ML111010427
| ML111010427 | |
| Person / Time | |
|---|---|
| Site: | Ginna  |
| Issue date: | 12/06/2010 |
| From: | Garnish K Constellation Energy Nuclear Group |
| To: | David Silk Operations Branch I |
| Hansell S | |
| Shared Package | |
| ML103200302 | List: |
| References | |
| TAC U01838, ES-401-2 | |
| Download: ML111010427 (45) | |
Text
To:
Mr. David Silk From:
Kyle Garnish, General Supervisor Operations Training
Subject:
R.E. Ginna 2011 Retake Written Examination Outline Date:
December 6,2010 Please find enclosed materials supporting administration ofthe R.E. Ginna 2011 Retake examination scheduled to be administered to Dan Tiberio the week of January 24th 2011.
The following documents are enclosed:
- 1. Form ES-201-2 Examination Outline Quality Checklist
- 2. R.E. Ginna 2011 NRC Initial License Written Retake Examination Written Examination Outline Methodology
- 3. Topic Level and Statement Level Suppression list
- 4. Form ES-401-2 Written Examination Outline
- 5. Form ES-401 Generic Knowledge and Abilities Outline
- 6. Form ES-401-4 Record of Rejected KiA's The enclosed examination materials must be withheld from public disclosure until after the examination is comflete. Administration ofthe exam is scheduled to be concluded on or about January 28t 2011.
Contact the Ginna General Supervisor-Operations Training ifyou have any questions.
Sincerely, Kyle G. Garnish General Supervisor-Operations Training Ginna Station Nuclear Power Plant 585-771-5321 kvle.garnish@cengllc.com
ES-401 Written Examination Outline Form ES-401-2 Facility: R.E. Ginna 2011 Retake Date of Exam:
01/27/11 RO KJA Category Points SRO-Only Points Tier Group K
K K
K K
K A
A A
A G
Total A2 G*
Total 1
2 3
4 5
6 1
2 3
4
- 1.
Emergency Plant Evaluations 1
2 Tier Totals 3
1 4
3 1
4 3
2 5
3 2
5 3
2 5
3 1
4 18 9
27 3
2 5
3 2
5 6
4 10 1
3 2
2 3
3 2
2 3
3 2
3 28 2
3 5
- 2.
Plant Systems 2
Tier Totals 1
4 1
3 1
3 1
4 1
4 0
2 1
3 1
4 1
4 1
3 1
4 10 38 0
1 3
2 5
3 8
- 3. Generic Knowledge & Abilities 1
2 3
4 10 1
2 3
4 7
3 2
3 2
2 1
2 2
Note
- 1.
Ensure that at least two topics from every applicable KIA category are sampled within each tier of the RO and SRO-only outlines (i.e., except for one category in Tier 3 of the SRO-only outline, the Tier Totals in each KIA category shall not be less than two).
- 2.
The point total for each group and tier in the proposed outline must match that specified in the table.
The final point total for each group and tier may deviate by 1 from that specified in the table based on NRC revisions. The final RO exam must total 75 points and the SRO-only exam must total 25 points.
- 3.
Systems/evolutions within each group are identified on the associated outline; systems or evolutions that do not apply at the facility should be deleted and justified; operationally important, site-specific systems that are not included on the outline should be added. Refer to section D.1.b of ES-401, for guidance regarding elimination of inappropriate KIA statements.
- 4.
Select topics from as many systems and evolutions as possible; sample every system or evolution in the group before selecting a second topic for any system or evolution.
- 5.
Absent a plant specific priority, only those KAs having an importance rating (IR) of 2.5 or higher shall be selected. Use the RO and SRO ratings for the RO and SRO-only portions, respectively.
- 6.
Select SRO topics for Tiers 1 and 2 from the shaded systems and KIA categories.
7.*
The generic (G) KlAs in Tiers 1 and 2 shall be selected from Section 2 of the KIA Catalog, but the topics must be relevant to the applicable evolution or system. Refer to Section D.1.b of ES-401 for the applicable KIA's B.
