ML15258A378
ML15258A378 | |
Person / Time | |
---|---|
Site: | SHINE Medical Technologies |
Issue date: | 08/27/2015 |
From: | Bynum R V Shine Medical Technologies |
To: | Office of Nuclear Reactor Regulation |
Lynch S | |
References | |
SHINE, SHINE.SUBMISSION.22, SHN.PSAR.P, SHN.PSAR.P.10 | |
Download: ML15258A378 (27) | |
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Chapter 8 - Electrical Power SystemsTable of ContentsSHINE Medical Technologies8-iRev. 0CHAPTER 8ELECTRICAL POWER SYSTEMSTable of ContentsSectionTitlePage8a1HETEROGENEOUS REACTOR ELECTRICAL POWER SYSTEMS ...........8a1-18a2IRRADIATION UNIT ELECTRICAL POWER SYSTEMS...............................8a2-18a2.1NORMAL ELECTRICAL POWER SYSTEMS ...............................................8a2-1 8a2.1.1SHINE FACILITY OFF-SITE POWER SERVICE ..........................................8a2-18a2.1.2SHINE FACILITY POWER DISTRIBUTION SYSTEM ..................................8a2-18a2.1.3SHINE FACILITY STANDBY DIESEL GENERATOR ...................................8a2-18a2.1.4SHINE FACILITY LOADS SUPPORTED BY SDG .......................................8a2-28a2.1.5POWER DISTRIBUTION EQUIPMENT ........................................................8a2-2 8a2.1.6SHINE FACILITY GROUNDING SYSTEM ...................................................8a2-2 8a2.1.7LIGHTNING PROTECTION SYSTEM ..........................................................8a2-38a2.1.8CATHODIC PROTECTION SYSTEM ...........................................................8a2-38a2.1.9FREEZE PROTECTION ................................................................................8a2-3 8a2.1.10CABLE AND RACEWAY COMPONENTS ....................................................8a2-38a2.1.11RACEWAY AND CABLE ROUTING .............................................................8a2-38a2.1.12SHINE FACILITY IRRADIATION UNITS .......................................................8a2-4 8a2.1.13DESIGN BASES.............................................................................................8a2-48a2.1.14TECHNICAL SPECIFICATIONS....................................................................8a2-48a2.2EMERGENCY ELECTRICAL POWER SYSTEMS .......................................8a2-98a2.2.1CLASS 1E UPSS ..........................................................................................8a2-98a2.2.2250 VDC CLASS 1E BATTERY SUBSYSTEM .............................................8a2-98a2.2.3SHINE FACILITY SYSTEMS SERVED BY THE CLASS 1E UPSS ............8a2-108a2.2.4NONSAFETY-RELATED LOADS ...............................................................8a2-10 8a2.2.5MAINTENANCE AND TESTING .................................................................8a2-108a2.2.6SURVEILLANCE METHODS ......................................................................8a2-118a2.2.7SEISMIC QUALIFICATION .........................................................................8a2-11 8a2.2.8INDEPENDENCE ........................................................................................8a2-118a2.2.9SINGLE-FAILURE CRITERION ..................................................................8a2-118a2.2.10SAFE SHUTDOWN OF THE IRRADIATION UNIT .....................................8a2-11 8a2.2.11MONITORING SYSTEMS ON UPSS ..........................................................8a2-128a2.2.12TECHNICAL SPECIFICATIONS..................................................................8a2-128a2.3IRRADIATION FACILITY ELECTRICAL POWER SYSTEMSTECHNICAL SPECIFICATIONS..................................................................8a2-158a
2.4REFERENCES
............................................................................................8a2-16 Chapter 8 - Electrical Power SystemsTable of ContentsSHINE Medical Technologies8-iiRev. 0Table of Contents(cont'd)SectionTitlePage8bRADIOISOTOPE PRODUCTION FACILITY ELECTRICAL POWER SYSTEMS ...................................................................................8b-18b.1NORMAL ELECTRICAL POWER SYSTEMS ...........................................8b-18b.2EMERGENCY ELECTRICAL POWER SYSTEMS ...................................8b-28b.3RADIOISOTOPE PRODUCTION FACILITY ELECTRICALPOWER SYSTEMS TECHNICAL SPECIFICATIONS...............................8b-3 Chapter 8 - Electrical Power SystemsList of TablesSHINE Medical Technologies8-iiiRev. 0List of TablesNumberTitle8a2.1-1Normal Electrical Power Switchgear Load List8a.2.1-2 Standby Diesel Generator Load List8a.2.1-3 Normal Electrical Power Supply System Major Component Data8a.2.1-4 Standby Diesel Generator System Major Component Data 8a.2.2-1UPSS Load List8a.2.2-2 Emergency Electrical Power Supply System Major Component Data Chapter 8 - Electrical Power SystemsList of FiguresSHINE Medical Technologies8-ivRev. 