ML17095A852
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BYRON -FPR AMENDMENT 27 DECEMBER 2016 2.4-12.4 SAFE SHUTDOWN ANALYSIS 2.4.1 Introduction 2.4.1.1 Purpose The purpose of this analysis is to demonstrate that for a fire in any single plant fire zone in the Byron plant, sufficient equipment will remain operational in other parts of the plant toachieve and maintain a safe shutdown condition in both units independent of that fire
zone. For the purpose of this analysis, hot standby and cold shutdown are defined as
follows:a.Hot standby -A plant condition in which the reactor is subcritical with a shutdown margin per the Technical Requirements Manual, and the
primary coolant system average temperature is greater than or equal to 350!F.b.Cold shutdown -A plant condition in which the reactor is subcritical with a shutdown margin per the Technical Requirements Manual, and the
primary coolant system average temperature is less than or equal to 200!F.A safe shutdown condition is achieved by satisfying the following requirements:a.maintain a condition of negative reactivity, b.monitor and control the primary system coolant inventory and pressure, c.remove decay heat, d.provide process monitoring capability, and e.provide essential support functions.
BYRON -FPR AMENDMENT 27 DECEMBER 2016 2.4-2 2.4.1.2 Analysis CriteriaThe criteria used as a guideline for this safe shutdown analysis are that for a fire in any fire zone in the plant, sufficient redundant and/or diverse equipment will remain
available to ensure that the capability to achieve safe shutdown still exists independent of equipment or systems located within or affected by the fire in theaffected fire
area/zone. The requirements listed above in Subsection 2.4.1.1 shall be satisfied. A
secondary goal of the analysis was to identify adjacent fire zones in the plant where the wall or barrier separating the two fire zones does not meet the separation requirements of Section C.5.b of BTP CMEB 9.5 -1. For those cases, one of the following was
provided: 1) a BTP CMEB 9.5 -1 deviation was prepared for which justification for the
existing separation is provided, 2) an evaluation was performed per the guidance of
Generic Letter 86-10, which determined that the barrier is adequate to prevent the
spread of fire such that redundant safe shutdown components are not adversely affected, or 3) the separation was upgraded to a justifiable level.
2.4.1.3 Evaluation Methodology The evaluation methodology, which was utilized to conduct this safe shutdown evaluation, can be summarized as follows:a.Systems, components, and instrumentation that could be used to satisfy the safe shutdownrequirements listed in Subsection 2.4.1.1 were
identified. Criteria and assumptions used to identify safe shutdown
components are provided in following Subsection 2.4.1.4. The systems so identified are listed in Table 2.4-1 and the equipment and instrumentation so identified are listed in Table 2.4-2.b.Once safe shutdown equipment and instrumentation had been identified, power, control and instrumentation cables necessary for the operation of this equipment and instrumentation were then identified. For equipment, the cables identified include power cables back to the primary source of power (the 4160V and 480V safety-related buses, MCCs, and the 125Vdc
distribution buses), and all control cables necessary for proper functioning
of the control circuit. For instrumentation, cables identified include power
feeds from the instrument power buses, and signal cables to primary
display locations (usually the main control room, the remote shutdown
control panels, and/or the fire hazard panel). Cables associated with
tertiary functions are not included. The detailed criteria used for the cable
selection process are provided in following Subsection 2.4.1.5.
BYRON -FPR AMENDMENT 27 DECEMBER 2016 2.4-3c.Once the list of safe shutdown cables was generated, the routing of each cable through the plant fire zones was identified. This was accomplished
in the following manner. For the Byron/Braidwood plants, the cable tray
system has routing points identified at frequent intervals. Each of these routing points was assigned the number of the fire zone in which it was
located. A computerized database containing important cable data is
maintained for all cables in the plant. For cables routed in the tray
system, the routing points through which the cable passes are listed in the data base. Using the routingpoint/fire zone correlation which was
developed, the fire zones through which each safe shutdown cable
passes were listed. For cables routed wholly or partially in conduit, or in
free air, the cable routings were manually checked, and all fire zones
through which they passed were added to the previously generated list of
fire zones for each cable. The cable data base is kept current and is
updated periodically, thus, the routing information is current and
representative of the as-built condition of the plant.d)A logic model of the plant was developed to aid the analysts in performing the area analysis. The logic model is in the form of a fault tree. It
incorporates each individual component from the safe shutdown
equipment list, and associated cables, if any.e)An area analysis was performed for each fire zone in the plant that contains safe shutdown components or cables. The logic model of the
plant was used to identify each instance where components or cables located within a given fire zone are redundant to each other. Each such
occurrence is evaluated to determine other acceptable means to satisfy
safe shutdown requirements. The means of satisfying the safe shutdown
requirements for each such occurrence is documented by identification of
an "exception". The "exceptions" provide the detailed rationale why the
presence of redundant components or cables is acceptable from a safe
shutdown viewpoint. Typical "exceptions" consist of the following items: 1) identification of a manual action to compensate for the postulated fire
damage (e.g., manually operate a valve with its handwheel); 2)
justification for existing physical separation as documented in a BTP
CMEB 9.5-1 deviation or technical evaluation per the guidance of NRC
Generic Letter 86-10; or 3) fire proofing of potentially affected cables.
BYRON -FPR AMENDMENT 27 DECEMBER 2016 2.4-4 2.4.1.4 Identification of Safe Shutdown Equipment The philosophy used in generating the Byron/Braidwood safe shutdown equipment lists was to identify as much safety-related equipment as possible which could be available
during and after a fire and utilized to perform the safe shutdown functions identified in
Subsection 2.4.1.1. The result is that the list includes redundant and in some cases diverse equipment for performing each function. It also follows that not all of this
equipment needs to be available to achieve safe shutdown following a fire in any plant
fire zone.
The safe shutdown equipment list that has been generated for the Byron plant is presented below.a.Systems which may be used by the operators to perform the safe shutdown functions of reactivity control, primary coolant system inventory and pressure
control, decay heat removal, and provide essential support are listed in Table 2.4-1.b.Equipment and instruments which may be used to accomplish the safe shutdown functions for both hot standby and cold shutdown are listed in Table 2.4-2. The
equipment on this list includes redundant, and in some cases, diverse means of
accomplishing the safe shutdown functions.
The safe shutdown component selection process and criteria are described below.
Once the safe shutdown systems were identified, the P&IDs for those systems were
reviewed to identify essential safe shutdown flowpaths and system boundaries.
Component selection was performed by reviewing the flowpaths to identify components which require operation/repositioning to accomplish the desired safe shutdown function.
In addition, components whose fire-induced spurious operation could impair safe
shutdown are identified. This includes normally open valves/dampers in the required
flowpath whose spurious closure could prevent the required flow, and normally closed
valves/dampers forming a system boundary whose spurious opening could divert flow
from the desired flowpath.
The following guidelines were used to determine which components to include on the safe shutdown equipment list:a.Components such as pumps and fans which require operation to accomplish the desired safe shutdown function are listed on the safe shutdown equipment list.
