Revision 4106/29/23 MPS-2 FSAR 11-i CHAPTER 11RADIOACTIVE WASTE PROCESSING AND RADIATION PROTECTION SYSTEMS Table of Contents Section Title Page 11.1 RADIOACTIVE WASTE PROCESSING SYSTEMS..................................... 11.1-1 11.1.1 General...................................................................................................... 11.1-1 11.1.2 Design Bases............................................................................................. 11.1-1 11.1.2.1 Functional Requirements.......................................................................... 11.1-1 11.1.2.2 Design Criteria.......................................................................................... 11.1-1 11.1.2.3 System Components................................................................................. 11.1-3 11.1.3 Liquid Waste Processing System.............................................................. 11.1-3 11.1.3.1 System Descriptions................................................................................. 11.1-3 11.1.3.2 System Operation...................................................................................... 11.1-7 11.1.4 Gaseous Waste Processing System........................................................... 11.1-9 11.1.4.1 System Descriptions................................................................................. 11.1-9 11.1.4.2 System Operation.................................................................................... 11.1-10 11.1.4.3 Gaseous Release Radiological Consequences........................................ 11.1-10 11.1.4.4 Waste Gas System Failure...................................................................... 11.1-10 11.1.4.4.1 General.................................................................................................... 11.1-10 11.1.4.4.2 Method of Analysis................................................................................. 11.1-11 11.1.4.4.3 Results of Analysis................................................................................. 11.1-11 11.1.4.4.4 Conclusions............................................................................................. 11.1-11 11.1.5 Solid Waste Processing System.............................................................. 11.1-11 11.1.5.1 System Descriptions............................................................................... 11.1-11 11.1.6 System Reliability and Availability........................................................ 11.1-14 11.1.6.1 Special Features...................................................................................... 11.1-14 11.1.6.2 Tests and Inspections.............................................................................. 11.1-15 11.1.7 References............................................................................................... 11.1-16 11.2 RADIATION PROTECTION........................................................................... 11.2-1 11.2.1 Final Safety Analysis Report Update........................................................ 11.2-1 11.2.2 Design Bases............................................................................................. 11.2-1 11.2.3 Description................................................................................................ 11.2-3 11.2.3.1 Containment Shielding............................................................................. 11.2-3

Revision 4106/29/23 MPS-2 FSAR 11-ii CHAPTER 11RADIOACTIVE WASTE PROCESSING AND RADIATION PROTECTION SYSTEMS Table of Contents (Continued) 11.2.3.2 Auxiliary Building Shielding.................................................................... 11.2-4 11.2.3.3 Control Room Shielding........................................................................... 11.2-5 11.2.3.4 Spent Fuel Pool Shielding and Fuel Handling Shielding......................... 11.2-5 11.2.3.5 Piping Systems Shielding......................................................................... 11.2-5 11.2.4 Health Physics Program............................................................................ 11.2-6 11.2.5 References................................................................................................. 11.2-6 11.A SOURCE TERMS FOR RADIOACTIVE WASTE PROCESSING AND RELEASES TO THE ENVIRONMENT......................................................... 11.A-1 11.A.1 Reactor Coolant Design Basis Radionuclide Activities.......................... 11.A-1 11.A.1.1 Development of Reactor Core Radionuclide Activities.......................... 11.A-1 11.A.1.2 Corrosion Products.................................................................................. 11.A-2 11.A.1.3 Tritium Production................................................................................... 11.A-2 11.A.1.4 Fuel Experience....................................................................................... 11.A-3 11.A.2 Reactor Coolant Expected Radionuclide Activities................................. 11.A-4 11.A.3 Calculation of Liquid and Gaseous Effluent Releases............................. 11.A-4 11.A.3.1 Expected Liquid and Gaseous Radioactive Effluent Releases................ 11.A-4 11.A.3.2 Design Basis Liquid and Gaseous Radioactive Effluent Releases.......... 11.A-5 11.A.4 Solid Waste Processing System............................................................... 11.A-5 11.A.4.1 Spent Resins............................................................................................. 11.A-6 11.A.4.1.1 Spent Resins from CVCS Ion Exchanger................................................ 11.A-6 11.A.4.1.2 Spent Resins from Clean Liquid Waste Processing System Demineralizers......

11.A-6 11.A.4.1.3 Spent Resins from Aerated Liquid Waste Processing System Demineralizer.....

11.A-6 11.A.4.1.4 Spent Resins from Spent Fuel Pool Demineralizer................................. 11.A-6 11.A.4.1.5 Contaminated Filter Cartridges................................................................ 11.A-7 11.B RADIOACTIVE WASTE PROCESSING OF RELEASES TO ENVIRONMENT........................................................................................11.B-1 11.B.1 Bases.........................................................................................................11.B-1 11.B.2 Liquid Waste Processing System..............................................................11.B-1 11.B.2.1 Processing of Clean Liquid Waste............................................................11.B-1

Revision 4106/29/23 MPS-2 FSAR 11-iii CHAPTER 11RADIOACTIVE WASTE PROCESSING AND RADIATION PROTECTION SYSTEMS Table of Contents (Continued) 11.B.2.2 Processing of Aerated Liquid Waste........................................................11.B-2 11.B.2.3 Processing of Secondary Side Liquid Waste............................................11.B-2 11.B.3 Gaseous Waste Processing System...........................................................11.B-3 11.C DOSES FROM RADIOACTIVE RELEASES AND COST-BENEFIT ANALYSIS........................................................................................................11.C-1 11.C.1 Doses to Humans......................................................................................11.C-1 11.C.2 Methods for Calculating Doses From Liquid Releases............................11.C-1 11.C.2.1 Generalized Equation for Calculating Radiation Doses to Humans via Liquid Pathways...................................................................................................11.C-1 11.C.2.2 Doses from Aquatic Foods.......................................................................11.C-2 11.C.2.3 Doses from Shoreline Deposits.................................................................11.C-2 11.C.2.4 Doses from Swimming and Boating.........................................................11.C-3 11.C.3 Method for Calculating Doses From Gaseous Releases...........................11.C-3 11.C.3.1 Gamma and Beta Doses from Noble Gas Discharged to the Atmosphere.11.C-4 11.C.3.1.1 Annual Air Doses from Noble Gas Releases (Non-Elevated)..................11.C-4 11.C.3.1.2 Annual Total Body Dose from Noble Gas Releases (Non-Elevated).......11.C-5 11.C.3.1.3 Annual Skin Dose from Noble Gas Releases (Non-Elevated).................11.C-5 11.C.3.1.4 Annual Gamma Air Dose and Annual Total Body Dose Due to Noble Gas Re-leases from Free-Standing Stacks More Than 80 Meters Tall..................11.C-6 11.C.3.2 Doses from Radioiodines and Other Radionuclides, Exclusive of Noble Gases, Released to the Atmosphere.....................................................................11.C-6 11.C.3.2.1 Annual Organ Dose Due to External Irradiation from Ground Deposition of Ra-dionuclides................................................................................................11.C-6 11.C.3.2.2 Annual Organ Dose from Inhalation of Radionuclides in Air..................11.C-6 11.C.3.2.3 Annual Organ Dose from Ingestion of Atmospherically Released Radionuclides in Food......................................................................................................11.C-7 11.C.4 Comparison of Calculated Annual Maximum Individual Doses with Appendix I Design Objectives.....................................................................................11.C-7 11.C.5 General Expression for Population Doses................................................11.C-8 11.C.6 Cost-Benefit Analysis...............................................................................11.C-8 11.C.6.1 Procedure Used for Performing Cost-Benefit Analysis............................11.C-9

Revision 4106/29/23 MPS-2 FSAR 11-iv CHAPTER 11RADIOACTIVE WASTE PROCESSING AND RADIATION PROTECTION SYSTEMS Table of Contents (Continued) 11.C.6.2 Augments to the Liquid Radioactive Waste Processing System............11.C-10 11.C.6.3 Augments to the Gaseous Radioactive Waste Processing System.........11.C-10 11.D EXPECTED ANNUAL INHALATION DOSES AND ESTIMATED AIR CONCENTRATIONS OF RADIOACTIVE ISOTOPES FOR MP2 FACILITIES....

11.D-1 11.E AIRBORNE ACTIVITY SAMPLING SYSTEM FOR CONTAINMENT, SPENT FUEL AND RADWASTE ATMOSPHERES...................................................11.E-1

Revision 4106/29/23 MPS-2 FSAR 11-v CHAPTER 11RADIOACTIVE WASTE PROCESSING AND RADIATION PROTECTION SYSTEMS List of Tables Number Title 11.1-1 Radioactive Waste Processing System Component Description 11.1-2 Sources and Expected Volumes of Solid Wastes 11.1-3 Radioactivity levels of solid wastes (See Note) 11.1-4 Curie Inventory of Solid Waste Shipped from Millstone Unit 2 (See Note) 11.1-5 Assumptions for Waste Gas Decay Tank Accident 11.2-1 Source Terms for Shielding Design 11.A-1 Design-Basis and Expected Primary Coolant Activity Concentrations 11.A-2 Calculated Reactor Core Activities 11.A-3 Expected Annual Effluent Releases (Curies Per Year), by Radionuclide, from Each Release Point 11.A-4 Expected Annual Liquid Effluent Activity Releases (Curies/Year), by Radionuclide, from Each Waste Stream 11.A-5 Expected Annual Liquid Effluent Concentrations (Diluted and Undiluted), by Radionuclide, from Each Waste System 11.A-6 Design Basis Radionuclide Concentrations in Liquid Effluent, in Fractions of 10 CFR Part 20 Concentration Limits 11.A-7 Design-Basis Radionuclide Airborne Concentrations at the Site Boundary From All Gaseous Effluent Release Points Combined, in Fractions of 10 CFR Part 20 Concentration Limits 11.A-8 Total Annual Design-Basis and Expected Releases of Radioactive Liquid Waste to the Environment From All Sources Combined, in Curies Per Year 11.A-9 Total Annual Design Basis and Expected Releases of Airborne Radioactive Waste to the Environment From All Release Points Combined, in Curies Per Year 11.A-10 Basis for Reactor Coolant System Activity NUREG-0017 gale Code Input 11.B-1 Inputs to PWR-GALE Code 11.C-1 Comparison of Calculated Annual Maximum Individual Doses with 10 CFR Part 50 Appendix I Design Objectives

Revision 4106/29/23 MPS-2 FSAR 11-vi CHAPTER 11-RADIOACTIVE WASTE PROCESSING AND RADIATION PROTECTION SYSTEMS List of Tables (Continued) 11.C-2 Annual Total Body and Thyroid Doses to the Population Within 50 Miles of the Millstone Site, In Man-Rem, From Expected Liquid and Airborne Effluent Releases 11.D-1 Containment Building Airborne Concentrations 11.D-2 Auxiliary Building Airborne Concentrations 11.D-3 Turbine Building Airborne Concentrations

CHAPTER 11RADIOACTIVE WASTE PROCESSING AND RADIATION PROTECTION SYSTEMS List of Figures Number Title 11.1-1 P&ID Clean Liquid Radwaste System 11.1-2 P&ID Clean Liquid Radwaste System 11.1-3 P&ID Drains (Containment & Auxiliary Building and Auxiliary Yard Sump)