On the following pages, enter the KIA numbers, a brief description of each topic, the topics' importance ratings (IR) for the applicable license level, and the point totals (#) for each system and category. Enter the group and tier totals for each category in the table above. If fuel handling equipment is sampled in other than Category A2 or G* on the SRO-only exam, enter it on the left side of Column A2 for Tier 2, Group 2 (Note #1 does not apply). Use duplicate pages for RO and SRO-only exams.
- 9.
For Tier 3, select topics from Section 2 of the KIA Catalog, and enter the KIA numbers, descriptions, IRs, and point totals (#) on Form ES-401-3. Limit SRO selections to KlAs that are linked to 10CFR55.43
ES-401 Form ES-401-2 R.E. Ginna 2011 Retake Written Examination Outline Emergency and Abnormal Plant Evolutions - Tier 1 Group 1 EAPE#/Name Safety Function KIA Topic(s)
AA2.12 - Ability to determine and interpret the following as 008 1 Pressurizer Vapor they apply to the X
3.7 76 Space Accident 1 3 Pressurizer Vapor Space Accident: PZR level indicators AA2.15 - Ability to determine and interpret the following as 027 1 Pressurizer Pressure they apply to the Control System Malfunction X
Pressurizer Pressure Control 4.0 77 13 Malfunctions: Actions to be taken if PZR pressure instrument fails hiQh EA2.16 - Ability to determine or interpret the following as 038 1 Steam Generator they apply to a SGTR:
X 4.6 78 Tube Rupture 1 3 Actions to be taken if S/G goes solid and water enters steam line 2.4.47 - Emergency Procedures 1Plan: Ability to diagnose and recognize 026 1 Loss of Component X
trends in an accurate and 4.2 79 Cooling Water 1 8 timely manner utilizing the appropriate control room reference material.
2.2.39 - Equipment Control:
077 1 Generator Voltage Knowledge of less than or and Electric Grid X
equal to one hour technical 4.5 80 Disturbances specification action statements for systems.
2.4.8 - Emergency Procedures 1Plan:
015 117 1 Reactor Coolant Knowledge of how abnormal X
4.5 81 Pump Malfunctions 1 4 operating procedures are used in conjunction with EOP's.
EK1.05 - Knowledge of the operational implications of the following concepts as 029 1 AntiCipated Transient they apply to the A TWS:
X 2.8 39 Without Scram (A TWS) 1 1 definition of negative temperature coefficient as applied to large PWR coolant systems 2
ES-401 Form ES-401-2 R.E. Ginna 2011 Retake Written Examination Outline Emergency and Abnormal Plant Evolutions - Tier 1 Group 1 EAPE#/Name Safety Function 027 1 Pressurizer Pressure Control System Malfunction 13 X
AK1.02 - Knowledge of the operational implications of the following concepts as they apply to Pressurizer Pressure Control Malfunctions: Expansion of liquids as temperature increases 2.8 40 E04 I LOCA Outside Containment / 3 X
EK1.3 - Knowledge of the operational implications of the following concepts as they apply to the (LOCA Outside Containment)
Annunciators and conditions indicating signals, and remedial actions associated 3.5 41 with the (LOCA Outside Containm EK2.1 - Knowledge of the interrelations between the E11/ Loss of Emergency Coolant Recirculation / 4 X
(Loss of Emergency Coolant Recirculation) and the following: Components, and functions of control and safety systems, including instrumentation, signals, interlocks, failure modes, and automatic and manual 3.6 42 features.
077/ Generator Voltage and Electric Grid Disturbances X
AK2.02 - Knowledge of the interrelations between Generator Voltage and Electric Grid Disturbances and the following: Breakers, 3.1 43 3
ES-401 Form ES-401-2 R.E. Ginna 2011 Retake Written Examination Outline Emergency and Abnormal Plant Evolutions - Tier 1 Group 1 EAPE#/Name Safety Function E051 Inadequate Heat Transfer - Loss of x
Secondary Heat Sink I 4 065 I Loss of Instrument Air x
18 E121 Steam Line Rupture x
Excessive Heat Transfer I 4 057 I Loss of Vital AC Electrical Instrument Bus I x
6 KIA Topic(s)
EK2.2 - Knowledge of the interrelations between the (Loss of Secondary Heat Sink) and the following:
Facility's heat removal systems, including primary coolant, emergency coolant, the decay heat removal systems, and relations between the proper operation of these systems to the operation of the faci AK3.03 - Knowledge of the reasons for the following responses as they apply to the Loss of Instrument Air:
Knowing effects on plant
- ~""".'***.,"*l operation of isolating certain equipment from instrument air EK3.1 - Knowledge of the reasons for the following responses as they apply to the (Uncontrolled Depressurization of all Steam Generators) Facility operating characteristics during transient conditions, including coolant chemistry and the effects of temperature, pressure, and reactivity changes and operating limitations and reasons for these operating characteristics.