BYRON -FPR AMENDMENT 27 DECEMBER 2016 2.4-5b.Valves or dampers in the identified safe shutdown flowpath whose spurious operation could adversely affect system operation are included on the safe
shutdown equipment list. Manual valves or dampers requiring repositioning
during the post-fire shutdown are also included. Manual valves/dampers/check valves which do not require manual actions during the post-fire shutdown are not
required to be included.c.Electrically operated/controlled valves or dampers constituting system boundaries are evaluated for spurious operation. If the spurious operation of a
single valve or damper could have a significant adverse impact on the capability
to achieve a safe shutdown function by diverting flow from the desired safe
shutdown flowpath, then the valve or damper is included on the safe shutdown equipment list. When performing this evaluation, it is necessary to consider only
a single spurious operation. Normally closed manual valves and properly oriented check valves credited as system boundaries are not required to be
included.d.Manual drain, vent, and instrument root valves are not included on the safe shutdown equipment list.e.Safety/Relief valves provided for equipment and piping protection are not included. However, safety/relief valves which provide an active safe shutdown
function, such as main steam safety valves, or pressurizer power-operated relief
valves, are included on the safe shutdown equipment list.f.Loops or bypasses within a system where spurious operation would not result in a loss of flow or inadequate flow to safe shutdown flowpaths are not included in
the safe shutdown equipment list.g.For tanks, all outlet lines are evaluated for their functional requirements. For lines not required to be functional, a means of isolation is included when
necessary to prevent unnecessary drawdown of the tank. Tank fill lines are also
evaluated as necessary.h.Steam traps in the safe shutdown flowpath, designed to remove condensate and trap steam, are not included in the safe shutdown equipment list. Based on this
design function, steam exiting via these flowpaths is considered to have a
negligible impact on RCS cooldown.i.Solenoid pilot valves are not listed on the safe shutdown equipment list. The process valves with which the pilot valves are associated are identified on the
safe shutdown equipment list. Cabling for the solenoid pilot valves is associated
with the process valve component number.j.Passive mechanical components such as tanks, heat exchangers and pressure vessels are specifically included on the list for completeness.
BYRON -FPR AMENDMENT 27 DECEMBER 2016 2.4-6k.Fire dampers in the flowpath whose operation could adversely affect system operation, whether actuated by fusible links or electro-thermal links, are included on the list. Fire dampers actuated by electro-thermal links are evaluated for
spurious operation.l.Equipment that is not normally required for safe shutdown, but whose spurious operation could either prevent or have a significant adverse impact on the capability to achieve a safe shutdown function, isincluded on the safe shutdown
equipment list.
Components for functions not involving mechanical/fluid flowpaths (e.g., process monitoring, essential power, support systems) were then identified. The following
guidelines were used:a.For the process monitoring function, the guidance provided in IE Information Notice No. 84-09 was considered in the identification of the minimum set of
instruments that are required to monitor plant process variables.b.Power supplies for safe shutdown components that require power to achieve their safe shutdown function are identified as safe shutdown components.
Identification of power supplies includes both motive and control power sources.c.Safe shutdown components typically are major components within a safe shutdown system, such as pumps, fans, valves, tanks, electrical busses, etc.
The subcomponents such as panels, cabinets, control boards, solenoids, relays, switches, transmitters, etc. are not included on the safe shutdown equipment list.
The circuits associated with these items are included via the cable selection
criteria, and the cables are listed with the major safe shutdown components.
Therefore, these subcomponents are implicitly accounted for in the analysis via identification of the electrical schematic diagrams and their identified safe
shutdown cables.d.Other diesel-backed support systems such as service water, component cooling water, HVAC, heat tracing, lubrication, and air systems are included in the safe shutdown equipment list if required for system support.e.For the 4160Vac ESF switchgear busses, special selection criteria apply. Power feeds to these busses, and loads fed from these busses are controlled by air
circuit breakers (ACBs). The fire-induced spurious closure of an ACB in
conjunction with a fault on the feed cable or bus bar associated with that ACB
could disable the bus. Therefore, all 4160Vac ACBs which are not associated
with a safe shutdown component are specifically listed on the safe shutdown
equipment list.
BYRON -FPR AMENDMENT 27 DECEMBER 2016 2.4-7 2.4.1.5 Cable Selection Criteria and Damage Assumptions The criteria used to select safe shutdown cables for components identified on the safe shutdown equipment list, and the assumed failure modes and related assumptions are
described in the following subsections.
2.4.1.5.1 Cable Selection Criteria The method used to identify safe shutdown cables is described in the following paragraphs.a.Review the safe shutdown equipment list to determine all safe shutdown components which are required to be evaluated. All electrically powered or
electrically controlled components are identified. Passive mechanical
components such as pressure vessels, tanks, heat exchangers and manual
valves are excluded from the list of components to be evaluated.b.For each component,review the applicable schematic diagram, single-line diagram, instrument loop schematic, wiring diagram, or vendor drawings, as
required.c.For electrically powered components, the power cable from the primary power supply for the component (e.g. 4160Vac or 480Vac safety-related buses or
MCCs, or 125Vdc distribution panel) is identified as a safe shutdown cable if the
component is an active component.d.For electrically controlled components whose control circuits receive power from separate and specific power sources, the control power cables are identified as
safe shutdown cables.e.For electrically controlled components, each conductor in the control circuit is reviewed to evaluate the effect on the circuit of the four postulated failure modes (open circuit, short circuit, short to ground, hot short) described in the following
subsection. If the effect of one or more of the failure modes is to render the
component unavailable, or cause a spurious operation of the component, then
the cable which carries that conductor is identified as a safe shutdown cable.f.The following assumptions were made when evaluating safe shutdown component control circuit conductors for failures:1)Components are assumed to be in their normal operating position.
2)All relay, position switch, and control switch contacts in the control circuit are assumed to be in the position that corresponds to the normal plant
operating condition of that device unless specifically stated otherwise.
BYRON -FPR AMENDMENT 27 DECEMBER 2016 2.4-83)Test switches in the control circuits are assumed to be in their normal plant operating position.4)Automatic logic interlocks from other circuits are assumed to be in a permissive position unless the circuits for the interlock are included in the safe shutdown cable selection for thecomponent of concern, or the
interlock is otherwise shown to be unaffected by fire.5)Isolation switches in control circuits are analyzed in their expected positions. For control room operation, isolation switches are not operated and are assumed to bein the "REMOTE" position. For local operations, both "REMOTE" and "LOCAL" positions are considered, since the
switches are initially in the "REMOTE" position, and will subsequently be placed in the "LOCAL" position. (The diesel generators are an exampleof
a component that must be evaluated with the switches in both positions).6)Annunciator alarm, metering, and instrument circuits and cables whose failure does not impact safe shutdown functions are not included in the
safe shutdown equipment-cable list.7)Associated circuits cables, as defined in Generic Letter 81-12, are identified unless manual actions are identified that mitigate the
consequences of the postulated cable failure.g.For instrumentation required for safe shutdown, power cables from the Instrument Buses to the required instruments were identified as safe shutdown
cables. Also instrument cables from the required instrument sensors to the
required instrument indicators were also identified as safe shutdown cables.h.The final product of the safe shutdown cable selection process is an equipment -
cable list which lists required safe shutdown cables for each electrically powered
and/or controlled safe shutdown component. The list includes appropriate
annotations or notes to identify cables capable of causing spurious operation of
the component, and for components with isolation switches, the list identifies
cables which cause loss of local and/or control room control.
BYRON -FPR AMENDMENT 27 DECEMBER 2016 2.4-9 2.4.1.5.2 Cable Damage Assumptions This subsection describes the basic assumptions made with regard to fire damage to electrical cables.a.The insulation and external jacket material of electrical cables is susceptible to fire damage. Damage may assume several forms including deformation, loss of
structure, cracking, and ignition. The relationship between exposure of electrical
cable insulation to fire conditions, the failure mode, and time to failure may vary
with the configuration and cable type. To accommodate these uncertainties in a consistent and conservative manner, this analysis assumes that the functional
integrity of electrical cables is lost when cables are exposed to a postulated fire
in a fire area, except where protected by a fire rated barrier within the fire area (or radiant energy shield within containment). Electrical cable failures are limited
by the following considerations:1)Fire damage occurs throughout the fire area or fire zone under consideration.2)Fire damage results in an unusable cable that cannot be considered functional with regard to ensuring proper circuit operation.b.Fire-induced damage to cables may cause the following types of failures:1)Open Circuit -An individual conductor that loses electrical continuity.