0List of FiguresNumberTitle8a2.1-1One-Line Diagram - Normal Electrical Power Supply System8a2.2-1One-Line Diagram - Uninterruptible Electrical Power Supply System Chapter 8 - Electrical Power SystemsAcronyms and AbbreviationsSHINE Medical Technologies8-vRev. 1Acronyms and AbbreviationsAcronym/AbbreviationDefinitionAampereACalternating current ANSIAmerican National Standards Institute CAAScriticality accident and alarm system CAMScontinuous air monitoring system DCdirect current ESFengineered safety feature FFPSfacility fire detection and suppression FSARFinal Safety Analysis Report HCFDhot cell fire detection and suppression system hphorsepower HVACheating, ventilation, and air conditioning Hzhertz IEEEInstitute of Electrical and Electronics EngineersIFirradiation facility kVkilovolt kVAkilovoltampere kWkilowatt LEUlow enriched uranium LOEPloss of electric power LOOPloss of off-site power LWPSlight water pool system MCCmotor control center NACENational Association of Corrosion Engineering NDASneutron driver assembly system NECNational Electrical Code NEMANational Electrical Manufacturers Association Chapter 8 - Electrical Power SystemsAcronyms and AbbreviationsSHINE Medical Technologies8-viRev. 0Acronyms and Abbreviations (cont'd)Acronym/AbbreviationDefinitionNFPANational Fire Protection AssociationNPSSnormal electrical power supply system RAMSradiation area monitoring system RCAradiologically controlled area SCADA/HMIsupervisory control and data acquisition/ human machine interfaceSDGstandby diesel generator SHINESHINE Medical Technologies, Inc.
SWGRswitchgear TPStritium purification systemTOGSTSV off-gas systemTPCSTSV process control system TRPSTSV reactivity protection system TSVtarget solution vessel UPSSuninterruptible power supply system Vvolts VACvolts - alternating current VDCvolts - direct current Chapter8 -Electrical Power SystemsHeterogeneous Reactor Electrical Power SystemsSHINE Medical Technologies8a1-1Rev. 0CHAPTER 8ELECTRICAL POWER SYSTEMS8a1HETEROGENEOUS REACTOR ELECTRICAL POWER SYSTEMSThe SHINE Medical Technologies, Inc. (SHINE) facility is not a reactor-based facility; therefore,this section does not apply to the SHINE facility.
Chapter8 -Electrical Power SystemsNormal Electrical Power SystemsSHINE Medical Technologies8a2-1Rev. 08a2IRRADIATION UNIT ELECTRICAL POWER SYSTEMS8a2.1NORMAL ELECTRICAL POWER SYSTEMSThe normal electrical power supply consists of 480 volts-alternating current (VAC) off-site power service from the local utility, Alliant Energy, and an on-site commercial standby diesel generator (SDG). The normal power is used for normal operation and normal shutdown of the facility.8a2.1.1SHINE FACILITY OFF-SITE POWER SERVICEThe SHINE facility receives a single, independent power off-site circuit from the transmission electric network. This power circuit feeds into two 12 kilovolt (kV) power feeds connected to two local outdoor 12 kV - 480Y/277 VAC 3-phase transformers at 2000 kilovoltampere (kVA) each.
Approximate connected facility loads to each of these transformers are about 1500 kVA. Table 8a2.1-1 provides a listing of the loads connected to the main facility switchgear (SWGR) A and B. The 12 kV feeders originate from the Alliant Energy Turtle substation located in Turtle Township, Rock County, Wisconsin about 4.5 circuit miles from the SHINE facility. The 12 kV feeders and transformers are utility-owned equipment. The SHINE facility metering point is at each of the transformer secondary sides at 480 VAC. The metering point is the interface between the SHINE facility and the utility.Each of the two transformers is connected to one of the SHINE facility's two main 480 VAC switchgear buses. Figure 8a2.1-1 depicts the off-site connections to the SHINE facility. 8a2.1.2SHINE FACILITY POWER DISTRIBUTION SYSTEMThe SHINE facility power distribution voltages are 480Y/277 VAC and 208Y/120 VAC 3-phase, 60 hertz (Hz). The outdoor lighting system utilizes 480Y/277 VAC, 3-phase, 60 Hz. The power distribution is designed to operate within the service voltage range of 504Y/291 V to 456Y/263 V (ANSI, 2011). Larger 480 VAC motor loads consist of heating, ventilation, and air conditioning (HVAC) chillers, supply and exhaust fans, and a motor driven fire pump which is connected directly to the off-site transformer A. Each main facility switchgear feeds two motor control centers (MCCs) which supply the smaller motor loads, cranes, heaters, facility indoor and outdoor lighting, etc. Table 8a2.1-1 contains the normal electrical power switchgear nominal load list. Table 8a2.1-3 contains component data for the normal electrical power supply system (NPSS).8a2.1.3SHINE FACILITY STANDBY DIESEL GENERATOR The standby power system is powered by an on-site commercially available diesel generator system and supplies power to selected loads in the event of loss of off-site power (LOOP).