(Sheet 1) 11.1-4 P&ID Aerated Liquid Radwaste System 11.1-5 P&ID Diagram Gaseous Radwaste System 11.1-6 Degasifier Performance Curve 11.1-7 P&ID Spent Resin Radwaste System 11.2-1 P&ID, Radiation Zones and Access Control Normal Operation With 1.0% Failed Fuel Containment and Auxiliary Building - Elevation (-) 45 Feet 6 Inches 11.2-2 P&ID, Radiation Zones and Access Control Normal Operation With 1.0% Failed Fuel Containment and Auxiliary Building - Elevation (-) 29 Feet 6 Inches 11.2-3 P&ID, Radiation Zones and Access Control Normal Operation With 1.0% Failed Fuel Containment and Auxiliary Building - Elevation (-) 5 Feet 0 Inches 11.2-4 P&ID, Radiation Zones and Access Control Normal Operation With 1.0% Failed Fuel Containment Building - Elevation 14 Feet 6 Inches and 38 Feet 6 Inches 11.2-5 P&ID, Radiation Zones and Access Control Normal Operation With 1.0% Failed Fuel Auxiliary Building - Elevation 14 Feet 6 Inches and 25 Feet 6 Inches 11.2-6 P&ID, Radiation Zones and Access Control Normal Operation With 1.0% Failed Fuel Turbine Building - Elevation 14 Feet 6 Inches 11.2-7 P&ID, Radiation Zones and Access Control Normal Operation With 1.0% Failed Fuel Auxiliary Building - Elevation 36 Feet 6 Inches 11.2-8 P&ID, Radiation Zones and Access Control Normal Operation With 1.0% Failed Fuel Containment and Auxiliary Building - Section A-A 11.2-9 P&ID, Radiation Zones and Access Control Normal Operation With 1.0% Failed Fuel Containment and Auxiliary Building - Section B-B 11.2-10 P&ID, Radiation Zones and Access Control Normal Operation With 1.0% Failed Fuel Containment and Auxiliary 11.2-11 Neutron Shield Segment

CHAPTER 11-RADIOACTIVE WASTE PROCESSING AND RADIATION PROTECTION SYSTEMS List of Figures (Continued) 11.2-12 Neutron Shielding - Sectional View 11.2-13 Not Used 11.2-14 Not Used 11.2-15 Neutron Shield - Thermal Loadings (Typical Annular Section) 11.2-16 Neutron Shield - Thermal Loadings (Plug Shield Section) 11.A-1 Escape Rate Coefficients 11.B-1 NUREG-0017 Gale Code Input Diagram - Liquid Waste System 11.B-2 NUREG-0017 Gale Code Input Diagram - Airborne

Revision 4106/29/23 MPS-2 FSAR 11.1-1 CHAPTER 11 - RADIOACTIVE WASTE PROCESSING AND RADIATION PROTECTION SYSTEMS 11.1 RADIOACTIVE WASTE PROCESSING SYSTEMS 11.1.1 GENERAL The purpose of the radioactive waste processing systems is to provide controlled handling of all radioactive waste, proper discharging of radioactivity in liquid and gaseous effluents, and proper packaging for shipment of solid waste containing radioactivity from Millstone Unit 2.

On occasion, the Unit will generate liquid radioactive waste that cannot practicably be processed in the liquid radwaste system. The station may process this waste outside the Unit in compliance with state and federal regulations, and in accordance with the Radiological Effluent Control Program outlined in the Administrative Section of the Technical Specifications (e.g., Unit 1 evaporator or shipped off site for processing).

11.1.2 DESIGN BASES 11.1.2.1 Functional Requirements These systems are required to ensure that the general public and plant personnel are protected against exposure to radioactive material in accordance with the regulations of 10CFRPart 20, and the recommended guidelines of 10CFRPart 50, AppendixI. Under normal plant operating conditions, the radioactive waste processing systems are required to limit radionuclide release concentrations to unrestricted areas to less than the maximum permissible concentrations as specified in 10CFRPart 20, Section1302, and AppendixB.

Interim onsite storage facilities accept waste from Millstone Units 1, 2 and 3. Information regarding facility design criteria is presented in Section11.4 of the Millstone Unit 3 Final Safety Analysis Report.

11.1.2.2 Design Criteria The radioactive waste processing system is designed in accordance with the following criteria:

a.

To protect the general public and plant operating personnel against radiation from materials in accordance with 10CFRPart 20 and 10CFRPart 50, AppendixI.

b.

To limit the levels of radioactivity of the effluents in unrestricted areas to as low as reasonably achievable (ALARA).

c.

To provide suitable control of the release of radioactive materials in gaseous and liquid effluents during normal plant operation including anticipated operational occurrences.

 

e.

To ensure adequate safety under normal and postulated accident conditions.

f.

To provide the capability to permit inspection and testing of appropriate components.

g.

To provide suitable shielding for radiation protection.

h.

To provide appropriate containment and confinement of radioactive materials.

i.

To provide appropriate monitoring capability to detect excessive radiation levels and to monitor effluent discharge paths.

j.

To provide suitable processing of liquid and gaseous radwaste generated in accordance with the following operating and design criteria:

1.

Normal operation with expected primary and secondary side activities calculated in accordance with NUREG-0017 Rev. 1 (Reference11.1-1) using the PWR-GALE code.

2.

Normal operation with design basis reactor coolant activities based on 1%

The only portions of the radioactive waste processing system designated as Seismic Category I are the containment penetration piping and isolation valves. However, the high pressure (150 psig) portions of the gaseous waste system, consisting of the compressors, decay tanks, interconnecting piping and valves (see Figure11.1-5), have been designed and analyzed for Seismic Category I requirements as given in Section5.8.

An analysis had been performed, at the time of initial plant licensing, to determine the site boundary doses due to simultaneous failure of the entire radioactive waste processing system, excluding those portions of gaseous waste processing system that were analyzed to Seismic Category I requirements. That analysis was predicated on the original design and operation of the radioactive waste processing system. More recently, this chapter was updated to reflect changes to the radioactive waste processing system design and operation. The results of this update are bounded by those of the original analysis discussed in this subsection.

Failure the of the radioactive waste processing system may release gaseous and liquid wastes into the auxiliary building. The auxiliary building, a Seismic Category I structure, is designed to contain all liquids within the building.

Therefore, the total inventory of radioactivity within the gases contained in the radioactive waste processing system, excluding high pressure portion of gaseous waste system, are assumed to be released.

Under these conditions, the X/Q value of 9.6 x 10-5 sec/m3 is applicable. The doses at 625 meters were calculated by the method of Safety Guides 3 and 4. Based on the results of the original plant licensing analysis, the site boundary doses due to simultaneous failure of entire radioactive waste processing system, excluding portions of gaseous waste system, are as follows:

Normal Operation Based on 0.1% Failed Fuel Thyroid dose (rem) - 3.9 x 10-4 Whole body dose (rem) - 5.04 x 10-2 Normal Operation Based on 1.0% Failed Fuel Thyroid dose (rem) - 4.35 x 10-3 Whole body dose (rem) - 5.78 x 10-1 Since the doses are approximately equal to or less than the limits given in 10CFRPart 20, Sections 105 and 106 and AppendixB (version prior to January 1, 1994), a Seismic Noncategory 1 waste processing system is acceptable.

11.1.2.3 System Components Descriptions of the radioactive waste processing system components are given in Table11.1-1.

11.1.3 LIQUID WASTE PROCESSING SYSTEM 11.1.3.1 System Descriptions Clean Liquid Waste Processing System:

Clean liquid waste is normally tritiated, non-aerated, low conductivity liquid waste consisting primarily of reactor coolant letdown and liquid waste collected from equipment leaks and drains and certain valve and pump seal leaks. The clean liquid radioactive waste processing system is shown schematically in Figures 11.1-1 and 11.1-2. The design of the clean liquid radioactive waste processing system is based upon processing of radioactive liquids postulated to be released from the reactor coolant system (RCS) during normal reactor operation with design basis reactor coolant activities. Operating experience of nuclear power plants indicates that Millstone Unit 2 can expect to continue operating with a percentage of fuel failure much less than the postulated design basis of one percent. Nevertheless, the performance of the clean liquid waste processing system during normal operation is based on both expected and design basis primary side activities.

Discussed in Appendix11.A are the methodologies used to determine the expected and design basis radionuclide activity concentrations in the reactor coolant.

Revision 4106/29/23 MPS-2 FSAR 11.1-4 The clean liquid waste processing system is designed to support the processing of 14 RCS volumes per year of reactor coolant waste. However, the quantity of wastes to be generated and processed annually by this system is approximately 1,200,000 gallons, based on the assumptions used in the 10CFR 50 Appendix I analysis. The liquid waste input streams are shown in Figure 11.B-1.

The clean liquid waste processing system is designed for the processing of reactor coolant wastes concurrently with the letdown flow from the chemical and volume control system (CVCS). This mode of operation, at the maximum clean liquid waste processing flow of 132 gpm, sets the maximum system flow rate.

Reactor coolant is diverted to the clean liquid radioactive waste processing system from the CVCS when changes in RCS inventory or boron concentration are necessitated by startups, shutdowns, fuel depletion, etc. Reactor coolant at a rate of 44 gpm to 132 gpm is let down from the CVCS through a filter to reduce insoluble particulate, after which it flows to the clean liquid radioactive waste processing system for further processing.

Sources of clean liquid waste in the containment are collected in the primary drain tank. A heat exchanger and pump are provided for cooling the primary drain tank content as well as the content of the pressurizer quench tank. The contents of these tanks are maintained or cooled to 120F to minimize the carryover of radioactive moisture to the gaseous waste processing system due to tank venting.

Equipment drains, valve leak-offs, and relief valve discharges from components that are located in the auxiliary building and that contain liquids with dissolved fission gases are collected in the equipment drain sump tank via the closed drain system, as shown in Figure11.1-3. This design minimizes the uncontrolled release of gaseous radioactivity to the atmosphere.

The liquid contents of both the primary drain tank and the equipment drain sump tank are pumped via the demineralizers to the coolant waste receiver tank, bypassing the degasifier. The demineralizers and degasifier are discussed below:

1.

Degasifier The degasifier is installed but not used. The following describes original design.

Reactor coolant degassing is accomplished by diverting the letdown flow in the CVCS to the degasifier in the clean liquid waste system. Interconnecting piping and valves are provided for degassing the reactor coolant prior to cold shutdown of the reactor for refueling operations. The degasifier is placed in service, prior to cold shutdown, to remove hydrogen, fission product gases, and other dissolved gases from the reactor coolant system liquid and to discharge these gases to the waste gas surge tank in the gaseous waste processing system. (See Section11.1.4)

The degassed liquid is pumped through the degasifier effluent cooler, which is used to lower the temperature of this liquid to 120F before it is passed through one of two primary demineralizers. This is done to protect liquid radwaste system demineralizer resins against the damage caused by high liquid temperatures. The  

Revision 4106/29/23 MPS-2 FSAR 11.1-5 degassed reactor coolant is returned to either the volume control tank inlet or to the clean liquid radwaste system primary demineralizers for processing and discharge to the environment.

2.

Demineralizers The two (2) primary and two (2) secondary demineralizers are of the mixed-bed non-regenerating type, the designs of which are based on an expected operating ion exchange capacity of 12,000 grains of CaCO3. The resin beds for mixed-bed non-regenerating demineralizers are mixtures of cation and anion resins in the H-OH forms. These demineralizers are bypassed automatically upon detection of liquid waste temperatures above 135F. An additional secondary demineralizer provides the capability to further polish the waste stream, with the capability of placing the two (2) secondary demineralizers in series operation.

