2.18 1.17 0.547 3.11 2.13 1.60 E 45.2 N/A N/A N/A 5.06 2.17 1.75 1.34 1.10 0.921 0.791 0.685 0.542 0.446 3.25 1.75 0.815 4.64 3.18 2.39 ESE 29.7 N/A N/A N/A 7.92 3.44 2.67 1.93 1.51 1.22 1.01 0.848 0.637 0.502 3.44 1.67 0.706 3.82 2.54 1.87 SE 11.0 N/A N/A N/A 6.22 2.68 2.07 1.48 1.16 0.928 0.766 0.639 0.477 0.374 2.54 1.23 0.514 2.78 1.85 1.37 UFSAR 2018 Page 17 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.4-5 POINT BEACH NUCLEAR PLANT GROWING/GRAZING SEASON /Q AUXILIARY BUILDING VENT, CONTINUOUS ELEVATED RELEASE (IA)

DATA PERIOD: 4/19/67-10/18/67 AND: 4/19/68-10/18/68

/Q (Sec/M3) at Various Receptor Distances (M)

Downwind Shoreline Site Nearest Nearest Sector Boundary Boundary Residence Farm 805 1,700 1,980 2,415 2,800 3,200 3,600 4,025 4,830 5,635 7,245 12,070 24,140 40,235 56,330 72,425 Order E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-08 E-08 E-08 E-09 E-09 E-09 SSE 2.55 2.08 1.23 2.08 2.38 1.47 1.19 0.893 0.716 0.591 0.495 0.419 0.314 0.246 1.62 0.736 0.296 1.55 1.01 0.731 S N/A 2.75 1.19 2.75 4.20 1.98 1.71 1.41 1.23 1.08 0.968 0.862 0.750 0.672 5.00 2.77 1.37 7.95 5.52 4.19 SSW N/A 3.90 3.57 2.83 4.75 3.35 3.14 2.71 2.28 1.94 1.68 1.44 1.11 0.885 6.15 2.77 1.27 6.86 4.56 3.35 SW N/A 3.29 2.96 3.26 3.17 2.93 2.96 2.69 2.35 2.04 1.80 1.58 1.10 0.808 5.01 2.31 1.15 6.10 4.02 2.93 WSW N/A 1.29 1.22 1.29 1.11 1.20 1.27 1.21 1.02 1.06 0.989 0.922 0.737 0.604 3.62 1.75 0.888 4.84 3.22 2.37 W N/A 0.937 1.06 0.937 0.870 1.08 1.11 1.07 1.09 1.08 1.06 1.01 0.803 0.658 3.66 2.10 1.11 5.93 3.90 2.85 WNW N/A 0.858 1.06 1.05 0.686 0.922 1.19 1.05 1.13 1.16 1.18 1.17 0.834 0.628 5.02 2.45 1.21 6.42 4.22 3.08 NW N/A 1.24 1.13 1.13 1.83 1.34 1.26 1.12 1.15 1.16 1.17 1.17 1.18 1.15 7.84 2.91 1.50 8.15 5.43 4.01 NNW 3.57 1.74 1.43 1.74 3.38 2.12 1.78 1.45 1.34 1.28 1.24 1.19 1.12 1.04 6.96 3.13 1.25 6.60 4.33 3.16 N 13.6 1.21 1.09 N/A 6.10 3.72 3.06 2.34 1.91 1.58 1.34 1.22 1.08 0.981 7.86 4.21 1.63 8.43 5.46 3.95 NNE 67.8 N/A N/A N/A 9.46 4.95 4.11 3.22 2.67 2.26 1.94 1.68 1.32 1.08 7.74 3.99 1.78 9.93 6.72 5.00 NE 53.9 N/A N/A N/A 4.95 2.11 1.76 1.42 1.22 1.07 0.946 0.844 0.698 0.593 4.52 2.61 1.31 7.69 5.37 4.09 ENE 29.4 N/A N/A N/A 3.25 1.55 1.27 0.988 0.819 0.692 0.596 0.518 0.410 0.337 2.45 1.30 0.604 3.43 2.35 1.77 E 33.2 N/A N/A N/A 4.13 1.73 1.38 1.03 0.834 0.691 0.586 0.502 0.390 0.316 2.26 1.19 0.556 3.19 2.19 1.66 ESE 16.3 N/A N/A N/A 5.38 2.13 1.63 1.16 0.914 0.739 0.616 0.521 0.398 0.319 2.25 1.17 0.535 3.02 2.07 1.55 SE 6.53 N/A N/A N/A 4.25 1.71 1.30 0.928 0.722 0.579 0.478 0.399 0.298 0.234 1.59 0.778 0.335 1.84 1.24 0.924 UFSAR 2018 Page 18 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.4-6 POINT BEACH NUCLEAR PLANT ANNUAL AVERAGE /Q AUXILIARY BUILDING VENT, INTERMITTENT ELEVATED RELEASE (IB)

Data Period: 4/19/67-4/18/69

/Q (sec/m3) at Various Receptor Distances (m)

Downwind Shoreline Site Nearest Nearest Sector Boundary Boundary Residence Farm Order E-07 E-07 E-07 E-07 SSE 9.83 9.36 6.61 9.36 S N/A 9.43 5.25 9.43 SSW N/A 8.41 8.05 7.58 SW N/A 8.63 8.70 9.13 WSW N/A 5.33 5.90 5.33 W N/A 4.40 5.53 4.40 WNW N/A 4.26 5.65 5.69 NW N/A 5.40 5.14 5.10 NNW 11.56 6.15 5.46 6.15 N 30.07 3.61 3.53 N/A NNE 106. N/A N/A N/A NE 129. N/A N/A N/A ENE 85.8 N/A N/A N/A E 116. N/A N/A N/A ESE 63.4 N/A N/A N/A SE 28.2 N/A N/A N/A UFSAR 2018 Page 19 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.4-7 POINT BEACH NUCLEAR PLANT GROWING/GRAZING SEASON /Q AUXILIARY BUILDING VENT, INTERMITTENT ELEVATED RELEASE (IB) 4/19/67-10/18/67 AND 4/19/68-10/18/68

/Q at Various Receptor Distances Downwind Shoreline Site Nearest Nearest Sector Boundary Boundary Residence Farm Order E-07 E-07 E-07 E-07 SSE 8.86 8.44 5.93 8.44 S N/A 7.34 4.64 7.34 SSW N/A 9.21 9.00 8.77 SW N/A 10.1 10.1 10.7 WSW N/A 5.72 7.03 5.72 W N/A 4.72 6.60 4.72 WNW N/A 4.72 6.66 6.81 NW N/A 5.92 5.99 5.69 NNW 12.62 6.98 6.25 6.98 N 31.7 4.14 4.08 N/A NNE 116 N/A N/A N/A NE 142 N/A N/A N/A ENE 96.0 N/A N/A N/A E 103 N/A N/A N/A ESE 48.3 N/A N/A N/A SE 22.5 N/A N/A N/A UFSAR 2018 Page 20 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.4-8 POINT BEACH NUCLEAR PLANT ANNUAL AVERAGE /QS, UNIT 1 OR UNIT 2 CONTAINMENT PURGE VENT, CONTINUOUS GROUND LEVEL RELEASE (IIA) AND GAS STRIPPER BUILDING VIA UNIT 2 CONTAINMENT PURGE VENT, CONTINUOUS GROUND LEVEL RELEASE (IIC)

DATA PERIOD: 4/19/67-10/18/67

/Q (Sec/M3) at Various Receptor Distances (M)

Downwind Shoreline Site Nearest Nearest Sector Boundary Boundary Residence Farm 805 1,700 1,980 2,415 2,800 3,200 3,600 4,025 4,830 5,635 7,245 12,070 24,140 40,235 56,330 72,425 Order E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-08 E-08 E-08 E-09 E-09 E-09 SSE 22.9 19.5 7.40 19.5 44.3 10.0 6.96 4.40 3.16 2.35 1.83 1.44 0.985 0.721 4.43 1.79 0.633 3.10 1.95 1.37 S N/A 60.7 9.22 60.7 129.0 29.8 21.2 13.7 10.1 7.64 6.03 4.84 3.41 2.56 16.3 7.10 2.80 14.9 9.82 7.20 SSW N/A 32.3 23.9 9.89 69.8 16.6 11.7 7.48 5.42 4.08 3.19 2.54 1.77 1.31 8.22 3.44 1.30 6.70 4.33 3.13 SW N/A 15.7 8.45 11.7 51.7 12.0 8.45 5.41 3.92 2.95 2.31 1.84 1.28 0.947 5.94 2.49 0.941 4.85 3.14 2.27 WSW N/A 17.5 5.02 17.5 41.1 9.43 6.63 4.24 3.08 2.32 1.81 1.44 1.00 0.745 4.68 1.97 0.749 3.87 2.51 1.82 W N/A 20.5 5.97 20.5 46.2 10.7 7.50 4.81 3.49 2.63 2.06 1.64 1.14 0.846 5.31 2.24 0.851 4.40 2.85 2.06 WNW N/A 14.9 7.21 6.55 58.1 13.5 9.50 6.11 4.44 3.35 2.62 2.09 1.46 1.08 6.83 2.90 1.11 5.74 3.73 2.71 NW N/A 8.60 3.96 6.01 57.3 13.0 9.19 5.93 4.32 3.27 2.57 2.05 1.44 1.07 6.79 2.91 1.12 5.90 3.87 2.82 NNW 49.7 8.23 4.42 8.23 52.1 12.1 8.52 5.46 3.95 2.98 2.33 1.85 1.29 0.956 6.01 2.53 0.958 4.93 3.18 2.30 N 367.0 2.65 1.80 N/A 77.7 17.6 12.3 7.83 5.65 4.24 3.30 2.62 1.81 1.33 8.29 3.44 1.27 6.41 4.10 2.94 NNE 1,190.0 N/A N/A N/A 117.0 27.0 19.1 12.3 8.92 6.73 5.28 4.21 2.94 2.18 13.8 5.83 2.23 11.6 7.55 5.49 NE 1,540.0 N/A N/A N/A 108.0 24.9 17.7 11.4 8.36 6.34 5.00 4.00 2.81 2.10 13.4 5.79 2.26 12.0 7.87 5.76 ENE 796.0 N/A N/A N/A 57.6 13.1 9.27 5.97 4.35 3.29 2.58 2.06 1.44 1.07 6.77 2.89 1.11 5.81 3.80 2.77 E 1,150. N/A N/A N/A 83.6 19.1 13.5 8.65 6.28 4.74 3.71 2.96 2.06 1.53 9.66 4.09 1.56 8.10 5.27 3.83 ESE 711. N/A N/A N/A 77.7 17.2 12.0 7.64 5.52 4.14 3.23 2.56 1.77 1.31 8.17 3.42 1.27 6.48 4.18 3.01 SE 298. N/A N/A N/A 62.6 13.7 9.60 6.12 4.42 3.32 2.59 2.06 1.42 1.05 6.57 2.76 1.03 5.29 3.42 2.48 UFSAR 2018 Page 21 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.4-9 POINT BEACH NUCLEAR PLANT GROWING/GRAZING SEASON /QS, UNIT 1 OR UNIT 2 CONTAINMENT PURGE VENT, CONTINUOUS GROUND LEVEL RELEASE (IIA) AND GAS STRIPPER BUILDING VIA UNIT 2 CONTAINMENT PURGE VENT, CONTINUOUS GROUND LEVEL RELEASE (IIC)

DATA PERIOD: 4/19/67-10/18/67 AND 4/19/68-10/18/68

/Q (Sec/M3) at Various Receptor Distances (M)

Downwind Shoreline Site Nearest Nearest Sector Boundary Boundary Residence Farm 805 1,700 1,980 2,415 2,800 3,200 3,600 4,025 4,830 5,635 7,245 12,070 24,140 40,235 56,330 72,425 Order E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-08 E-08 E-08 E-09 E-09 E-09 SSE 15.4 13.1 4.95 13.1 29.9 6.70 4.66 2.94 2.11 1.57 1.22 0.959 0.655 0.479 2.94 1.19 0.420 2.06 1.29 0.911 S N/A 51.9 7.96 51.9 112 25.4 18.1 11.8 8.68 6.61 5.23 4.21 2.98 2.24 14.4 6.36 2.54 13.6 9.07 6.69 SSW N/A 37.8 28.0 11.6 81.8 19.4 13.7 8.82 6.40 4.83 3.78 3.02 2.10 1.56 9.82 4.13 1.57 8.14 5.28 3.82 SW N/A 21.8 11.7 16.2 72.1 16.7 11.7 7.52 5.45 4.11 3.22 2.56 1.78 1.32 8.30 3.49 1.32 6.84 4.43 3.21 WSW N/A 26.4 7.58 26.4 61.8 14.2 10.0 6.42 4.56 3.51 2.75 2.19 1.52 1.13 7.12 3.01 1.14 5.92 3.84 2.78 W N/A 30.1 8.75 30.1 68.1 15.6 11.0 7.04 5.11 3.85 3.01 2.40 1.67 1.24 7.80 3.30 1.25 6.49 4.21 3.05 WNW N/A 19.0 9.12 8.28 73.3 M 12.1 7.72 5.59 4.21 3.29 2.62 1.82 1.35 8.47 3.57 1.34 6.89 4.45 3.21 NW N/A 12.3 5.71 8.66 82.8 18.6 13.2 8.54 6.24 4.73 3.72 2.98 2.09 1.56 9.95 4.30 1.68 8.87 5.84 4.28 NNW 68.0 11.3 6.06 11.3 71.4 M 11.6 7.48 5.43 4.09 3.20 2.55 1.78 1.32 8.33 3.53 1.35 6.99 4.54 3.30 N 513 3.68 2.50 N/A 108 24.2 17.0 10.8 7.81 5.86 4.57 3.63 2.51 1.85 11.6 4.82 1.79 9.09 5.84 4.20 NNE 1,630 N/A N/A N/A 161 37.1 26.2 16.8 12.2 9.24 7.24 5.77 4.03 2.99 18.9 8.00 3.06 15.9 10.4 7.52 NE 1,850 N/A N/A N/A 127 29.2 20.7 13.5 9.85 7.48 5.90 4.73 3.33 2.50 15.9 6.93 2.72 14.5 9.54 6.99 ENE 894 N/A N/A N/A 64.3 14.5 10.3 6.62 4.82 3.65 2.86 2.29 1.60 1.19 7.54 3.23 1.24 6.54 4.29 3.13 E 822 N/A N/A N/A 58.8 13.2 9.28 5.98 4.35 3.29 2.58 2.06 1.44 1.07 6.77 2.89 1.11 5.81 3.80 2.77 ESE 620 N/A N/A N/A 64.2 14.1 9.94 6.39 4.64 3.50 2.75 2.19 1.53 1.14 7.18 3.07 1.18 6.16 4.04 2.95 SE 206 N/A N/A N/A 41.8 9.11 6.38 4.08 2.95 2.22 1.74 1.38 0.961 0.713 4.48 1.91 0.722 3.74 2.44 1.77 UFSAR 2018 Page 22 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.4-10 POINT BEACH NUCLEAR PLANT ANNUAL AVERAGE /QS, UNIT 1 OR UNIT 2 CONTAINMENT PURGE VENT, INTERMITTENT RELEASE (IIB) 4/19/67-4/18/69

/Q (Sec/M3) at Various Receptor Distances (M)

Downwind Shoreline Site Nearest Nearest Sector Boundary Boundary Residence Farm 805 2,415 4,025 5,635 7,245 12,070 24,140 40,235 56,330 72,425 Order E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-08 E-08 E-08 E-09 E-09 E-09 SSE 18.6 16.7 9.60 16.7 11.8 2.20 0.890 0.492 3.16 1.37 0.528 2.69 1.72 1.23 S N/A 27.0 8.96 27.0 24.8 4.64 2.11 1.37 9.42 4.62 2.04 11.3 7.62 5.67 SSW N/A 22.9 19.1 12.8 17.0 3.91 1.68 0.951 6.31 2.74 1.16 6.13 4.02 2.93 SW N/A 17.3 13.7 15.9 11.4 3.25 1.49 0.744 4.57 2.00 0.890 4.64 3.03 2.20 WSW N/A 13.5 8.90 13.5 5.41 1.68 0.911 0.538 3.20 1.44 0.662 3.51 2.31 1.68 W N/A 12.0 8.74 12.0 4.54 1.66 1.08 0.629 3.51 1.79 0.829 4.32 2.81 2.04 WNW N/A 8.75 8.86 8.69 3.72 1.63 1.29 0.663 5.00 2.32 1.08 5.67 3.71 2.70 NW N/A 9.41 7.24 7.84 7.93 1.91 1.29 0.982 6.41 2.45 1.11 5.85 3.85 2.81 NNW 27.9 9.04 7.10 9.04 9.61 1.97 1.19 0.871 5.61 2.43 0.937 4.86 3.15 2.28 N 135 4.28 3.85 N/A 16.5 2.96 1.29 0.915 6.87 3.33 1.25 6.34 4.06 2.92 NNE 461 N/A N/A N/A 28.6 4.63 1.94 1.12 7.60 3.61 1.53 8.29 5.53 4.08 NE 533 N/A N/A N/A 17.5 2.99 1.38 0.850 6.01 3.09 1.41 7.94 5.41 4.05 ENE 323 N/A N/A N/A 9.71 1.72 0.765 0.459 3.18 1.57 0.690 3.81 2.57 1.91 E 494 N/A N/A N/A 18.3 2.87 1.23 0.729 5.00 2.44 1.06 5.79 3.88 2.87 ESE 283 N/A N/A N/A 21.0 3.10 1.21 0.676 4.47 2.07 0.846 4.48 2.95 2.15 SE 110 N/A N/A N/A 14.9 2.33 0.915 0.511 3.37 1.56 0.634 3.37 2.22 1.63 UFSAR 2018 Page 23 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.4-11 POINT BEACH NUCLEAR PLANT GROWING/GRAZING SEASON /QS, UNIT 1 OR UNIT 2 CONTAINMENT PURGE VENT, INTERMITTENT RELEASE (IIB) 4/19/67-10/18/67 AND 4/19/68-10/18/68