Availability of the standby diesel generator (SDG) power source is not required for any Class 1E safety function at the SHINE facility. If loss of voltage is detected at both SDG switchgear (SWGR) A and B, the SDG starts automatically and is directly connected to both SDG SWGR A and B.If loss of voltage is detected at only one SDG SWGR, either SWGR A or B, the SDG starts automatically and is directly connected only to the bus that lost voltage.
Chapter8 -Electrical Power SystemsNormal Electrical Power SystemsSHINE Medical Technologies8a2-2Rev. 0In all cases, the SDG voltage and frequency is established before the connection and is directly connected in less than sixty seconds from a detected loss of voltage. The SDG SWGRs and SDG MCCs are fed automatically. The SDG operates in an isochronous mode when operating under a LOOP event.When off-site power is available to be restored to main SWGR buses A and B, the SDG is disconnected from the SDG SWGR before off-site power is re-connected to the main switchgear buses A and B via a manually initiated dead bus (slow) transfer.When off-site power is available to be restored to either main SWGR bus A or B, the SDG is disconnected from the SDG SWGR bus A or B before off-site power is re-connected to its respective main switchgear bus via a manually initiated dead bus (slow) transfer.Table 8a2.1-4 contains component data for the SDG system.8a2.1.4SHINE FACILITY LOADS SUPPORTED BY SDG The SDG load profile contains priority loads for asset protection, battery chargers, inverter bypass voltage regulating transformers, emergency lighting, and other nonsafety-related loads that are required during a loss of off-site power. Table 8a2.1-2 contains an SDG load list.The SDG is sized to provide power to the asset protection loads such as battery chargers, inverter bypass voltage regulating transformers, emergency lighting, and SDG MCCs. Under normal operation these loads are powered from the off-site source. Upon loss of off-site power, the SDG is automatically connected to SDG switchgears and associated SDG MCCs. The operator has the option of adding additional facility loads to the SDG bus manually based on SDG capacity availability.8a2.1.5POWER DISTRIBUTION EQUIPMENT Low voltage switchgear, MCCs, power distribution panels, lighting panels, and other electrical components comply with acceptable industry standards such as Institute of Electrical and Electronics Engineers (IEEE), American National Standards Institute (ANSI), and National Electrical Manufacturers Association (NEMA). The installation of the electrical power distribution system and associated equipment complies with local codes and National Fire Protection Association (NFPA) 70 (National Electrical Code [NEC]) (NFPA, 2011a).8a2.1.6SHINE FACILITY GROUNDING SYSTEM The SHINE facility grounding system complies with the guidelines provided in local codes, NFPA70 (NEC) (NFPA, 2011a), and IEEE 1050 (IEEE, 2004b). It consists of facility grounding grid, system grounding, equipment grounding, and instrument/computer grounding. The grounding grid consists of buried, interconnected bare copper rods and ground rods forming a facility ground grid matrix.The system grounding provides grounding of neutrals of transformers and SDG.
The equipment grounding sub-system provides grounding of equipment enclosures, metal structures, metallic tanks, low voltage switchgear, MCCs, and control cabinets.
Chapter8 -Electrical Power SystemsNormal Electrical Power SystemsSHINE Medical Technologies8a2-3Rev. 0The instrument/computer grounding design is consistent with the guidance provided in IEEE 1050 (IEEE, 2004b). Surge suppression devices are placed as needed on incoming 480 VAC feeds from the utility.8a2.1.7LIGHTNING PROTECTION SYSTEMThe SHINE facility lightning protection system complies with local codes and NFPA 780 (NFPA, 2011b) and is directly connected to the facility ground system.8a2.1.8CATHODIC PROTECTION SYSTEM The buried metallic pipes, tanks, structures are provided with a cathodic protection system in accordance with guidance provided in National Association of Corrosion Engineering (NACE).8a2.1.9FREEZE PROTECTIONEquipment and piping runs that are required for normal functions and are impacted by extreme winter temperature elements are provided with freeze protection.8a2.1.10CABLE AND RACEWAY COMPONENTSThe design, installation, and separation of the cable raceway components for SHINE facility complies with NFPA 70 (NEC) (NFPA, 2011a) and local codes. Circuit voltages are designated per the guidance provided in ANSI C84.1 (ANSI, 2001).Circuit voltages are:*480Y/277 VAC power*250 volts-direct current (VDC) power (limited to battery connections to uninterruptible power supply system [UPSS])*208Y/120 VAC control and power*Instrumentation circuits (less than 120 V).8a2.1.11RACEWAY AND CABLE ROUTINGThere are three separation groups for cables and raceways: Group A, B, and N. Separation Group A contains safety-related circuits from Division A. Similarly, separation Group B contains safety-related circuits from Division B. Group N contains remaining facility non-safety related cables. Spatial separation between groups is in accordance with IEEE 384 (IEEE, 2008) and Regulatory Guide 1.75.Non-Class 1E circuits are electrically isolated from Class 1E circuits by isolation devices in accordance with IEEE 384 (IEEE, 2008).