2)Short Circuit -An individual conductor that comes into electrical contact with another electrical conductor and bypasses the normal electrical load (i.e., relay coil, solenoid valve, motor, etc.), thereby resulting in a very high
current flow.3)Short to Ground -An individual conductor that comes into electrical contact with a grounded conducting device, such as a cable tray, conduit, or metal housing.4)Hot Short -An energized conductor that comes into electrical contact with another conductor and bypassing control contacts in a circuit, thereby spuriously energizing the affected electrical load.c.For components which do not form part of a high-low pressure interface between the RCS and a lower pressure system, credible circuit failures include multiple open circuits, short circuits, shorts to ground, and asingle hot short on any one conductor within the control circuit. For these components, 3-phase ac power circuit cable-to-cable proper phase sequence faults and 2-wire ungrounded dc circuit cable-to-cable proper polarity faults are considered of sufficiently low
likelihood that they are not assumed to be credible. This assumption is consistent with guidance provided in Generic Letter 86-10.
BYRON -FPR AMENDMENT 27 DECEMBER 2016 2.4-10d.For components which do form part of a high-low pressure interface between the RCS and a lower pressure system, credible circuit failures include multiple open
circuits, short circuits, shorts to ground, and multiple hot shorts within the control circuit. In addition, 3-phase ac power circuit cable-to-cable proper phase
sequence faults and 2-wire ungrounded dc circuit cable-to-cable proper polarity
faults are considered to be credible, and must be evaluated. The application of
this assumption to high-low pressure interfaces is discussed in Section 2.4.3.2.4.1.6Associated Circuits and Other Electrical Issues Associated circuits and other electrical issues that are relevant to BTP CMEB 9.5-1 are discussed in the following sections.
2.4.1.6.1 Common Power Source Associated Circuits
For the majority of ESF power supplies, this issue is addressed by providing coordinated circuit protection between the feed breakers for a supply and the load
breakers fed by the supply. Calculations are available to demonstrate proper breaker
coordination for these power supplies. The coordinated circuit protection ensures that thepower supply will provide sufficient current to a faulted load to clear the load breaker
prior to affecting the power supply feed breaker. Such coordination is demonstrated for
the following ESF power supplies: 1) 4160Vac switchgear buses; 2) 480Vac unit
substations; 3) 480Vac motor control centers; 4) 120Vac panels; and 5) 125Vdc
distribution systems.
The interrupting device design is factory tested to verify overcurrent protection as designed in accordance with the applicable standards. The low and medium voltage
switchgear (480V and above) circuit breaker protective relay will be periodically tested
to demonstrate that the overall coordination scheme remains within the limits specified.
The molded case circuit breakers will be periodically manually exercised and inspected
to ensure ease of operation. In addition, a sample of these breakers will be periodically
tested to determine that breaker drift is within the allowed according to the design criteria, and all the tests will be performed in accordance with an accepted industry
testing program. In the instances where fuses are being used as interrupting devices, administrative controls will ensure that correct replacement fuses will be used.
Therefore, a common source with the redundant shutdown equipment is always
protected.
For the Byron station, one bifurcated feed is present between 480Vac switchgear bus 132X and motor control centers 132X3 and 132X5 (component id numbers 1AP12E, 1AP24E and 1AP32E, respectively). This is accounted for in the safe shutdown
analysis by including the feed cables for both MCCs with the safe shutdown cable list
for each MCC.
BYRON -FPR AMENDMENT 27 DECEMBER 2016 2.4-11 Coordinated circuit protection cannot be demonstrated for each unit's four 120 Vac instrument power buses between the main feed breakers and the load breakers. The
120Vac instrument bus distribution panels are normally powered from the 120Vac vital
instrument inverters, which current limit at 150% of rated output current. This is
accounted for in the safe shutdown analysis by including all of the cables fed from each
120Vac instrument bus distribution panel as safe shutdown cables. Therefore, an
instrument bus is only considered to be available for safe shutdown use if none of the
bus's cables are routed in the fire zone being analyzed.
2.4.1.6.2 Common Enclosure Associated Circuits
This issue is not a concern at Byron for the following reasons. The raceway system is divided by unit, by division (train), by safety class, and by cable type (power, control, or
instrument). Each raceway is assigned a segregation code, and only cables with the
same segregation code are routed together. Therefore, cables from unit 1 are not
routed together with cables from unit 2. Cables from one division (e.g. Division 11) are not routed together with cables from the redundant division (e.g. Division 12). Non-
safety related cables are not routed together with safety related cables. Finally, power, control and instrument cables are not intermixed within any given raceway; each is routed in separate raceways with cables of the same type. In addition, cables used for Byron meet the flame test of IEEE 383-1974, which demonstrates that the cable does
not propagate fire outside of the area of flame impingement. Thus, in the absence of
external influences, a cable fire in one fire zone will not propagate through the raceway
system to a different fire zone.When non-safety related cables share a common enclosure (e.g., control panel, motor control center, terminal box) with safety related cables, an analysis has been performed and documented to demonstrate that a failure of the non-safety related cable will not
degrade any safety related circuits in the enclosure.
BYRON -FPR AMENDMENT 27 DECEMBER 2016 2.4-12 2.4.1.6.3 Multiple High Impedance Faults (MHIF)High impedance faults are defined in Generic Letter 86-10 as postulated faults which result in fault currents just below the breaker/fuse fault current setting or rating.
Therefore, high impedance faults by definition do not result in clearing of the fault by
the load breaker (or fuse). The referenced Generic Letter requested nuclear plant
licensees to consider multiple (simultaneous) high impedance faults on safe shutdown
power supplies. The concern is that the summation of fault current from such faults on both safe shutdown and non-safe shutdown loads could trip the main feed breaker for
the affected safe shutdown power supply prior to clearing the individual load faults.
For Byron Station, MHIF are not considered to be credible for medium voltage buses (4.16 kV and 6.9kV) because at this voltagelevel, postulated arcing faults will clear by
one of two mechanisms. The fault current will rapidly propagate into a bolted fault, which will be cleared by the individual feed breaker, or the energy of the postulated fault
will be sufficient to vaporize the target and break the fault circuit path. Also, at this
voltage level, phase-to-phase and three-phase arcing faults approach the magnitude of a three-phase bolted fault. Even if this fault were to remain an arcing fault, it would be
cleared by the protective devices. Minimum arcing ground faults are not a concern at
the medium voltage level because the individual load breakers are provided with ground
fault protection. Coordination of the ground fault protection between the bus main
supply breaker and the individual load breakers ensures that a ground fault on an
individual load will trip the load breaker first.
MHIF are considered to be credible at the 480 Vac level. An analysis has been performed to demonstrate that the 480 Vac switchgear buses and MCCs required for safe shutdown are adequately protected against MHIF. For phase-to-phase and three-
phase MHIF, the analysis assumed that the normally energized cables that are not routed in the fire zone under consideration will draw their rated full load current. A High
Impedance Fault (HIF), where the load current is assumed to be just below the trip
setpoint of an individual load breaker, is assumed to be present on all normally energized cables that are routed in the zone under consideration. To address the
design basis of one spurious operation, the worst case (i.e., largest breaker trip rating)
normally de-energized load on the bus is assumed to be always faulted due to the fire.
The analysis verified that the individual load breakers would tripbefore the main supply
breaker for phase-to-phase and three-phase MHIF.