The two receiver tanks provide storage for approximately two RCS volumes (120,000 gal.

nominal) of liquid wastes. A nitrogen gas blanket in each of the tanks is automatically maintained above atmospheric pressure to prevent air in-leakage. The nitrogen cover gas is vented to the gaseous waste processing system or displaced into the other receiver tank or monitor tanks as liquid fills the first receiver tank. No flashing occurs in the receiver tanks, and any transfer of hydrogen or fission gases from the liquid to the cover gas occurs via the slow process of molecular diffusion.

The content of the coolant waste receiver tank is sampled prior to processing. The content of the coolant waste receiver tank is then pumped through either secondary demineralizer(s) or a liquid radioactive waste processing system (activated carbon filters and demineralizers) that can be  

Revision 4106/29/23 MPS-2 FSAR 11.1-6 connected to the Clean Liquid Waste Processing system via connections in the Auxiliary Building Warehouse and then to one of two coolant waste monitor tanks or the aerated waste monitor tank (5,000 gal), which offers a final check on the liquid waste to be released. The total storage capacity of the monitor tanks is approximately one RCS volume (60,000 gal. nominal).

All liquid to be released will be sampled to ensure that the limits set forth in 10CFR Part 20, Sections 1301 and 1302, and Appendix B are not exceeded. If the activity level is unacceptable after sampling the monitor tank contents, then the liquid is reprocessed through the demineralizers or the liquid radioactive waste processing system. If the activity level is within discharge limits, the liquid is pumped through a final filter, at a rate selectable over a range of 10 gpm to 132 gpm, to the circulating water system where it is diluted with the water in the discharge conduit. The proper rate of liquid release to the discharge conduit is determined by sampling the liquid to be released. The concentrations of the limiting isotopes for release are determined. Based on the circulating water flow rate, the discharge rate is selected such that the releases to unrestricted areas are within permissible concentrations as specified in 10 CFRPart 20, AppendixB. The second isolation valve in the waste discharge header to the circulating water system is provided with a panel mounted manual controller for setting the desired flow rate. The clean liquid waste processing system effluent enters the circulating water system discharge box that runs along the south wall of the auxiliary building, as shown in Figure1.2-10. The routing of the discharge structure to the quarry is shown on the plot plan, Figure1.2-2. The circulating water is further diluted by the Long Island Sound tidal flow.

The only liquid discharge path from the clean liquid waste processing system to the environment is through the discharge header, which contains a radiation monitor. The radiation monitor and redundant isolation valves are installed between the waste processing system and the circulating water system. This radiation monitor annunciates in the control room on high radioactivity level and instrument failure, and will automatically close the isolation valves to prevent further discharge. The single radiation monitor serves as a backup system to sampling of the liquid to be released. All liquid to be released is sampled to confirm that the regulations of 10CFRPart 20, Sections 1301 and 1302, and AppendixB and 10CFRPart 50, AppendixI are met. The radiation monitor is described in Section7.5.6.

To prevent the addition of waste to a monitor tank, the content of which is being discharged to the circulating water system, a valve interlock system is provided. The pneumatic valves, located in the discharge piping from each tank, can be opened and kept open only if the corresponding valve in the inlet piping to each tank is closed. This arrangement prohibits the addition of wastes to a previously sampled tank whose content is being released.

Aerated Liquid Waste Processing System:

The design of the aerated liquid waste processing system, shown in Figure11.1-4, is based upon the processing of radioactive liquids (other than those handled by the clean liquid waste processing system) postulated to be generated annually. However, the expected quantity of wastes to be generated and processed annually by this system is approximately 600,000 gallons, based on the assumptions used in the 10CFR50 AppendixI analysis.

Revision 4106/29/23 MPS-2 FSAR 11.1-7 The aerated liquid waste system design is based upon the processing of wastes with a radioactivity level resulting from normal reactor operation with design basis reactor coolant activity concentrations. The performance of the aerated liquid waste processing system during normal operation is evaluated based upon processing of wastes with radioactivity levels resulting from expected reactor coolant source terms as well as from design basis reactor coolant source terms.

Aerated liquid wastes are collected by the open drains system (shown in Figure 11.1-3) that empties into one of two drain tanks. The system is designed for batch processing. The contents of the drain tanks are monitored by sampling and processed through either a system that contains a filter, and one hard-piped demineralizer or a radioactive liquid waste processing system (activated carbon filters and demineralizers) which can be connected to the Aerated Waste Liquid Processing System via connection points located in the Auxiliary Building Warehouse.

The demineralizer/radioactive liquid waste processing system effluent is collected in the aerated waste monitor tank, or the clean waste monitor tanks which offers a final check on the liquid to be released. If the radioactivity level is within discharge limits, as determined by sampling, the liquid is then pumped, at a rate selected over a range of 10 gpm to 100 gpm, to the circulating water system, where it is diluted with water in the discharge conduit. The second isolation valve in the waste discharge header to the circulating water system is provided with a panel mounted manual controller for setting the desired flow rate. The liquid released from the aerated liquid radioactive waste processing system is monitored continuously for radioactivity. The radiation monitor annunciates in the control room on high radioactivity and instrument failure, and will automatically close two isolation valves in the discharge piping to prevent further discharge. The radiation monitor is discussed in Section7.5.6. Provisions are furnished for recycling the monitor tanks content for further processing.

The only liquid discharge path from the aerated liquid waste processing system to the environment is through the discharge pipe containing the radiation monitor. All system leakage, drains, and relief valve flows are collected in the drains system and returned to the aerated liquid waste processing system.

11.1.3.2 System Operation Clean Liquid Waste Processing Systems:

1.

Normal Operation Letdown from the RCS is automatically diverted to the radioactive waste processing system on detection of a high volume control tank liquid level. The flow of wastes into the radioactive waste processing system, normally at a rate of 44 gpm, is intermittent due to changes in RCS inventory or boron concentration necessitated by startups, shutdowns, fuel depletion, etc.

All other liquid wastes input into the clean liquid waste processing system are intermittent due to plant operation. Liquid wastes are collected in either the equipment drain sump tank  

Revision 4106/29/23 MPS-2 FSAR 11.1-8 (EDST) or the primary drain tank. On high tank level, the equipment drain sump tank contents are pumped to the coolant waste receiver tank. During reactor shutdown for refueling, a greater quantity of waste is anticipated due to draining of system equipment for maintenance or inspection. The operation of the primary drain tank system, for collection of liquid wastes in the containment, is on a batch-type basis. On primary drain tank high tank liquid level, an alarm is annunciated in the main control room to alert the plant operator. The operation of the primary drain tank pumps and opening of the containment isolation valves are initiated manually from the control room. The initiation of the operation from the main control room is required to maintain the tank normal operating temperature of 120F.

The processed wastes are collected in the monitor tanks, which offer a final check on the liquid to be released. Sampling is employed to determine the required discharge rate to ensure releases are within 10 CFR Part 20, Sections 1301 and 1302 and AppendixB and 10CFRPart 50, AppendixI limits.

2.

Abnormal Operation Abnormal operation of the clean liquid waste processing system may involve reactor operation with greater than expected failed fuel and larger than anticipated volume of liquid waste generated, such as for cold-shutdowns and startups late in the core cycle. Since the clean liquid radioactive waste processing system is designed for reactor operation with design basis reactor coolant activities for processing 14 RCS volumes of waste per year and with sufficient storage capacity, system operation for these abnormal occurrences will be the same as for normal operation described above.

Aerated Liquid Waste Processing Systems:

1.

Normal Operation The aerated liquid waste processing system is operated on a batch type basis. System processing will vary with the volume of waste generated. The typical processing cycle is expected to be 5 to 7 days.

The aerated waste monitor tank provides a final check on the liquid to be released to ensure compliance with 10CFR Part 20, Sections 1301 and 1302 and Appendix B, and 10 CFR50 AppendixI limits. All potential releases are sampled prior to discharge to the environment.

2.

Abnormal Operation Abnormal operating occurrences considered are larger than expected volumes of wastes, such as for steam generator blowdown processing. If the waste generation rate exceeds the capacity of the system, interconnecting piping is provided for pumping the wastes to the clean liquid radioactive waste processing system for treatment.

11.1.4 GASEOUS WASTE PROCESSING SYSTEM 11.1.4.1 System Descriptions The gaseous waste processing system, shown in Figure11.1-5, processes potentially radioactive hydrogenated waste gases. The system design is based upon the processing of radioactive gases postulated to be released from the RCS during normal operation with design basis reactor coolant activities. The gaseous waste processing system is shown as one of the streams in Figure11.B-2.

Waste gases flow to the waste gas header and are collected in the waste gas surge tank. When the surge tank pressure increases to approximately 3 psig, one of the two 25 scfm compressors is automatically started by pressure instrumentation located on the tank. The surge tank gases are compressed into one of the six waste gas decay tanks, where gases are stored at a maximum pressure of 150 psig.

The storage capacity of each waste gas decay tank is based on the storage of waste gases expected to enter the system during any two months of normal operation. For all the waste gases entering the system, including those contributed by operational occurrences, the six decay tanks provide adequate storage capacity for a decay time of 90 days. Gases are held in the decay tanks until the radioactivity level has been reduced by decay and the gases are suitable for release. Prior to release, the gases in the decay tanks are sampled to determine compliance with the regulations of 10CFRPart 20, Sections 1301 and 1302 and AppendixB, and 10CFRPart 50, AppendixI.

The decay tanks discharge through an absolute (i.e., HEPA) filter to the Millstone stack. The discharge pipe contains a radiation monitor and redundant automatic isolation valves. A radiation monitor annunciates in the control room on high radioactivity level and instrument failure and will automatically close the isolation valves to prevent any further release.

The release rate for waste gases is selectable over a range of 10 scfm to 50 scfm. The rate is determined by sampling the content of the decay tank to be discharged. The radionuclide concentrations are correlated with the potential site boundary dose and the 10CFRPart 20, AppendixB Effluent Concentrations, and the release rate is determined.

The pneumatic valve in the inlet to each decay tank is interlocked with the corresponding valve in the tank discharge piping. The discharge valve can be opened and remains open only when the inlet valve is closed. This feature precludes the inadvertent release of waste gases that are not sampled.

11.1.4.2 System Operation 1.

Normal Operation Waste gases from the sources shown in Figure11.B-2 are collected in the waste gas surge tank through the waste gas header. As the pressure in the surge tank increases to 3 psig, one compressor is automatically started by pressure instrumentation mounted on the surge tank. If the surge tank pressure continues to increase, the second compressor is automatically started at 5 psig. The compressor discharges the waste gases into one of the six decay tanks selected by the operator. When the decay tank being filled reaches approximately 140 psig pressure, an alarm is annunciated in the control room to alert the operating personnel. The inlet valve to the decay tank is closed remotely by the operator, and one of the five remaining decay tanks is selected to receive the gases.

After an appropriate storage period, and after sampling has confirmed that 10CFRPart 20, Sections 1301 and 1302 and AppendixB, and 10CFR50 AppendixI limits are met, the gases are released on a controlled batch basis to the Millstone stack.

2.

Abnormal Operation The gaseous waste processing system, under abnormal conditions (e.g., unexpectedly large volumes of gases) will function in a fashion similar to that for normal conditions.

11.1.4.3 Gaseous Release Radiological Consequences Annual design basis and expected releases of radioactive gaseous waste are presented in Table11.A-9. Gaseous release radiological consequences are presented in Appendix11.C.