/Q (Sec/M3) at Various Receptor Distances (M)

Downwind Shoreline Site Nearest Nearest Sector Boundary Boundary Residence Farm 805 2,415 4,025 5,635 7,245 12,070 24,140 40,235 56,330 72,425 Order E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-08 E-08 E-08 E-09 E-09 E-09 SSE 13.7 12.4 7.23 12.4 6.58 1.29 0.532 0.298 1.93 0.855 0.336 1.73 1.11 0.794 S N/A 22.1 7.07 22.1 17.6 3.06 1.47 1.01 7.19 3.70 1.71 9.68 6.63 4.98 SSW N/A 24.8 20.7 13.9 20.1 4.64 2.00 1.14 7.56 3.28 1.40 7.42 4.88 3.56 SW N/A 19.4 15.4 17.9 14.1 4.28 2.02 1.01 6.18 2.72 1.24 6.49 4.24 3.08 WSW N/A 14.1 10.5 14.1 5.53 2.22 1.30 0.781 4.63 2.11 0.993 5.29 3.49 2.55 W N/A 11.5 9.64 11.5 4.16 2.00 1.45 0.870 4.79 2.53 1.21 6.34 4.14 3.01 WNW N/A 9.63 10.0 9.83 4.25 2.07 1.66 0.850 6.29 2.90 1.29 6.76 4.40 3.19 NW N/A 10.0 8.06 8.41 8.81 2.26 1.73 1.42 9.35 3.52 1.65 8.78 5.80 4.26 NNW 30.0 9.93 7.99 9.93 11.2 2.48 1.61 1.22 7.89 3.42 1.33 6.92 4.51 3.28 N 140 4.78 4.46 N/A 18.7 3.59 1.61 1.18 9.17 4.62 1.74 8.94 5.76 4.15 NNE 473 N/A N/A N/A 33.8 5.79 2.50 1.47 10.0 4.84 2.07 11.3 7.54 5.57 NE 562 N/A N/A N/A 19.5 3.17 1.49 0.932 6.67 3.50 1.63 9.27 6.36 4.79 ENE 355 N/A N/A N/A 11.1 1.84 0.811 0.485 3.36 1.67 0.734 4.08 2.76 2.06 E 422 N/A N/A N/A 13.2 1.91 0.795 0.464 3.18 1.57 0.694 3.86 2.61 1.95 ESE 202 N/A N/A N/A 11.9 1.76 0.726 0.426 2.92 1.46 0.642 3.56 2.41 1.80 SE 76.6 N/A N/A N/A 8.62 1.33 0.527 0.297 1.98 0.939 0.396 2.16 1.44 1.07 UFSAR 2018 Page 24 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.4-12 POINT BEACH NUCLEAR PLANT ANNUAL AVERAGE /QS, TURBINE BUILDING ROOF EXHAUSTERS, CONTINUOUS GROUND LEVEL RELEASE (III)

DATA PERIOD: 4/19/67-10/18/68

/Q (Sec/M3) at Various Receptor Distances (M)

Downwind Shoreline Site Nearest Nearest Sector Boundary Boundary Residence Farm 805 1,700 1,980 2,415 2,800 3,200 3,600 4,025 4,830 5,635 7,245 12,070 24,140 40,235 56,330 72,425 Order E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-08 E-08 E-08 E-09 E-09 E-09 SSE 24.8 21.0 7.83 21.0 49.7 10.7 7.36 4.61 3.29 2.44 1.89 1.49 1.01 0.738 4.51 1.81 0.639 3.13 1.96 1.38 S N/A 70.4 10.3 70.4 147 34.7 24.3 15.6 11.3 8.47 6.63 5.29 3.69 2.75 17.4 7.44 2.89 15.3 10.1 7.39 SSW N/A 36.3 26.6 10.7 81.4 18.3 12.7 8.07 5.80 4.34 3.37 2.68 1.85 1.36 8.50 3.52 1.32 6.79 4.38 3.16 SW N/A 17.5 9.27 13.0 59.3 13.3 9.27 5.87 4.21 3.15 2.45 1.94 1.34 0.990 6.17 2.56 0.959 4.93 3.19 2.30 WSW N/A 19.7 5.49 19.7 46.9 10.5 7.31 4.63 3.32 2.48 1.93 1.53 1.06 0.782 4.88 2.03 0.765 3.94 2.55 1.85 W N/A 23.1 6.55 23.1 52.9 11.9 8.28 5.24 3.76 2.82 2.19 1.74 1.20 0.887 5.54 2.31 0.870 4.48 2.90 2.10 WNW N/A 16.8 7.94 7.19 66.5 15.2 10.6 6.70 4.82 3.61 2.81 2.23 1.54 1.14 7.14 2.99 1.13 5.86 3.80 2.76 NW N/A 9.69 4.35 6.70 64.3 14.9 10.4 6.61 4.77 3.58 2.79 2.22 1.54 1.14 7.17 3.03 1.16 6.06 3.96 2.89 NNW 57.1 9.05 4.77 9.05 60.0 13.5 9.38 5.93 4.26 3.19 2.48 1.97 1.36 1.00 6.25 2.61 0.978 5.02 3.24 2.33 N 427 2.79 1.88 N/A 87.4 19.3 13.3 8.41 6.02 4.49 3.48 2.75 1.89 1.39 8.58 3.53 1.29 6.52 4.17 2.99 NNE 1,230 N/A N/A N/A 133 30.4 21.2 13.5 9.70 7.27 5.67 4.50 3.11 2.30 14.4 6.03 2.28 11.9 7.70 5.59 NE 1,560 N/A N/A N/A 122 28.8 20.1 12.9 9.29 6.98 5.46 4.35 3.03 2.25 14.2 6.05 2.33 12.3 8.07 5.90 ENE 813 N/A N/A N/A 64.7 14.9 10.4 6.63 4.77 3.58 2.79 2.22 1.54 1.14 7.13 3.01 1.14 5.96 3.89 2.83 E 1,180 N/A N/A N/A 94.4 21.5 15.0 9.50 6.84 5.12 3.99 3.17 2.19 1.62 10.1 4.23 1.60 8.29 5.38 3.91 ESE 773 N/A N/A N/A 86.1 19.0 13.2 8.30 5.95 4.43 3.44 2.72 1.87 1.38 8.52 3.53 1.30 6.63 4.27 3.08 SE 337 N/A N/A N/A 69.1 15.3 10.6 6.68 4.78 3.57 2.77 2.19 1.51 1.11 6.89 2.86 1.06 5.42 3.50 2.53 UFSAR 2018 Page 25 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.4-13 GROWING/GRAZING SEASON /QS, TURBINE BUILDING ROOF EXHAUSTERS, CONTINUOUS GROUND LEVEL RELEASE (III)

DATA PERIOD: 4/19/67-10/18/67 AND: 4/19/68-10/18/68

/Q (Sec/M3) at Various Receptor Distances (M)

Downwind Shoreline Site Nearest Nearest Sector Boundary Boundary Residence Farm 805 1,700 1,980 2,415 2,800 3,200 3,600 4,025 4,830 5,635 7,245 12,070 24,140 40,235 56,330 72,425 Order E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-07 E-08 E-08 E-08 E-09 E-09 E-09 SSE 16.6 14.1 5.24 14.1 33.4 7.14 4.92 3.08 2.20 1.63 1.26 0.990 0.673 0.491 3.00 1.20 0.424 2.08 1.30 0.919 S N/A 60.8 9.03 60.8 125 30.2 21.2 13.6 9.87 7.45 5.84 4.67 3.26 2.44 15.5 6.71 2.64 14.1 9.35 6.88 SSW N/A 42.7 31.4 12.7 95.0 21.7 15.1 9.58 6.89 5.16 4.02 3.19 2.21 1.63 10.2 4.24 1.60 8.28 5.36 3.88 SW N/A 24.4 12.9 18.1 82.4 18.6 12.9 8.19 5.88 4.40 3.43 2.72 1.87 1.39 8.64 3.59 1.35 6.96 4.51 3.26 WSW N/A 29.7 8.32 29.7 70.7 15.9 11.1 7.01 5.04 3.77 2.94 2.33 1.61 1.19 7.43 3.11 1.17 6.04 3.91 2.83 W N/A 33.9 9.61 33.9 77.6 17.5 12.2 7.70 5.53 4.14 3.22 2.56 1.76 1.30 8.14 3.40 1.28 6.62 4.29 3.11 WNW N/A 21.1 9.93 8.99 84.7 19.0 13.2 8.37 6.01 4.49 3.49 2.77 1.91 1.41 8.80 3.66 1.37 7.01 4.51 3.25 NW N/A 14.1 6.35 9.75 92.3 21.6 15.1 9.62 6.95 5.22 4.08 3.25 2.26 1.68 10.6 4.50 1.73 9.14 6.01 4.39 NNW 78.2 12.5 6.58 12.5 82.1 18.6 12.9 8.18 5.88 4.40 3.43 2.72 1.88 1.39 8.70 3.64 1.38 7.13 4.63 3.35 N 593 3.88 2.62 N/A 120 26.7 18.5 11.7 8.37 6.25 4.85 3.84 2.63 1.94 12.0 4.96 1.83 9.26 5.94 4.27 NNE 1,690 N/A N/A N/A 183 41.8 29.1 18.5 13.3 9.97 7.77 6.17 4.27 3.16 19.8 8.27 3.13 16.3 10.6 7.67 NE 1,870 N/A N/A N/A 144 34.0 23.8 15.2 11.0 8.29 6.49 5.18 3.60 2.68 17.0 7.26 2.82 14.9 9.80 7.17 ENE 914 N/A N/A N/A 71.7 16.6 11.6 7.38 5.32 3.99 3.12 2.48 1.72 1.27 7.97 3.37 1.28 6.72 4.40 3.21 E 846 N/A N/A N/A 65.4 15.0 10.5 6.65 4.79 3.59 2.80 2.23 1.54 1.14 7.15 3.02 1.14 5.97 3.90 2.84 ESE 658 N/A N/A N/A 70.7 16.1 11.2 7.12 5.12 3.83 2.99 2.37 1.64 1.21 7.60 3.20 1.21 6.35 4.15 3.03 SE 228 N/A N/A N/A 46.2 10.3 7.14 4.51 3.23 2.42 1.88 1.49 1.03 0.758 4.72 1.98 0.744 3.85 2.50 1.81 UFSAR 2018 Page 26 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.4-14 POINT BEACH NUCLEAR PLANT ANNUAL AVERAGE D/QS, AUXILIARY BUILDING VENT, CONTINUOUS ELEVATED RELEASE (IA)

DATA PERIOD: 4/19/67-10/18/68 D/Q (Sec/M-2) at Various Receptor Distances (m)

Downwind Shoreline Site Nearest Nearest Sector Boundary Boundary Residence Farm 805 1,700 1,980 2,415 2,800 3,200 3,600 4,025 4,830 5,635 7,245 12,070 24,140 40,235 56,330 72,425 Order E-09 E-09 E-09 E-09 E-09 E-09 E-09 E-09 E-09 E-09 E-09 E-10 E-10 E-10 E-10 E-10 E-11 E-11 E-11 E-12 SSE 24.0 20.1 6.95 20.1 46.9 9.85 6.48 3.80 2.58 1.84 1.37 10.4 6.78 4.81 2.89 1.12 3.61 1.45 0.758 4.63 S N/A 13.3 1.48 13.3 29.4 6.10 4.04 2.40 1.65 1.19 0.905 7.13 5.12 4.19 3.48 2.12 9.36 3.80 1.89 11.0 SSW N/A 8.07 5.90 2.12 18.7 3.88 2.57 1.53 1.05 0.760 0.580 4.58 3.30 2.72 2.28 1.40 6.23 2.53 1.25 7.27 SW N/A 4.73 2.29 3.36 16.8 3.47 2.29 1.36 0.930 9.669 0.507 3.96 2.78 2.21 1.74 1.00 4.33 1.76 0.880 5.15 WSW N/A 3.64 0.886 3.64 9.08 1.86 1.23 0.727 0.498 0.358 0.271 2.11 1.48 1.17 0.910 0.519 2.23 0.913 0.459 2.69 W N/A 4.15 1.02 4.15 9.94 2.03 1.34 0.790 0.540 0.387 0.293 2.28 1.58 1.24 0.942 0.525 2.23 0.917 0.463 2.73 WNW N/A 1.92 0.810 0.722 8.27 1.71 1.13 0.665 0.454 0.325 0.246 1.91 1.33 1.05 0.812 0.460 1.97 0.805 0.404 2.38 NW N/A 1.71 0.672 1.11 13.5 2.80 1.85 1.09 0.747 0.536 0.405 3.16 2.20 1.73 1.33 0.753 3.21 1.31 0.657 3.85 NNW 23.6 3.26 1.55 3.26 24.6 5.15 3.39 1.99 1.36 0.968 0.725 5.57 3.73 2.76 1.86 0.887 3.41 1.38 0.700 4.16 N 153 1.57 1.00 N/A 69.5 14.7 9.64 5.66 3.84 2.73 2.03 15.5 10.1 7.15 4.29 1.67 5.37 2.14 1.12 6.80 NNE 219 N/A N/A N/A 63.6 13.4 8.82 5.20 3.54 2.53 1.90 14.6 9.91 7.47 5.25 2.65 10.5 4.24 2.13 12.6 NE 135 N/A N/A N/A 25.9 5.36 3.54 2.09 1.43 1.03 0.784 6.16 4.39 3.57 2.92 1.76 7.74 3.16 1.67 9.19 ENE 100 N/A N/A N/A 24.8 5.19 3.42 2.01 1.37 0.979 0.735 5.66 3.82 2.87 2.00 0.993 3.93 1.59 0.806 4.78 E 208 N/A N/A N/A 43.6 9.03 5.96 3.51 2.40 1.71 1.28 9.89 6.64 4.95 3.38 1.64 6.37 2.59 1.32 7.83 ESE 425 N/A N/A N/A 84.3 17.0 11.2 6.61 4.51 3.21 2.40 18.3 12.0 8.54 5.14 2.00 6.67 2.79 1.50 9.35 SE 229 N/A N/A N/A 63.5 12.6 8.30 4.90 3.34 2.39 1.79 13.7 8.94 6.36 3.82 1.48 4.96 2.12 1.16 7.29 UFSAR 2018 Page 27 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.4-15 POINT BEACH NUCLEAR PLANT GROWING/GRAZING SEASON D/QS, AUXILIARY BUILDING VENT, CONTINUOUS ELEVATED RELEASE (IA)

DATA PERIOD: 4/19/67-10/18/67 AND 4/19/68-10/18/68 D/Q (Sec/M-2) at Various Receptor Distances (m)

Downwind Shoreline Site Nearest Nearest Sector Boundary Boundary Residence Farm 805 1,700 1,980 2,415 2,800 3,200 3,600 4,025 4,830 5,635 7,245 12,070 24,140 40,235 56,330 72,425 Order E-09 E-09 E-09 E-09 E-09 E-09 E-09 E-09 E-09 E-09 E-09 E-10 E-10 E-10 E-10 E-10 E-11 E-11 E-11 E-12 SSE 14.1 11.7 4.06 11.7 27.7 5.76 3.79 2.22 1.51 1.07 0.801 6.10 3.98 2.83 1.71 0.668 2.19 0.891 0.470 2.88 S N/A 6.78 0.766 6.78 15.2 3.11 2.06 1.23 0.849 0.618 0.476 3.81 2.87 2.49 2.28 1.51 6.95 2.84 1.41 8.16 SSW N/A 9.65 7.08 2.53 22.2 4.65 3.08 1.82 1.25 0.903 0.688 5.43 3.92 3.23 2.73 1.69 7.50 3.04 1.51 8.74 SW N/A 6.50 3.14 4.61 23.0 4.76 3.14 1.86 1.27 0.911 0.689 5.37 3.76 2.97 2.31 1.31 5.63 2.29 1.15 6.73 WSW N/A 4.76 1.15 4.76 11.8 2.44 1.61 0.947 0.645 0.462 0.349 2.71 1.89 1.48 1.13 0.634 2.70 1.11 0.556 3.27 W N/A 5.30 1.30 5.30 12.7 2.59 1.71 1.00 0.684 0.490 0.369 2.86 1.96 1.51 1.12 0.600 2.51 1.03 0.525 3.11 WNW N/A 2.65 1.11 0.990 11.3 2.35 1.55 0.911 0.621 0.444 0.335 2.60 1.80 1.40 1.06 0.586 2.48 1.01 0.510 3.00 NW N/A 1.94 0.762 1.26 15.5 3.19 2.10 1.24 0.847 0.608 0.460 3.59 2.52 2.01 1.58 0.916 3.97 1.63 0.817 4.80 NNW 26.2 3.60 1.71 3.60 27.3 5.69 3.75 2.21 1.50 1.07 0.806 6.21 4.20 3.17 2.23 1.12 4.48 1.82 0.923 5.47 N 194. 1.90 1.22 N/A 84.4 17.7 11.7 6.84 4.65 3.30 2.46 18.7 12.2 8.68 5.25 2.06 6.75 2.71 1.42 8.65 NNE 272. N/A N/A N/A 80.4 16.9 11.1 6.56 4.47 3.20 2.40 18.5 12.5 9.45 6.67 3.38 13.5 5.44 2.74 16.2 NE 161. N/A N/A N/A 29.8 6.11 4.04 2.39 1.74 1.18 0.895 7.03 5.02 4.07 3.34 2.01 8.87 3.63 1.81 10.6 ENE 122. N/A N/A N/A 28.1 5.85 3.86 2.27 1.55 1.11 0.830 6.39 4.31 3.24 2.25 1.12 4.42 1.80 0.911 5.41 E 173. N/A N/A N/A 32.6 6.68 4.41 2.60 1.77 1.27 0.951 7.32 4.91 3.65 2.47 1.18 4.59 1.88 0.967 5.79 ESE 298. N/A N/A N/A 48.7 9.57 6.33 3.74 2.56 1.83 1.37 10.5 6.91 4.98 3.08 1.26 4.47 1.90 1.03 6.41 SE 151. N/A N/A N/A 37.4 7.25 4.49 2.83 1.94 1.39 1.04 7.96 5.24 3.76 2.30 0.923 3.25 1.41 0.775 4.86 UFSAR 2018 Page 28 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.4-16 POINT BEACH NUCLEAR PLANT ANNUAL AVERAGE D/QS, AUXILIARY BUILDING VENT, INTERMITTENT ELEVATED RELEASE (IB) 4/19/67-10/18/68 D/Q (m-2) at Various Receptor Distances (m)