BYRON -FPR AMENDMENT 27 DECEMBER 2016 2.4-13 High impedance arcing ground faults were also evaluated for the safe shutdown 480 Vac switchgear buses. Each 480 Vac switchgear breaker provides phase overcurrent
protection. Additionally, ground fault protection is provided for each 480 Vac switchgear bus by a ground overcurrent relay that monitors current on the 4160 -480/277 volt
transformer secondary grounded neutral. If a ground fault is sensed, the ground
overcurrent relay will trip the 4160 volt supply breaker to the transformer that feeds the
480 Vac switchgear bus. However, an arbitrary fault current, just below the feed
breaker trip setting, is not credible. Research has shown that the minimum arcing
ground fault current is 38 percent of the bolted three-phase ground fault value. If the
ground fault current is less than 38 percent, the ground fault will self extinguish. If the
ground fault current is greater than 38 percent, the energy of the fault will cause the fault current to go to a condition close to a three-phase bolted fault current value. The
analysis has verified that for each high impedance arcing ground fault, the individual load breaker will clear 38 percent of the three-phase bolted fault current value prior to
the ground overcurrent relay tripping the switchgear bus supply breaker. Therefore, the
safe shutdown 480 Vac switchgear buses and MCCs are adequately protected against
both ungrounded MHIF and grounded arcing MHIF.For the 120 Vac distribution buses, high impedance arcing faults are not considered to be credible. Based upon research, the peak line-to-neutral voltage is not high enough
to cause arcing current to flow. However, a coordination analysis has been performed to verify that the circuitbreakers for the 120 Vac distribution buses provide adequate
protection against multiple faults with minimum fault current values. For worst case
loads with the longest cable runs and therefore the lowest fault currents, the analysis calculated the minimum fault current that could be present at a load taking into account
the impedance of the cable between the bus and the load. The analysis verified that
the load protective device (i.e., a fuse or circuit breaker) would trip before the upstream protectivedevice. The analysis also verified that the upstream protective devices have
adequate margin to accommodate multiple faults. Therefore, the 120 Vac voltage level
distribution buses are adequately protected against multiple faults with minimum current values.A MHIF analysis has not been performed for the 120 Vac instrument power buses. As stated previously in Section 2.4.1.6.1, an instrument bus is only considered to be available for safe shutdown use if none of the bus's cables are routed in the fire zone
being analyzed.
BYRON -FPR AMENDMENT 27 DECEMBER 2016 2.4-14 For the 125 Vdc distribution buses, high impedance arcing faults are not considered to be a concern, because the fault will either develop into a full bolted fault or will self
extinguish. Given the very small maximum separation requirements between
conductors for an arc to occur at the 125 Vdc level, there is enough energy in a 125
Vdc fault to melt the two conductors together which will result in a bolted fault that will
trip the protective device or to burn the wire open. However, a coordination analysis
has been performed to verify that the circuit breakers for the 125 Vdc distribution buses
provide adequate protection against multiple faults with minimum fault current values.
For worst case loads with the longest cable runs andtherefore the lowest fault currents, the analysis calculated the minimum fault current that could be present at a load taking
into account the impedance of the cable between the bus and the load. The analysis
verified that the load protective device would trip before the upstream protective device.
The analysis also verified that the upstream protective devices have adequate margin
to accommodate multiple faults. Therefore, the 125 Vdc voltage level distribution buses are adequately protected against multiple faults with minimum current values.
2.4.1.6.4 Spurious Operations
The licensing basis of the Byron plant is to assume one spurious operation per fire, as documented in the Byron and Braidwood SERs. Each electrically controlled component
on the safe shutdown equipment list was considered to be susceptible to postulated
spurious operations.
As discussed in criteria (b) and (l) from the component selection criteria presented in Subsection 2.4.1.4, the spurious operation of valves and dampers in safe shutdown
flowpaths was considered during the component selection process. The effects of
postulated spurious operation of these components, and the required actions to mitigate them, if any, are addressed in the safe shutdown analyses for individual fire
zones in Section 2.4.2. Post-fire operating procedures have also been prepared which
include manual actions to address postulated spurious operations for selected
electrically driven safe shutdown components (fans and pumps powered from the
4160Vac ESF switchgear buses). For other electrically powered components (480Vac
and lower rated supplies), the spurious start of an inactive component has no adverse
consequences (e.g., spurious start of a small pump or fan). For these components, any
damage to the components' control circuit is assumed to render the component
unavailable for safe shutdown. No specific discussion of spurious operation is
provided.
BYRON -FPR AMENDMENT 27 DECEMBER 2016 2.4-152.4.1.6.5Cable Fireproofing Material1.The 3M Interam Type E-54 fire wrap is an acceptable one-hour and three-hour fire barrier based on existing qualification reports and test data (ASTM E-119 Fire Test, Hose Stream tests, etc.). Furthermore, the 3M
Type E-54 fire wrap possesses endothermic properties and shall not be
treated as a combustible. Per the Technical Evaluation of 3M Interam one and three-hour Fire Protective Wraps Applied to Electrical Circuits (June 1999), the E-50 series of 3M Interam base material has passed the
ASTM E-136 testing requirements for noncombustible materials, It has also passed the ASTM E-84 testing requirements for surface flame spread (with a flame spreadrating of 0.7). The ASTM E-136 testing was
conducted at Omega Point Laboratories in January of 1995, project 14540-99235 (CTP-2004), and the ASTM E-84 testing wasconducted at Underwriter's Laboratories, report file R10125, project 82NK21937.
It is recognized that deviations from the tested fire wrap configuration will occur. Generic Letter 86-10 also recognizes this fact and allows for technically justified deviations. Any deviations that occur during the
installation will be evaluated based on the criteria discussed in Generic
Letter 86-10 (e.g., continuity of the fire barrier, adequacy of the barrier
thickness, etc.) prior to acceptance of the installation.2.4.1.7Assumptions The following assumptions were made in performing the safe shutdown analysis:1.Initial Plant Operating Conditions
- a. Both units of the station are operating at 100% power.
- b. Normal system and component alignments are assumed.2.All safe shutdown components and systems are assumed to be available prior to the onset of the fire. In other words, no allowance is made for
systems or components being out of service for maintenance or testing.3.Independent failures (i.e., failures that arenot a direct consequence of fire damage) of systems, equipment, instrumentation, controls, or power
supplies, do not occur before, during, or following the fire.
BYRON -FPR AMENDMENT 27 DECEMBER 2016 2.4-164.The postulated fire shall not be considered to occur simultaneously with other accidents, events, or phenomena such as a design-basis accident
except a Loss of Offsite Power (LOOP). Furthermore, for any given fire
zone, a LOOP need only be postulated if the offsite power circuits are affected by a fire in that fire zone. When it can be demonstrated that a
fire in a specific zone will not affect the offsite power circuits, and
alternative shutdown capability is not credited, then a LOOP need not be
postulated to occur. In the event of a LOOP and the failure of the
emergency diesel generator to auto start due to fire damage, station
emergency procedures initiate actions to restore at least one ESF 4 KV
bus using the unit to unit 4 KV cross-tie or local start of the emergency diesel generator. The SSA credits either local start of the emergency
diesel generator or use of the 4 KV cross-tie in the fire zones where
LOOP can occur. Depending upon what equipment is affected by the fire, station emergency procedures may require the stopping of the Reactor
Coolant Pumps (RCPs), isolation of RCP seal cooling, and proceeding to
cold shutdown using natural circulation in the reactor coolant system.5.Assumptions regarding fire damage to mechanical components are described in Subsection 2.1.1(h) of the Fire Hazards Analysis.6.Assumptions regarding fire damage to electrical cables are described in previous Subsection 2.4.1.5.2 "Cable Damage Assumptions."7.For a control room fire, evacuation of the control room is assumed.
However, credit is taken for reactor trip and verification of control rod
insertion prior to evacuation. Control rod insertion is sufficient to ensure
subcriticality to maintain hot standby. For this event, the operators would utilize plant procedures 1(2)BOA PRI-5 Control Room Inaccessibility -Unit
1(2) and fire response guideline procedures to control the plant.