11.1.4.4 Waste Gas System Failure 11.1.4.4.1 General The limiting accident considered is the postulated and uncontrolled release to the auxiliary building of the radioactive xenon and krypton gases stored in one waste gas decay tank. The credibility of such an occurrence is low since the waste gas system is not subjected to pressures  

Revision 4106/29/23 MPS-2 FSAR 11.1-11 greater than 150 psig, or large stresses. The result of a rupture of a gas decay tank is analyzed in order that the maximum hazard, which would result from a malfunction in the radioactive waste process system, will be defined.

11.1.4.4.2 Method of Analysis It is assumed that the tank contains the gaseous activity evolved from degassing one system volume of reactor coolant for refueling. The maximum activity would exist prior to cold shutdown at the end of an operating cycle during which extended operation with one percent defective fuel had occurred. Based on this and neglecting decay after degasification, the noble gas activity in the tank is given in Table 11.1-5.

11.1.4.4.3 Results of Analysis (1)

The current waste gas system failure analysis is based on updated reactor coolant design activity contained in Table11.A-1. This analysis results in a whole body dose of 3.0E-01 rem at the EAB and 4.0E-02 rem at the LPZ. The current results are bounded by the licensed values listed above.

11.1.4.4.4 Conclusions If a waste gas decay tank rupture did occur, the dose would be substantially below 10CFRPart 100 guidelines.

11.1.5 SOLID WASTE PROCESSING SYSTEM 11.1.5.1 System Descriptions The solid waste processing system is designed to provide controlled handling of spent resins, contaminated filter cartridges, and miscellaneous solid waste. The system is designed for handling solid waste with radioactivity levels resulting from reactor operation with design basis reactor coolant source terms. The sources and expected annual volumes of solid wastes are given in Table11.1-2.

The estimated isotopic curie inventory for each source of solid waste is given in Table11.1-3. The activity data in Table11.1-3 are based on analyses done for the original licensing of Millstone Dose (rems)

Design of the solid waste processing system for handling and disposal of each type of solid waste is as follows:

Solid waste containers, shipping casks, methods of packaging, and transportation meet applicable federal regulations 10 CFR Part 71and 10CFR171-178, and wastes are buried at a licensed burial site in accordance with applicable NRC 10CFRPart 61. Solid waste treatment design is in compliance with the requirements of 10CFRPart 20, Sections 1301 and 1302 as it relates to radioactivity in effluents to unrestricted areas.

The spent resin radwaste system is shown in Figure11.1-7.

B.

(See FSAR Section11.2 for shielding design.) For the removal of contaminated cartridges, the concrete hatch plug is removed first. Then contaminated cartridges are removed in accordance with plant procedures.

Miscellaneous Solid Wastes Contaminated metallic materials and solid objects are placed in disposable shipping containers for transportation to an off site waste-processing facility or disposal site.

A temporary storage facility for two high-integrity containers is provided in the container storage area of the auxiliary building. Temporary storage for various containers prior to further disposition can also be provided depending on curie content and container quantity.

Casks used for shipment of filter cartridges and miscellaneous solid wastes are rented as needed.

The containers are designed to prevent loss or dispersal of the contents and to maintain self-shielding properties under normal conditions of transport. Where surface dose rates exceed those allowed by the applicable Department of Transportation (DOT) regulations, the containers are provided with additional shielding. Where the curie content of the containers might exceed the regulatory limit applicable to this type of shipment, special casks licensed by DOT and by NRC, if required, would be used.

The shipment of radioactive waste materials is governed by NRC regulations as set forth in 10 CFR Part 71 and regulations of the U. S. DOT contained in 49CFRParts 170 through 178.

The packaging and shipping of all waste from the Millstone site is in accordance with these regulations and any other applicable regulations that may come into effect. All loading of radioactive waste containers is performed by qualified personnel and monitored by radiation protection personnel. The transportation is provided by a carrier authorized by the disposal site operator in accordance with NRC and DOT regulations. The material to be shipped from the site is sent to a licensed waste disposal site or to a licensed waste-processing facility.

Table11.1-4 gives the total estimated annual curie inventory of solid wastes to be shipped from the station for off-site burial. This estimated inventory is based on analyses done for the original licensing of Millstone Unit 2 and is not derived from the updated radionuclide activities shown in the Appendices to FSAR Chapter11.

System Operation 1.

Normal Operation Spent resins from the sources listed in Table11.1-3 are collected in the spent resin tank for radioactive decay, or loaded directly into a shipping container, dewatered using a radioactive solid waste processing system and then sealed and prepared for shipment. The spent resins from the spent resin tank are subsequently loaded into a shipping container and are dewatered by the spent resin shipping cask dewatering pump and portable dewatering pumps. After dewatering, the shipping container and cask are sealed and prepared for shipment.

 

 

Individual system components are located so as to allow access for periodic inspection and testing after component decontamination. Major components are located in individual shielded rooms or compartments to maintain access control.

Revision 4106/29/23 MPS-2 FSAR 11.1-16 11.

==1.7 REFERENCES==

11.1-1 NUREG-0017 Rev. 1, Calculation of Releases of Radioactive Materials in Gaseous and Liquid Effluents from Pressurized Water Reactors, PWR-GALE Code.

Revision 4106/29/23 MPS-2 FSAR 11.1-17 TABLE11.1-1 RADIOACTIVE WASTE PROCESSING SYSTEM COMPONENT DESCRIPTION CLEAN LIQUID WASTE PROCESSING SYSTEM Primary Drain Tank Pumps Type Inline horizontal centrifugal with mechanical seals Quantity 2

Case ASTM A-351 Gr CF8M Impeller ASTM A-351 Gr CF8M Shaft ASTM A-276 TP 316 Motor 7.5 hp Codes and Standards ASME Section III Class 3 (1971)

===1.5 Material===

Case ASTM A-351 Gr CF8M Impeller ASTM A-351 Gr CF8M Shaft ASTM A-276 TP 316  

Degasifier Pumps (continued)

Motor (hp) 7.5 Code ASME Section III Class 3 (1971)

Seismic design class 2

Design integrated radiation dosage (rad) 106 Coolant Waste Receiver Tank and Monitor Tank Pumps Type Inline horizontal centrifugal with mechanical seals Quantity 2

Design temperature (F) 175 Design head (TDH) (feet) 115 Design capacity (gpm) 132 NPSH available (feet) 30 Minimum NPSH required (feet) 10 Material:

Case ASTM A-351 Gr CF8M Impeller ASTM A-351 Gr CF8M Shaft ASTM A-276 TP 316 Motor (hp) 7.5 Code ASME Section III Class 3 (1971)

Seismic design class 2

Design integrated radiation dosage (rad) 106 Equipment Drain Sump Tank Pumps Type Vertical wet pit Quantity 2

Design temperature (F) 150 Design head (feet) 125 Design capacity (gpm) 50 Material:

Case Type 316 stainless steel Impeller Type 316 stainless steel Shaft Type 316 stainless steel  

Equipment Drain Sump Tank Pumps (continued)

Motor (hp) 10 Code Hydraulic Pump Institute Seismic design class 2

Design integrated radiation dosage (rad) 106 Primary Drain Tank and Quench Tank Cooler Pump Type Inline horizontal centrifugal with mechanical seals Quantity 1

Design temperature (F) 325 Design head (TDH) (feet) 125 Design capacity (gpm) 100 NPSH available (feet) 3.3-50 Minimum NPSH required (feet) 3 Material:

Case ASTM A-351 Gr CF8M Impeller ASTM A-351 Gr CF8M Shaft ASTM A-276 TP 316 Motor (hp) 10 Code ASME Section III Class 3 (1971)

Seismic design class 2

Design integrated radiation dosage (rad) 106 Primary Drain Tank Type Horizontal Quantity 1

Volume (gallons net) 1,500 Design pressure (psig) 20 Design temperature (F) 250 Operating pressure (psig) 3 Operating temperature (F) 120-150 Material ASTM A-240 TP 304 Design code ASME Section III Class 3 (1971)

Seismic design classification 2  

Coolant Waste Receiver Tanks Type Vertical Quantity 2

Volume (gallons net) 60,000 Design pressure (psig) 15 Design temperature (F) 150 Operating pressure (psig) 3 Operating temperature (F) 120 Material ASTM A-240 TP 304 Design code:

ASME Section III Class C (1968 Edition including addenda through Summer 1970)

Seismic design classification 2

Coolant Waste Monitor Tanks Type Vertical Quantity 2

Volume (gallons net) 30,000 Design pressure (psig) 15 Design temperature (F) 150 Operating pressure (psig) 3 Operating temperature (F) 120 Material ASTM A-240 TP 304 Design code:

ASME SectionIII Class C (1968 Edition including Addenda through Summer 1970)

Seismic design classification 2

Equipment Drain Sump Tank Type Vertical Quantity 1

Volume (gallons net) 500 Design pressure (psig 20 Design temperature (F) 150 Operating pressure (psig) 3  

Equipment Drain Sump Tank (continued)

Operating temperature (F) 120 Material ASTM A-240 TP 304 Design code ASME Section III Class 3 (1971)

Seismic design classification 2

Degasifier Type Packed column utilizing internally generated stripping steam.

Quantity 1

Design pressure (psig) 50 Design temperature (F) 250 Operating pressure (psig) 5.3 Operating temperature (F) 228 Design capacity (gpm) 40 to 132 Performance See Figure 11.1-6 Design codes:

ASME SectionVIII, ANSI B31.1 Column:

Packing One inch Rashig rings.

Height (feet) 4.25 Diameter (feet) 2 Materials:

Components containing radioactive material: ASTM A-240 TP 304 Other components:

Carbon steel Seismic design classification 2  

Coolant Waste-Demineralizers (Primary and Secondary)

Type Mixed-bed, non-regenerative Quantity 4 (See Note 3)

Design pressure (psig) 100 Design temperature (F) 150 Operating pressure (psig) 60 Operating temperature (F) 120 Design flow (gpm) 132 Design code ASME Section III Class 3 (1971)

Material ASTM A-240 TP 304 Seismic design classification 2

Coolant Waste-Filters Type Disposable cartridge Quantity 2

Design pressure (psig) 200 Design temperature (F) 250 Operating pressure (psig) 60 Operating temperature (F) 120 Design flow rate (gpm) 132 Operating flow (gpm) 40-132 Filter rating (micron) 3 Design filter efficiency (%)

80 Design code:

Materials:

Vessel ASTM A-312 TP 304 Internals TP 304 SS, Micarta Cartridges Ethylene propylene Seismic design classification 2  

Coolant Waste-Piping and Valves Piping:

Material ASTM A-312 TP-304 or 316/316L Design pressure (psig) 50, 100, 150 Design temperature (F) 150, 250, 300, 350 Joints 2.5 inches and larger Butt welded except at flanged equipment.

Joints 2 inches and smaller Socket welded except at flanged equipment **

Codes:

Fabrication ANSI B31.7 Class III

* Testing and Installation ASME SectionIII Class 3 (1971) *, **

Valves:

ASTM A-182 F304, F316; ASTM A-351 CF8, CF-8M, ASME SA-479 Ratings:

2.5 inches and larger 150 lb ANSI 2 inches and smaller 600 lb ANSI ***

Code:

* Portions of the Clean Liquid Waste Processing System have been replaced with piping and piping components designed, constructed and tested to the ANSI B31.1 Power Piping Code with augmented requirements per the guidance in Regulatory Guide 1.143.  