Downwind Shoreline Site Nearest Nearest Sector Boundary Boundary Residence Farm Order E-09 E-09 E-09 E-09 SSE M 60.5 25.0 60.5 S N/A 31.3 4.65 31.3 SSW N/A 21.4 16.6 7.24 SW N/A 16.8 9.22 12.8 WSW N/A 17.3 5.67 17.3 W N/A 20.6 6.69 20.6 WNW N/A 12.1 5.91 5.35 NW N/A 8.96 3.91 6.19 NNW 92.2 14.6 7.77 14.6 N 383 6.05 4.23 N/A NNE 419 N/A N/A N/A NE 364 N/A N/A N/A ENE 368 N/A N/A N/A E 534 N/A N/A N/A ESE 907 N/A N/A N/A SE 588 N/A N/A N/A UFSAR 2018 Page 29 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.4-17 POINT BEACH NUCLEAR PLANT GROWING/GRAZING SEASON D/QS, AUXILIARY BUILDING VENT, INTERMITTENT ELEVATED RELEASE (IB) 4/19/67-10/18/67 AND 4/19/68-10/18/68 D/Q (m-2) at Various Receptor Distances (m)

Downwind Shoreline Site Nearest Nearest Sector Boundary Boundary Residence Farm Order E-09 E-09 E-09 E-09 SSE M 47.5 19.6 47.5 S N/A 18.1 2.98 18.1 SSW N/A 22.2 17.8 7.84 SW N/A 19.8 10.8 15.2 WSW N/A 21.1 6.62 21.1 W N/A 26.7 8.10 26.7 WNW N/A 14.6 6.98 6.42 NW N/A 9.26 4.04 6.34 NNW 92.6 14.5 7.47 14.5 N 452 6.51 4.57 N/A NNE 464 N/A N/A N/A NE 425 N/A N/A N/A ENE 398 N/A N/A N/A E 538 N/A N/A N/A ESE 882 N/A N/A N/A SE 521 N/A N/A N/A UFSAR 2018 Page 30 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.4-18 POINT BEACH NUCLEAR PLANT ANNUAL AVERAGE D/QS, UNIT 1 OR UNIT 2 PURGE VENT, CONTINUOUS GROUND LEVEL RELEASE (IIA), GAS STRIPPER BUILDING VIA UNIT 2 PURGE VENT, CONTINUOUS GROUND LEVEL RELEASE (IIC), AND TURBINE BUILDING ROOF EXHAUSTERS, CONTINUOUS GROUND LEVEL RELEASE (III)

DATA PERIOD: 4/19/67-10/18/68 D/Q (Sec/M-2) at Various Receptor Distances (m)

Downwind Shoreline Site Nearest Nearest Sector Boundary Boundary Residence Farm 805 1,700 1,980 2,415 2,800 3,200 3,600 4,025 4,830 5,635 7,245 12,070 24,140 40,235 56,330 72,425 Order E-09 E-09 E-09 E-09 E-09 E-09 E-09 E-09 E-09 E-09 E-09 E-10 E-10 E-10 E-10 E-10 E-11 E-11 E-11 E-12 SSE 29.3 24.6 8.72 24.6 60.2 12.1 8.17 4.94 3.42 2.47 1.86 1.43 9.33 6.56 3.76 1.28 3.35 1.25 0.650 3.96 S N/A 47.9 5.63 47.9 110 22.1 14.9 9.01 6.24 4.50 3.39 2.60 17.0 12.0 6.86 2.34 6.12 2.29 1.19 7.24 SSW N/A 30.4 21.8 8.18 72.7 14.6 9.86 5.96 4.13 2.98 2.24 1.72 11.3 7.92 4.54 1.55 4.05 1.51 0.785 4.78 SW N/A 14.1 7.10 10.2 52.4 10.5 7.10 4.29 2.97 2.15 1.62 1.24 8.11 5.71 3.27 1.11 2.92 1.09 0.566 3.45 WSW N/A 10.7 2.69 10.7 27.2 5.47 3.69 2.23 1.54 1.11 0.839 0.644 4.21 2.97 1.70 0.579 1.51 0.567 0.294 1.79 W N/A 11.3 2.89 11.3 27.6 5.55 3.74 2.26 1.57 1.13 0.851 0.653 4.27 3.01 1.72 0.587 1.54 0.575 0.298 1.82 WNW N/A 5.43 2.39 2.15 24.2 4.86 3.28 1.98 1.37 0.991 0.746 0.573 3.75 2.64 1.51 0.514 1.35 0.504 0.261 1.59 NW N/A 4.95 2.02 3.28 39.5 7.93 5.35 3.23 2.24 1.62 1.22 0.934 6.11 4.30 2.46 0.839 2.20 0.822 0.426 2.60 NNW 44.7 6.13 3.03 6.13 47.0 9.45 6.37 3.85 2.67 1.93 1.45 1.11 7.28 5.12 2.93 1.00 2.62 0.979 0.508 3.09 N 458 2.16 1.38 N/A 89.7 18.0 12.2 7.35 5.09 3.67 2.77 2.12 13.9 9.78 5.60 1.91 4.99 1.87 0.969 5.90 NNE 1,360 N/A N/A N/A 139 28.0 18.9 11.4 7.90 5.70 4.29 3.29 21.5 15.2 8.68 2.96 7.74 2.90 1.50 9.15 NE 1,160 N/A N/A N/A 91.8 18.5 12.4 7.52 5.21 3.76 2.83 2.17 14.2 10.0 5.72 1.95 5.11 1.91 0.991 6.04 ENE 665 N/A N/A N/A 52.5 10.5 7.11 4.30 2.98 2.15 1.62 1.24 8.12 5.72 3.27 1.12 2.92 1.09 0.566 3.45 E 1,090 N/A N/A N/A 86.3 17.4 11.7 7.07 4.90 3.53 2.66 2.04 13.4 9.41 5.38 1.84 4.80 1.80 0.932 5.68 ESE 973 N/A N/A N/A 107 21.6 14.6 8.80 6.09 4.40 3.31 2.54 16.6 11.7 6.70 2.28 5.98 2.24 1.16 7.07 SE 385 N/A N/A N/A 79.5 16.0 10.8 6.52 4.51 3.26 2.45 1.88 12.3 8.66 4.96 1.69 4.43 1.66 0.859 5.23 UFSAR 2018 Page 31 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.4-19 POINT BEACH NUCLEAR PLANT GROWING/GRAZING SEASON D/QS, UNIT 1 OR UNIT 2 PURGE VENT, CONTINUOUS GROUND LEVEL RELEASE (IIA), GAS STRIPPER BUILDING VIA UNIT 2 PURGE VENT, CONTINUOUS GROUND LEVEL RELEASE (IIC), AND TURBINE BUILDING ROOF EXHAUSTERS, CONTINUOUS GROUND LEVEL RELEASE (III)

DATA PERIOD: 4/19/67-10/18/67 AND 4/19/68-10/18/68 D/Q (Sec/M-2) at Various Receptor Distances (m)

Downwind Shoreline Site Nearest Nearest Sector Boundary Boundary Residence Farm 805 1,700 1,980 2,415 2,800 3,200 3,600 4,025 4,830 5,635 7,245 12,070 24,140 40,235 56,330 72,425 Order E-09 E-09 E-09 E-09 E-09 E-09 E-09 E-09 E-09 E-09 E-09 E-10 E-10 E-10 E-10 E-10 E-11 E-11 E-11 E-12 SSE 17.5 14.7 5.22 14.7 36.0 7.25 4.89 2.95 2.05 1.48 1.11 8.53 5.58 3.93 2.25 0.767 2.01 0.751 0.389 2.37 S N/A 34.1 4.01 34.1 78.3 15.7 10.6 6.41 4.44 3.21 2.41 18.5 12.1 8.53 4.88 1.66 4.36 1.63 0.845 5.15 SSW N/A 36.6 26.3 9.86 87.6 17.6 11.9 7.18 4.97 3.59 2.70 20.7 13.6 9.55 5.47 1.86 4.88 1.82 0.946 5.76 SW N/A 18.6 9.32 13.4 68.8 13.8 9.32 5.64 3.90 2.82 2.12 16.3 10.6 7.49 4.29 1.46 3.83 1.43 0.743 4.53 WSW N/A 13.1 3.31 13.1 33.4 6.72 4.53 2.74 1.90 1.37 1.03 7.91 5.18 3.64 2.09 0.711 1.86 0.696 0.361 2.20 W N/A 13.0 3.33 13.0 31.8 6.39 4.31 2.60 1.80 1.30 0.980 7.52 4.92 3.46 1.98 0.676 1.77 0.662 0.343 2.09 WNW N/A 6.95 3.06 2.75 31.0 6.22 4.20 2.54 1.76 1.27 0.955 7.33 4.79 3.37 1.93 0.658 1.72 0.645 0.334 2.04 NW N/A 6.05 2.46 4.01 48.2 9.68 6.53 3.95 2.73 1.97 1.49 11.4 7.45 5.25 3.00 1.02 2.68 1.00 0.520 3.17 NNW 56.3 7.73 3.82 7.73 59.3 11.9 8.04 4.86 3.36 2.43 1.83 14.0 9.18 6.46 3.70 1.26 3.30 1.23 0.640 3.90 N 567 2.67 1.71 N/A 111 22.3 15.0 9.10 6.30 4.55 3.42 26.3 17.2 12.1 6.92 2.36 6.18 2.31 1.20 7.30 NNE 1,740 N/A N/A N/A 178 35.8 24.1 14.6 10.1 7.28 5.49 42.1 27.5 19.4 11.1 3.78 9.90 3.70 1.92 11.7 NE 1,330 N/A N/A N/A 105 21.1 14.2 8.61 5.96 4.30 3.24 24.9 16.3 11.5 6.56 2.24 5.85 2.19 1.13 6.91 ENE 748 N/A N/A N/A 59.0 11.9 8.00 4.84 3.35 2.42 1.82 14.0 9.14 5.43 3.68 1.26 3.28 1.23 0.637 3.88 E 794 N/A N/A N/A 62.6 12.6 8.48 5.13 3.55 2.56 1.93 14.8 9.69 6.82 3.90 1.33 3.48 1.30 0.676 4.12 ESE 612 N/A N/A N/A 67.5 13.6 9.16 5.53 3.83 2.77 2.08 16.0 10.5 7.36 4.21 1.44 3.76 1.41 0.729 4.44 SE 240 N/A N/A N/A 49.7 9.99 6.73 4.07 2.82 2.03 1.53 11.8 7.69 5.41 3.10 1.06 2.76 1.03 0.536 3.27 UFSAR 2018 Page 32 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.4-20 POINT BEACH NUCLEAR PLANT ANNUAL AVERAGE D/QS, UNIT 1 OR UNIT 2 CONTAINMENT PURGE VENT, INTERMITTENT RELEASE (IIB) 4/19/67-4/18/69 D/Q (Sec/M2) at Various Receptor Distances (m)

Downwind Shoreline Site Nearest Nearest Sector Boundary Boundary Residence Farm 805 2,415 4,025 5,635 7,245 12,070 24,140 40,235 56,330 72,425 Order E-09 E-09 E-09 E-09 E-09 E-09 E-10 E-10 E-10 E-10 E-11 E-11 E-11 E-11 SSE M 50.0 21.0 50.0 49.4 4.01 11.2 5.20 3.09 1.17 3.61 1.43 0.745 0.454 S N/A 47.6 7.43 47.6 56.2 4.59 13.4 6.77 4.60 2.19 8.28 3.30 1.66 0.977 SSW N/A 39.3 29.1 12.9 40.6 3.33 9.67 4.81 3.18 1.46 5.33 2.11 1.06 0.626 SW N/A 22.7 12.8 17.4 29.1 2.36 6.82 3.39 2.25 1.03 3.83 1.53 0.773 0.458 WSW N/A 23.0 7.33 23.0 15.2 1.23 3.53 1.75 1.16 0.533 1.98 0.797 0.404 0.241 W N/A 23.9 7.18 23.9 14.3 1.14 3.28 1.65 1.12 0.535 2.06 0.834 0.425 0.253 WNW N/A 11.9 5.98 5.39 11.8 0.951 2.73 1.39 0.956 0.468 1.83 0.739 0.374 0.221 NW N/A 10.5 4.81 7.15 21.4 1.73 4.99 2.49 1.66 0.774 2.90 1.16 0.589 0.350 NNW 83.5 13.6 7.53 13.6 30.1 2.44 6.96 3.37 2.14 0.923 3.24 1.29 0.659 0.394 N 572 5.58 3.89 N/A 72.5 5.90 16.6 7.70 4.60 1.75 5.45 2.15 1.11 0.677 NNE 1,128 N/A N/A N/A 86.1 7.03 20.2 9.82 6.31 2.76 9.75 3.86 1.96 1.16 NE 851 N/A N/A N/A 39.5 3.21 9.38 4.91 3.51 1.80 7.21 2.90 1.46 0.856 ENE 700 N/A N/A N/A 29.8 2.42 6.94 3.42 2.25 1.03 3.78 1.51 0.769 0.457 E 1,221 N/A N/A N/A 55.7 4.51 12.9 6.27 3.99 1.71 5.98 2.39 1.22 0.730 ESE 1,228 N/A N/A N/A 89.1 7.12 20.2 9.40 5.59 2.11 6.5 2.65 1.40 0.864 SE 600 N/A N/A N/A 66.7 5.26 14.8 6.90 4.09 1.54 4.86 2.00 1.08 0.671 UFSAR 2018 Page 33 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.4-21 POINT BEACH NUCLEAR PLANT GROWING/GRAZING SEASON D/QS, UNIT 1 OR UNIT 2 CONTAINMENT PURGE VENT, INTERMITTENT ELEVATED RELEASE (IIB) 4/19/67-10/18/68 AND 4/19/68-10/18/69 D/Q (Sec/M-2) at Various Receptor Distances (m)

Downwind Shoreline Site Nearest Nearest Sector Boundary Boundary Residence Farm 805 2,415 4,025 5,635 7,245 12,070 24,140 40,235 56,330 72,425 Order E-09 E-09 E-09 E-09 E-09 E-09 E-10 E-10 E-10 E-10 E-11 E-11 E-11 E-11 SSE M 37.9 15.9 37.9 28.9 2.33 6.51 3.02 1.81 0.691 2.19 0.877 0.461 0.282 S N/A 33.2 5.02 33.2 32.4 2.64 7.80 4.12 2.98 1.55 6.24 2.51 1.26 0.736 SSW N/A 40.4 30.1 13.2 45.7 3.75 10.9 5.48 3.70 1.74 6.54 2.60 1.30 0.766 SW N/A 25.1 14.0 19.2 36.5 2.96 8.53 4.27 2.87 1.35 5.08 2.04 1.03 0.611 WSW N/A 23.3 7.21 23.3 16.5 1.33 3.80 1.93 1.32 0.646 2.51 1.02 0.515 0.305 W N/A 24.3 7.13 24.3 15.2 1.21 3.44 1.75 1.22 0.606 2.41 0.985 0.502 0.299 WNW N/A 14.2 6.95 6.31 15.5 1.25 3.56 1.79 1.23 0.595 2.31 0.934 0.473 0.281 NW N/A 10.1 4.58 6.83 22.6 1.82 5.26 2.69 1.88 0.935 3.69 1.49 0.755 0.447 NNW 86.5 13.6 7.43 13.6 33.9 2.74 7.85 3.87 2.54 1.16 4.27 1.71 0.871 0.519 N 617 6.03 4.27 N/A 87.7 7.11 19.9 9.27 5.57 2.15 6.81 2.70 1.41 0.856 NNE 1,088 N/A N/A N/A 104 8.47 24.2 11.9 7.77 3.49 12.7 5.05 2.55 15.2 NE 814 N/A N/A N/A 41.6 3.36 9.87 5.26 3.87 2.05 8.42 3.41 1.71 10.0 ENE 754 N/A N/A N/A 33.4 2.70 7.76 3.83 2.53 1.16 4.27 1.71 0.870 0.518 E 986 N/A N/A N/A 39.1 3.14 8.99 4.38 2.81 1.23 4.40 1.77 0.912 0.548 ESE 940 N/A N/A N/A 51.5 4.06 11.5 5.44 3.31 1.31 4.37 1.80 0.958 0.590 SE 465 N/A N/A N/A 39.3 3.04 8.61 4.04 2.44 0.949 3.17 1.34 0.726 0.452 UFSAR 2018 Page 34 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.4-22 POINT BEACH NUCLEAR PLANT PERCENTAGE FREQUENCY DISTRIBUTION OF PASQUILL STABILITY CLASS FOR POINT BEACH, HAVEN, AND MILWAUKEE VALID DATA PASQUILL STABILITY CLASS FREQUENCY PERCENTAGE LOCATION DATA HOURS PERIOD A B C D E F G POINT BEACH (1) 14,647 4/19/67-4/18/69 0.87 1.37 9.39 35.02 34.55 11.67 7.13 HAVEN (2) 7,968 6/1/73 -