AK3.01 - Knowledge the reasons for the following responses as they apply to the Loss of Vital AC Instrument Bus: Actions contained in EOP for loss of vital ac electrical instrument bus 3.9 44 2.9 45 3.5 46 4.1 47 4
ES-401 Form ES-401-2 RE. Ginna 2011 Retake Written Examination Outline Emergency and Abnormal Plant Evolutions - Tier 1 Group 1 EAPE#lName Safety Function 007 / Reactor Trip Stabilization - Recovery /1 011 / Large Break LOCA / 3 026 / Loss of Component Cooling Water / 8 056 / Loss of Off-site Power 6
058 / Loss of DC Power I 6 022 / Loss of Reactor Coolant Makeup / 2 055 / Station Blackout I 6 009/ Small Break LOCA / 3 KIA Topic(s)
EA 1.04 - Ability to operate and monitor the following as they apply to a reactor trip:
RCP operation and flow rates EA 1.05 - Ability to operate and monitor the following as they apply to a Large Break LOCA: Manual and/or automatic transfer of suction of charging pumps to borated source AA1.01 - Ability to operate and / or monitor the following as they apply to the Loss of Component Cooling Water:
CCW/nuclear service water tem indications AA2.43 - Ability to determine and interpret the following as they apply to the Loss of Offsite Power: Occurrence of a turbine tri AA2.01 - Ability to determine and interpret the following as they apply to the Loss of DC Power: That a loss of dc power has occurred; verification that substitute 2.4.3 - Emergency Procedures I Plan: Ability to identify post-accident instrumentation.
3.6 4.3 3.1 3.9 3.7 3.2 3.9 3.7 48 49 50 51 52 53 54 5
ES-401 Form ES-401-2 RE. Ginna 2011 Retake Written Examination Outline Emergency and Abnormal Plant Evolutions - Tier 1 Group 1 EAPE#fName Safety Function I K1 I K2 I K3 I A1 I A2 G I KJA Topic(s) 2.4.8 - Emergency Procedures I Plan:
038 I Steam Generator Knowledge of how abnormal 3.8 56 Tube Rupture I 3 operating procedures are used in conjunction with
~__________________~~L-~~__~
'~~'~~~'0~~E~O~P_'~s.~_______________~.-~~
KJA CategoryTotals 333 Gwup Point Total:
18/6 6
ES-401 Form ES-401-2 R.E. Ginna 2011 Retake Written Examination Outline Emergency and Abnormal Plant Evolutions - Tier 1 Group 2 EAPE#/Name Safety Function KJA Topic(s)
EA2.1 - Ability to determine and interpret the following as they apply to the (Steam E13 / Steam Generator Generator Overpressure)
X 3.4 82 Overpressure / 4 Facility conditions and selection of appropriate procedures during abnormal and emergency operations.
AA2.01 - Ability to determine and interpret the following as they apply to the Steam 037 / Steam Generator X
Generator Tube Leak:
3.4 83 Tube Leak / 3 Unusual readings of the monitors; steps needed to verify readings 2.4.1 - Emergency Procedures / Plan:
E07 / Saturated Core X
Knowledge of EOP entry 4.8 84 Cooling /4 conditions and immediate action steps.
2.1.32 - Conduct of 076 / High Reactor Coolant Operations: Ability to explain X
4.0 85 Activity / 9 and apply all system limits and precautions.