Chapter8 -Electrical Power SystemsNormal Electrical Power SystemsSHINE Medical Technologies8a2-4Rev. 18a2.1.12SHINE FACILITY IRRADIATION UNITSEach irradiation unit (IU) requires two separate power supplies, one at 480 VAC, 3-phase, 60 Hz and one at 208 VAC, 3-phase, 60 Hz. The anticipated loads for each IU are as follows:*480 VAC load is approximately 50 kVA*208 VAC load is approximately 11 kVAThe fission process is monitored and controlled for conditions from source range through high operating ranges. The source and high ranges of the flux monitoring system detect neutron flux during startup and irradiation modes and provide a signal to the TSV reactivity protection system (TRPS). Flux monitors, located in the light water pool, are used for neutron detection. The monitors are located to provide optimum monitoring in the source and high ranges. This information is input to the TRPS for appropriate automatic response. The TRPS protects the TSV integrity by monitoring IU parameters and causing an IU shutdown when predetermined setpoints are exceeded. Separation of the TRPS functions and normal TSV process control function prevents failures in the TSV process control system (TPCS) control circuit from affecting the TRPS circuitry. Items that are safety-related are supported by the safety-related UPSS and are not dependent on utility power. Therefore, any LOOP, either for a short or long duration, does not affect the safe operation of the IUs.8a2.1.13DESIGN BASESThe design function is to provide sufficient, and reliable electrical power to all SHINE facility systems and components requiring electrical power for normal operations and abnormal operations. The normal electrical power supply system (NPSS) is nonsafety-related but may support safety-related systems or components during normal operations. In the event of the loss of normal AC electrical power, the UPSS automatically provides power to the safety-related systems and components. Systems powered by the NPSS are described in Chapters 4, 5, 9, and 11. Further information on the design bases is provided in Chapter 3.8a2.1.14TECHNICAL SPECIFICATIONSThere are no potential variables, conditions, or other items that will be probable subjects of atechnical specification associated with the normal electrical power system.
Chapter8 -Electrical Power SystemsNormal Electrical Power SystemsSHINE Medical Technologies8a2-5Rev. 0Table 8a2.1-1 Normal Electrical Power Switchgear Load ListBusLoad DescriptionNominalConnected Load (kVA)NominalDemand Load(kVA)SWGR AZone 2 Exhaust Fan B (Stand-by) (100 horsepower [hp])82.90.0Zone 2 Exhaust Fan A (100 hp)82.982.9Distribution Panel for Tritium Purification System (TPS) 1,2,3,475.060.0Chiller 1 (200 hp)165.8165.8Chiller 2 (200 hp)165.8165.8 Feeder to MCC A1387.8381.8Feeder to MCC A2374.5368.5Feeder to SDG SWGR A219.6119.6 Misc Load45.345.3 SWGR A Total Nominal Demand Load1389.7SWGR BZone 1 Exhaust Fan A (125 hp)103.6103.6Zone 1 Exhaust Fan B (Standby) (125 hp)103.60.0 Distribution Panel for TPS 5,6,7,875.060.0Chiller 3 (200 hp)165.8165.8Chiller 4 (200 hp)165.8165.8 Feeder to MCC B1466.5421.7Feeder to MCC B2356.9350.9Feeder to SDG SWGR B240.5140.5 Misc Load45.345.3 SWGR B Total Nominal Demand Load1453.6 Chapter8 -Electrical Power SystemsNormal Electrical Power SystemsSHINE Medical Technologies8a2-6Rev. 0Table 8a2.1-2 Standby Diesel Generator Load ListLoadDescriptionNominalConnected Load (kVA)Nominal Demand Load (kVA)TPS SystemTPS 480V Loads84.084.0TPS 208V Loads150.0150.0 Control Power Transformer 208/120 VAC - 30 kVA: TPS Support30.030.0RCA HVACZone 1 Exhaust Fan A 103.6103.6Zone 1 Exhaust Fan B (Standby) 103.60.0Instrument Air Instrument Air compressor41.441.4Facility HVACAir Handling Unit 12.412.4Exhaust Fan for UPSS A0.10.1 Unit Heater 10.10.1Unit Heater 20.10.1Unit Heater 30.10.1 Unit Heater 40.10.1Unit Heater 50.10.1Unit Heater 60.10.1 Air Cooled Condenser 3.73.7Exhaust Fan for UPSS B0.10.1Unit Heater 70.10.1 Unit Heater 80.10.1Unit Heater 90.10.1Unit Heater 100.10.1 Unit Heater 110.10.1Unit Heater 120.10.1Emergency LightingFacility Emergency Lighting6.06.0RCA Emergency Lighting13.013.0UPSSBattery Charger A100.0100.0UPSS Voltage Regulating Transformer Assembly A0.00.0Battery Charger B0.00.0UPSS Voltage Regulating Transformer Assembly B0.00.0Misc LoadsSump Pumps8.38.3On-Site Fire Systems4.14.1Security22.222.2Freeze Protection5.65.6Raw Material Storage Area Heaters16.716.7Emergency Operating Center5.65.6SDG Total Nominal Demand Load608.0 Chapter8 -Electrical Power SystemsNormal Electrical Power SystemsSHINE Medical Technologies8a2-7Rev. 0Table 8a2.1-3 Normal Electrical Power