** Portions of the Clean Liquid Radwaste System have been designed, constructed and tested to the ANSI B31.1 Piping Code with augmented quality requirements per Regulatory Guide 1.143.  

*** 2inch and smaller Socket-Welding Ends valves were originally specified as an ANSI 600lb rating. The pressure temperature rating class of valves replaced in accordance with the Dominion Design Control Process is determined based on the design conditions of the application in accordance with applicable Construction Code requirements. Therefore, the pressure temperature rating class of installed replacement valves may be higher or lower than 600lb, based on the design conditions of the specific application.

Revision 4106/29/23 MPS-2 FSAR 11.1-24 TABLE11.1-1 RADIOACTIVE WASTE PROCESSING SYSTEM COMPONENT DESCRIPTION (CONTINUED)

AERATED LIQUID WASTE PROCESSING SYSTEM Aerated Waste Drain and Monitor Tanks Type Vertical Quantity 3

Volume (gallons net) 5,000 Design pressure Atmospheric Design temperature (F) 150 Operating pressure Atmospheric Operating temperature (F) 120 Material ASTM A-240 TP 304 Design codes ASME Section III - ASME Section VIII (Original Fabrication)

Seismic design classification 2

Aerated Waste Demineralizer Type Mixed-bed, non-regenerative Quantity 1

Design pressure (psig) 100 Design temperature (F) 150 Operating pressure (psig) 60 Operating temperature (F) 120 Design flow (gpm) 132 Normal operating flow (gpm) 50 Design code ASME Section III Class 3 (1971)

Material ASTM A-240 TP 304 Seismic design classification 2

Filters Type Disposable cartridge Quantity 2

Design pressure (psig) 200 Design temperature (F) 250 Operating pressure (psig) 60  

Operating temperature (F) 120 Design flow rate (gpm) 132 Operating flow (gpm) 40-132 Filter rating (micron) 3 Design filter efficiency (%)

80 Design code:

Seismic design 2

A Aerated Waste Drain Tank Pump Type Inline horizontal centrifugal with mechanical seals Quantity 1

Design temperature (F) 180 Design head (TDH) (feet) 238 Design capacity (gpm) 90 NPSH available (feet) 27 Minimum NPSH required (feet) 9 Horsepower (hp) 15 Material:

Case ASTM A-351 Gr CF8M Impeller ASTM A-351 Gr CF8M Shaft ASTM A-276 TP 316 Codes and standards ASME Section III Class 3 (1971)

Seismic design classification 2

Design integrated radiation dosage (rads) 106 B Aerated Waste Drain Tank and Monitor Tank Pumps Type Inline horizontal centrifugal with mechanical seals Quality 2

Design temperature (F) 150 Design head (TDH) (feet) 135 Design capacity (gpm) 50 NPSH available (feet) 27 Minimum NPSH required (feet) 5 Horsepower (hp) 5  

Material:

Case ASTM A-351 Gr CF8M Impeller ASTM A-351 Gr CF8M Shaft ASTM A-276 TP 316 Codes and standards ASME Section III Class 3 (1971)

Seismic design classification 2

Design integrated radiation dosage (rads) 106 Piping and Valves Piping:

Material ASTM A-316 TP 304 or 316L Design pressure (psig) 50 and 100 Design temperature (F) 150 Joints:

2.5 inches and larger Butt welded except at flanged equipment 2 inches and smaller Socket welded except at flanged equipment Codes:

Fabrication ANSI B31.7 Class III

* Testing and Installation ASME Section III Class 3 (1971)

* Valves Material ASTM A-182 F 304, F316, ASME SA-479 Ratings:

2.5 inches and larger 150 lb ANSI 2 inches and smaller 600 lb ANSI**

Code ASME Draft for Pumps and Valves for Nuclear Service (1968) *

* Portions of the Aerated Liquid Waste Processing System have been replaced with piping and piping components designed, constructed and tested to the ANSI B31.1 Power Piping Code with augmented requirements per the guidance in Regulatory Guide 1.143.  

** 2inch and smaller Socket-Welding Ends valves were originally specified as an ANSI 600lb rating. The pressure temperature rating class of valves replaced in accordance with the Dominion Design Control Process is determined based on the design conditions of the application in accordance with applicable Construction Code requirements. Therefore, the pressure temperature rating class of installed replacement valves may be higher or lower than 600lb, based on the design conditions of the specific application.

Revision 4106/29/23 MPS-2 FSAR 11.1-27 TABLE11.1-1 RADIOACTIVE WASTE PROCESSING SYSTEM COMPONENT DESCRIPTION (CONTINUED)

GASEOUS WASTE PROCESSING SYSTEM Waste Gas Compressors Type Diaphragm, single state Quantity 2

Capacity (scfm) 25 at 14.7 psia suction pressure Design discharge pressure (psig) 150 Design pressure (psig) 165 Materials:

Diaphragm TP 301 stainless steel or 316 stainless steel Support cylinder ASTM A-105 Grade 2 Motor (hp) 40 Seismic design classification See Note 1 Design integrated radiation level (rads) 3.5 x 105 Code:

ASME SectionVIII, ASME Draft for Pump and Valves for Nuclear Service, ANSI B31.7.

Waste Gas Surge Tank Quantity 1

Type Vertical Design pressure (psig) 20 Design temperature (F) 150 Normal operating pressure (psig) 3 to 5 Normal operating temp (F) 150 Volume (ft3) approx 609 Material ASTM A-240 TP 304 Seismic design classification 2

Code:

ASME SectionIII Class C (1968 Edition including Addenda through 1970).

Waste Gas Decay Tank Type Vertical Quantity 6

Design pressure (psig) 165 Design temperature (F) 150 Normal operating pressure (psig) 5 to 150 Normal operating temp (F) 120 Volume (ft3) 582 Specified 627 As-Built Material ASTM A-515 Grade 70 Seismic design classification See Note 1 Code:

ASME SectionIII Class C (1968 Edition including Addenda through summer 1970).

Waste Gas Filter Type Disposable cartridge with HEPA filter and demister Quantity 1

Design flow (scfm) 50 Normal operating flow (scfm) 5 - 25 Design pressure (psig) 165 Design temperature (F) 150 Normal operating pressure (psig) 4 Normal operating temp (F) 120 Design efficiency 99.97% of particles 0.3 micron and larger Material:

Filter housing ASTM A-240 TP 304 Internals TP 304 stainless steel Cartridge Glass fiber Code ASME Section III Class 3 (1971)

Seismic design classification See Note 1  

Piping and Valves Piping:

Material ASTM A-106 Grade B Design pressure (psig) 50, 150 and 200 Design temperature (F) 150, 200 and 300 Joints:

2.5 inches and larger Butt welded except at flanged equipment.

2 inches and smaller Socket welded except at flanged equipment.

Codes:

Fabrication ANSI B31.7 Class III Testing and Installation ASME SectionIII Class 3 (1971)

Design seismic classification 2 (See Note1)

Valves:

Materials ASTM A-216, Grade WCB Ratings:

2.5 inches and larger 150 lb ANSI butt weld ends 2 inches and smaller 3,000 lb ANSI socket weld ends Code:

ASME Draft for Pup and Valves for Nuclear Service (1968).  

Revision 4106/29/23 MPS-2 FSAR 11.1-30 TABLE11.1-1 RADIOACTIVE WASTE PROCESSING SYSTEM COMPONENT DESCRIPTION (CONTINUED)

SOLID WASTE PROCESSING SYSTEM Spent Resin Storage Tank Type Vertical Quantity 1

Volume (ft3) 380 Design pressure (psig) 75 Operating pressure (psig) 35 Design temperature (F) 175 Operating temperature (F) 120 Material ASTM A-240 TP 304 Design code ASME SectionIII Class 3 (1971)

Seismic design classification 2

Spent Resin Shipping Cask Dewatering Pump Type Horizontal Centrifugal Quantity 1

Capacity (gpm) 10 Head (feet) 92 Material Stainless steel Note 1:

The high pressure components of the gaseous waste processing system are designated as Seismic Class 2 equipment. However, the components are designed to meet Seismic Class 1 loadings due to the nature of the equipment service.

Note 2:

The supply lines to the solidification concentrates pump were cut in accordance with PDCR 2-54-95.

Note 3:

Secondary Demineralizer may be filled with either ion-specific resin or mixed bed resin.

Revision 4106/29/23 MPS-2 FSAR 11.1-31

** 55 gallon drums Aerated Waste hardpiped demineralizer at 42 cu. ft. x 1 =

42 cubic feet Aerated Waste sluicible portable demineralizers at 15 cubic feet/each x 3 = 45 cubic feet Spent Fuel Pool demineralizer at 42 cubic feet x 1 =

42 cubic feet Primary Liquid Radwaste demineralizers at 42 cubic feet x 2 =

84 cubic feet Secondary Liquid Radwaste demineralizer at 42 cubic feet x 1 =

42 cubic feet Letdown Ion Exchangers at 32 cubic feet x 3 =

96 cubic feet 351 cubic feet Note:

The data in this Table is not derived from the updated 10CFR50 AppendixI analysis. The best source of Solid Waste Volumes can be found in the Annual Radiological Effluent Release Report.

ION EXCHANGER AND DEMINERALIZER RESINS Chemical and Volume Control System Purification Ion Exchanger Resin Chemical and Volume Control System Purification Ion Exchanger Resin Chemical and Volume Control System Deborating Ion Exchanger Resin Primary Clean Liquid Waste Demineralizer Demineralizer Resin Aerated Liquid Waste Demineralizer Resin Spent Fuel Pool Clean-up Demineralizer Resin Isotope (Curies)

(Li Removal) (Curies)

(Curies)

(Curies)

(Curies)

(Curies)

Normal Maximum Normal Maximum Normal Maximum Normal Maximum Normal Maximum Normal Maximum Cr-51 Mn-54 Mn-56 Co-58 Fe-59 Co-60 4.78 x 10-2 0.478 9.6 x 10-3 9.6 x 10-2 1.2 x 10-3 1.2 x 10-2 1.12 x 10-4 1.9 x 10-3 8.72 x 10-5 1.01 x 10-2 1.23 12.3 Rb-88 1.366 13.66 0.246 2.46 3.1 x 10-3 5.22 x 10-2 2.4 x 10-3 0.279 67.2 672 Rb-89 3.06 x 10-2 0.306 5.5 x 10-3 5.5 x 10-2 6.9 x 10-5 1.17 x 10-3 5.38 x 10-5 6.25 x 10-3 1.69 16.9 Sr-89 13.8 138.0 2.398 23.98 3.11 x 10-2 0.525 2.41 x 10-2 2.80 0.134 1.34 Sr-90 3.052 30.52 0.471 4.71 6.77 x 10-3 0.114 5.25 x 10-3 0.610 6.88 x 10-3 6.88 x 10-2 Y-90 2.24 x 10-2 0.224 4.31 x 10-5 7.26 x 10-4 3.34 x 10-5 3.88 x 10-3 2.69 x 10-2 0.269 Sr-91 6.9 x 10-2 0.691 1.26 x 10-2 0.126 1.57 x 10-4 2.65 x 10-3 1.22 x 10-4 1.41 x 10-2 9.39 x 10-2 0.939 Y-91 7.71 x 10-2 0.771 1.48 x 10-4 2.5 x 10-3 1.15 x 10-4 1.33 x 10-2 2.93 29.3 Zr-95 Mo-99 52.46 524.6 0.101 1.70 7.82 x 10-2 9.08 53.5 535 Ru-103 7.84 78.4 1.57 x 10-2 0.157 1.51 x 10-2 0.255 1.17 x 10-2 1.36 0.109 1.09 Ru-106 2.02 20.2 0.363 3.63 4.58 x 10-3 7.72 x 10-2 3.55 x 10-3 0.412 6.54 x 10-3 6.54 x 10-2