5/31/74 1.91 1.50 2.35 34.63 37.83 14.02 7.76 MILWAUKEE (3) 5,848 (4) 4/19/67 -

4/18/69 0.17 2.89 8.96 69.90 8.81 6.24 4.04 MILWAUKEE (3) 2,920 (4) 6/1/73 -

5/31/74 0.00 1.10 7.23 74.37 9.67 5.72 1.82 MILWAUKEE (3) 110,968 (4) 1/1/56 -

12/31/75 0.08 2.28 8.09 68.75 10.03 7.13 3.65 Notes:

1. Stability Class determined by wind range.

2. Stability Class determined by Regulatory Guide 1.23 T Classifications.

3. Stability Class determined by the STAR Program of the National Weather Service.

4. Observations recorded every third hour from 1/1/65 - 12/31/75.

UFSAR 2018 Page 35 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.4-23 POINT BEACH NUCLEAR PLANT PERCENTAGE FREQUENCY DISTRIBUTION OF WIND DIRECTION FOR POINT BEACH, HAVEN, AND MILWAUKEE WIND FREQUENCY PERCENTAGE BY QUADRANT VALID DATA ONSHORE OFFSHORE CALM AND LOCATION DATA HOURS PERIOD NNE - E ESE - S SSW - W WNW - N VARIABLE POINT BEACH (1) 14,647 4/19/67-4/18/69 16.06 17.84 33.17 32.02 0.91 HAVEN (2) 7,968 6/1/73 -

5/31/74 16.97 21.99 33.36 27.18 0.50 MILWAUKEE (3) 5,848 (4) 4/19/67 -

4/18/69 17.93 21.84 35.51 22.00 2.72 MILWAUKEE (3) 2,920 (4) 6/1/73 -

5/31/74 14.69 23.01 34.45 25.86 1.99 MILWAUKEE (3) 110,968 (4) 1/1/56 -

12/31/75 17.54 22.17 34.23 24.12 1.94 Notes:

1. Monitored at the Point Beach Nuclear Plant.

2. Monitored at the Haven Site, according to Regulatory Guide 1.23 recommendations.

3. Observations taken at General Mitchell Field, a first-order National Weather Service Station.

4. Observations recorded every third hour from 1/1/65 - 12/31/75.

UFSAR 2018 Page 36 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.4-24 POINT BEACH NUCLEAR PLANT WIND SPEED BY QUADRANT FOR POINT BEACH, HAVEN, AND MILWAUKEE AVERAGE WIND SPEED BY QUADRANT (MPH)

VALID DATA ONSHORE OFFSHORE LOCATION DATA HOURS PERIOD NNE - E ESE - S SSW - W WNW - N POINT BEACH (1) 14,647 4/19/67-4/18/69 12.3 11.7 12.5 12.8 HAVEN (2) 7,968 6/1/73 -

5/31/74 10.1 8.2 8.4 10.3 MILWAUKEE (3) 5,848 (4) 4/19/67 -

4/18/69 10.6 9.9 11.1 12.0 MILWAUKEE (3) 2,920 (4) 6/1/73 -

5/31/74 12.0 10.5 12.0 12.1 MILWAUKEE (3) 110,968 (4) 1/1/56 -

12/31/75 12.0 10.4 11.8 12.8 Notes:

1. Monitored at the Point Beach Nuclear Plant.

2. Monitored at the Haven Site, according to Regulatory Guide 1.23 recommendations.

3. Observations taken at General Mitchell Field, a first-order National Weather Service Station.

4. Observations recorded every third hour from 1/1/65 - 12/31/75.

UFSAR 2018 Page 37 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.4-25 POINT BEACH NUCLEAR PLANT WIND-PRECIPITATION (FREQUENCY PERCENT)

SUMMARY

FOR 1/1/56 - 12/31/75 AT MILWAUKEE WINDS BLOWING PRECIPITATION OCCURING DURING WIND SPEED CLASSIFICATIONS (MPH)

FROM 1-3 4-7 8 - 12 13 - 18 19 - 24 > 25 TOTAL N .024 .087 .207 .393 .189 .199 1.020 NNE .030 .128 .280 .441 .235 .117 1.231 NE .026 .085 .169 .259 .102 .075 .716 ENE .023 .041 .133 .180 .101 .035 .513 E .032 .085 .147 .205 .059 .047 .575 ESE .030 .091 .209 .229 .056 .021 .635 SE .036 .099 .206 .223 .064 .033 .661 SSE .043 .128 .268 .220 .054 .011 .724 S .054 .174 .308 .256 .059 .011 .862 SSW .033 .137 .257 .229 .060 .019 .735 SW .030 .088 .176 .191 .054 .036 .575 WSW .030 .096 .169 .200 .068 .041 .605 W .038 .147 .225 .264 .091 .040 .805 WNW .032 .138 .221 .320 .124 .030 .864 NW .028 .078 .260 .296 .102 .030 .793 NNW .028 .078 .260 .296 .102 .030 .793 TOTAL OBSERVATIONS = 110,960.

PRECIPITATION OCCURING DURING CALM WIND CONDITIONS = 0.086.

UFSAR 2018 Page 38 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.4-26 POINT BEACH NUCLEAR PLANT AVERAGE PRECIPITATION FOR WEATHER STATIONS IN THE VICINITY OF POINT BEACH NUCLEAR PLANT PERIOD STATION DISTANCE FROM OF AVERAGE PRECIPITATION (INCHES)

LOCATION PBNP (MILES) RECORD JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC Manitowoc 13 SSW 1863 -

1960 1.58 1.54 2.09 2.65 2.98 3.49 3.22 3.08 3.24 2.48 2.20 1.69 Kewaunee 12 N 1913 -

1960 1.44 1.36 1.59 2.51 3.08 3.26 2.94 2.78 3.09 2.04 2.27 1.45 Brillion 27 WSW 1924 -

1960 1.35 1.40 1.66 2.40 2.90 3.61 2.63 3.11 3.25 1.96 2.06 1.20 Green Bay 32 NW 1931 -

1960 1.15 1.08 1.34 2.46 3.06 3.36 2.71 2.75 2.92 1.91 1.91 1.18 Two Rivers 9 SSW 1951 -

1960 0.99 1.29 1.79 3.01 3.12 2.66 4.29 3.04 2.49 2.58 1.97 1.42 Annual Average Precipitations:

Manitowoc 30.24 inches Kewaunee 27.81 inches Brillion 27.53 inches Green Bay 25.83 inches Two Rivers 28.65 inches UFSAR 2018 Page 39 of 248

STABILITY CLASS - ALL -

METER WINDS, PERIOD 6/1/73 TO 5/31/74, NUMBER OF HOURLY OBSERVATIONS WIND SPEED (MPH)

STABILITY CLASS - ALL - ANNUAL 6/1/73 TO 5/31/74 NUMBER OF HOURLY OBSERVATIONS WIND SPEED (MPH)

STABILITY CLASS - ALL - ANNUAL 4/19/67 TO 4/18/69 NUMBER OF HOURLY OBSERVATIONS WIND SPEED (MPH)

STABILITY CLASS - ALL - ANNUAL 1/1/56 TO 12/31/75 NUMBER OF HOURLY OBSERVATIONS WIND SPEED (MPH)

WINDS FROM 1-3 4-7 8-12 13-18 19-24 25+ TOTAL N 9 11 31 6 10 21 88 NNE 0 7 1 0 0 4 12 NE 0 1 1 0 0 9 11 ENE 0 0 0 1 6 10 17 E 1 0 2 8 4 9 24 ESE 1 0 3 5 2 5 16 SE 0 3 6 13 9 19 50 SSE 1 3 7 5 7 4 27 S 0 4 6 14 9 8 41 SSW 1 6 13 24 32 18 94 SW 3 9 12 32 12 6 74 WSW 0 9 20 7 6 7 49 W 4 12 30 23 10 18 97 WNW 1 13 28 67 20 17 146 NW 5 15 23 86 15 13 157 NNW 3 9 17 23 7 5 64 TOTAL 29 102 200 314 149 173 967 Number of calm hours 0 Number of variable directions 0 Total number of observations 967 Sheet 96 of 96 UFSAR 2018 Page 176 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.6-1 POINT BEACH NUCLEAR PLANT NEAREST SITE BOUNDARY (METERS)

N - Lake: nearest shoreline - 300 m; nearest land - 4000 m.

NNE - Lake: nearest shoreline - 200 m; nearest land - >50 miles NE - Lake: nearest shoreline - 170 m; nearest land - >50 miles ENE - Lake: nearest shoreline - 170 m; nearest land - >50 miles E - Lake: nearest shoreline - 170 m; nearest land - >50 miles ESE - Lake: nearest shoreline - 210 m; nearest land - >50 miles SE - Lake: nearest shoreline - 310 m; nearest land - >50 miles SSE - 1300 m; nearest shoreline - 1220 m S - 1270 m -

SSW - 1290 m -

SW - 1520 m -

WSW - 1320 m -

W - 1300 m -

WNW - 1630 m -

NW - 2040 m -

NNW - 2010 m; nearest shoreline - 830 m; Note: The nearest shoreline access points for any individual are as follows, measured from the midpoint of a line connecting the containment centers:

a) Onsite north - at Unit 2 discharge flume, 170 m b) Onsite south - at Unit 1 discharge flume, 170 m c) Offsite north - at site boundary, 2010 m d) Offsite south - at sire boundary, 1500 m UFSAR 2018 Page 177 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.6-2 POINT BEACH NUCLEAR PLANT DISTANCE TO NEAREST RESIDENCE AND NEAREST VEGETABLE GARDEN IN SEARCH SECTOR(1)

Sector Distance (meters)

N 4840 NNE Lake NE Lake ENE Lake E Lake ESE Lake SE Lake SSE 1930 S 2920 SSW 1460 SW 1980 WSW 2240 W 2190 WNW 1250 (onsite) (2); 2240 (offsite)

NW 2920 NNW 1980, (onsite) (2); 2660 (offsite)

Notes:

1. It is assumed that every residence (farm or non-farm) has the potential for having a vegetable garden. Distances are scaled from topographic maps and buildings were located by visual automobile survey. Accuracy is estimated to be within 100 meters.

2. There are 3 onsite residences leased to plant employees, one in the WNW sector and two in the NNW sector. Onsite residents are assumed to have vegetable gardens but do not have milk or meat producing animals. (These residences were later demolished or abandoned.)

UFSAR 2018 Page 178 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.6-3 POINT BEACH NUCLEAR PLANT DISTANCE TO NEAREST MILK COW, MEAT ANIMAL AND MILK GOAT IN EACH SECTOR(1)

Sector Distance (meters)

N none NNE Lake NE Lake ENE Lake E Lake ESE Lake SE Lake SSE 1300 (site boundary)

S 1270 (site boundary)

SSW 2130 SW 1720 WSW 1320 (site boundary)

W 1300 (site boundary)

WNW 2340 NW 2400 NNW 2010 (site boundary)

Notes:

1. Since the PBNP area land use is predominantly agricultural, the distance to the nearest milk cow, milk goat, and meat animal is assumed to be the distance to the nearest practicing farm having a dwelling and a barn.

However, it is assumed that land surrounding the site, owned by the Licensee and leased to local farmers, is unlikely to be used for pasture.

UFSAR 2018 Page 179 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.6-4 POINT BEACH NUCLEAR PLANT CONTAINMENT PURGE

SUMMARY

(1) 1/1/74 TO 2/29/76 Unit 1 Date Condition Start Time Duration 3/5/74 At Power 0957 3 hrs.

4/14/74 Shutdown 0035 16 days 5/1/74 Shutdown (Continued) 17 days 1/13/75 At Power 1615 3 hrs.

1/26/75 Shutdown 2310 5 days 2/28/75 Shutdown 1650 30 days 4/2/75 Shutdown 1830 2 days 5/21/75 At Power 1115 2 hrs.

6/6/75 At Power 0355 5 hrs.

6/11/75 At Power 0415 5 hrs.

6/12/75 At Power 0400 10 hrs.

6/28/75 Shutdown 0640 6 hrs.

8/13/75 At Power 2045 4 hrs.

9/26/75 At Power 0443 3 hrs.

9/17/75 At Power 2315 7 hrs.

9/17/75 At Power 0427 3 hrs.

11/20/75 Shutdown 1243 44 days 1/13/76 At Power 2135 3 hrs.

2/19/76 At Power 1040 22 hrs.

2/20/76 At Power 1150 7 hrs.

UFSAR 2018 Page 180 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.6-4 (CONTINUED)

POINT BEACH NUCLEAR PLANT CONTAINMENT PURGE

SUMMARY

(1) 1/1/74 TO 2/29/76 Unit 2 10/22/74 Shutdown 0935 50 days 2/21/75 Shutdown 0045 6 hrs.

4/19/75 Shutdown 0110 4 hrs.

5/10/75 Shutdown 0305 3 hrs.

7/20/75 Shutdown 0212 13 hrs.

8/13/75 Shutdown 0257 4 days 2/19/76 At Power 1545 22 hrs.

2/27/76 Shutdown 0307 23 days Note:

1. Average purge duration at power (1/1/74 - 3/1/76) = 7 hours8.101852e-5 days 0.00194 hours 1.157407e-5 weeks 2.6635e-6 months UFSAR 2018 Page 181 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.6-5 POINT BEACH NUCLEAR PLANT GAS DECAY TANK RELEASES (1974-1975)

Date GDT# (3) Start Stop Time Ci ft3 %Kr-85(1)

(min) 2/6/74 D 1736 1145 1089 28.15 3544 19.9%

2/18/74 B 0900 0007(2) 743 10.89 3628 44.4%

10/22/74 C 1559 2220 261 4.23 3607 98.6%

1/26/75 B 0954 1410 256 24.52 3393 25.2%

2/8/75 C 1632 0450 738 11.19 3696 38.1%

3/29/75 B 1440 2215 455 6.19 3376 80.4%

4/18/75 D 0730 0815 1042 1820 503 3.28 2807 89.6%

5/12/75 C 1155 0355 240 3.62 3000 99.7%

5/29/75 B 1335 1505 90 14.50 200 33.9%

7/14/75 C 1150 2100 550 5.13 3393 64.1%

8/11/75 D 1605 1435 1350 2.54 3178 96.7%

9/9/75 C 1102 1115 12 0.154 173 97.0%

11/5/75 C 1628 1900 152 3.43 2357 100.0%

1920 2055 95 857 11/18/75 B 1845 0655 730 2.79 3625 97.8%

Notes:

1. Principally Xe-133 and Kr-85 with minor amounts of Xe-131 and Xe-133m

2. There were several start/stops during this period

3. Gas decay tank number UFSAR 2018 Page 182 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.7 -1POINT BEACH NUCLEAR PLANT CALCULATED TOTAL ANNUAL GASEOUS RELEASES (Ci/yr)

UNIT 1 CONTAINMENT TURBINE BUILDING AUXILIARY BUILDING VENT* PURGE VENT UNIT 2 CONTAINMENT PURGE VENT ROOF EXHAUST Unit 1 Unit 2 Auxiliary Gas Decay Unit 1 and Unit 2 Unit 1 Continuous Unit 2 Continuous Gas Stripper Turbine Total Building Tank Condenser Air Containment Containment Containment Containment Building Building Annual Isotope Ventilation Effluent Ejectors Purge Ventilation Purge Ventilation Ventilation Ventilation Releases Ar-41 - - - 2.5E+01 - 2.5E+01 - - - 5.0E+01 Kr-83m 7.2E-01 - 3.2E-01 5.4E-02 8.2E-03 5.4E-02 8.2E-03 2.3E-02 1.23-04 1.2E+00 Kr-85m 3.0E+00 - 1.6E+00 4.1E-01 8.4E-02 4.1E-01 8.4E-02 1.1E-01 5.0E-04 5.7E+00 Kr-85 2.6E+00 7.2E+01 1.6E+00 1.7E+01 2.5E+00 1.7E+01 2.5E+00 2.3E+00 4.2E-04 1.2E+02 Kr-87 2.2E+00 - 8.0E-01 1.3E-01 1.7E-02 1.3E-01 1.7E-02 6.6E-02 3.4E-04 3.4E+00 Kr-88 6.4E+00 - 3.1E+00 6.3E-01 1.1E-01 6.3E-01 1.1E-01 2.2E-01 1.0E-03 1.1E+01 Kr-89 2.0E-01 - 2.5E-07 9.8E-04 6.8E-05 9.8E-04 6.8E-05 4.0E-03 3.4E-05 2.1E-01 Xe-131m 1.8E-01 - 1.1E-01 7.3E-01 1.3E-01 7.3E-01 1.3E-01 4.0E-02 3.0E-05 2.1E+00 Xe-133m 1.4E+00 - 8.3E-01 1.6E+00 3.4E-01 1.6E+00 3.4E-01 1.2E-01 2.2E-04 6.2E+00 Xe-133 5.6E+01 3.1E+01 3.4E+01 1.4E+02 2.8E+01 1.4E+02 2.8E+01 9.2E+00 8.8E-03 4.7E+02 Xe-135m 5.6E-01 - 2.2E-02 1.0E-02 8.4E-04 1.0E-02 8.4E-04 1.2E-02 8.6E-05 6.2E-01 Xe-135 7.2E+00 - 4.3E+00 1.7E+00 4.0E-01 1.7E+00 4.0E-01 3.1E-01 1.2E-03 1.6E+01 Xe-137 3.8E-01 - 4.7E-06 2.1E-03 1.5E-04 2.1E-03 1.5E-04 7.7E-03 6.0E-05 3.9E-01 Xe-138 1.8E+00 - 6.1E-02 3.3E-02 2.7E-03 3.3E-02 2.7E-03 3.9E-02 2.8E-04 2.0E+00 I-131 7.4E-02 - 4.6E-02 3.1E-03 5.7E-04 3.1E-03 5.7E-04 - 3.0E-03 1.3E-01 I-133 1.0E-01 - 6.4E-02 4.9E-04 1.7E-04 6.9E-04 1.7E-04 - 4.2E-03 1.7E-01 Co-58 1.2E-03 - - 7.5E-04 - 7.5E-04 - - - 2.7E-03 Co-60 5.4E-04 - - 3.4E-04 - 3.4E-04 - - - 1.2E-03 UFSAR 2018 Page 183 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.7-1 (CONTINUED)