EK1.1 - Knowledge of the operational implications of the following concepts as E09 / Natural Circulation they apply to the (Natural X
3.0 57 Operations / 4 Circulation Operations)
Components, capacity, and function of emergency systems.
AK2.01 - Knowledge of the interrelations between the 036 / Fuel Handling X
Fuel Handling Incidents and 2.9 58 Incidents / 8 the following: Fuel handling equipment AK3. 17 - Knowledge of the reasons for the following 068 / Control Room responses as they apply to X
3.7 59 Evacuation / 8 the Control Room Evacuation: Injection of boric acid into the RCS 7
ES-401 Form ES-401-2 R.E. Ginna 2011 Retake Written Examination Outline Emergency and Abnormal Plant Evolutions - Tier 1 Group 2
- lName Safety Function 0031 Dropped Control Rod 11 E031 LOCA Cooldown and Depressurization 1 4 E07 1Saturated Core Cooling 14 001 1Continuous Rod Withdrawal 1 1 051 1Loss of Condenser Vacuum 14 067 1 Plant Fire On-site 1 8 x
KJA CategoryTotals 2
,)";,.~;*,*~i'!*'V*1 AA1.01 - Ability to operate and 1or monitor the following as they apply to the Dropped Control Rod:
Demand position counter and converter EA2.1 - Ability to determine and interpret the following as they apply to the (LOCA Cooldown and Depressurization) Facility conditions and selection of appropriate procedures during abnormal and 2.1.27 - Conduct of Operations: Knowledge of system purpose and 1or function.
AA1.02 - Ability to operate and lor monitor the following as they apply to the Continuous Rod Withdrawal:
Rod in-out-hold switch AA2.02 - Ability to determine and interpret the following as they apply to the Loss of Condenser Vacuum:
Conditions requiring reactor and/or turbine AK3.02 - Knowledge of the reasons for the following responses as they apply to the Plant Fire on Site Steps called out in the site fire protection plan, FPS manual, and fire zone manual Group Point Total:
2.9 60 3.4 61 3.9 62 3.6 63 3.9 64 2.5 65 8
ES-401 Form ES-401-2 System #/Name 010 Pressurizer Pressure Control 076 Service Water 061 Auxiliary/Emergency Feedwater 064 Emergency Diesel Generator 073 Process Radiation Monitoring R.E. Ginna 2011 Retake Written Examination Outline Plant Systems - Tier 2 Group 1 KIA Topic(s)
A2.01 - Ability to (a) predict the impacts of the following malfunctions or operations on the PZR PCS; and (b) based on those predictions, use X
3.6 86 procedures to correct, control, or mitigate the consequences of those malfunctions or operations: Heater failures A2.01 - Ability to (a) predict the impacts of the following malfunctions or operations on the SWS; and (b) based on those X
predictions, use 3.7 87 procedures to correct, control, or mitigate the consequences of those malfunctions or operations: Loss of SWS 2.4.46 - Emergency Procedures / Plan: Ability X
to verify that the alarms 4.2 88 are consistent with the plant conditions.
2.4.4 - Emergency Procedures / Plan: Ability to recognize abnormal indications for system X
operating parameters 4.7 89 which are entry-level conditions for emergency and abnormal operating procedures.
2.1.7 - Conduct of Operations: Ability to evaluate plant performance and make X
operational judgments 4.7 90 based on operating characteristics, reactor behavior, and instrument interpretation.