Revision 4106/29/23 MPS-2 FSAR 11.1-33 I-129 9.36 x 10-4 9.36 x 10-3 1.56 x 10-4 1.56 x 10-3 2.1 x 10-6 3.54 x 10-5 1.63 x 10-6 1.89 x 10-4 1.9 x 10-6 1.9 x 10-5 Te-129 5.42 x 10-2 0.542 1.09 x 10-2 0.109 1.3 x 10-3 1.3 x 10-2 1.28 x 10-4 2.15 x 10-3 9.88 x 10-5 1.15 x 10-2 0.662 6.62 I-131 1,680.0 16,800.0 336.0 3,360.0 19.2 192.0 3.91 65.9 3.03 352 105 1,050 I-132 5.04 50.4 1.007 10.07 0.121 1.21 1.19 x 10-2 0.20 9.19 x 10-3 1.07 26.9 269 Te-132 49.3 493.0 9.86 98.6 0.944 9.44 0.116 1.95 8.96 x 10-2 10.4 8.7 87.0 I-133 247.0 2,470.0 4.94 49.4 5.91 59.1 0.496 8.35 0.384 44.6 149 1,490 Cs-134 388.0 3,800.0 517.0 5,170.0 1.74 29.3 1.35 156 2.64 26.4 I-134 1.06 10.6 0.212 2.12 2.54 x 10-2 0.254 2.49 x 10-3 4.2 x 10-2 1.93 x 10-3 0.225 16.3 163 Te-134 3.19 x 10-2 0.319 6.4 x 10-3 6.4 x 10-2 7.65 x 10-4 7.65 x 10-4 7.5 x 10-5 1.26 x 10-3 5.82 x 10-3 6.76 x 10-3 0.691 6.91 I-135 35.9 359.0 7.24 72.4 0.869 8.69 8.46 x 10-2 1.43 6.56 x 10-2 7.62 71.2 712 Cs-136 18.12 181.2 3.48 x 10-2 0.587 2.7 x 10-2 3.14 0.672 6.72 Cs-137 1,695.0 16,950.0 1,728.0 17,280.0 6.58 111 5.10 593 8.44 84.4 Cs-138 0.14 1.40 2.69 x 10-4 4.54 x 10-3 2.09 x 10-4 2.42 x 10-2 18.2 182 Ba-140 4.08 40.8 0.743 7.43 9.27 x 10-3 0.156 7.19 x 10-3 0.835 0.161 1.61 La-140 0.469 4.69 9.37 x 10-2 0.937 1.08 x 10-3 1.82 x 10-2 8.38 x 10-4 9.74 x 10-2 0.154 1.54 Pr-143 3.49 34.9 0.697 6.97 8.05 x 10-3 0.136 6.24 x 10-3 0.725 0.154 1.54 Ce-144 26.2 262.0 5.24 52.4 6.04 x 10-2 1.02 4.68 x 10-2 5.44 0.109 1.09 TABLE 11.1-3 RADIOACTIVITY LEVELS OF SOLID WASTES (SEE NOTE) (CONTINUED)

Revision 4106/29/23 MPS-2 FSAR 11.1-34 TABLE11.1-3 RADIOACTIVITY LEVELS OF SOLID WASTES (SEE NOTE) FILTER CARTRIDGES Chemical and Volume Control System Filter Cartridges Clean Liquid Waste Filter Cartridges Aerated Liquid Waste Filter Cartridges Spent Fuel Pool Clean-up Filter Cartridges Reactor Vessel Head Decontamination System Filter Cartridges Isotope (Curies/Cartridges)

(Curies/Cartridge)

(Curies/Cartridges)

(Curies/Cartridge)

(Curies/Cartridges)

Normal Maximum Normal Maximum Normal Maximum Normal Maximum Normal Maximum Cr-51 0.209 13.05 0.001 0.043 0.452 0.003 0.185 0.039 0.039 Mn-54 0.935 0.67 0.002 0.002 0.004 0.024 0.004 0.003 0.028 0.028 Mn-56 0.486 0.002 0.018 Co-58 64.0 107.0 0.123 0.347 0.192 3.702 0.50 0.84 4.78 4.78 Fe-59 0.192 0.069 0.001 0.001 0.002 0.002 0.001 0.022 0.022 Co-60 0.025 61.0 0.166 1.766 0.068 0.142 0.533 0.533 Br-84 Rb-88 Rb-89 Sr-89 Sr-90 Y-90 Sr-91 Y-91 Zr-95 Mo-99 Ru-103 Ru-106 I-129 Te-129 I-131

Chemical and Volume Control System Filter Cartridges Clean Liquid Waste Filter Cartridges Aerated Liquid Waste Filter Cartridges Spent Fuel Pool Clean-up Filter Cartridges Reactor Vessel Head Decontamination System Filter Cartridges Isotope (Curies/Cartridges)

(Curies/Cartridge)

(Curies/Cartridges)

(Curies/Cartridge)

(Curies/Cartridges)

Normal Maximum Normal Maximum Normal Maximum Normal Maximum Normal Maximum

Revision 4106/29/23 MPS-2 FSAR 11.1-36 Note:

The activity data in this Table are based on analysis done for the original licensing of Millstone Unit 2 and are not derived from the updated radionuclide activities shown in the Appendices to FSAR Chapter11. The best source of Solid Waste data can be found in the Annual Radiological Effluent Release Report.

Revision 4106/29/23 MPS-2 FSAR 11.1-37 TABLE11.1-5 ASSUMPTIONS FOR WASTE GAS DECAY TANK ACCIDENT Assumption (1) Maximum Noble Gas Activity in Waste Gas Decay Tank.

Basis: Maximum activity in tanks based on 1% degraded fuel, core power = 2700 MWt and degassing one system volume.

Assumption (2) 2 Hour Ground Level Release.

Basis: Regulatory Guide 1.24 Assumption (3) Ground Level X/Q:

LPZ 4.80 E -05 (sec/m3)

Basis: 95% maximum X/Qs during the years 1974 -1981.

 

 

 

The figure indicated above represents an engineering controlled drawing that is Incorporated by Reference in the MPS-2 FSAR. Refer to the List of Effective Figures for the related drawing number and the controlled plant drawing for the latest revision.  

The figure indicated above represents an engineering controlled drawing that is Incorporated by Reference in the MPS-2 FSAR. Refer to the List of Effective Figures for the related drawing number and the controlled plant drawing for the latest revision.  

The figure indicated above represents an engineering controlled drawing that is Incorporated by Reference in the MPS-2 FSAR. Refer to the List of Effective Figures for the related drawing number and the controlled plant drawing for the latest revision.  

Revision 4106/29/23 MPS-2 FSAR 11.1-43 FIGURE 11.1-4 P&ID AERATED LIQUID RADWASTE SYSTEM The figure indicated above represents an engineering controlled drawing that is Incorporated by Reference in the MPS-2 FSAR. Refer to the List of Effective Figures for the related drawing number and the controlled plant drawing for the latest revision.  

Revision 4106/29/23 MPS-2 FSAR 11.1-44 FIGURE 11.1-5 P&ID DIAGRAM GASEOUS RADWASTE SYSTEM The figure indicated above represents an engineering controlled drawing that is Incorporated by Reference in the MPS-2 FSAR. Refer to the List of Effective Figures for the related drawing number and the controlled plant drawing for the latest revision.  

Revision 4106/29/23 MPS-2 FSAR 11.1-45 FIGURE 11.1-6 DEGASIFIER PERFORMANCE CURVE

Revision 4106/29/23 MPS-2 FSAR 11.1-46 FIGURE 11.1-7 P&ID SPENT RESIN RADWASTE SYSTEM The figure indicated above represents an engineering controlled drawing that is Incorporated by Reference in the MPS-2 FSAR. Refer to the List of Effective Figures for the related drawing number and the controlled plant drawing for the latest revision.  

Revision 4106/29/23 MPS-2 FSAR 11.2-1 11.2 RADIATION PROTECTION 11.2.1 FINAL SAFETY ANALYSIS REPORT UPDATE It should be noted that the information in this section provided the basis and description of the shielding design prior to operation. As the station has operated, dose rates have fluctuated within the various areas as a function of time but for the most part have remained well within the zone designation limits presented below. Minor changes in equipment layout from that indicated in Figures 11.2-1 through 11.2-10 have been made, but since the values and figures given in this section provided the design basis for the major shielding structures, they are not being changed.

The values and figures given in this section should not be used to estimate area dose rates. Actual health physics surveys are available and should be consulted to get a more accurate and up-to-date indication of radiological conditions.

Appendices 11.D and 11.E provide some of the design basis considerations on the control and expected levels of airborne radioactivity in the plant. Again, health physics survey data should be consulted for more realistic indications of actual airborne radioactivity levels. The occupational exposure due to airborne radioactivity has been insignificant in comparison to the direct radiation exposure.

Revision 4106/29/23 MPS-2 FSAR 11.2-2 The maximum external dose rates within the station are shown in the radiation zone diagrams, Figures11.2-1 through 11.2-10, as described in this subsection and later in Section 11.2.2. These maximum external dose rates are based on one percent failed fuel. Since the expected amount of failed fuel is much less than this, the average external dose rates will be much lower. The unrestricted areas in the plant where construction workers and plant visitors may be are all radiation Zone A areas which have a maximum dose rate of 0.5 mrem/hr. Only plant workers are allowed in radiation zones with dose rates above this level, and their stay times are increasingly limited as the dose rate increases.

The anticipated average dose rates will vary within each zone and with operating conditions. In general, the dose rate normally around process equipment is expected to be at least an order of magnitude lower than indicated by the applicable zone. This is due to the extremely conservative assumptions made concerning the quantity of failed fuel. The direct dose at the site boundary is negligible both in the case of normal operation and under postulated incident conditions.

Shielding wall thicknesses, as shown in Figures11.2-1 through 11.2-10, were found using the theory of the Reactor Shielding Design Manual by T. Rockwell, Reactor Physics Constants ANL-5800, Table of Isotopes by Perlman and Lederer, Engineering Compendium on Radiation Shielding and Nuclear Engineering Handbook by H. Etherington. The geometric considerations were determined by each physical situation, such as source configurations and distances to dose points.

If the source was liquid, then self-attenuation by water was used. If the source was gaseous, then no self-attenuation was assumed. If the source was solid, the volume percentages of each solid were used for self-attenuation (for example, solidified waste in drums).

Shields included the tank or pipe walls which were assumed to have an attenuation coefficient similar to that for iron.

Sources were given in Mev/cm3 sec for each of 7 standard energy bins: 0.4, 0.8, 1.3, 1.7, 2.2, 2.5, > 2.5 Mev, and 6.1 and 7.1 Mev for nitrogen 16. One percent failed fuel was assumed.

The shield thicknesses were determined by the amount of shielding required to achieve a dose rate less than the upper limit for the radiation zone in which the dose point was located.