Supply System Major Component DataEquipmentSpecificationMain Utility Transformer ARating (Power)2000 kVAPrimary Voltage12 kV - delta connected Secondary Voltage480Y/277 V - wye connected, solidly groundedPhase/Frequency3 phase, 60 Hz EnvironmentOutdoor typeSwitchgear (typical for SWGR A & B)Rating (Voltage)600 VMain Bus Rating (Current)2000 ampere (A) minimum Phase/Frequency3-phase, 60 HzEnvironmentIndoor typeInterrupting Rating65,000 A 480 V BreakersMetal enclosed draw-out circuit breakers or motor starter (contactors)Motor Control Center (typical for MCC A1, A2, B1, B2)Rating (Voltage)600 VHorizontal Bus Rating (Current)800 AVertical Bus Rating (Current)300 APhase/Frequency3-phase,60 HzEnvironmentIndoor typeInterrupting Rating65,000 A 480 V BreakersMolded case circuit breakers Chapter8 -Electrical Power SystemsNormal Electrical Power SystemsSHINE Medical Technologies8a2-8Rev. 0Table 8a2.1-4 Standby Diesel Generator System Major Component DataEquipmentSpecificationStandby Diesel GeneratorVoltage480Y/277 V, solidly groundedPhase/Frequency3 phase, 60 Hz EnvironmentIndoor typeSwitchgear (typical for SDG SWGR A & B)Rating (Voltage)600 VMain Bus Rating (Current)1200 A minimum Phase/Frequency3-phase, 60 HzEnvironmentIndoor typeInterrupting Rating65,000 A 480 V BreakersMetal enclosed draw-out circuit breakers or motor starter (contactors)Motor Control Center (typical for SDG MCC A & B)Rating (Voltage)600 VHorizontal Bus Rating (Current)800 AVertical Bus Rating (Current)300 APhase/Frequency3-phase, 60 HzEnvironmentIndoor type Interrupting Rating65,000 A480 V BreakersMolded case circuit breakers Chapter8 -Electrical Power SystemsEmergency Electrical Power SystemsSHINE Medical Technologies8a2-9Rev. 08a2.2EMERGENCY ELECTRICAL POWER SYSTEMSThe emergency electrical power system in the SHINE facility consists of the UPSS and provides reliable power for the safety-related equipment required for facility instrumentation, control, monitoring, and other vital functions needed for shutdown of the plant. The UPSS contains a 250VDC battery subsystem, inverters, bypass voltage regulating transformers, distribution panels, and other distribution equipment necessary to feed safety-related alternating current (AC) or direct current (DC) loads.8a2.2.1CLASS 1E UPSS The Class 1E UPSS provides two independent divisions of 208Y/120 VAC to emergency power buses. Each division of the Class 1E UPSS consists of a 250 VDC battery subsystem, inverter, battery charger, voltage regulating transformer, panels, and 208Y/120 VAC bus system. For the UPSS loads, refer to Table 8a2.2-1.Refer to Figure 8a2.2-1 for UPSS components configuration. The buses provide feeds to instrument and control distribution panels. The inverter is powered from the 250 VDC bus connected to the battery bank with associated battery charger. During normal operations, the battery charger provides the battery float charge load requirements and also provides normal operational controls, and critical instrument and monitoring loads. Under normal operation, the Class 1E inverters receive 250 VDC from the 250 VDC bus tied to batteries and battery chargers. If an inverter is inoperable, or the Class 1E 250 VDC input to the inverter is unavailable, the power is transferred automatically to the back-up AC source via a voltage regulating transformer by a static transfer switch.Refer to Table 8a2.2-2 for UPSS major component specifications.The UPSS meets the guidance in IEEE 603 (IEEE, 2009) and IEEE 308 (IEEE, 2012b).For further discussion of the design bases of the UPSS see Subsection 3.5b.1.11 and Tables3.5-1 and 3.5a-1.8a2.2.2250 VDC CLASS 1E BATTERY SUBSYSTEM The SHINE facility is provided with a 250 VDC, redundant, Class 1E battery subsystem. Under normal facility operation and normal shutdown, the battery charger provides power to the required operational loads via the Class 1E inverter while the battery bank is kept fully charged and maintained at float charge. During LOOP, an on-site battery subsystem supplies power to the Class 1E 208Y/120 VAC 60 Hz inverter to critical monitoring and control functions. As the voltage and frequency are established with automatic start of the SDG, the battery chargers associated with the Class 1E battery subsystem are connected to the bus fed by the SDG. The brief interruption of power to the Class 1E battery chargers is restored and the battery bank returns to the fully charged status.In the event of loss of AC power to the facility (LOOP concurrent with unavailable SDG), the Class 1E battery subsystem continues to provide uninterrupted emergency power to the required safe shutdown loads