BYRON -FPR AMENDMENT 27 DECEMBER 2016 2.4-178.For fires outside the control room, the operators are assumed to remain in the control room and to utilize the instruments and controls provided there to the greatest extent, in accordance with existing station procedures.
Operators would utilize fire response guideline procedures in conjunction
with Emergency, Abnormal, Normal and General Operating procedures to
place the plant in a safe condition during fires affecting safe shutdown
equipment. The fire response guideline procedure provides operators
with guidance describing the potential affects of a fire on a specific fire zone basis and actions to mitigate the potential affects. When proper
operation of equipment cannot be performed or confirmed from the control room, alternate procedures are utilized. For example, 1(2)BOA PRI-5 Control Room Inaccessibility -Unit 1(2), or 1(2)BOA ELEC-5 Local Emergency Control of Safe Shutdown Equipment -Unit 1(2) could be used (this list is not meant to be complete -other procedures are available and could be used). These procedures are symptom-oriented rather than
event-oriented. That is, there are no special procedures for fire in fire
zone X, rather the procedures cover the loss of equipment X for whatever reason. Where the safe shutdown analysis shows that control cables
from both redundant trains of equipment are located in the same fire
zone, credit is taken for shutdown via local operation of equipment as specified in various plant procedures (including but not limited to the
procedures referenced above). However, reference to a particular
procedure for a particular fire zone, is not a commitment to automatically
use that procedure in the event of a fire in that zone. For a fire less severe than the design basis fire, normal control room controls will
continue to be used as long as they remain undamaged. 9If a fire causes electrical shorting or overload, it is assumed that automatic circuit protection will function properly. If manual action is required to
reclose a breaker that is not in the fire zone, credit is taken for such action
where the breaker is accessible.
BYRON -FPR AMENDMENT 27 DECEMBER 2016 2.4-18 2.4.1.8 Repairs For many of the fire zones, credit is taken for making repairs to equipment in order to perform one or more of the safe shutdown functions. In all cases, such credit is taken
only to accomplish a function required for cold shutdown. The ability to achieve and
maintain hot standby independent of each fire zone, without taking credit for repairs, is
demonstrated in Subsection 2.4.2.
Specific repairs credited for individual fire zones are discussed in Subsection 2.4.2 and summarized in Table 2.4-3. Most repairs identified consist of installing temporary cable to replace cables that are assumed to be damaged by a fire. For each repair credited
in Subsection 2.4.2, a station procedure has been written and is available to cover the
repair. The procedure is general for each type of repair. For example, a repair procedure covers the temporary repair of cables and is applicable for all zones where
such repairs are referenced. For each repair credited in Subsection 2.4.2, the quantity
and specific type of materials required by the analysis and the procedure are reserved
onsite.The nature and scope of these repairs are such that they can be implemented and cold shutdown can be achieved in the affected unit(s) within 72 hours8.333333e-4 days <br />0.02 hours <br />1.190476e-4 weeks <br />2.7396e-5 months <br />. This meets the
requirements of BTP CMEB 9.5-1. The repairs would be performed by the plant's
normal maintenance staff, who possess adequate training to complete these tasks.
Neither additional nor specially trained personnel would be required. Furthermore, the
repairs are simple enough that no special efforts to demonstrate the capability to implement them within a 72 hour8.333333e-4 days <br />0.02 hours <br />1.190476e-4 weeks <br />2.7396e-5 months <br /> time period (and subsequently achieve cold shutdown)
are deemed to be necessary.
For Measurement Uncertainty Recapture (MUR) Power Uprate (EC 378382(B-1) EC378383(B-2) EC 378380(BR-1) EC 378381(BR-2)), an analysis was performed based on bounding repair activities performed concurrently with bounding plant
operating conditions and concluded that the unit can reach cold shutdown in 72 hours8.333333e-4 days <br />0.02 hours <br />1.190476e-4 weeks <br />2.7396e-5 months <br />.
(Reference EXBY001-RPT-001 Rev 0 dated March 14, 2011 BYRON & BRAIDWOOD FIRE PROTECTION COLD SHUTDOWN EVALUATION IN SUPPORT OF MUR PU
REPORT).2.4.1.9 Staffing Requirements for Safe Shutdown Staffing requirements for safe shutdown are met by the minimum plant operating staff as set forth in the current plant procedure that governs staffing. A control room fire is
generally assumed to be the most restrictive fire with regards to staffing, since
evacuation of the main control room (MCR) is required for both units. Fire damage
assumptions for a postulated control room fire are addressed in the introductory
paragraphs to subsection 2.4.2.3. Based upon the assumptions, 3 licensed operators, 4 non-licensed operators for safe shutdown, 4 non-licensed operators for the fire
brigade, and one fire brigade chief will be available to shut down the fire affected unit and the opposite unit. Current minimum staffing levels are adequate to support
shutdown of both units as specified above, and also man the fire brigade.
BYRON -FPR AMENDMENT 27 DECEMBER 2016 2.4-19 2.4.2 Fire Area/Zone Safe Shutdown Analysis The following safe shutdown analysis is performed on a fire zone basis. For Byron and Braidwood, the firezones on which this analysis are based are considered to be
equivalent to fire areas.
The fire zone boundaries and designations originated during the preparation of the original fire hazards analysis Fire Area Analysis in approximately 1977, prior to the issuance of 10CFR50 Appendix R and BTP CMEB 9.5-1. However, these same zone
boundaries and designations were utilized during preparation of the original Byron unit
1 safe shutdown analysis (circa 1982), and the subsequent safe shutdown analyses for the other three units. They are retained during the current re-analysis.
All fire zone boundaries in the safety related auxiliary building, where most safe shutdown equipment is located, consist of walls, floors and ceilings of substantial construction. Manyfire zone boundaries carry a three hour fire rating, and therefore
qualify as fire area boundaries. Many other fire zone boundaries are designated as
radiation barriers, flood barriers or ventilation barriers. The fire hazards analysis Fire
Area Analysis has demonstrated that a fire in any fire zone of the plant will not
propagate to adjacent fire zones. Therefore, for the purpose of the safe shutdown
analysis, the existing fire zones are considered to be equivalent to fire areas.
The present analysis applies to both unit 1 and unit 2. A safe shutdown component/cable listing and evaluation are provided for the majority of the fire zones
included in the fire hazards analysis (Section 2.3). Essentially all safety related and
many non-safety related areas are included. Those fire zones which are not addressed
primarily consist of outbuildings and administrative offices, which have no safe
shutdown impact.
For the individual fire zone evaluations, the discussion follows a structured format.
First, common systems are addressed. Common safe shutdown systems include the
control room ventilation (VC) system and the auxiliary building ventilation (VA) system
supply and exhaust fans. Other systems, such as component cooling and essential
service water, have the capability to be shared, but are normally operated in a unit
isolated mode. These systems are discussed separately for each unit. Following the
discussion of common systems, the discussion of the safe shutdown impact on unit 1 is provided, followed by the unit 2 discussion.
For each unit, the discussion first addresses essential AC and DC support systems.
These are addressed first since the availability (or unavailability) of these systems can significantly impact the choice of individual componentsor trains of remaining safe
shutdown systems which are to be credited for safe shutdown. Next, the following safe
shutdown functions are discussed in order: RCS inventory control (including reactivity control), hot standby decay heat removal, essential support, and cold shutdown decay
heat removal. For fire zones where essentially all of the components/cables are
associated with only one unit, and the other unit is unaffected or minimally affected, the
discussion for the unaffected/minimally affected unit is condensed into a single
paragraph.
BYRON-FPR AMENDMENT 27 DECEMBER 2016 F i nally, for fire zones whose boundaries dev i ate from BTP CMEB 9.5-1 , e i ther a dev i ation or Generic Letter 86-10 evaluat i on is d i scussed at the end of the subsection.