Revision 4106/29/23 MPS-2 FSAR 11.2-3 The shielding design, therefore, is based on conservative assumptions ensuring adequate radiation protection to the general public and to operating personnel as well.

11.

==2.3 DESCRIPTION==

Shielding throughout Millstone Unit 2 is designed in accordance with the criteria specified in Section 11.2.1. Figures11.2-1 through 11.2-10 show the equipment placement, the quantity of shielding used and the appropriate radiation zones. All components containing radioactive fluids are shown on the figures except the refueling water storage tank (RWST), located as shown on Figure1.2-2. The maximum direct dose rate from the content of the RWST is 5.6 x 10-3 mr/hr, based on reactor operation with one percent failed fuel. The maximum total site boundary dose due to the RWST is approximately 1.66 mrem/yr. For normal operating conditions, the site boundary doses will be approximately one-tenth of those values given above.

11.2.3.1 Containment Shielding The containment shielding consisting of the primary shielding, the reactor cavity neutron shielding, the secondary shielding, and the containment wall, is shown on Figure1.2-6.

Primary shielding is provided to limit radiation emanating from the reactor vessel. The primary shielding is designed to:

a.

Attenuate the neutron flux to limit the activation of components and structural steel.

b.

Limit the radiation level after shutdown to permit access to the reactor coolant system equipment.

c.

To reduce, in conjunction with the secondary shield, the radiation level from sources within the reactor vessel to allow limited access to the containment during normal operation.

The primary shield consists of a minimum of five feet of reinforced concrete surrounding the reactor vessel. The cavity between the primary shield and the reactor vessel insulation is air-cooled to prevent overheating and dehydration of the concrete primary shield wall.

A reactor cavity neutron shield reduces the operating neutron and gamma dose rates in the containment. A dose reduction factor of 40 on the operating floor of the containment was the design goal for the shield. With the postulation of leak-before-break applied to the reactor coolant piping, the neutron shield design does not consider dynamic effects resulting from a design basis LOCA.

The permanent reactor cavity neutron shield consists of borated concrete blocks contained inside stainless steel containers. The concrete blocks are supported by the shielding support bars, which span between the reactor vessel flange and the embedment ring. The borated concrete blocks are 15 inches high and 23.25 inches wide, located all around the reactor vessel beneath the permanent

Revision 4106/29/23 MPS-2 FSAR 11.2-4 reactor cavity seal. The bottom and the sides of the shielding are insulated by NUKON blanket insulation to maintain an acceptable shielding temperature as well as limit heat loss from the reactor vessel (Figures11.2-11 through 11.2-12). Thermal analysis has shown that the borated concrete blocks inside the stainless steel containers could reach a temperature of up to 455F in some sections of the concrete blocks during normal operation.

The shielding is provided with personnel access openings, located directly above the neutron detector wells. During reactor operation these openings are plugged with borated concrete shield plugs to further minimize neutron flux. The shield plugs are removed through the access openings in the permanent cavity seal for maintenance of the neutron detector instrumentation.

The shielding in combination with the reactor cavity seal described in Section4.3.10 will provide adequate airflow channels to maintain sufficient cavity cooling during reactor operation.

In addition to the borated concrete shielding, borated polyethylene layers are installed approximately at the reactor vessel flange elevation to reduce streaming between the borated concrete shielding and the primary shield wall. The thickness of the polyethylene shielding ranges from 1 to 3 inches contained in stainless steel liner between the ribs of the support members. The borated polyethylene layers are not insulated. This shielding is cooled by cavity cooling air passing under the shielding at temperatures less than 150F. Together, the borated concrete blocks and the borated polyethylene layers are capable of reducing the neutron radiation by a dose factor of approximately 16 to 27.

Secondary shielding is provided to reduce the activity from the reactor coolant system to radiation levels which allow limited access to the containment during normal operation and to supplement primary shielding. Nitrogen 16 is the major source of radioactivity in the reactor coolant during operation and controls the thickness of the secondary shield. The secondary shielding consists of a minimum of 3.5 feet of reinforced concrete surrounding the reactor coolant piping, pumps, steam generators and pressurizer. The N-16 activity concentration at the reactor vessel outlet nozzles is 9.8 x 10-5 Ci/cc at full power.

The containment is a reinforced prestressed concrete structure with 3.75 feet thick cylindrical walls and a 3.25 feet thickness dome. In conjunction with the primary and secondary shield, it will limit the radiation level outside the enclosure building due to sources inside the structure to no more than 0.5 mrem/hr at full power operation. The structure is also designed to protect plant personnel from radiation sources inside the structure following a postulated incident.

11.2.3.2 Auxiliary Building Shielding The function of the auxiliary building shielding is to protect personnel working near various system components, such as those in the CVCS, the radioactive waste processing system, sampling system, and the spent fuel pool cooling system. Controlled access to the auxiliary building is allowed during reactor operation. Each equipment compartment is individually shielded to reduce the radiation level in it and adjacent compartments as reflected by the zone designations. Source terms used in the design of shielding for major components throughout the  

Revision 4106/29/23 MPS-2 FSAR 11.2-5 auxiliary building are listed in Table11.2-1. Similar source terms for all components containing radioactive materials were developed and used in the shielding design.

11.2.3.3 Control Room Shielding The layout of the control room is shown in Figure1.2-7. In conformance with General Criterion Number 19 of 10CFRPart 50, the control room shielding is designed to ensure that the dose will not exceed 5 rem for the duration of the incident (see Subsection 14.18.3.3). The walls of the control room are two feet thick. Under normal operating conditions, the control room is a Zone A region with expected dose rates well below the indicated limits.

11.2.3.4 Spent Fuel Pool Shielding and Fuel Handling Shielding Fuel handling shielding is designed to facilitate the removal and transfer of spent fuel assemblies from the reactor vessel to the spent fuel pool. it is designed to protect personnel against the radiation emitted from the spent fuel and control rod assemblies.

The refueling cavity above the reactor vessel is flooded to Elevation 36 feet 6 inches to provide a temporary water shield above the components being withdrawn from the reactor vessel.

The water height is approximately 24 feet above the reactor vessel flange. This height assures a minimum of 108 inches of water above the active portion of a withdrawn fuel assembly at its highest point of travel. Under these conditions, the dose rate from the spent fuel assembly is less than 1.0 mrem/hr at the water surface.

Upon removal of the fuel assembly from the reactor vessel, it is moved to the spent fuel pool by the fuel transfer mechanism, via the fuel transfer tube. Concrete shielding is provided around reactor internals storage and the steam generator for personnel protection during refueling. The spent fuel pool in the auxiliary building is permanently flooded to provide a minimum of 108 inches of water above the active portion of a fuel assembly when being withdrawn from the fuel transfer tube and raised by the fuel pool platform crane, prior to insertion in the spent fuel storage rack. The minimum water height above stored fuel assemblies is approximately 24.5 feet during operation of the spent fuel pool cooling system, described in Section9.5.2.1, to avoid air entrainment at the pump suction intakes. Otherwise, a minimum height of 23 feet prevails in the spent fuel pool and also, while fuel is in movement, above the reactor pressure vessel, to satisfy fission product retention assumptions for fuel handling accident calculations (see Section14.7.4.2). The sides of the spent fuel pool are six feet thick concrete to ensure a dose rate of less than 0.035 mrem/hr on the outer surface of the spent fuel pool.

11.2.3.5 Piping Systems Shielding All piping systems containing radioactive material are routed and/or provided with shielding in accordance with the radiation zones given in Section11.2.1. Consideration is given to maintenance and inspection requirements for components located in shielded compartments through which these lines are routed.

Revision 4106/29/23 MPS-2 FSAR 11.2-6 Isometrics of field run piping, two inches and smaller in diameter, were reviewed and approved by Bechtel Corporation Engineering Department.

11.2.4 HEALTH PHYSICS PROGRAM Information regarding the health physics program organization is presented in Section 12.5 of Millstone 3 Final Safety Analysis Report (Reference 11.2-1). That information is contained herein by reference.

11.

==2.5 REFERENCES==

11.2-1 Millstone Unit 3, Final Safety Analysis Report, Section12.5 - Health Physics Program

Revision 4106/29/23 MPS-2 FSAR 11.2-7 TABLE11.2-1 SOURCE TERMS FOR SHIELDING DESIGN Isotope Letdown Pre-Filter (Curies)

Purification Ion Exchanger (Curies)

Letdown Post-filter (Curies)

Volume Control Tank Demineralizer Degasifier (Curies)

Br-84 1.23 840.6 4.24x10-3 Kr-85m 34.0 0.0 Kr-85 87.1 0.0 Kr-87 18.4 0.0 Kr-88 58.2 0.0 Rb-88 38.20 4.63 0.23 Rb-89 0.82 0.11 4.02x10-3 Sr-89 339.80 0.01 5.24x10-4 Sr-90 85.90 5.0x10-4 2.63x10-5 Y-90 1.79 2.1x10-2 1.05x10-3 Sr-91 6.7x10-3 3.32x10-4 Y-91 5.22 0.26 Mo-99 40.86 2.06 Ru-103 222.0 8.4x10-3 4.24x10-4 Ru-106 59.4 4.9x10-4 2.49x10 Te-129 1.54 5.0x10-2 2.52x10-3 I-129 2.4x10-2 1.44x107 7.29x10-9 I-131 4.26x104 8.01 4.04x10-1 Xe-131m 50.8 0.0 Te-132 1.40x103 0.65 3.27x10-2 I-132 129.0 2.03 1.03x10-1 I-133 6.32x102 10.90 5.51x10-1 Xe-133 5012.3 0.0 Te-134 0.92 4.7x102 2.39x10-3

Revision 4106/29/23 MPS-2 FSAR 11.2-8 I-134 27.55 1.13 5.72x10-2 Cs-134 8.19 4.13X10-1 I-135 933.4 5.04 2.54x10-1 Xe-135 172.4 0.0 Cs-136 0.28 1.45x10-2 Cs-137 39.78 2.0 Xe-138 8.16 0.0 Cs-138 1.24 3.27x10-2 Ba-140 104.2 1.23x10-2 6.23x10-4 La-140 13.1 1.19x10-2 6.00x10-4 Pr-143 1.08x10-2 5.45x10-3 Ce-143 7.74x10-3 3.91x10-3 Co-60 263.0 2.63 1.98x10-4 1.0x10-5 Fe-59 0.45 4.5x10-3 3.83x10-6 2.09x10-7 Co-58 690.0 6.90 1.42x10-3 7.18x10-6 Mn-56 3.27 3.27x10-2 4.14x10-3 2.09x10-5 Mn-54 3.69 3.69x10-2 4.95x10-6 2.50x10-7 Cr-51 88.10 0.88 4.32x10-4 2.18x10-7 Zr-95 1.54 0.15 3.42x10-6 1.73x10-7 TABLE 11.2-1 SOURCE TERMS FOR SHIELDING DESIGN (CONTINUED)