POINT BEACH NUCLEAR PLANT CALCULATED TOTAL ANNUAL GASEOUS RELEASES (Ci/yr)

UNIT 1 CONTAINMENT TURBINE BUILDING AUXILIARY BUILDING VENT* PURGE VENT UNIT 2 CONTAINMENT PURGE VENT ROOF EXHAUST Unit 1 Unit 2 Auxiliary Gas Decay Unit 1 and Unit 2 Unit 1 Continuous Unit 2 Continuous Gas Stripper Turbine Total Building Tank Condenser Air Containment Containment Containment Containment Building Building Annual Isotope Ventilation Effluent Ejectors Purge Ventilation Purge Ventilation Ventilation Ventilation Releases Mn-54 3.6E-04 - - 2.2E-04 - 2.2E-04 - - - 8.0E-04 Fe-59 1.2E-04 - - 7.5E-05 - 7.5E-05 - - - 2.7E-04 Sr-89 2.6E-05 - - 1.7E-05 - 1.7E-05 - - - 6.0E-05 Sr-90 4.0E-06 - - 3.0E-06 - 3.0E-06 - - - 1.0E-05 Cs-134 3.6E-04 - - 2.2E-04 - 2.2E-04 - - - 8.0E-04 Cs-137 6.0E-04 - - 3.8E-04 - 3.8E-04 - - - 1.4E-03 C-14 1.6E+01 - - - - - - - - 1.6E+01 H-3 7.7E+01 - - 2.65E+02 - 2.65E+02 - - - 6.1E+02 Total Noble Gases 8.3E+01 1.0E+02 4.7E+01 1.9E+02 3.2E+01 1.9E+02 3.2E+01 1.2E+01 1.3E-02 6.9E+02 Total Iodines 1.7E-01 - 1.1E-01 3.8E-03 7.4E-04 3.8E-03 7.4E-04 - 7.2E-03 3.0E-01 Total Particulates 2.3E-03 - - 2.0E-03 - 2.0E-03 - - - 7.2E-03

<*>.Unit 1 and 2 Auxiliary Building Ventilation Releases Include Drumming Area Vent Releases Since Exit Velocities and Locations are Essentially Identical.

UFSAR 2018 Page 184 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.7-2 POINT BEACH NUCLEAR PLANT TOTAL LIQUID RELEASES PER PALNT - CALCULATED(1)

Annual Isotope Radioactivity (Ci/gm) Release (Ci)

H-3 2.7E-03 6.1E+02 Kr-85 Kr-85m Kr-87 Xe-131m Xe-133 Xe-133m Xe-135 Xe-138 I-130 6.6E-12 3.8E-03 I-131 9.4E-10 5.4E-01 I-132 2.0E-10 1.2E-01 I-133 1.3E-09 7.6E-01 I-134 3.5E-11 2.0E-02 I-135 4.9E-10 2.8E-01 Na-24 Cr-51 8.7E-12 5.0E-03 Mn-54 2.0E-12 1.1E-03 Fe-55 8.0E-12 4.6E-03 Fe-59 5.9E-12 3.4E-03 Co-57 Co-58 8.0E-11 4.6E-02 Co-60 8.7E-12 5.0E-03 Br-83 7.7E-12 4.4E-03 Br-84 1.2E-12 7.0E-04 Br-85 2.0E-14 1.1E-05 Rb-86 4.2E-13 2.4E-04 Rb-88 5.9E-11 3.4E-02 Sheet 1 of 3 UFSAR 2018 Page 185 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.7-2 (CONTINUED)

POINT BEACH NUCLEAR PLANT TOTAL LIQUID RELEASES PER PALNT - CALCULATED(1)

Annual Isotope Radioactivity (Ci/gm) Release (Ci)

Sr-89 2.0E-12 1.1E-03 Sr-90 3.8E-14 2.2E-05 Sr-91 5.2E-13 3.0E-04 Y-90 3.8E-14 2.2E-05 Y-91m 3.0E-13 1.7E-04 Y-91 8.7E-12 5.0E-03 Y-93 2.1E-13 1.2E-04 Zr-95 3.8E-13 2.2E-04 Nb-95 3.8E-13 2.2E-04 Mo-99 7.0E-10 4.0E-01 Tc-99m 6.3E-10 3.6E-01 Ru-103 2.0E-13 1.1E-04 Ru-106 3.8E-14 2.2E-05 Rh-103m 2.0E-13 1.1E-04 Rh-106 3.8E-14 2.2E-05 Cd-109 Ag-110m Sb-124 Sb-125 Te-125m 5.9E-14 3.4E-05 Te-127m 9.8E-13 5.6E-04 Te-127 3.1E-12 1.8E-03 Te-129m 5.9E-12 3.4E-03 Te-129 5.9E-12 3.4E-03 Te-131m 1.0E-11 5.8E-03 Te-131 2.0E-12 1.1E-03 Te-132 1.0E-10 5.8E-02 Cs-134 1.1E-10 6.4E-02 Sheet 2 of 3 UFSAR 2018 Page 186 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.7-2 (CONTINUED)

POINT BEACH NUCLEAR PLANT TOTAL LIQUID RELEASES PER PALNT - CALCULATED(1)

Annual Isotope Radioactivity (Ci/gm) Release (Ci)

Cs-136 6.3E-11 3.6E-02 Cs-137 9.1E-11 5.2E-02 Cs-138 Ba-137m 8.7E-11 5.0E-02 Ba-140 9.8E-13 5.6E-04 La-140 7.0E-13 4.0E-04 Ce-141 3.8E-13 2.2E-04 Ce-143 1.0E-13 5.8E-05 Ce-144 2.0E-13 1.1E-04 Pr-143 2.0E-13 1.1E-04 Pr-144 2.0E-13 1.1E-04 Bi-207 Th-232 Np-239 5.9E-12 3.4E-03 Total Calculated Release 5.0E-09 2.9E+00 Anticipated Operational Occurrences 5.2E-10 3.0E-01 Total (Excluding Tritium) 5.5E-09 3.2E+00

1. Isotope Releases of less than 1.E-10 curies/year are set to 0.0.

2. Anticipated operational occurrences 3.00E-01 curies are added to calculated releases and assumed to have the same isotopic distribution for dose calculations.

Sheet 3 of 3 UFSAR 2018 Page 187 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.7-3 POINT BEACH NUCLEAR PLANT CALCULATED ANNUAL RELEASES BY SOURCE (Ci/yr)

Steam Generator Sampling Laundry and Containment Aux. Bldg. Misc. Turb. Bldg. Secondary Side Blowdown, Lab. Drains Drains Shower Drains Sump Drains Floor Drains Waste Floor Drains, Sampling Reactor Coolant Reactor Coolant Isotope Ea. Unit Per Plant Per Unit Per Plant Ea. Unit Per Plant Per Plant Ea. Unit Per Plant Letdown Each Unit Leakage Each Unit Br-83 2.2E-03 4.5E-09 2.0E-07 0.0 2.3E-07 2.3E-07 7.8E-08 0.0 0.0 0.0 0.0 Br-84 3.5E-04 6.1E-12 2.5E-10 0.0 2.9E-10 2.9E-10 1.0E-10 0.0 0.0 0.0 0.0 Br-85 5.6E-06 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 I-130 1.9E-03 2.6E-08 1.2E-06 0.0 1.3E-06 1.3E-06 4.6E-07 0.0 0.0 1.0E-09 7.3E-10 I-131 2.7E-01 1.5E-05 6.2E-04 3.5E-08 7.3E-04 7.2E-04 2.5E-04 2.0E-04 3.0E-05 2.6E-04 1.8E-04 I-132 5.8E-02 1.3E-06 5.8E-05 0.0 6.6E-05 5.5E-05 2.3E-05 4.9E-08 7.5E-09 6.4E-07 4.5E-07 I-133 3.8E-01 7.7E-06 3.5E-04 0.0 4.0E-04 4.0E-04 1.4E-04 1.4E-13 2.6E-14 2.5E-06 1.8E-06 I-134 9.9E-03 1.8E-09 7.7E-08 0.0 8.8E-08 8.8E-08 3.0E-08 0.0 0.0 0.0 0.0 I-135 1.4E-01 1.1E-06 4.7E-04 0.0 5.4E-05 5.4E-05 1.9E-05 0.0 0.0 5.4E-10 3.8E-10 Rb-86 1.2E-04 5.2E-09 2.3E-07 0.0 2.6E-07 2.6E-07 9.1E-08 3.8E-08 5.9E-09 9.9E-08 1.3E-08 Rb-88 1.7E-02 2.5E-12 1.1E-10 0.0 1.3E-10 1.3E-10 4.4E-11 0.0 0.0 0.0 0.0 Cs-134 3.2E-02 1.6E-06 7.2E-05 8.7E-07 8.3E-05 8.3E-05 2.9E-05 3.0E-05 4.7E-06 6.4E-05 8.6E-06 Cs-136 1.8E-02 8.3E-07 3.5E-05 0.0 4.0E-05 4.0E-05 1.4E-05 3.5E-06 5.4E-07 1.1E-05 1.6E-06 Cs-137 2.6E-02 1.2E-06 5.3E-05 1.6E-06 6.1E-05 6.1E-05 2.1E-05 2.5E-05 3.9E-06 4.7E-05 6.5E-06 Cr-51 2.5E-03 1.1E-07 4.8E-06 0.0 5.5E-06 5.5E-06 1.9E-06 1.2E-06 1.8E-07 5.2E-07 3.7E-07 Mn-54 5.6E-04 1.9E-08 8.2E-07 6.8E-08 9.4E-07 9.4E-07 3.2E-07 5.1E-07 7.8E-08 1.5E-07 1.0E-07 Fe-55 2.3E-03 9.4E-08 4.2E-06 0.0 4.8E-06 4.8E-06 1.7E-06 2.3E-06 3.5E-07 7.6E-07 5.3E-07 Fe-59 1.7E-03 6.1E-08 2.6E-06 0.0 3.0E-06 3.0E-06 1.0E-06 1.1E-06 1.7E-07 3.3E-07 2.3E-07 Co-58 2.3E-02 9.4E-07 4.1E-05 2.6E-07 4.7E-05 4.7E-05 1.6E-05 1.7E-05 2.6E-06 5.8E-06 4.1E-06 Co-60 2.5E-03 1.3E-07 5.3E-06 6.0E-07 6.1E-06 6.1E-06 2.1E-06 2.5E-06 3.8E-07 9.9E-07 6.9E-07 Sr-89 5.7E-04 2.1E-08 9.1E-07 0.0 1.0E-06 1.0E-06 3.6E-07 3.7E-08 5.7E-09 1.2E-07 8.6E-08 Sheet 1 of 3 UFSAR 2018 Page 188 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.7-3 (CONTINUED) POINT BEACH NUCLEAR PLANT CALCULATED ANNUAL RELEASES BY SOURCE (Ci/yr)

Steam Generator Sampling Laundry and Containment Aux. Bldg. Misc. Turb. Bldg. Secondary Side Blowdown, Lab. Drains Drains Shower Drains Sump Drains Floor Drains Waste Floor Drains, Sampling Reactor Coolant Reactor Coolant Isotope Ea. Unit Per Plant Per Unit Per Plant Ea. Unit Per Plant Per Plant Ea. Unit Per Plant Letdown Each Unit Leakage Each Unit Sr-90 1.1E-05 6.1E-10 2.6E-08 0.0 3.0E-08 3.0E-08 1.1E-08 1.1E-08 1.7E-09 4.8E-09 3.4E-09 Sr-91 1.5E-04 6.1E-09 2.6E-07 0.0 3.0E-07 3.0E-07 1.0E-07 0.0 0.0 5.0E-12 3.5E-12 Y-90 1.1E-05 8.8E-10 3.8E-08 0.0 4.4E-08 4.4E-08 1.5E-09 1.1E-08 1.7E-09 5.0E-09 3.5E-09 Y-91m 8.4E-05 4.0E-09 1.8E-07 0.0 2.0E-07 2.0E-07 7.0E-08 0.0 0.0 3.4E-12 2.4E-12 Y-91 2.5E-03 1.2E-07 5.3E-06 0.0 6.1E-06 6.1E-06 2.1E-06 1.8E-06 2.7E-07 7.6E-07 5.3E-07 Y-93 5.8E-05 1.3E-09 5.8E-08 0.0 6.6E-08 6.6E-08 2.3E-08 0.0 0.0 1.7E-12 1.2E-12 Zr-95 1.1E-04 3.6E-09 1.6E-07 9.3E-08 1.8E-07 1.8E-07 6.3E-08 7.8E-08 1.2E-08 2.3E-08 1.6E-08 Nb-95 1.1E-04 3.0E-09 1.3E-07 1.3E-07 1.5E-07 1.5E-07 5.5E-08 9.8E-08 1.5E-08 2.4E-08 1.7E-08 Mo-99 2.0E-01 1.9E-05 8.2E-04 0.0 9.4E-04 9.4E-04 3.2E-04 9.8E-08 1.5E-08 7.6E-06 5.3E-06 Tc-99m 1.8E-01 1.8E-05 7.7E-04 0.0 8.8E-04 8.8E-04 3.0E-04 9.8E-08 1.5E-08 7.6E-06 5.3E-06 Ru-103 5.7E-05 2.6E-09 1.2E-07 9.3E-09 1.3E-07 1.3E-07 4.6E-08 3.3E-08 5.1E-09 1.4E-08 9.8E-09 Ru-106 1.1E-05 6.1E-10 2.6E-08 1.6E-07 3.0E-08 3.0E-08 1.0E-08 9.8E-09 1.5E-09 4.6E-09 3.2E-09 Rh-103m 5.7E-05 2.6E-09 1.2E-07 8.7E-09 1.3E-07 1.3E-07 4.6E-08 3.2E-08 5.0E-09 1.4E-08 9.8E-09 Rh-106 1.1E-05 6.1E-10 2.6E-08 1.6E-07 3.0E-08 3.0E-08 1.0E-08 9.8E-09 1.5E-09 4.6E-09 3.2E-09 Te-125m 1.7E-05 1.7E-09 7.7E-08 0.0 8.8E-08 8.8E-08 3.0E-08 1.2E-08 1.8E-09 1.0E-08 7.3E-09 Te-127m 2.8E-04 1.7E-08 7.2E-07 0.0 8.3E-07 8.3E-07 2.9E-07 2.3E-07 3.5E-08 1.2E-07 8.2E-08 Te-127 8.7E-04 2.2E-08 9.6E-07 0.0 1.1E-06 1.1E-06 3.8E-07 2.3E-07 3.5E-08 1.1E-07 7.8E-08 Te-129m 1.7E-03 8.3E-08 3.7E-06 0.0 4.2E-06 4.2E-06 1.5E-06 8.9E-07 1.4E-07 4.3E-07 3.0E-07 Te-129 1.7E-03 5.4E-08 2.4E-06 0.0 2.7E-06 2.7E-06 9.3E-07 5.7E-07 8.7E-08 2.7E-07 1.9E-07 Te-131m 2.9E-03 7.2E-08 3.1E-06 0.0 3.5E-06 3.5E-06 1.2E-06 1.7E-13 2.6E-14 6.4E-09 4.5E-09 Te-131 5.6E-04 1.3E-08 5.8E-07 0.0 6.6E-07 6.6E-07 2.3E-07 3.0E-14 4.7E-15 1.2E-09 8.2E-10 Sheet 2 of 3 UFSAR 2018 Page 189 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.7-3 (CONTINUED) POINT BEACH NUCLEAR PLANT CALCULATED ANNUAL RELEASES BY SOURCE (Ci/yr)