2.4-20 BYRON - FPR AMENDMENT 20 DECEMBER 2002 (Sheet 1 of 6) TABLE 2.4-5
REMOTE SHUTDOWN PANEL (RSP) INSTRUMENTATION
A. PANEL 1PL04J
INSTRUMENT NO.
DESCRIPTION
1FI-AF011B* Auxiliary Feedwater Pump 1A Flow to Steam Generator 1A 1FI-AF013B* Auxiliary Feedwater Pump 1A Flow to Steam Generator 1B 1FI-AF015B* Auxiliary Feedwater Pump 1A Flow to Steam Generator 1C 1FI-AF017B* Auxiliary Feedwater Pump 1A Flow to Steam Generator 1D 1LI-501 Steam Generator 1A Level
1LI-502 Steam Generator 1B Level
1LI-503 Steam Generator 1C Level 1LI-504 Steam Generator 1D Level
- Essential Service Water Pump 1A Discharge Temperature
- Essential Service Water Return Header OA Temperature
1PI-0514B Steam Generator 1A Steam Pressure
1PI-0544B Steam Generator 1D Steam Pressure
BYRON - FPR AMENDMENT 20 DECEMBER 2002 (Sheet 2 of 6)
TABLE 2.4-5 (Cont'd)
B. PANEL 1PL05J
INSTRUMENT NO.
DESCRIPTION
1FI-AF012B* Auxiliary Feedwater Pump 1B Flow to Steam Generator 1A 1FI-AF014B* Auxiliary Feedwater Pump 1B Flow to Steam Generator 1B 1FI-AF016B* Auxiliary Feedwater Pump 1B Flow to Steam Generator 1C 1FI-AF018B* Auxiliary Feedwater Pump 1B Flow to Steam Generator 1D 1TI-RC005A Reactor Coolant Loop 1A Hot Leg Temperature 1TI-RC006A Reactor Coolant Loop 1B Hot Leg Temperature 1TI-RC007A Reactor Coolant Loop 1C Hot Leg Temperature 1TI-RC008A Reactor Coolant Loop 1D Hot Leg Temperature 1TI-RC005B Reactor Coolant Loop 1A Cold Leg Temperature 1TI-RC006B Reactor Coolant Loop 1B Cold Leg Temperature 1TI-RC007B Reactor Coolant Loop 1C Cold Leg Temperature 1TI-RC008B Reactor Coolant Loop 1D Cold Leg Temperature
BYRON - FPR AMENDMENT 20 DECEMBER 2002 (Sheet 3 of 6)
TABLE 2.4-5 (Cont'd)
B. PANEL 1PL05J (Cont'd)
INSTRUMENT NO.
DESCRIPTION
- Essential Service Water Pump 1B Discharge Temperature
- Essential Service Water Return Header OB Temperature
1PI-0524B Steam Generator 1B Steam Pressure
1PI-0534B Steam Generator 1C Steam Pressure
1FT-0110* Emergency Boron Injection Flow
C. PANEL 1PL06J
INSTRUMENT NO. DESCRIPTION
1LI-0459B Pressurizer Level 1LI-0460B Pressurizer Level
1PI-0455B Pressurizer Pressure
- Volume Control Tank Level
- Charging Header Pressure
1FI-0121B* Charging Header Flow
1NI-NR001* Source Range Neutron (NE-31) Indicator
1NI-NR002* Source Range Neutron (NE-32) Indicator
BYRON - FPR AMENDMENT 20 DECEMBER 2002 (Sheet 4 of 6)
TABLE 2.4-5 (Cont'd)
D. PANEL 2PL04J
INSTRUMENT NO.
DESCRIPTION
2FI-AF011B* Auxiliary Feedwater Pump 2A Flow to Steam Generator 2A 2FI-AF013B* Auxiliary Feedwater Pump 2A Flow to Steam Generator 2B 2FI-AF015B* Auxiliary Feedwater Pump 2A Flow to Steam Generator 2C 2FI-AF017B* Auxiliary Feedwater Pump 2A Flow to Steam Generator 2D 2LI-501 Steam Generator 2A Level
2LI-502 Steam Generator 2B Level
2LI-503 Steam Generator 2C Level
2LI-504 Steam Generator 2D Level
- Essential Service Water Pump 2A Discharge Temperature
- Essential Service Water Return Header OA Temperature
2PI-0514B Steam Generator 2A Steam Pressure
2PI-0544B Steam Generator 2D Steam Pressure
BYRON - FPR AMENDMENT 20 DECEMBER 2002 (Sheet 5 of 6)
TABLE 2.4-5 (Cont'd)
E. PANEL 2PL05J
INSTRUMENT NO.
DESCRIPTION
2FI-AF012B* Auxiliary Feedwater Pump 2B Flow to Steam Generator 2A 2FI-AF014B* Auxiliary Feedwater Pump 2B Flow to Steam Generator 2B 2FI-AF016B* Auxiliary Feedwater Pump 2B Flow to Steam Generator 2C 2FI-AF018B* Auxiliary Feedwater Pump 2B Flow to Steam Generator 2D 2TI-RC005A Reactor Coolant Loop 2A Hot Leg Temperature 2TI-RC006A Reactor Coolant Loop 2B Hot Leg Temperature 2TI-RC007A Reactor Coolant Loop 2C Hot Leg Temperature 2TI-RC008A Reactor Coolant Loop 2D Hot Leg Temperature 2TI-RC005B Reactor Coolant Loop 2A Cold Leg Temperature 2TI-RC006B Reactor Coolant Loop 2B Cold Leg Temperature 2TI-RC007B Reactor Coolant Loop 2C Cold Leg Temperature 2TI-RC008B Reactor Coolant Loop 2D Cold Leg Temperature
BYRON - FPR AMENDMENT 20 DECEMBER 2002 (Sheet 6 of 6)
TABLE 2.4-5 (Cont'd)
E. PANEL 2PL05J (Cont'd)
INSTRUMENT NO.
DESCRIPTION
- Essential Service Water Pump 2B Discharge Temperature
- Essential Service Water Return Header OB Temperature
2PI-0524B Steam Generator 2B Steam Pressure
2PI-0534B Steam Generator 2C Steam Pressure
2FT-0110* Emergency Boron Injection Flow
F. PANEL 2PL06J
INSTRUMENT NO. DESCRIPTION
2LI-0459B Pressurizer Level 2LI-0460B Pressurizer Level
2PI-0455B Pressurizer Pressure
- Volume Control Tank Level
- Charging Header Pressure
2FI-0121B* Charging Header Flow
2NI-NR001* Source Range Neutron (NE-31) Indicator
2NI-NR002* Source Range Neutron (NE-32) Indicator
_________________________
- Not identified as a safe shutdown instrument.