of the SHINE facility operations. The battery chargers provide the required Chapter8 -Electrical Power SystemsEmergency Electrical Power SystemsSHINE Medical Technologies8a2-10Rev. 1isolation between the non-1E NPSS and Class 1E 250VDC. The AC input breakers on both battery chargers and voltage regulating transformers are qualified as isolation devices using guidance from IEEE 384 (IEEE, 2008).Each of the redundant Class 1E battery subsystems is capable of delivering required emergency power for the required duration during facility normal and abnormal operations. The scope of compliance encompasses physical separation, electrical isolation, equipment qualification, effects of single active component failure, capacity of battery, battery chargers, instrumentation, protective devices, and surveillance test requirements. Each of the Class 1E battery subsystems is separately housed in a seismically qualified Seismic Category I structure.Class 1E battery subsystem equipment sizing is designed using guidance from IEEE 485 (IEEE,2010a) and IEEE 946 (IEEE, 2004a).8a2.2.3SHINE FACILITY SYSTEMS SERVED BY THE CLASS 1E UPSS*TRPS - TSV reactivity protection system (Section 7a2.4)*TRPS/HMI - TSV reactivity protection system/human machine interface (Subsection7a2.6.8)*NFDS - neutron flux detection system (Subsection 7a2.4.3)*PVVS - process vessel vent system blower (Section 9b.6.1)*CAMS - continuous air monitoring system (Subsection 7a2.7.4.1)*RAMS - radiation area monitoring system (Subsection 7a2.7.4.2)
- CAAS - criticality accident and alarm system (Section 7b.6)*RICS - radiological integrated control system (Section 7b.2.3)*ESFAS - engineered safety features actuation system (Section 7a2.5)
- ESFAS/HMI - engineered safety features actuation system/human machine interface (Subsection 7a2.5.2)*TOGS - TSV off-gas system (Section 4a2.8)8a2.2.4NONSAFETY-RELATED LOADSThe SHINE facility Class 1E UPSS is primarily designed to serve facility essential monitoring and control functions and safe shutdown of the irradiation units. Under normal operating conditions, a limited use for nonsafety-related loads may be acceptable after approved analysis is established that such use has no adverse impact on the safety function of the system. The non-Class 1E circuits are designed with the independence and isolation guidance from IEEE 384 (IEEE, 2008).8a2.2.5MAINTENANCE AND TESTINGMaintenance and testing of the UPSS is designed using guidance from IEEE 450 (IEEE, 2010b) and IEEE 336 (IEEE, 2010c).
Chapter8 -Electrical Power SystemsEmergency Electrical Power SystemsSHINE Medical Technologies8a2-11Rev. 08a2.2.6SURVEILLANCE METHODSSurveillance of the UPSS is designed using guidance from IEEE 338 (IEEE, 2012a) and IEEE 308 (IEEE, 2012b).8a2.2.7SEISMIC QUALIFICATIONThe UPSS Class 1E power system equipment is qualified using guidance from IEEE 323 (IEEE, 2003). Additionally, battery chargers and inverters are qualified using guidance from IEEE 650 (IEEE, 2006a) and batteries are qualified using guidance from IEEE 535 (IEEE, 2006b).8a2.2.8INDEPENDENCEIndependence of redundant UPSS equipment and circuits is designed using guidance from IEEE 384 (IEEE, 2008).8a2.2.9SINGLE-FAILURE CRITERIONThe application of single-failure criterion in the UPSS is designed using guidance from IEEE 379 (IEEE, 2000).8a2.2.10SAFE SHUTDOWN OF THE IRRADIATION UNITThe present design for the SHINE radiologically controlled area (RCA) does not require any electrical power (normal or emergency) to attain a safe shutdown. The overriding design criteria are for active safety related systems within the RCA to acquire their respective safe states without the assistance of electrical power.The eight IU cells have safety-related isolation and dump valves that isolate and dump any filled TSV of its contents upon loss of off-site power (LOOP) without any UPSS electrical input. A LOOP is a condition defined as a loss of AC power to the facility. The target solution can remain in the criticality-safe dump tank located in each IU cell until power is returned.In order to maintain a safe shutdown during a LOOP event, the UPSS is required to power active safety related systems in the TOGS. These safety related systems specific to TOGS are a small recirculating electric blower that will continue to move the off-gas that is being produced by the irradiated target solution and the hydrogen recombiners. During normal operation, radiolytic hydrogen gas is produced and is circulated through a catalytic hydrogen recombiner that keeps the hydrogen concentration below preset limits. For the LOOP event, the target solution is dumped into the