Steam Generator Sampling Laundry and Containment Aux. Bldg. Misc. Turb. Bldg. Secondary Side Blowdown, Lab. Drains Drains Shower Drains Sump Drains Floor Drains Waste Floor Drains, Sampling Reactor Coolant Reactor Coolant Isotope Ea. Unit Per Plant Per Unit Per Plant Ea. Unit Per Plant Per Plant Ea. Unit Per Plant Letdown Each Unit Leakage Each Unit Te-132 2.9E-02 1.2E-06 5.3E-05 0.0 6.1E-05 6.1E-05 2.1E-05 4.7E-08 7.2E-09 6.4E-07 4.5E-07 Ba-137m 2.5E-02 1.1E-06 4.8E-05 1.5E-06 5.5E-05 5.5E-05 1.9E-05 2.5E-05 3.8E-06 4.4E-05 6.1E-06 Ba-140 2.8E-04 1.2E-08 5.3E-07 0.0 6.1E-07 6.1E-07 2.1E-07 5.4E-08 8.3E-09 3.3E-08 5.7E-08 La-140 2.0E-04 1.1E-08 4.8E-07 0.0 5.4E-07 5.4E-07 1.9E-07 6.2E-08 9.5E-09 3.8E-08 2.7E-08 Ce-141 1.1E-04 4.1E-09 1.8E-07 0.0 2.0E-07 2.0E-07 7.0E-08 5.7E-08 8.7E-09 2.0E-08 1.4E-08 Ce-143 2.9E-05 1.2E-09 5.3E-08 0.0 6.1E-08 6.1E-08 2.1E-08 7.7E-15 1.2E-15 1.3E-10 9.4E-11 Ce-144 5.6E-05 2.0E-09 8.6E-08 3.3E-07 9.9E-08 9.9E-08 3.4E-08 5.1E-08 7.8E-09 1.5E-08 1.0E-08 Pr-143 5.7E-05 3.0E-09 1.3E-07 0.0 1.5E-07 1.5E-07 5.1E-08 1.3E-08 2.0E-09 8.7E-09 6.1E-09 Pr-144 5.6E-05 2.0E-09 8.6E-08 3.3E-07 9.9E-08 9.9E-08 3.4E-08 5.1E-08 7.8E-09 1.5E-08 1.0E-08 Np-239 1.7E-03 4.6E-08 2.0E-06 0.0 2.3E-06 2.3E-06 8.0E-07 2.5E-10 3.8E-11 1.5E-08 1.0E-08 Total 1.44E+00 6.99E-05 3.43E-03 6.15E-06 3.45E-03 3.45E-03 1.19E-03 3.13E-04 4.74E-05 4.56E-04 2.24E-04 Sheet 3 of 3 UFSAR 2018 Page 190 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.7-4 POINT BEACH NUCLEAR PLANT AIRBORNE RELEASES (1974-1975) (Ci/yr)

Annual Isotope 1974 1975 Average H-3 4.28E+01 1.77E+02 1.10E+02 Ar-41 3.20E+01 4.16E+02 2.24E+02 Kr-85 2.31E+01 4.48E+01 3.40E+01 Kr-85m 3.74E+02 2.48E+03 1.43E+03 Kr-87 2.51E+02 1.79E+03 1.02E+03 Kr-88 5.42E+02 3.35E+03 1.95E+03 Xe-131m 4.10E+02 8.56E-01 2.05E+02 Xe-133 6.04E+03 1.99E+04 1.30E+04 Xe-133m 1.33E+02 3.18E+02 2.26E+02 Xe-135 1.30E+03 1.05E+04 5.90E+03 Xe-135m 3.22E+02 2.68E+03 1.50E+03 Xe-138 3.21E+02 2.97E+03 1.65E+03 I-131 5.31E-02 2.35E-02 3.83E-02 I-132 4.71E-08 1.52E-01 7.60E-02 I-133 3.84E-02 1.04E-02 2.44E-02 I-134 <MDA 8.76E-04 4.38E-04 I-135 <MDA 5.58E-04 2.79E-04 F-18 6.68E-06 <MDA 3.34E-06 Na-24 3.16E-05 5.47E-06 1.85E-05 Mn-54 <MDA 4.66E-05 2.33E-05 Co-57 <MDA 5.50E-07 2.75E-07 Co-58 3.79E-03 1.13E-03 2.46E-03 Co-60 1.50E-03 2.81E-03 2.16E-03 Rb-88 9.15E-04 4.95E-03 2.93E-03 Zr-95 <MDA 1.49E-10 7.50E-11 Nb-95 3.19E-04 1.69E-04 2.44E-04 Mo-99 <MDA 3.28E-03 1.64E-03 Ru-103 <MDA 2.73E-05 1.37E-05 Cd-109 <MDA 1.95E-08 9.75E-09 Cs-134 <MDA 4.08E-05 2.04E-05 Sheet 1 of 2 UFSAR 2018 Page 191 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.7-4 (CONTINUED)

POINT BEACH NUCLEAR PLANT AIRBORNE RELEASES (1974-1975) (Ci/yr)

Annual Isotope 1974 1975 Average Cs-136 <MDA 7.00E-06 3.50E-06 Cs-137 2.32E-04 1.38E-03 8.06E-04 Cs-138 1.41E-04 3.55E-02 1.78E-02 Ce-141 <MDA 1.29E-05 6.45E-06 Ce-144 <MDA 1.11E-04 5.55E-05

SUMMARY

OF AIRBORNE RELEASES:

FOR DECEMBER, 1974 Unit 1 - No Shutdowns Unit 2 - 21 Day Outage for Refueling & Maintenance; 2 Shutdowns for Testing & Turbine Balancing (0.3 Day Additional Outage)

Isotope Unit 1 Air Ej. Unit 2 Air Ej. Aux. Bldg. Vent Unit 1 Contain. Unit 2 Contain. Turb. Bldg. Dr. Area Vent H-3 7.70E-01 5.31E-03 5.31E-04 9.77E-01 F-18 Ar-41 3.90E-02 1.60E+01 1.50E-03 7.39E-02 Kr-85 7.24E-03 3.00E+00 3.89E-03 6.85E-02 Kr-85m 2.34E-01 9.41E+01 5.16E-02 1.99E-01 Kr-87 1.6E-01 6.55E+01 1.04E-02 4.97E-01 Kr-88 3.84E-01 1.54E+02 5.41E-02 1.83E-01 Xe-131m Xe-133 4.45E+00 1.79E+03 4.07E+00 2.05E+01 6.02E-01 Xe-133m 6.08E-02 2.70E+01 5.50E-02 5.20E-01 Xe-135 1.41E+00 5.68E+02 5.74E-01 2.07E+00 2.41E+00 Xe-135m 2.46E-01 9.90E+01 3.26E-03 1.00E-02 Xe-138 2.36E-01 9.50E+01 3.51E-03 8.57E-03 I-131 1.82E-03 1.92E-07 3.90E-06 1.82E-03 I-132 I-133 5.73E-03 1.01E-08 2.29E-06 3.20E-06 I-134 I-135 Na-24 Mn-54 Co-57 Co-58 1.27E-04 1.36E-06 3.36E-06 9.01E-05 Co-60 4.46E-06 8.32E-05 Rb-88 Zr-95 Nb-95 Mo-99 Ru-103 Ru-106 Cd-109 Cs-134 Cs-136 Cs-137 Cs-138 Ce-141 Ce-144 Sheet 12 of 24 UFSAR 2018 Page 204 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.7-5 (CONTINUED)- POINT BEACH NUCLEAR PLANT OBSERVED MONTHLY GASEOUS RELEASES BY RELEASE POINT PBNP AIRBORNE RELEASE

SUMMARY

FOR JANUARY, 1975 Unit 1 - 18 Day Outage for Sludge Lancing & Maintenance Unit 2 - No Shutdowns Isotope Unit 1 Air Ej. Unit 2 Air Ej. Aux. Bldg. Vent Unit 1 Contain. Unit 2 Contain. Turb. Bldg. Dr. Area Vent H-3 1.37E-01 2.84E-03 2.14E-01 F-18 Ar-41 9.25E-03 4.24E+01 9.16E-03 3.04E-02 Kr-85 8.93E-04 4.09E+00 5.19E-03 3.26E-02 Kr-85m 4.73E-02 2.17E+02 5.13E-01 2.10E-02 Kr-87 3.82E-02 1.75E+02 1.29E-01 3.73E-03 Kr-88 7.45E-02 3.41E+02 5.50E-01 1.97E-02 Xe-131m Xe-133 5.72E-01 2.62E+03 3.83E+01 2.06E+00 Xe-133m 9.14E-03 4.19E+01 5.92E-03 5.11E-04 Xe-135 2.73E-01 1.25E+03 5.75E+00 2.43E-01 Xe-135m 5.21E-02 2.39E+02 2.25E+00 5.76E-02 Xe-138 5.40E-02 2.47E+02 4.18E-02 1.21E-03 I-131 6.91E-03 8.81E-06 2.16E-07 1.84E-04 I-132 4.61E-05 1.80E-08 I-133 1.56E-03 6.66E-09 1.65E-07 I-134 3.57E-08 I-135 6.12E-08 Na-24 Mn-54 1.66E-05 Co-57 Co-58 1.70E-04 4.25E-07 1.66E-08 2.56E-06 Co-60 6.74E-07 3.12E-08 7.12E-06 Rb-88 Zr-95 Nb-95 3.30E-06 Mo-99 Ru-103 5.86E-06 Ru-106 Cd-109 Cs-134 Cs-136 Cs-137 Cs-138 Ce-141 Ce-144 Sheet 13 of 24 UFSAR 2018 Page 205 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.7-5 (CONTINUED)- POINT BEACH NUCLEAR PLANT OBSERVED MONTHLY GASEOUS RELEASES BY RELEASE POINT PBNP AIRBORNE RELEASE

SUMMARY

FOR FEBRUARY, 1975 Unit 1 - 5 Day Shutdown for Steam Generator Tube Repair & CRD Maintenance Unit 2 - 2 Shutdowns for Maintenance & Valve Lineup (Total 3.4 Day Outage)

SUMMARY

FOR AUGUST, 1975 Unit 1 - No Shutdowns Unit 2 - 8.2 Days Shutdown for S. G. Tube Plugging & Minor Maint.

Isotope Combined Air Ej. Aux. Bldg. Vent Unit 1 Contain. Unit 2 Contain. Turb. Bldg. Dr. Area Vent Gas. Str. Bldg.

H-3 1.05E-05 9.07E-01 3.12E-02 3.63E-03 4.18E-02 1.81E-01 F-18 Ar-41 7.80E-03 1.97E+01 1.35E-02 1.33E-02 1.50E-01 Kr-85 Kr-85m 8.52E-02 1.65E+02 3.21E-01 2.53E-02 1.25E+00 Kr-87 3.86E-02 1.20E+02 6.93E-02 4.94E-03 9.08E-01 Kr-88 1.05E-01 2.27E+02 2.90E-01 2.19E-02 1.72E+00 Xe-131m Xe-133 2.84E-01 4.56E+02 2.12E+01 3.68E+00 3.46E+00 Xe-133m 5.24E-03 8.51E+00 1.09E-01 6.01E-02 6.47E-02 Xe-135 3.23E-01 5.67E+02 2.25E+00 1.73E-01 4.30E+00 Xe-135m 4.36E-03 1.76E+02 1.74E-02 1.80E-03 1.34E+00 Xe-138 7.89E-03 2.25E+02 2.24E-02 1.28E-03 1.71E+00 I-131 6.48E-04 1.33E-06 7.18E-05 I-132 I-133 6.77E-04 1.61E-06 I-134 I-135 Na-24 Mn-54 1.12E-06 Co-57 Co-58 5.94E-08 1.23E-08 9.50E-08 6.38E-06 Co-60 1.75E-09 8.58E-10 1.12E-05 Rb-88 Zr-95 Nb-95 Mo-99 Ru-103 Ru-106 Cd-109 Cs-134 Cs-136 Cs-137 Cs-138 1.29E-06 Ce-141 Ce-144 Sheet 20 of 24 UFSAR 2018 Page 212 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.7-5 (CONTINUED)- POINT BEACH NUCLEAR PLANT OBSERVED MONTHLY GASEOUS RELEASES BY RELEASE POINT PBNP AIRBORNE RELEASE

SUMMARY

FOR SEPTEMBER, 1975 Unit 1 - No Shutdowns Unit 2 - No Shutdowns Isotope Combined Air Ej. Aux. Bldg. Vent Unit 1 Contain. Unit 2 Contain. Turb. Bldg. Dr. Area Vent Gas. Str. Bldg.

H-3 9.15E-01 2.34E-02 1.98E-03 1.60E-01 F-18 Ar-41 2.42E-03 4.64E+01 2.95E-02 1.47E-02 2.08E-01 Kr-85 Kr-85m 1.69E-02 2.46E+02 6.77E-01 1.28E-02 1.10E+00 Kr-87 7.99E-03 1.89E+02 1.50E-01 2.43E-03 8.46E-01 Kr-88 2.16E-02 3.52E+02 6.21E-01 1.09E-02 1.58E+00 Xe-131m Xe-133 6.35E-02 7.64E+02 2.41E+01 1.83E+00 3.42E+00 Xe-133m 1.46E-03 1.77E+01 1.93E-01 1.69E-02 7.92E-02 Xe-135 7.19E-02 9.44E+02 4.41E+00 1.04E-01 4.23E+00 Xe-135m 7.74E-04 2.59E+02 4.02E-02 6.16E-04 1.16E+00 Xe-138 1.33E-03 3.10E+02 5.49E-02 7.32E-04 1.39E+00 I-131 8.33E-04 5.15E-10 5.48E-05 I-132 I-133 8.03E-04 8.56E-10 I-134 I-135 Na-24 Mn-54 Co-57 Co-58 6.97E-07 Co-60 5.29E-08 Rb-88 1.61E-04 Zr-95 Nb-95 1.21E-06 Mo-99 Ru-103 Ru-106 Cd-109 3.79E-09 Cs-134 2.31E-06 Cs-136 Cs-137 Cs-138 2.12E-04 Ce-141 1.10E-06 Ce-144 Sheet 21 of 24 UFSAR 2018 Page 213 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.7-5 (CONTINUED)- POINT BEACH NUCLEAR PLANT OBSERVED MONTHLY GASEOUS RELEASES BY RELEASE POINT PBNP AIRBORNE RELEASE

SUMMARY

FOR OCTOBER, 1975 Unit 1 - No Shutdowns Unit 2 - 1.1 Day Maintenance Outage Isotope Combined Air Ej. Aux. Bldg. Vent Unit 1 Contain. Unit 2 Contain. Turb. Bldg. Dr. Area Vent Gas. Str. Bldg.

H-3 2.28E-05 3.91E-01 1.74E-02 2.39E-03 3.21E-01 F-18 Ar-41 3.29E-01 2.57E+01 2.18E-04 8.21E-03 9.26E-01 Kr-85 Kr-85m 2.53E+00 1.04E+02 4.34E-03 7.95E-03 3.75E+00 Kr-87 1.19E+00 7.73E+01 9.39E-04 1.48E-03 2.78E+00 Kr-88 3.14E+00 1.44E+02 3.89E-03 6.77E-03 5.17E+00 Xe-131m Xe-133 6.43E+00 2.04E+02 2.79E-01 1.43E+00 8.64E+00 Xe-133m 1.44E-01 6.12E+00 2.21E-03 1.86E-02 2.20E-01 Xe-135 9.34E+00 3.51E+02 3.17E-01 6.71E-02 1.26E+01 Xe-135m 1.40E-01 1.09E+02 2.55E-04 3.92E-04 3.93E+00 Xe-138 2.58E-01 1.43E+02 3.48E-04 4.91E-04 5.14E+00 I-131 7.75E-04 1.83E-10 8.23E-10 6.70E-06 I-132 I-133 8.06E-04 1.32E-09 I-134 I-135 Na-24 Mn-54 Co-57 Co-58 Co-60 4.25E-06 4.45E-10 Rb-88 Zr-95 Nb-95 2.89E-06 Mo-99 Ru-103 Ru-106 Cd-109 1.20E-08 Cs-134 5.51E-07 Cs-136 Cs-137 Cs-138 8.84E-05 Ce-141 2.62E-07 Ce-144 Sheet 22 of 24 UFSAR 2018 Page 214 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.7-5 (CONTINUED)- POINT BEACH NUCLEAR PLANT OBSERVED MONTHLY GASEOUS RELEASES BY RELEASE POINT PBNP AIRBORNE RELEASE

SUMMARY

FOR NOVEMBER, 1975*

Unit 1 - Refueling Shutdown; 15 Days Unit 2 - 1.1 Day Maintenance Outage Isotope Combined Air Ej. Aux. Bldg. Vent Unit 1 Contain. Unit 2 Contain. Turb. Bldg. Dr. Area Vent Gas. Str. Bldg.

H-3 3.93E-05 6.26E-01 2.39E+00 6.20E-03 8.17E-02 1.07E+00 F-18 Ar-41 4.33E-03 1.65E+01 7.86E-02 9.21E-04 1.75E+01 Kr-85 Kr-85m 2.34E-02 5.98E+01 5.70E-01 9.39E-04 6.35E+01 Kr-87 8.11E-03 4.18E+01 4.11E-01 1.65E-04 4.43E+01 Kr-88 2.71E-02 8.15E+01 7.78E-01 7.92E-04 8.64E+01 Xe-131m Xe-133 8.50E-02 1.65E+02 2.84E+00 1.68E-01 9.02E-01 1.75E+02 Xe-133m 8.71E-04 1.72E+00 4.99E-03 2.30E-03 1.83E+00 Xe-135 9.54E-02 2.11E+02 2.05E+00 7.54E-03 2.23E+02 Xe-135m 2.07E-04 6.31E+01 5.82E-01 4.85E-05 6.70E+01 Xe-138 5.30E-04 7.35E+01 7.51E-01 6.07E-05 7.80E+01 I-131 2.31E-06 2.21E-05 2.65E-08 9.81E-05 I-132 2.45E-05 I-133 1.10E-03 1.66E-05 I-134 I-135 Na-24 Mn-54 Co-57 Co-58 1.45E-06 Co-60 3.18E-06 5.61E-10 7.54E-06 Rb-88 Zr-95 Nb-95 Mo-99 Ru-103 Ru-106 Cd-109 1.05E-09 Cs-134 Cs-136 Cs-137 Cs-138 3.48E-02 Ce-141 Ce-144 Sheet 23 of 24 UFSAR 2018 Page 215 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.7-5 (CONTINUED)- POINT BEACH NUCLEAR PLANT OBSERVED MONTHLY GASEOUS RELEASES BY RELEASE POINT PBNP AIRBORNE RELEASE

SUMMARY

FOR DECEMBER, 1975 Unit 1 - Refueling Outage; Entire Month Unit 2 - No Shutdowns Isotope Combined Air Ej. Aux. Bldg. Vent Unit 1 Contain. Unit 2 Contain. Turb. Bldg. Dr. Area Vent Gas. Str. Bldg.