BYRON -FPR AMENDMENT 20 DECEMBER 2002 (Sheet 1 of 12) TABLE 2.4-6
REMOTE SHUTDOWN PANEL CONTROLS
A. PANEL 1PL04J
EQUIPMENT NUMBER DESCRIPTION CONTROL NUMBER CONTROL FUNCTION 1AF005A AFW Regulating Valve 1HK-AF031B Position controller
1AF005B AFW Regulating Valve 1HK-AF033B Position controller
1AF005C AFW Regulating Valve 1HK-AF035B Position controller
1AF005D AFW Regulating Valve 1HK-AF037B Position controller
1AF013A AFW Steam Generator 1HS-AF071 Open-close switch Isolation Valve
1AF013B AFW Steam Generator 1HS-AF073 Open-close switch Isolation Valve
1AF013C AFW Steam Generator 1HS-AF075 Open-close switch Isolation Valve 1AF013D AFW Steam Generator 1HS-AF077 Open-close switch Isolation Valve
1AF01PA AFW Pump 1A 1HS-AF003 On-off switch
1CV01PA Centrifugal Charging 1HS-CV001 On-off switch Pump 1A
1CV01PA-A CCP 1A Lube Oil Pump 1HS-CV013 On-off switch
0CC01P Component Cooling 0HS-CC001 On-off switch Pump O
1CC01PA Component Cooling 1HS-CC001 On-off switch Pump 1A
1MS001A,D Main Steam Isolation 1HS-MS143 Open-close switch Valves 1A, 1D
BYRON -FPR AMENDMENT 20 DECEMBER 2002 (Sheet 2 of 12)
TABLE 2.4-6 (Cont'd)
A. PANEL 1PL04J (Cont'd)
EQUIPMENT NUMBER DESCRIPTION CONTROL NUMBER CONTROL FUNCTION 1MS018A Main Steam Atmospheric Relief Valve 1A 1PK-MS041B Setpoint controller 1MS018D Main Steam Atmospheric Relief Valve 1D 1PK-MS044B Setpoint controller 1RC01PA Reactor Coolant Pump 1A 1HS-RC001 On-off switch
1RC01PD Reactor Coolant Pump 1D 1HS-RC004 On-off switch
1SX01PA ESW Pump 1A 1HS-SX003 On-off switch
0SX02PA ESW Makeup Pump 0A 0HS-SX009 On-off switch
0SX03CA ESW Cooling Tower Fan 0A low speed 0HS-SX001 On-off switch 0SX03CB ESW Cooling Tower Fan 0B low speed 0HS-SX002 On-off switch 0VC01CA MCR Supply Fan 0A 0HS-VC111 On-off switch
0VC02CA MCR Return Fan 0A 0HS-VC008 On-off switch
0VC18Y,19Y, 20Y MCR Outside Air Dampers0HS-VC118 Open-close switch 0VC21Y,22Y, 43Y MCR Charcoal Filter Iso.
Dampers 0HS-VC120 Open-close switch 1VP01CA Reactor Cont. Fan Cooler high speed 1HS-VP011 On-off switch 1VP01CC Reactor Cont. Fan Cooler high speed 1HS-VP013 On-off switch
BYRON -FPR AMENDMENT 20 DECEMBER 2002 (Sheet 3 of 12)
TABLE 2.4-6 (Cont'd)
B. PANEL 1PL05J
EQUIPMENT NUMBER DESCRIPTION CONTROL NUMBER CONTROL FUNCTION 1AF005E AFW Regulating Valve 1HK-AF032B Position controller
1AF005F AFW Regulating Valve 1HK-AF034B Position controller
1AF005G AFW Regulating Valve 1HK-AF036B Position controller
1AF005H AFW Regulating Valve 1HK-AF038B Position controller
1AF013E AFW Steam Generator 1HS-AF072 Open-close switch Iso. Valve
1AF013F AFW Steam Generator 1HS-AF074 Open-close switch Iso. Valve
1AF013G AFW Steam Generator 1HS-AF076 Open-close switch Iso. Valve
1AF013H AFW Steam Generator 1HS-AF078 Open-close switch Iso. Valve 1AF01PB AFW Pump 1B 1HS-AF004 On-off switch
1CV01PB Centrifugal Charging 1HS-CV002 On-off switch Pump 1B
1CV01PB-A CCP 1B Lube Oil Pump 1HS-CV014 On-off switch
1CV8104 Emergency Boration 1HS-CV005 Open-close switch Valve
0CC01P Component Cooling 0HS-CC002 On-off switch Pump 0
1CC01PB Component Cooling 1HS-CC002 On-off switch Pump 1B
1MS001B,C Main Steam Isolation 1HS-MS144 Open-close switch Valves 1B, 1C
BYRON -FPR AMENDMENT 20 DECEMBER 2002 (Sheet 4 of 12)
TABLE 2.4-6 (Cont'd)
B. PANEL 1PL05J (Cont'd)
EQUIPMENT NUMBER DESCRIPTION CONTROL NUMBER CONTROL FUNCTION 1MS018B Main Steam Atmospheric 1PK-MS042B Setpoint controllers Relief Valve 1B
1MS018C Main Steam Atmospheric 1PK-MS043B Setpoint controller Relief Valve 1C
1RC01PB Reactor Coolant 1HS-RC002 On-off switch Pump 1B
1RC01PC Reactor Coolant 1HS-RC003 On-off switch Pump 1C
1SXO1PB ESW Pump 1B 1HS-SX004 On-off switch
0SX02PB ESW Makeup Pump 0B 0HS-SX010 On-off switch
0SX03CE ESF Cooling Tower 0HS-SX005 On-off switch Fan 0E low speed 0SX03CF ESF Cooling Tower 0HS-SX006 On-off switch Fan 0F low speed
1VP01CB Reactor Containment 1HS-VPO12 On-off switch Fan Cooler - high speed
1VP01CD Reactor Containment 1HS-VP014 On-off switch Fan Cooler - high speed
BYRON -FPR AMENDMENT 20 DECEMBER 2002 (Sheet 5 of 12)
TABLE 2.4-6 (Cont'd)
C. PANEL 1PL06J
EQUIPMENT NUMBER DESCRIPTION CONTROL NUMBER CONTROL FUNCTION -- Plant Evacuation Alarm 1HS-CQ001 On switch
-- Plant-wide Fire Alarm 1HS-CQ002 On switch
-- Plant Evac. & Fire Alarm Reset 1HS-CQ003 Reset switch
1AB03P Boric Acid Transfer 1HS-AB001 On-off switch Pump 1A
1CV8145 Pressurizer Auxiliary 1HS-CV039 Open-close switch Spray Valve
1CV8149A Letdown Orifice 1HS-CV007 Open-close switch Isolation Valve
1CV8149B Letdown Orifice 1HS-CF009 Open-close switch Isolation Valve 1CF8149C Letdown Orifice 1HS-CV011 Open-close switch Isolation Valve
1CV02P Position Displacement 1HS-CV017 On-off switch Charging Pump
1CV-LCV459 Letdown Isolation Valve 1HS-CV019 Open-close switch
1CV-LCV460 Letdown Isolation Valve 1HS-CV021 Open-close switch
1CV02P P. D. Charging Pump 1SHC-459B Pump speed controller
1CV-FCV121 Charging flow 1FHC-121 Flow controller control valve
BYRON -FPR AMENDMENT 20 DECEMBER 2002 (Sheet 6 of 12)
TABLE 2.4-6 (Cont'd)
C. PANEL 1PL06J (Cont'd)
EQUIPMENT NUMBER DESCRIPTION CONTROL NUMBER CONTROL FUNCTION
-- Steam Generator 1LSH-FW047SG high level alarm 1A Level
-- Steam Generator 1LSH-FW048SG high level alarm 1B Level
-- Steam Generator 1LSH-FW049SG high level alarm 1C Level
-- Steam Generator 1LSH-FW050SG high level alarm 1D Level
0PW02A Primary Water Pump 0A 0HS-PW011 On-off switch
-- Press. Heaters Backup 1HS-RY001 On-off switch Group A Breaker
-- Press. Heaters Backup 1HS-RY002 On-off switch Group B Breaker
-- Press. Heaters Backup 1HS-RY005 On-off switch Group A Contactor
-- Press. Heaters Backup 1HS-RY006 On-off switch Group B Contactor