criticality-safe dump tank, but hydrogen off-gas production continues even without irradiation from the neutron driver. To address this limited hydrogen off-gas production that continually decreases over time, the UPSS powers the TOGS recirculating blower to the hydrogen recombiner in the TOGS post-LOOP. Loss of off-site power blower systems are in place in the TOGS for each IU cell.The TSV and TSV dump tank are both immersed in the light water pool. In the LOOP event, the target solution flows to the TSV dump tank without need of power because the TSV dump tank is below the TSV. When in the criticality-safe dump tank, the residual heat contained in the target solution is passively transferred to the LWPS without the requirement of any cooling pumps or Chapter8 -Electrical Power SystemsEmergency Electrical Power SystemsSHINE Medical Technologies8a2-12Rev. 0motors. The light water pool is sufficiently-sized to passively absorb the residual heat from the target solution without the need for any UPSS electrical power input.In addition, with the LOOP event, the neutron driver assembly system (NDAS) loses its ability to function as the accelerator section of the NDAS will be without power. For the LOOP event, Class 1E interrupting devices are utilized to facilitate the complete shutdown of the NDAS and its control system for each one of the IU cell's NDASs. The operator follows an approved procedure to re-energize any of the systems that tripped during a LOOP event.Detailed discussion of the LOOP event is provided in Subsections 13a2.1.5 and 13a2.2.5. Use ofthe UPSS for other design basis accidents is discussed throughout Chapter 13.8a2.2.11MONITORING SYSTEMS ON UPSS There are a number of monitoring systems that require UPSS power upon the LOOP. The primary function of the various systems post-safe shutdown due to LOOP is to monitor reactivity and radiation levels in the RCA, and those systems are listed in Subsection 8a2.2.3.The TOGS design includes hydrogen monitoring capability. This analytical monitoring system needs to be powered by the UPSS for as long as the monitoring is required for the facility. All of the outlined systems serve to monitor the status and health of the primary system and process components within the RCA.The RAMS and CAMS both require UPSS power upon the LOOP.8a2.2.12TECHNICAL SPECIFICATIONSPotential variables, conditions, or other items that will be probable subjects of a technicalspecification associated with the emergency electrical power system are provided in Chapter 14.
Chapter8 -Electrical Power SystemsEmergency Electrical Power SystemsSHINE Medical Technologies8a2-13Rev. 2a) Load information above is for a single train. The same loads apply to the redundant UPSS train.8a2.2-1 UPSS Load List(a)Load DescriptionNominal Connected Load(kW)NominalDemandLoad (kW)TSV Reactivity Protection System (TRPS)7.207.20 Neutron Flux Detection System (NFDS)1.21.2Continuous Air Monitoring System (CAMS)2.402.40Radiation Area Monitoring System (RAMS)2.402.40 Criticality Accident and Alarm System (CAAS)2.402.40Radiological Integrated Control System (RICS)3.603.60Engineered Safety Features Actuation System (ESFAS)7.207.20TSV Off-Gas System (TOGS) Recirculating Blower5.5713.92Human Machine Interface (HMI)/ESFAS2.402.40Process Vessel Vent System (PVVS) Blower5.5713.92 HMI/TRPS3.603.60UPSS Total Nominal Demand Load61.44 kW Chapter8 -Electrical Power SystemsEmergency Electrical Power SystemsSHINE Medical Technologies8a2-14Rev. 0a) Preliminary specifications above are for equipment for a single train. The same ratings apply to the redundant UPSS train equipment.Table 8a2.2-2 Emergency Electrical Power Supply System Major Component DataEquipmentSpecification(a)Battery Nominal Voltage250 VDCBattery Type:Lead calciumNumber of Cells120 kW/cell @ 2 hour2.314815e-5 days <br />5.555556e-4 hours <br />3.306878e-6 weeks <br />7.61e-7 months <br />s1.26Battery ChargerAC Input480 VACDC output250 VDC Rating400 AInverterDC Input210 - 280 VDCAC Output: Voltage208Y/120 VAC +/- 5%
AC Output: Frequency60 Hz +/- 0.5%AC Output: Rating100 kVAVoltage Regulating TransformerAC Input480 VACAC Output: Voltage208Y/120 VAC AC Output: Regulation+/ 2%AC Output: Frequency60 HzAC Output: Rating112 kVA Irradiation Facility Electrical PowerChapter8 -Electrical Power SystemsSystems Technical SpecificationsSHINE Medical Technologies8a2-15Rev. 08a2.3IRRADIATION FACILITY ELECTRICAL POWER SYSTEMS TECHNICAL SPECIFICATIONSPotential variables, conditions, or other items that are probable subjects of a technicalspecification associated with the IF electrical power systems are provided in Chapter 14.