H-3 1.96E-03 7.76E+00 1.43E-02 3.12E-01 3.02E+00 F-18 Ar-41 1.16E-04 3.70E+01 1.24E-03 3.12E-01 Kr-85 2.71E-05 4.27E+00 9.07E-02 3.59E-02 Kr-85m 8.16E-05 1.72E+01 1.10E-03 1.45E-01 Kr-87 3.15E-05 1.37E+01 1.93E-04 1.15E-01 Kr-88 9.19E-05 2.29E+01 9.29E-04 1.93E-01 Xe-131m Xe-133 1.59E-03 2.53E+02 2.07E-01 2.13E+00 Xe-133m 2.63E-05 4.24E+00 2.68E-03 3.57E-02 Xe-135 4.79E-04 8.67E+01 9.05E-03 7.31E-01 Xe-135m 3.86E-07 8.55E+00 5.36E-05 7.20E-02 Xe-138 3.19E-06 4.13E+01 9.16E-05 3.48E-01 I-131 1.22E-03 1.85E-05 2.22E-09 1.34E-04 I-132 I-133 2.96E-05 I-134 I-135 Na-24 Mn-54 5.08E-07 Co-57 Co-58 1.81E-06 Co-60 5.94E-06 2.91E-06 5.88E-10 4.06E-06 Rb-88 Zr-95 4.47E-07 Nb-95 7.06E-07 4.56E-10 3.92E-06 Mo-99 Ru-103 6.59E-07 1.33E-06 Ru-106 Cd-109 Cs-134 Cs-136 Cs-137 4.56E-10 Cs-138 Ce-141 Ce-144 Sheet 24 of 24 UFSAR 2018 Page 216 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.7-6 POINT BEACH NUCLEAR PLANT LIQUID RELEASES (1974-1975) (Ci/yr)

Annual Isotope 1974 1975 Average H3 8.33E+02 8.85E+02 8.59E+02 Kr-85 1.08E-03 5.40E-04 Kr-85m 3.72E-04 1.86E-04 Kr-87 6.00E-07 3.00E-07 Xe-131m 3.39E-04 1.69E-03 1.01E-03 Xe-133 2.01E-01 2.07E-01 2.04E-01 Xe-133m 3.36E-04 1.34E-03 8.38E-04 Xe-135 8.98E-03 1.01E-01 5.50E-02 Xe-138 3.10E-04 1.55E-04 I-131 1.82E-02 1.71E-01 9.46E-02 I-132 1.20E-03 1.29E-01 6.51E-02 I-133 2.87E-02 2.68E-01 1.48E-01 I-134 1.36E-01 6.80E-02 I-135 6.98E-03 2.71E-01 1.39E-01 Na-124 4.80E-03 2.40E-03 Cr-51 7.89E-02 3.95E-02 Mn-54 1.96E-05 1.47E-02 7.36E-03 Fe-55 Fe-59 2.17E-03 1.09E-03 Co-57 2.32E-04 6.99E-02 3.51E-02 Co-58 1.02E-03 2.42E-01 1.22E-01 Co-60 2.12E-04 6.29E-02 3.16E-02 Br-83 Br-84 Br-85 Rb-86 Rb-88 Sr-89 1.17E-03 7.13E-04 9.42E-04 Sr-90 1.46E-04 2.36E-03 1.25E-03 Sr-91 Y-90 Y-91m Y-91 Y-93 Zr-95 7.95E-05 1.31E-01 6.55E-02 Sheet 1 of 3 UFSAR 2018 Page 217 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.7-6 (CONTINUED)

POINT BEACH NUCLEAR PLANT LIQUID RELEASES (1974-1975) (Ci/yr)

Annual Isotope 1974 1975 Average Nb-95 1.27E-04 1.87E-01 9.36E-02 Mo-99 1.75E-05 8.75E-06 Tc-99m Ru-103 5.40E-04 1.20E-01 6.03E-02 Ru-106 5.79E-04 1.02E-02 5.39E-03 Rh-103m Rh-106 Cd-109 2.08E-03 1.04E-03 Ag-110m 3.12E-04 1.56E-04 Sb-124 6.35E-05 3.18E-05 Sb-125 2.47E-04 1.24E-04 Te-125m Te-127m Te-127 Te-129m Te-129 Te-131m Te-131 Te-132 2.43E-04 1.22E-04 Cs-134 3.84E-02 1.79E-02 2.82E-02 Cs-136 7.99E-04 4.00E-04 Cs-137 9.82E-02 6.55E-02 8.19E-02 Cs-138 1.02E-01 5.10E-02 Ba-137m Ba-140 9.59E-02 4.80E-02 La-140 4.11E-02 2.06E-02 Ce-141 4.88E-02 2.44E-02 Ce-143 Ce-144 8.00E-06 1.09E-01 5.45E-02 Pr-143 Pr-144 Bi-207 9.34E-05 4.67E-02 Th-232 9.72E-06 4.86E-02 Np-239 Sheet 2 of 3 UFSAR 2018 Page 218 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.7-6 (CONTINUED)

POINT BEACH NUCLEAR PLANT LIQUID RELEASES (1974-1975) (Ci/yr)

Release Summary, Average Ci/yr:

Total Tritium 8.59E+02 Total Noble Gases 2.62E-01 Total Iodines 5.65E-01 Total Others 7.56E-01 Total Non-Tritium 1.39E+00 Sheet 3 of 3 UFSAR 2018 Page 219 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.7-7 POINT BEACH NUCLEAR PLANT PARAMETERS FOR RADIOACTIVE GASEOUS RELEASES Unit 1 and 2 Containment Releases (applicable to each unit)

Fraction/day of primary coolant noble gas activity released to containment 0.01 Fraction/day of primary coolant iodine activity released to the containment 0.00001 Iodine exhaust filter efficiency 90%

Particulate exhaust filter efficiency 99%

Purge exhaust ventilation rate (cfm) 12,500 Purge exhaust ventilation time (hrs) 7 Number of hot purges/year/unit 12 10 purges/year during operation 2 purges/year during hot shutdown Number of cold purges/year/unit 2 Continuous ventilation exhaust 10 Containment free volume (ft3) 1.065x106 Units 1 and 2 Auxiliary Building Releases Auxiliary building leakage of primary coolant (lb/day/unit) 160 Iodine partition factor for primary coolant leakage in the aux. bldg. 0.0075 No charcoal filters Auxiliary building HEPA filter efficiency 99%

Units 1 and 2 Turbine Building Releases Turbine building leakage (lb/hr/unit) 1700 Iodine partition coefficient for all iodines 1.0 No filters (charcoal or HEPA)

Main Condenser Air Ejector Fraction of the iodine inventory in the primary coolant which is volatile 0.05 Primary-to-secondary leak rate (lb/day/unit) 100 Main condenser air ejector iodine partition factor 0.15 Units 1 and 2 air ejector effluents enter a decay duct which provides a 1.0 hour0 days 0 hours 0 weeks 0 months delay before release to the environment No filters (charcoal or HEPA)

Sheet 1 of 2 UFSAR 2018 Page 220 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.7-7 (CONTINUED)

POINT BEACH NUCLEAR PLANT PARAMETERS FOR RADIOACTIVE GASEOUS RELEASES Blowdown Flash Tanks PBNP has blowdown flash tanks, however, liquid which flashes is all condensed; therefore, no iodines or noble gases are released through the plant vent from the blowdown flash tanks Gas Decay Tank Effluents 3750 ft3/month of gas decay tank effluent is released for 2 units 103 curies/yr are released from the gas decay tank in batched (70% Kr, 30% Xe-133)

Each release is intermittent and lasts for 250 minutes at a flow rate of 15 cfm No filters (charcoal/HEPA)

Gas Stripper Building Releases 2% of the noble gases in the Appendix I analysis will be assumed to come from the gas stripper building Gas stripper building ventilation (cfm) 400-12,000 No filters (charcoal or HEPA)

Sheet 2 of 2 UFSAR 2018 Page 221 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.8-1 POINT BEACH NUCLEAR PLANT ANNUAL DOSES TO MAXIMUM OFFSITE INDIVIDUAL IN ADULT GROUP FROM RADIOIODINE AND PARTICULATES IN GASEOUS EFFLUENTS ANNUAL DOSE (mrem/yr)

Pathway and Location Total Body Skin Bone Liver Thyroid Kidney Lung GI Tract Inhalation - SSW (1,460 m) 3.2E-02 - 2.6E-03 3.3E-02 5.58E-02 3.2E-02 3.3E-02 3.2E-02 Deposition on Ground - SSW (1,460 m) 3.3E-02 3.8E-02 3.3E-02 3.3E-02 3.3E-02 3.3E-02 3.3E-02 3.3E-02 Fresh Vegetables - SSW (1,460 m) 1.9E-02 - 2.6E-02 2.1E-02 6.7E-01 2.1E-02 1.7E-02 1.7E-02 Stored Vegetables - SSW (1,460 m) 1.5E-01 - 2.0E-01 1.5E-01 1.7E-01 1.4E-01 1.4E-01 1.4E-01 Cows milk - SSE (1,300 m) 4.0E-02 - 4.9E-02 4.6E-02 1.7E+00 4.2E-02 3.2E-02 3.3E-02 Goats milk - SSE (1,300 m) 6.9E-02 - 6.2E-02 8.0E-02 1.2E+00 6.3E-02 4.6E-02 4.5E-02 Meat - SSE (1,300 m) 1.6E-02 - 3.7E-02 1.6E-02 7.4E-02 1.5E-02 1.5E-02 1.6E-02 TOTAL OF ABOVE PATHWAYS WITH INGESTION OF COWS MILK 2.9E-01 3.8E-02 3.5E-02 3.0E-01 2.7E+00 2.8E-01 2.7E-01 2.7E-01 TOTAL OF ABOVE PATHWAYS WITH INGESTION OF GOATS MILK 3.2E-01 3.8E-02 3.6E-01 3.3E-01 3.1E+00 3.0E-01 2.8E-01 2.8E-01 UFSAR 2018 Page 222 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.8-2 POINT BEACH NUCLEAR PLANT ANNUAL DOSES TO MAXIMUM OFFSITE INDIVIDUAL IN TEEN GROUP FROM RADIOIODINE AND PARTICULATES IN GASEOUS EFFLUENTS ANNUAL DOSE (mrem/yr)

Pathway and Location Total Body Skin Bone Liver Thyroid Kidney Lung GI Tract Inhalation - SSW (1,460 m) 1.8E-02 - 5.1E-04 1.9E-02 3.9E-02 2.3E-02 1.9E-02 1.8E-02 Deposition on Ground - SSW (1,460 m) 3.3E-02 3.8E-02 3.3E-02 3.3E-02 3.3E-02 3.3E-02 3.3E-02 3.3E-02 Fresh Vegetables - SSW (1,460 m) 1.2E-03 - 6.8E-03 1.4E-02 5.0E-01 1.4E-02 1.1E-02 1.1E-02 Stored Vegetables - SSW (1,460 m) 1.6E-01 - 8.3E-02 1.8E-01 2.0E-01 1.7E-01 1.6E-01 1.6E-01 Cows milk - SSE (1,300 m) 4.8E-02 - 3.1E-02 6.2E-02 2.5E+00 5.5E-02 3.8E-02 3.8E-02 Goats milk - SSE (1,300 m) 7.6E-02 - 5.3E-02 1.1E-01 3.1E+00 8.2E-02 5.6E-02 5.2E-02 Meat - SSE (1,300 m) 9.6E-03 - 6.3E-03 1.0E-02 5.1E-02 9.0E-03 9.2E-03 9.7E-03 TOTAL OF ABOVE PATHWAYS WITH INGESTION OF COWS MILK 2.8E-01 3.8E-02 1.6E-01 3.2E-01 3.3E+00 3.0E-01 2.7E-01 2.7E-01 TOTAL OF ABOVE PATHWAYS WITH INGESTION OF GOATS MILK 3.1E-01 3.8E-02 1.8E-01 3.7E-01 3.9E+00 3.3E-01 2.9E-01 2.8E-01 UFSAR 2018 Page 223 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.8-3 POINT BEACH NUCLEAR PLANT ANNUAL DOSES TO MAXIMUM OFFSITE INDIVIDUAL IN CHILD GROUP FROM RADIOIODINE AND PARTICULATES IN GASEOUS EFFLUENTS ANNUAL DOSE (mrem/yr)

Pathway and Location Total Body Skin Bone Liver Thyroid Kidney Lung GI Tract Inhalation - SSW (1,460 m) 1.9E-02 - 8.0E-04 1.9E-02 4.6E-02 1.2E-02 1.9E-02 1.9E-02 Deposition on Ground - SSW (1,460 m) 3.3E-02 3.8E-02 3.3E-02 3.3E-02 3.3E-02 3.3E-02 3.3E-02 3.3E-02 Fresh Vegetables - SSW (1,460 m) 1.6E-02 - 1.2E-02 1.9E-02 7.5E-01 8.4E-03 1.5E-02 1.5E-02 Stored Vegetables - SSW (1,460 m) 3.0E-01 - 1.9E-01 3.4E-01 3.9E-01 1.4E-01 3.0E-01 3.0E-01 Cows milk - SSE (1,300 m) 7.6E-02 - 7.3E-02 1.1E-01 5.0E+00 4.5E-02 7.2E-02 7.1E-02 Goats milk - SSE (1,300 m) 1.1E-01 - 1.3E-01 2.0E-01 6.0E+00 6.8E-02 1.0E-01 9.3E-02 Meat - SSE (1,300 m) 1.5E-02 - 1.2E-02 1.6E-02 7.7E-02 5.6E-03 1.5E-02 1.5E-02 TOTAL OF ABOVE PATHWAYS WITH INGESTION OF COWS MILK 4.6E-01 3.8E-02 3.2E-01 5.4E-01 6.3E+00 2.4E-01 4.5E-01 4.5E-01 TOTAL OF ABOVE PATHWAYS WITH INGESTION OF GOATS MILK 4.9E-01 3.8E-02 3.8E-01 6.3E-01 7.3E+00 2.7E-01 4.8E-01 4.8E-01 UFSAR 2018 Page 224 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.8-4 POINT BEACH NUCLEAR PLANT ANNUAL DOSES TO MAXIMUM OFFSITE INDIVIDUAL IN INFANT GROUP FROM RADIOIODINE AND PARTICULATES IN GASEOUS EFFLUENTS ANNUAL DOSE (mrem/yr)

Pathway and Location Total Body Skin Bone Liver Thyroid Kidney Lung GI Tract Inhalation - SSW (1,460 m) 2.0E-02 - 1.2E-03 2.1E-02 6.6E-02 8.5E-03 2.1E-02 2.0E-02 Deposition on Ground - SSW (1,460 m) 3.3E-02 3.8E-02 3.3E-02 3.3E-02 3.3E-02 3.3E-02 3.3E-02 3.3E-02 Fresh Vegetables - SSW (1,460 m) - - - - - - - -

Stored Vegetables - SSW (1,460 m) - - - - - - - -

Cows milk - SSE (1,300 m) 1.5E-01 - 1.6E-01 2.3E-01 1.2E+01 4.5E-02 1.3E-01 1.3E-01 Goats milk - SSE (1,300 m) 2.0E-01 - 2.6E-01 4.0E-01 1.5E+01 6.8E-02 1.8E-01 1.6E-01 Meat - SSE (1,300 m) - - - - - - - -

TOTAL OF ABOVE PATHWAYS WITH INGESTION OF COWS MILK 2.0E-01 3.8E-02 1.9E-01 2.8E-01 1.2E+01 8.7E-02 1.8E-01 1.8E-01 TOTAL OF ABOVE PATHWAYS WITH INGESTION OF GOATS MILK 2.5E-01 3.8E-02 2.9E-01 4.5E-01 1.5E+01 1.1E-01 2.3E-01 2.1E-01 UFSAR 2018 Page 225 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.8-5 POINT BEACH NUCLEAR PLANT ANNUAL DOSES TO MAXIMUM INDIVIDUAL FROM NOBLE GASES IN GASEOUS EFFLUENTS Individual Total Body Dose Skin Dose (mrem/yr) (mrem/yr)

Onsite (1250 m, WNW) 1.7E-02 3.6E-02 Offsite (1460 m, SSW) 2.7E-02 5.6E-02 UFSAR 2018 Page 226 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.8-6 POINT BEACH NUCLEAR PLANT ANNUAL DOSES TO MAXIMUM OFFSITE INDIVIDUAL IN ADULT AGE GROUP FROM LIQUID EFFLUENTS UNDER EQUILIBRIUM CONDITIONS ANNUAL DOSE (mrem/yr)