1VP03CA CRDM Exhaust Fan 1A 1HS-VP112 On-off switch
1VP03CB CRDM Exhaust Fan 1B 1HS-VP114 On-off switch
1VP03CC CRDM Exhaust Fan 1C 1HS-VP116 On-off switch
1VP03CD CRDM Exhaust Fan 1D 1HS-VP118 On-off switch
BYRON -FPR AMENDMENT 20 DECEMBER 2002 (Sheet 7 of 12)
TABLE 2.4-6 (Cont'd)
D. PANEL 2PL04J
EQUIPMENT NUMBER DESCRIPTION CONTROL NUMBER CONTROL FUNCTION 2AF005A AFW Regulating Valve 2HK-AF031B Position controller
2AF005B AFW Regulating Valve 2HK-AF033B Position controller
2AF005C AFW Regulating Valve 2HK-AF035B Position controller
2AF005D AFW Regulating Valve 2HK-AF037B Position controller
2AF013A AFW Steam Generator 2HS-AF071 Open-close switch Isolation Valve
2AF013B AFW Steam Generator 2HS-AF073 Open-close switch Isolation Valve
2AF013C AFW Steam Generator 2HS-AF075 Open-close switch Isolation Valve 2AF013D AFW Steam Generator 2HS-AF077 Open-close switch Isolation Valve
2AF01PA AFW Pump 2A 2HS-AF003 On-off switch
2CV01PA Centrifugal Charging 2HS-CV001 On-off switch Pump 2A
2CV01PA-A CCP 2A Lube Oil Pump 2HS-CV013 On-off switch
0CC01P Component Cooling 0HS-CC001 On-off switch Pump O
2CC01PA Component Cooling 2HS-CC001 On-off switch Pump 2A
2MS001A,D Main Steam Isolation 2HS-MS143 Open-close switch Valves 2A, 2D
BYRON -FPR AMENDMENT 20 DECEMBER 2002 (Sheet 8 of 12)
TABLE 2.4-6 (Cont'd)
D. PANEL 2PL04J (Cont'd)
EQUIPMENT NUMBER DESCRIPTION CONTROL NUMBER CONTROL FUNCTION 2MS018A Main Steam Atmospheric Relief Valve 2A 2PK-MS041B Setpoint controller 2MS018D Main Steam Atmospheric Relief Valve 2D 2PK-MS044B Setpoint controller 2RC01PA Reactor Coolant Pump 2A 2HS-RC001 On-off switch
2RC01PD Reactor Coolant Pump 2D 2HS-RC004 On-off switch
2SX01PA ESW Pump 2A 2HS-SX003 On-off switch
0SX03CC ESW Cooling Tower Fan 0C low speed 0HS-SX003 On-off switch 0SX03CD ESW Cooling Tower Fan 0D low speed 0HS-SX004 On-off switch 2VP01CA Reactor Cont. Fan Cooler high speed 2HS-VP011 On-off switch 2VP01CC Reactor Cont. Fan Cooler high speed 2HS-VP013 On-off switch
BYRON -FPR AMENDMENT 20 DECEMBER 2002 (Sheet 9 of 12)
TABLE 2.4-6 (Cont'd)
E. PANEL 2PL05J
EQUIPMENT NUMBER DESCRIPTION CONTROL NUMBER CONTROL FUNCTION 2AF005E AFW Regulating Valve 2HK-AF032B Position controller
2AF005F AFW Regulating Valve 2HK-AF034B Position controller
2AF005G AFW Regulating Valve 2HK-AF036B Position controller
2AF005H AFW Regulating Valve 2HK-AF038B Position controller
2AF013E AFW Steam Generator 2HS-AF072 Open-close switch Iso. Valve
2AF013F AFW Steam Generator 2HS-AF074 Open-close switch Iso. Valve
2AF013G AFW Steam Generator 2HS-AF076 Open-close switch Iso. Valve
2AF013H AFW Steam Generator 2HS-AF078 Open-close switch Iso. Valve 2AF01PB AFW Pump 2B 2HS-AF004 On-off switch
2CV01PB Centrifugal Charging 2HS-CV002 On-off switch Pump 2B
2CV01PB-A CCP 2B Lube Oil Pump 2HS-CV014 On-off switch
2CV8104 Emergency Boration 2HS-CV005 Open-close switch Valve
0CC01P Component Cooling 0HS-CC004 On-off switch Pump 0
2CC01PB Component Cooling 2HS-CC002 On-off switch Pump 2B
2MS001B,C Main Steam Isolation 2HS-MS144 Open-close switch Valves 2B, 2C
BYRON -FPR AMENDMENT 20 DECEMBER 2002 (Sheet 10 of 12)
TABLE 2.4-6 (Cont'd)
E. PANEL 2PL05J (Cont'd)
EQUIPMENT NUMBER DESCRIPTION CONTROL NUMBER CONTROL FUNCTION 2MS018B Main Steam Atmospheric 2PK-MS042B Setpoint controllers Relief Valve 2B
2MS018C Main Steam Atmospheric 2PK-MS043B Setpoint controller Relief Valve 2C
2RC01PB Reactor Coolant 2HS-RC002 On-off switch Pump 2B
2RC01PC Reactor Coolant 2HS-RC003 On-off switch Pump 2C
2SXO1PB ESW Pump 2B 2HS-SX004 On-off switch
0SX03CG ESF Cooling Tower 0HS-SX007 On-off switch Fan 0G low speed
0SX03CH ESF Cooling Tower 0HS-SX008 On-off switch Fan 0H low speed 2VP01CB Reactor Containment 2HS-VPO12 On-off switch Fan Cooler - high speed
2VP01CD Reactor Containment 2HS-VP014 On-off switch Fan Cooler - high speed
BYRON -FPR AMENDMENT 20 DECEMBER 2002 (Sheet 11 of 12)
TABLE 2.4-6 (Cont'd)
F. PANEL 2PL06J
EQUIPMENT NUMBER DESCRIPTION CONTROL NUMBER CONTROL FUNCTION -- Plant Evacuation Alarm 2HS-CQ001 On switch
-- Plant-wide Fire Alarm 2HS-CQ002 On switch
-- Plant Evac. & Fire Alarm Reset 2HS-CQ003 Reset switch
2AB03P Boric Acid Transfer 2HS-AB001 On-off switch Pump 2A
2CV8145 Pressurizer Auxiliary 2HS-CV039 Open-close switch Spray Valve
2CV8149A Letdown Orifice 2HS-CV007 Open-close switch Isolation Valve
2CV8149B Letdown Orifice 2HS-CF009 Open-close switch Isolation Valve 2CF8149C Letdown Orifice 2HS-CV011 Open-close switch Isolation Valve
2CV02P Position Displacement 2HS-CV017 On-off switch Charging Pump
2CV-LCV459 Letdown Isolation Valve 2HS-CV019 Open-close switch
2CV-LCV460 Letdown Isolation Valve 2HS-CV021 Open-close switch
2CV02P P. D. Charging Pump 2SHC-459B Pump speed controller
2CV-FCV121 Charging flow 2FHC-121 Flow controller control valve
BYRON -FPR AMENDMENT 20 DECEMBER 2002 (Sheet 12 of 12)
TABLE 2.4-6 (Cont'd)
F. PANEL 2PL06J (Cont'd)
EQUIPMENT NUMBER DESCRIPTION CONTROL NUMBER CONTROL FUNCTION
-- Steam Generator 2LSH-FW047SG high level alarm 2A Level
-- Steam Generator 2LSH-FW048SG high level alarm 2B Level
-- Steam Generator 2LSH-FW049SG high level alarm 2C Level
-- Steam Generator 2LSH-FW050SG high level alarm 2D Level
0PW02B Primary Water Pump 0B 0HS-PW013 On-off switch
-- Press. Heaters Backup 2HS-RY001 On-off switch Group A Breaker
-- Press. Heaters Backup 2HS-RY002 On-off switch Group B Breaker
-- Press. Heaters Backup 2HS-RY005 On-off switch Group A Contactor
-- Press. Heaters Backup 2HS-RY006 On-off switch Group B Contactor
2VP03CA CRDM Exhaust Fan 2A 2HS-VP112 On-off switch
2VP03CB CRDM Exhaust Fan 2B 2HS-VP114 On-off switch