9
ES-401 Form ES-401-2 RE. Ginna 2011 Retake Written Examination Outline Plant Systems - Tier 2 Group 1 System #/Name KIA Topic(s}
K 1.03 Knowledge of the physical connections 062 AC Electrical Distribution x
and/or cause-effect relationships between the ac distribution 3.5 1
system and the following
"'\\I"'Ta"",,' DC distribution K1.05 Knowledge of the physical connections 012 Reactor Protection x
and/or cause effect relationships between the RPS and the 3.8 2 following systems:
ESFAS K2.02 - Knowledge of 064 Emergency Diesel Generator x
bus power sUPFPlieis ~ol the following: ue 01 2.8 3 061 Uary/Emergency Feedwater x
K2.01 - Knowledge of bus power supplies to the following: AFW
"'\\I"'*.a.., MOVs 3.2 4 K3.01 - Knowledge of the effect that a loss or 073 Process Radiation Monitoring x
malfunction of the PRM system will have on the 3.6 5 following: Radioactive effluent releases K3.01 - Knowledge of the effect that a loss or malfunction of the CCS 022 Containment Cooling will have on the following: Containment equipment subject to 2.9 6 damage by high or low temperature, humidity, re K4.01 - Knowledge of 007 Pressurizer Relief/Quench Tank x
PRTS design feature(s) and/or interlock(s) which provide for the following:
2.6 7 Quench tank coolin 10
ES-401 Form ES-401-2 System #lName 003 Reactor Coolant Pump 010 Pressurizer Pressure Control 006 Emergency Core Cooling 013 Engineered Safety Features Actuation 004 Chemical and Volume Control 005 Residual Heat Removal R.E. Ginna 2011 Retake Written Examination Outline Plant Systems - Tier 2 Group 1 KIA Topic(s)
K4.02 - Knowledge of RCPS design feature(s) and/or interlock(s) which provide for the following:
Prevention of cold water accidents or transients K5.01 - Knowledge of the operational implications of the following concepts as the apply to the PZR PCS:
Determination of condition of fluid in PZR, usin steam tables K5.05 - Knowledge of the operational implications of the x
following concepts as they apply to ECCS:
Effects of pressure on a sol id <;:\\"~T""rT1 K6.01 - Knowledge of the effect of a loss or malfunction on the following will have on the ESFAS: Sensors and detectors K6.05 - Knowledge of the effect of a loss or malfunction on the following CVCS components: Sensors and detectors A 1.02 - Ability to predict and/or monitor changes in parameters (to nrO:>\\lo:>rltl exceeding design limits) associated with operating the RHRS controls including: RHR flow rate 2.5 8 3.5 9 3.4 10 2.7 11 2.5 12 3.3 13 11
ES-401 Form ES-401-2 System #/Name 063 DC Electrical Distribution 026 Containment Spray 076 Service Water 008 Component Cooling Water 078 Instrument Air R.E Ginna 2011 Retake Written Examination Outline Plant Systems - Tier 2 Group 1 KIA Topic(s)
A1.01 - Ability to predict and/or monitor changes in parameters associated with operating the dc electrical system controls including: Battery capacity as it is affected rate A2.04 - Ability to (a) predict the impacts of the following malfunctions or operations on the CSS; and (b) based on those predictions, use procedures to correct, control, or mitigate the consequences of those malfunctions or operations: Failure of A2.02 - Ability to (a) predict the impacts of the following malfunctions or operations on the SWS; and (b) based on those predictions, use procedures to correct, control, or mitigate the consequences of those malfunctions or operations: Service water header re A3.05 - Ability to monitor automatic operation of the CCWS, including:
Control of the electrically operated. automatic isolation valves in the CCWS A3.01 - Ability to monitor automatic operation of the lAS, including: Air 2.5 14 3.9 15 2.7 16 3.0 17 3.1 18 12
ES-401 Form ES-401-2 System #/Name 039 Main and Reheat Steam 059 Main Feedwater 103 Containment 063 DC Electrical Distribution 012 Reactor Protection 061 Auxiliary/Emergency Feedwater R.E. Ginna 2011 Retake Written Examination Outline Plant Systems - Tier 2 Group 1 KIA Topic(s) room: Initiation of automatic feedwater isolation 2.2.42 _. Equipment Control:: Ability to recognize system parameters that are entry-level conditions for Technical S ons.
2.4.6 - Emergency Procedures / Plan:
Knowledge of EOP miti ation ies.