Pathway and Location Total Body Skin Bone Liver Thyroid Kidney Lung GI Tract Ingestion of potable water - (Two Rivers - 12 miles S) 3.1E-04 - 1.7E-04 3.9E-04 1.3E-02 3.0E-04 1.4E-04 2.2E-04 Ingestion of fish - (edge of initial mixing zone) 1.9E-01 - 1.3E-01 2.5E-01 1.3E-01 9.0E-02 2.8E-02 2.1E-02 Ingestion of fresh vegetables - (Two Rivers - 12 miles S) 1.4E-04 - 1.0E-04 1.9E-04 3.2E-03 8.9E-05 3.0E-05 4.0E-05 Ingestion of stored vegetables - (Two Rivers - 12 miles S) 1.0E-03 - 7.4E-04 1.4E-03 2.4E-04 5.2E-04 2.3E-04 1.8E-04 Ingestion of cows milk (Two Rivers - 12 miles S) 8.7E-04 - 5.9E-04 1.1E-03 1.1E-02 4.7E-04 1.7E-04 1.0E-04 Ingestion of meat - (Two Rivers - 12 miles S) 5.6E-05 - 3.1E-05 7.0E-05 2.1E-04 4.2E-05 2.6E-05 4.4E-05 Swimming - (edge of initial mixing zone) 1.3E-04 1.3E-04 1.3E-04 1.3E-04 1.3E-04 1.3E-04 1.3E-04 1.3E-04 Boating - (edge of initial mixing zones) 4.4E-05 4.4E-05 4.4E-05 4.4E-05 4.4E-05 4.4E-05 4.4E-05 4.4E-05 Shoreline deposits - (1500 meters - South) 1.2E-06 1.4E-06 1.2E-06 1.2E-06 1.2E-06 1.2E-06 1.2E-06 1.2E-06 TOTAL OF ABOVE PATHWAYS 1.9E-01 1.8E-04 1.3E-01 2.5E-01 1.6E-01 9.0E-02 2.9E-02 2.2E-02 UFSAR 2018 Page 227 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.8-7 POINT BEACH NUCLEAR PLANT ANNUAL DOSES TO MAXIMUM OFFSITE INDIVIDUAL IN TEEN AGE GROUP FROM LIQUID EFFLUENTS UNDER EQUILIBRIUM CONDITIONS ANNUAL DOSE (mrem/yr)

Pathway and Location Total Body Skin Bone Liver Thyroid Kidney Lung GI Tract Ingestion of potable water - (Two Rivers - 12 miles S) 1.8E-04 - 1.4E-04 3.1E-04 1.0E-02 2.1E-04 8.8E-05 1.4E-04 Ingestion of fish - (edge of initial mixing zone) 1.1E-01 - 1.3E-01 2.5E-01 1.2E-01 6.9E-02 3.1E-02 1.5E-01 Ingestion of fresh vegetables - (Two Rivers - 12 miles S) 7.4E-05 - 8.9E-05 1.7E-04 2.4E-03 5.8E-05 2.4E-02 2.4E-05 Ingestion of stored vegetables - (Two Rivers - 12 miles S) 9.6E-04 - 1.2E-03 2.2E-03 3.1E-01 6.2E-04 3.5E-04 1.9E-04 Ingestion of cows milk (Two Rivers - 12 miles S) 8.5E-04 - 1.0E-03 1.9E-03 1.8E-02 6.2E-04 2.8E-04 1.1E-04 Ingestion of meat - (Two Rivers - 12 miles S) 2.5E-05 - 2.3E-05 4.8E-05 1.4E-04 2.4E-05 1.5E-05 2.3E-05 Swimming - (edge of initial mixing zone) 1.3E-04 1.3E-04 1.3E-04 1.3E-04 1.3E-04 1.3E-04 1.3E-04 1.3E-04 Boating - (edge of initial mixing zones) 4.4E-05 4.4E-05 4.4E-05 4.4E-05 4.4E-05 4.4E-05 4.4E-05 4.4E-05 Shoreline deposits - (1500 meters - South) 6.8E-06 8.0E-06 6.8E-06 6.8E-06 6.8E-06 6.8E-06 6.8E-06 6.8E-06 TOTAL OF ABOVE PATHWAYS 1.1E-01 1.8E-04 1.3E-01 2.6E-01 1.5E-01 7.1E-02 3.3E-02 1.5E-01 UFSAR 2018 Page 228 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.8-8 POINT BEACH NUCLEAR PLANT ANNUAL DOSES TO MAXIMUM OFFSITE INDIVIDUAL IN CHILD AGE GROUP FROM LIQUID EFFLUENTS UNDER EQUILIBRIUM CONDITIONS ANNUAL DOSE (mrem/yr)

Pathway and Location Total Body Skin Bone Liver Thyroid Kidney Lung GI Tract Ingestion of potable water - (Two Rivers - 12 miles S) 2.1E-04 - 4.0E-04 6.1E-04 2.5E-02 2.1E-04 1.7E-04 2.0E-04 Ingestion of fish - (edge of initial mixing zone) 4.3E-02 - 1.7E-01 2.1E-01 1.3E-01 3.0E-02 2.4E-02 6.6E-03 Ingestion of fresh vegetables - (Two Rivers - 12 miles S) 4.3E-05 - 1.5E-04 2.0E-04 3.6E-03 3.6E-05 2.6E-05 1.8E-05 Ingestion of stored vegetables - (Two Rivers - 12 miles S) 7.8E-04 - 2.8E-03 3.5E-03 5.7E-04 5.2E-04 5.2E-04 2.0E-04 Ingestion of cows milk (Two Rivers - 12 miles S) 6.5E-04 - 2.3E-03 3.1E-03 3.4E-02 5.1E-04 4.1E-04 1.3E-04 Ingestion of meat - (Two Rivers - 12 miles S) 2.2E-05 - 4.4E-05 6.5E-05 2.3E-04 1.7E-06 1.8E-05 2.1E-05 Swimming - (edge of initial mixing zone) 7.3E-05 7.3E-05 7.3E-05 7.3E-05 7.3E-05 7.3E-05 7.3E-05 7.3E-05 Boating - (edge of initial mixing zones) 2.4E-05 2.4E-05 2.4E-05 2.4E-05 2.4E-05 2.4E-05 2.4E-05 2.4E-05 Shoreline deposits - (1500 meters - South) 1.4E-06 1.7E-06 1.4E-06 1.4E-06 1.4E-06 1.4E-06 1.4E-06 1.4E-06 TOTAL OF ABOVE PATHWAYS 4.5E-02 9.9E-05 1.8E-01 2.1E-01 2.0E-01 3.1E-02 2.5E-02 1.1E-02 UFSAR 2018 Page 229 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.8-9 POINT BEACH NUCLEAR PLANT ANNUAL DOSES TO MAXIMUM OFFSITE INDIVIDUAL IN INFANT AGE GROUP FROM LIQUID EFFLUENTS UNDER EQUILIBRIUM CONDITIONS ANNUAL DOSE (mrem/yr)

Pathway and Location Total Body Skin Bone Liver Thyroid Kidney Lung GI Tract Ingestion of potable water - (Two Rivers - 12 miles S) 3.7E-04 - 8.1E-04 1.3E-03 6.1E-02 2.1E-04 2.9E-04 2.5E-04 Ingestion of fish - (edge of initial mixing zone) - - - - - - - -

Ingestion of fresh vegetables - (Two Rivers - 12 miles S) - - - - - - - -

Ingestion of stored vegetables - (Two Rivers - 12 miles S) - - - - - - - -

Ingestion of cows milk (Two Rivers - 12 miles S) 7.7E-04 - 4.8E-03 6.9E-03 8.3E-02 5.1E-04 8.8E-04 1.7E-04 Ingestion of meat - (Two Rivers - 12 miles S) - - - - - - - -

Swimming - (edge of initial mixing zone) - - - - - - - -

Boating - (edge of initial mixing zones) - - - - - - - -

Shoreline deposits - (1500 meters - South) - - - - - - - -

TOTAL OF ABOVE PATHWAYS 1.1E-03 - 5.6E-03 8.2E-03 1.4E-01 7.2E-04 1.2E-03 4.2E-04 UFSAR 2018 Page 230 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.8-10 POINT BEACH NUCLEAR PLANT ANNUAL DOSES TO MAXIMUM ONSITE INDIVIDUAL IN ADULT GROUP FROM RADIOIODINE AND PARTICULATES IN GASEOUS EFFLUENTS ANNUAL DOSE (mrem/yr)

Pathway and Location Total Body Skin Bone Liver Thyroid Kidney Lung GI Tract Inhalation - WNW - 1250 m 2.0E-02 - 6.9E-04 2.0E-02 3.2E-02 2.0E-02 2.0E-02 2.0E-02 Deposition on ground - WNW - 1250 m 2.6E-02 3.1E-02 2.6E-02 2.6E-02 2.6E-02 2.6E-02 2.6E-02 2.6E-02 Fresh vegetables - WNW - 1250 m 1.1E-02 - 8.3E-03 1.2E-02 5.1E-01 1.2E-02 8.6E-03 9.5E-03 Stored vegetables - WNW - 1250 m 8.0E-02 - 5.7E-02 8.2E-02 9.3E-02 7.3E-02 7.0E-02 7.3E-02 TOTAL OF ABOVE PATHWAYS 1.4E-01 3.1E-02 9.2E-02 1.4E-01 6.6E-01 1.3E-01 1.2E-01 1.3E-01 UFSAR 2018 Page 231 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.8-11 POINT BEACH NUCLEAR PLANT ANNUAL DOSES TO MAXIMUM ONSITE INDIVIDUAL IN TEEN GROUP FROM RADIOIODINE AND PARTICULATES IN GASEOUS EFFLUENTS ANNUAL DOSE (mrem/yr)

Pathway and Location Total Body Skin Bone Liver Thyroid Kidney Lung GI Tract Inhalation - WNW - 1250 m 1.1E-02 - 1.6E-04 1.1E-02 2.1E-02 1.4E-02 1.1E-02 1.1E-02 Deposition on ground - WNW - 1250 m 2.6E-02 3.1E-02 2.6E-02 2.6E-02 2.6E-02 2.6E-02 2.6E-02 2.6E-02 Fresh vegetables - WNW - 1250 m 6.4E-03 - 3.43E-03 7.6E-03 3.8E-01 7.6E-03 4.9E-03 5.5E-03 Stored vegetables - WNW - 1250 m 8.2E-02 - 3.6E-02 9.3E-02 1.1E-01 8.8E-02 7.4E-02 7.6E-02 TOTAL OF ABOVE PATHWAYS 1.3E-01 3.1E-02 6.6E-02 1.4E-01 5.4E-01 1.4E-02 1.2E-01 1.2E-01 UFSAR 2018 Page 232 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.8-12 POINT BEACH NUCLEAR PLANT ANNUAL DOSES TO MAXIMUM ONSITE INDIVIDUAL IN CHILD GROUP FROM RADIOIODINE AND PARTICULATES IN GASEOUS EFFLUENTS ANNUAL DOSE (mrem/yr)

Pathway and Location Total Body Skin Bone Liver Thyroid Kidney Lung GI Tract Inhalation - WNW - 1250 m 1.1E-02 - 2.4E-04 1.1E-02 2.5E-02 7.3E-03 1.1E-02 1.1E-02 Deposition on ground - WNW - 1250 m 2.6E-02 3.1E-02 2.6E-02 2.6E-02 2.6E-02 2.6E-02 2.6E-02 2.6E-02 Fresh vegetables - WNW - 1250 m 7.0E-03 - 5.7E-03 9.9E-03 5.8E-01 4.8E-03 6.4E-03 6.7E-03 Stored vegetables - WNW - 1250 m 1.4E-01 - 7.9E-02 1.6E-01 1.9E-01 7.3E-02 1.3E-01 1.3E-01 TOTAL OF ABOVE PATHWAYS 1.8E-01 3.1E-02 1.1E-01 2.1E-01 8.2E-01 1.1E-01 1.7E-01 1.7E-01 UFSAR 2018 Page 233 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.8-13 POINT BEACH NUCLEAR PLANT ANNUAL DOSES TO MAXIMUM ONSITE INDIVIDUAL IN INFANT GROUP FROM RADIOIODINE AND PARTICULATES IN GASEOUS EFFLUENTS ANNUAL DOSE (mrem/yr)

Pathway and Location Total Body Skin Bone Liver Thyroid Kidney Lung GI Tract Inhalation - WNW - 1250 m 1.2E-02 - 3.6E-04 1.2E-02 3.5E-02 5.2E-03 1.2E-02 1.2E-02 Deposition on ground - WNW - 1250 m 2.6E-02 3.1E-02 2.6E-02 2.6E-02 2.6E-02 2.6E-02 2.6E-02 2.6E-02 Fresh vegetables - WNW - 1250 m - - - - - - - -

Stored vegetables - WNW - 1250 m - - - - - - - -

TOTAL OF ABOVE PATHWAYS 3.8E-02 3.1E-02 2.6E-02 3.8E-02 6.1E-02 3.1E-02 3.8E-02 3.8E-02 UFSAR 2018 Page 234 of 248

FSAR Appendix I Tables and Figures (Historical)

Table I.9-1 COMPARISON OF MAXIMUM CALCULATED DOSES FROM POINT BEACH NUCLEAR PLANT WITH DESIGN OBJECTIVES IN DOCKET RM-50-2(1)

RM-50-2 Calculated Maximum Dose Release Design Objective Individual Organ Dose Liquid Effluents

1. Total body 5 millirem/year Adult - 0.19 millirem/year

2. Any organ 5 millirem/year Teen Liver 0.26 millirem/year Noble gases

1. Gamma Dose in Air(2) 10 millirads/year - - 0.06 millirads/year

2. Beta Dose in Air(2) 20 millirads/year - - 0.07 millirads/year

3. Total body 5 millirem/year Any - 0.03 millirem/year Any(3) - 0.02 millirem/year

4. Skin 15 millirem/year Any Skin 0.06 millirem/year Any(3) Skin 0.04 millirem/year Radioiodine and Particulates in Gaseous Releases(4)

1. Any organ from all pathways 15 millirem/year Infant Thyroid 15.0 millirem/year Child(3) Thyroid 0.82 millirem/year

1. Concluding Statement of Position of the Regulatory Staff, Docket RM-50-2, February 20, 1974, U. S. Atomic Energy Commission, Washington, D.C.

2. Calculated at site boundary

3. Onsite resident

4. Carbon-14 and tritium have been added to this category.

UFSAR 2018 Page 235 of 248

FSAR Appendix I Tables and Figures (Historical)

Figure I.2-1 LIQUID WASTE SYSTEM PROCESS FLOW DIAGRAM c-1 .......i.

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,...1 / yr.

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UFSAR 2018 Page 236 of 248

FSAR Appendix I Tables and Figures (Historical)

Figure I.2-2 CHEMICAL & VOLUME CONTROL SYSTEM PROCESS FLOW DIAGRAM Hoa 1.

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UFSAR 2018 Page 237 of 248

FSAR Appendix I Tables and Figures (Historical)

Figure I.2-3 VENTILATION AND GASEOUS WASTE PROCESS FLOW DIAGRAM

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UFSAR 2018 Page 238 of 248

FSAR Appendix I Tables and Figures (Historical)

Figure I.2-4 PIPING & INSTRUMENT DIAGRAM HEATING & VENTILATION AIRFLOW UFSAR 2018 Page 239 of 248

FSAR Appendix I Tables and Figures (Historical)

Figure I.2-5 PIPING & INSTRUMENT DIAGRAM HEATING & VENTILATION SYSTEMS

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UFSAR 2018 Page 240 of 248

FSAR Appendix I Tables and Figures (Historical)

Figure I.4-1 GENERAL TOPOGRAPHY WITHIN 10-MILE RADIUS L A K -:-~~- M I C H I G A N

-+-~-

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UFSAR 2018 Page 241 of 248

FSAR Appendix I Tables and Figures (Historical)

Figure I.4-2 MAXIMUM TOPOGRAPHIC ELEVATION VS DISTANCE BY SECTOR 780 1rr------------------ ~- --- - - - --------------- - ------~----,

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UFSAR 2018 Page 242 of 248

FSAR Appendix I Tables and Figures (Historical) 180 1r---------- --- ------ --------------------- - --- ----------,,

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UFSAR 2018 Page 243 of 248

FSAR Appendix I Tables and Figures (Historical) 780

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-- 0 l 4 :; 7 e 9 iO D l,ST AJNCE - M ,LES SOUTIHWESl" 1n 1GuRE I4 - 2 (P3 OF 61 MAX MIIJM TOPOGRAIPHIIC ELEVAT ION V'S o , sTANCE BY' S E CT,OR 1 PO Nil" IBE.A-C H Nl.1-0LIE.Al'li IP IL.AN F'IINAL -

'S FET V A NAILVS IS REPQR UFSAR 2018 Page 244 of 248

FSAR Appendix I Tables and Figures (Historical) 780 r----- -------------- ------ ~---------- - - --- - ---------,,

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MAXI MU1M TOPOGIR APH'IC

'E LEVATION V'S, 0 STANCE BY S,ECTOR PO I T BE.A.CH NUCl.E iA PLAINT Fl~A SAFEili' Y AN IL r s ,s REPOR'iJ UFSAR 2018 Page 245 of 248

FSAR Appendix I Tables and Figures (Historical) 7\80 **-

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,en

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S.Af"ETT A ALV-S. I S REIPQR1' UFSAR 2018 Page 246 of 248

FSAR Appendix I Tables and Figures (Historical) 79-0

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FIIHAl.

$ AFlETY iilNAl..YS:IS: Rl::lf"IOfiT UFSAR 2018 Page 247 of 248

FSAR Appendix I Tables and Figures (Historical)

Figure I.6-1 FARM AND NON-FARM RESIDENCES WITHIN 3 MILES HI

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UFSAR 2018 Page 248 of 248

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