Isotope Waste Gas Surge Tank Waste Gas Decay Tank Aerated Waste Drain Tank Aerated Waste Demineralizer Aerated Waste Monitor Tank Br-84 8.8x10-3 2.78x10-5 8.8x10-4 Kr-85m 4.09x102 2.80x102 Kr-85 3.13.102 2.61x103 Kr-87 6.97x101 1.41x101 Kr-88 4.80x102 2.10x102 Rb-88 0.486 8.63x10-4 0.243 Rb-89 1.2x10-2 1.85x10-5 6x10-3 Sr-89 1.08x10-3 7.68x10-3 5.4x10-4 Sr-90 5.47x10-5 1.94x10-3 2.74x10-5 Y-90 2.20x10-4 4.05x10-5 2.2x10-4 Sr-91 7.04x10-4 3.52x10-4 Y-91 5.49x10-2 5.49x10-2 Mo-99 0.430 0.430 Ru-103 8.84x10-4 5.02x10-3 8.84x10-5 Ru-106 5.19x10-5 1.34x10-3 5.19x10-6 Te-129 5.24x10-3 3.48x10-5 5.24x10-4 I-129 1.52x10-8 5.42x10-7 1.52x10-9 I-131 0.842 9.63x10-1 8.42x10-2 Xe-131m 1.80x103 1.37x104 Te-132 6.81x10-2 3.16x10-2 6.81x10-3 I-132 0.214 2.92x10-3 2.14x10-2 I-133 1.15 1.43x10-2 1.15x10-1 Xe-133 1.71x105 1.17x106 Te-134 4.98x10-3 2.08x10-5 4.98x10-4

Revision 4106/29/23 MPS-2 FSAR 11.2-10 I-134 0.119 6.23x10-4 1.19x10-2 Cs-134 0.861 0.430 I-135 0.530 2.11x10-2 5.3x10-2 Xe-135 3.41x102 4.86x102 Cs-136 3.03x10-2 1.52x10-2 Cs-137 4.18 2.09 Xe-138 6.75 2.99x10-1 Cs-138 1.31x10-1 6.6x10-2 Ba-140 1.30x10-3 2.35x10-3 1.30x10-4 La-140 1.25x10-3 2.96x10-4 1.25x10-4 Pr-143 1.14x10-3 1.14x10-4 Ce-143 8.14x10-4 8.14x10-5 Co-60 2.08x10-4 2.08x10-5 Fe-59 4.03x10-6 4.03x10-7 Co-58 1.50x10-3 1.50x10-4 Mn-56 4.35x10-3 4.35x10-4 Mn-54 5.29x10-6 5.20x10-7 Cr-51 4.54x10-4 4.54x10-3 Zr-95 3.60x10-6 3.6x10-7 TABLE 11.2-1 SOURCE TERMS FOR SHIELDING DESIGNS (CONTINUED)

Isotope Primary Demineralizer Coolant Waste Receiver Secondary Demineralizer Coolant Waste Monitor Tanks Primary Drain Tank Br-84 4.87x10-1 0.106 4.87x10-2 5.30x10-3 2.65x10-1 Kr-85m Kr-85 Kr-87 Kr-88 Rb-88 4.87x10-1 5.84 4.87x10-2 2.92x10-2 1.50x10+1 Rb-89 1.04x10-2 0.145 1.04x10-3 7.24x10-3 3.62x10-1 Sr-89 4.34 1.30x10-2 4.34x10-2 6.48x10-4 3.24x10-2 Sr-90 1.10 6.56x10-4 1.10x10-1 3.28x10-5 1.64x10-3 Y-90 4.71x10-2 2.63x10-2 4.71x10-3 1.32x10-3 6.59x10-3 Sr-91 2.28x10-2 8.45x10-3 2.28x10-3 4.22x10-4 2.11x10-2 Y-91 2.50x102 6.59 2.50x10-1 3.29x10-1 1.65 Mo-99 9.47x101 5.16x101 9.47 2.58 1.29x101 Ru-103 2.83 1.06x10-2 2.83x10-1 5.30x10-4 2.65x10-2 Ru-106 7.59x10-1 6.22x10-4 7.59x10-2 3.11x10-4 1.56x10-3 Te-129 1.96x10-2 6.29x10-2 1.96x10-3 3.15x10-3 1.57x10-1 I-129 3.07x10-4 3.04x10-5 I-131 5.43x102 1.01x101 5.43x101 5.05x10-1 2.53x101 Xe-131m Te-132 1.77x101 0.818 1.77 4.09x10-2 2.04 I-132 1.64 2.566 1.65x101 1.28x10-1 6.42 I-133 8.06x101 1.378x101 8.06 6.89x10-1 3.45x101 Xe-133 Te-134 1.16x10-2 5.97x10-2 1.16x10-3 2.99x10-3 1.49x10-1

Revision 4106/29/23 MPS-2 FSAR 11.2-12 I-134 3.52x10-10 1.43 3.52x10-2 7.15x10-2 3.58 Cs-134 1.50x104 1.03x101 1.5x103 5.17x10-1 2.58x101 I-135 3.52x10-1 6.36 3.52x10-2 3.18x10-1 1.59x101 Xe-135 Cs-136 3.06x101 3.63x10-1 3.06 1.82x10-2 9.08x10-1 Cs-137 8.38x104 5.0x101 8.38x103 2.50 1.252 Xe-138 Cs-138 2.34x10-1 8.18x10-1 2.34x10-2 4.09x10-2 3.92 Ba-140 1.33 1.56x10-2 1.33x10-1 7.79x10-4 3.89x10-2 La-140 1.68x10-1 1.5x10-2 1.68x10-2 7.51x10-4 3.75x10-2 Pr-143 1.24 1.24x10-1 1.24x10-1 6.81x10-3 3.41x10-2 Ce-143 1.09x101 9.77x10-2 1.09 4.88x10-3 2.44x10-2 Co-60 6.25x10-3 Fe-59 1.21x10-4 Co-58 4.49x10-2 Mn-56 1.31x10-1 Mr-54 1.56x10-4 Cr-51 1.36x10-2 Zr-95 1.08x10-4 TABLE 11.2-1 SOURCE TERMS FOR SHIELDING DESIGNS (CONTINUED)

FIGURE 11.2-1 P&ID, RADIATION ZONES AND ACCESS CONTROL NORMAL OPERATION WITH 1.0% FAILED FUEL CONTAINMENT AND AUXILIARY BUILDING - ELEVATION (-) 45 FEET 6 INCHES  

FIGURE 11.2-3 P&ID, RADIATION ZONES AND ACCESS CONTROL NORMAL OPERATION WITH 1.0% FAILED FUEL CONTAINMENT AND AUXILIARY BUILDING - ELEVATION (-) 5 FEET 0 INCHES  

ELEVATION 14 FEET 6 INCHES AND 38 FEET 6 INCHES  

 

 

 

 

 

 

 

 

 

 

Revision 4106/29/23 MPS-2 FSAR 11.2-27 FIGURE 11.2-15 NEUTRON SHIELD - THERMAL LOADINGS (TYPICAL ANNULAR SECTION)

Revision 4106/29/23 MPS-2 FSAR 11.2-28 FIGURE 11.2-16 NEUTRON SHIELD - THERMAL LOADINGS (PLUG SHIELD SECTION)

Revision 4106/29/23 MPS-2 FSAR 11.A-1 11.A SOURCE TERMS FOR RADIOACTIVE WASTE PROCESSING AND RELEASES TO THE ENVIRONMENT 11.A.1 REACTOR COOLANT DESIGN BASIS RADIONUCLIDE ACTIVITIES To calculate reactor coolant design-basis radionuclide activities, a calculation of reactor core source term (discussed in Section 11.A.1.1 below) was performed. Reactor coolant activities were calculated taking into account (a) leakage from the fuel pellets to the primary coolant due to fuel pin cladding failure, (b) removal by radioactive decay, (c) removal by the CVCS purification system, (d) removal of primary coolant for boron reduction, and (e) discharge of primary coolant to the liquid waste processing system. Included in the resultant reactor coolant design-basis radionuclide inventory are activated corrosion products (crud) and tritium (discussed in Sections11.A.1.2 and 11.A.1.3, respectively). Table11.A-1 provides a tabulation of the design-basis reactor coolant radionuclide activities. Bases for the calculation of these activities are presented in Table11.A-10.

11.A.1.1 Development of Reactor Core Radionuclide Activities For conservatism, the model used to calculate reactor core radionuclide activities employs an end-of-cycle equilibrium fuel cycle condition. Cycle characteristics are consistent with nominal two-year fuel cycles (with an 80% capacity factor included). The ORIGEN-S computer program is used to model the buildup and decay of core fission product radionuclides.

1.

The ORIGEN-S results are calculated in terms of gram-atoms per metric tonne of initial heavy metal. These results are converted, as necessary, to activities (in Curies) in the core using the following equation:

=

Revision 4106/29/23 MPS-2 FSAR 11.A-2 where NA is in atoms per gram-atom, is in seconds-1, ACF is the activity conversion factor (equal to 3.7 x 1010 disintegrations/second per Curie), Mu1 is equal to 19.208 metric tonnes of uranium in Batch 1, Mu2 is equal to 13.72 metric tonnes of uranium in Batch 2, and where B1C1, B1C2, B1C3, B2C1, and B2C2 are batch/cycle-specific values (in gram-atoms per metric tonnes of uranium) calculated by ORIGEN-S.

The reactor core radionuclide activities thus calculated and used as basic source terms are tabulated in Table11.A-2. Also presented in Table11.A-2 are the bases for the calculation of these reactor core radionuclide activities.

11.A.1.2 Corrosion Products The activity concentrations of activated corrosion products (crud) in the reactor coolant have been calculated based on the model in the ANSI/ANS standard1 dealing with the radioactive source term for normal operation of light water reactors. The starting point for this calculation was the reactor coolant radionuclide activity concentrations specified in the standard for a reference PWR with U-tube steam generators (such as those used at Millstone Unit 2). These activity concentrations were altered by adjustment factors that were prepared in accordance with the ANSI/ANS model to reflect the operating parameter differences between Millstone Unit 2 and the reference PWR, and were then further adjusted to the Technical Specification radionuclide concentration limits.

11.A.1.3 Tritium Production Tritium may be produced in the coolant or enter the coolant from a number of sources. One source is from fissioning of uranium within the fuel, yielding tritium as a tertiary fission product. Since zircaloy fuel cladding reacts with tritium to form zircaloy hydride, no tritium diffuses through the cladding 2, 3. Therefore, the tritium released to the coolant from the fuel originates only from defective fuel.

Tritium is also produced by the reaction of neutrons with boron in the control element assemblies (CEAs). Data from operating plants using B4C control rods indicates that no tritium is released from the control rods. The tritium may combine with carbon to form hydrocarbons and/or with lithium to form lithium hydride, thereby preventing diffusion through the inconel cladding.

Another possibility is that the low internal temperature of the B4C control rods (relative to 1

ANSI/ANS-18.1-1984, American National Standard Radioactive Source Term for Normal Operation of Light Water Reactors, dated 12/31/1984 2

James M. Smith, Jr., The Significance of Tritium in Water Reactors, GE, APED, 9/19/67 3

Joseph W. Ray, et. al., Investigation of Tritium Generation and Release in PM Nuclear Power Plants, BMI-1787, 10/31/66

Revision 4106/29/23 MPS-2 FSAR 11.A-3 stainless clad fuel rods from which about 45% escape can be expected) may prohibit tritium diffusion. To account for possible control rod cladding defects, it is assumed that one percent of the tritium produced in the CEAs is released to the coolant.

Another source of tritium is the activation of boron, lithium, deuterium, and nitrogen within the reactor coolant. Boron in the form of boric acid is used in the coolant for reactivity control.

Lithium is produced in the coolant as a result of neutron-boron reaction and may also be added as a pH control agent. Deuterium is a naturally occurring constituent of water. Nitrogen may be present due to aeration of the coolant during shutdown and due to aerated makeup water.