Chapter8 -Electrical Power SystemsReferencesSHINE Medical Technologies8a2-16Rev. 08a
2.4REFERENCES
ANSI, 2011. Electric Power System and Equipment - Voltage Ratings (60 Hertz), ANSI C84.1, American National Standards Institute, 2011. IEEE, 2000. IEEE Standard Application of the Single-Failure Criterion to Nuclear Power Generating Station Safety Systems, IEEE 379, Institute of Electrical And Electronics Engineers, 2000.IEEE, 2003. IEEE Standard for Qualifying Class 1E Equipment for Nuclear Power Generating Stations, IEEE 323, Institute of Electrical And Electronics Engineers, 2003.IEEE, 2004a. IEEE Recommended Practice for the Design for DC Auxiliary Power Systems for Generating Stations, IEEE 946, Institute of Electrical And Electronics Engineers, 2004.IEEE, 2004b. IEEE Guide for Instrumentation and Control Equipment Grounding in Generating Stations, IEEE 1050, Institute of Electrical And Electronics Engineers, 2004.IEEE, 2006a. IEEE Standard for Qualification of Class 1E Static Battery Chargers and Inverters for Nuclear Power Generating Stations, IEEE 650, Institute of Electrical And Electronics Engineers, 2006.IEEE, 2006b. IEEE Standard for Qualification of Class 1E Lead Storage Batteries for Nuclear Power Generating Stations, IEEE 535, Institute of Electrical And Electronics Engineers, 2006.IEEE, 2008. IEEE Standard Criteria for Independence of Class 1E Equipment and Circuits, IEEE 384, Institute of Electrical And Electronics Engineers, 2008. IEEE, 2009. IEEE Standard Criteria for Safety Systems for Nuclear Power Generating Stations, IEEE 603, Institute of Electrical And Electronics Engineers, 2009.IEEE, 2010a. IEEE Recommended Practice for Sizing Lead-Acid Batteries for Stationary Applications, IEEE 485, Institute of Electrical And Electronics Engineers, 2010.IEEE, 2010b. IEEE Recommended Practice for Maintenance, Testing, and Replacement of Vented Lead-Acid Batteries for Stationary Applications, IEEE 450, Institute of Electrical And Electronics Engineers, 2010.IEEE, 2010c. IEEE Recommended Practice for Installation, Inspection, and Testing for Class IE Power, Instrumentation, and Control Equipment at Nuclear Facilities, IEEE 336, Institute of Electrical And Electronics Engineers, 2010.IEEE, 2012a. IEEE Standard for Criteria for the Periodic Surveillance Testing of Nuclear Power Generating Station Safety Systems, IEEE 338, Institute of Electrical And Electronics Engineers, 2012.IEEE, 2012b. IEEE Standard Criteria for Class 1E Power Systems for Nuclear Power Generating Stations, IEEE 308, Institute of Electrical And Electronics Engineers, 2012.
Chapter8 -Electrical Power SystemsReferencesSHINE Medical Technologies8a2-17Rev. 0NFPA, 2011a. National Electrical Code, NFPA 70, National Fire Protection Association, 2011.NFPA, 2011b. Standard for the Installation of Lightning Protection Systems, NFPA 780, National Fire Protection Association, 2011.
Chapter8 -Electrical Power SystemsNormal Electrical Power SystemsSHINE Medical Technologies8b-1Rev. 08bRADIOISOTOPE PRODUCTION FACILITY ELECTRICAL POWER SYSTEMS8b.1NORMAL ELECTRICAL POWER SYSTEMSThe SHINE facility has one common normal electrical power system. The common normal electrical power system is described in Section 8a2.1.
Chapter8 -Electrical Power SystemsEmergency Electrical Power SystemsSHINE Medical Technologies8b-2Rev. 08b.2EMERGENCY ELECTRICAL POWER SYSTEMSThe SHINE facility has one common emergency electrical power system. The commonemergency electrical power system is described in Section 8a2.2.
Radioisotope Production Facility ElectricalChapter8 -Electrical Power Systems Power Systems Technical SpecificationsSHINE Medical Technologies8b-3Rev. 08b.3RADIOISOTOPE PRODUCTION FACILITY ELECTRICAL POWER SYSTEMS TECHNICAL SPECIFICATIONSPotential variables, conditions, or other items that are probable subjects of a technical specification associated with the RPF electrical power systems are provided in Chapter 14.