2.2.36 - Equipment Control: Ability to analyze the effect of maintenance activities, such as degraded power sources, on the status of limiting conditions for K5.02 - Knowledge of the operational implications of the following concepts as the apply to the AFW: Decay heat sources and nitude 3.8 19 3.4 20 3.9 21 3.7 22 3.1 23 3.2 24 13
ES-401 Form ES-401-2 R.E. Ginna 2011 Retake Written Examination Outline Plant Systems - Tier 2 Group 1 006 Emergency Core Cooling 076 Service Water 010 Pressurizer Pressure Control 078 Instrument Air KJA Category Totals A2.12 - Ability to (a) predict the impacts of the following malfunctions or operations on the ECCS; and (b) based on those predictions. use procedures to correct, 4.5 25 control, or mitigate the consequences of those malfunctions or operations: Conditions requiring actuation of ECCS 2.5 26 3.6 27 K1.04 - Knowledge of the physical connections and/or cause-effect relationships between 2.6 28 the lAS and the following systems: Cooling water to comnrQ'C:::C:::i'\\r Group Point Total:
28/5 14
ES-401 Form ES-401-2 R.E. Ginna 2011 Retake Written Examination Outline Plant Systems - Tier 2 Group 2 System #/Name KIA Topic(s)
A2.02 - Ability to (a) predict the impacts of the following mal-functions or operations on the GS; and (b) based on those 035 Steam Generator X
predictions, use procedures to correct, 4.4 91 control, or mitigate the consequences of those malfunctions or operations: Reactor triQlturbine trip 2.4.3 - Emergency 034 Fuel Handling Equipment X
Procedures / Plan: Ability to identify post-accident 3.9 92 instrumentation.
2.2.22 - Equipment 014 Rod Position Indication X
Control: Knowledge of limiting conditions for operations and safety 4.7 93 limits.
K1.03 - Knowledge of the physical connections 056 Condensate System X
and/or cause-effect relationships between the Condensate System 2.6 29 and the following
~stems: MFW.
A 1.02 - Ability to predict and/or monitor changes in parameters (to prevent 034 Fuel Handling Equipment X
exceeding design limits) associated with Fuel Handling System 2.9 30 operating the controls including: Water level in the refueling canal A3.01 - Ability to monitor automatic operation of 086 Fire Protection X
the Fire Protection System including:
2.9 31 Starting mechanisms of fire water ~um~s 15
ES-401 Form ES-401-2 R.E. Ginna 2011 Retake Written Examination Outline Plant Systems - Tier 2 Group 2 System #/Name KIA Topic(s)
K3.02 - Knowledge of the effect that a loss or 029 Containment Purge malfunction of the Containment Purge System will have on the 2.9 32 following: Containment A4.06 - Ability to 045 Main Turbine Generator manually operate and/or monitor in the control room: Turbine stop 2.8 33 valves A2.03 - Ability to predict and/or monitor changes in parameters (to prevent 016 Non-nuclear Instrumentation exceeding design limits) associated with operating the NNIS 3
34 controls including:
Interruption of transmitted s I
K4.01 - Knowledge of 035 Steam Generator S/GS design feature(s) and/or interlock(s) which provide for the following:
3.6 35 S/G level control 027 Containment Iodine Removal x
K2.01 - Knowledge of bus power supplies to the followi
- Fans 3.1 36 K5.73 - Knowledge of the following operational 001 Control Rod Drive implications as they apply to the CRDS:
Need for maintenance of 2.7 37 stable plant conditions duri rod exercisi 2.4.46 - Emergency 071 Waste Gas Disposal Procedures / Plan: Ability to verify that the alarms are consistent with the 4.2 38 conditions.
KIA Category Totals 1
1 Group Point Total:
10/3 16
ES-401 Generic Knowledge and Abilities Outline (Tier 3)
Form ES-401-3 Facility:
R.E. Ginna 2011 Retake Date:
01/27/11 Category KA#
2.1.3 2.1.31
- 1. Conduct of 2.1.28 Operations 2.1.42 2.1.39 Subtotal 2.2.18 2.2.43
- 2. Equipment Control 2.2.14 Subtotal Topic Knowledge of shift or short-term relief turnover practices.
Ability to locate control room switches, controls, and indications, and to determine that they correctly reflect the desired plant lineup.
Knowledge of the purpose and function of major system components and controls.
RO IR Q#
3.7 66 4.6 67 4.1 75 SRO-Only IR Q#
Knowledge of new and spent fuel movement procedures.
Knowledge of conservative decision making practices.
3.4 4.3 94 98 Knowledge of the process for managing maintenance activities during shutdown operations, such as risk assessments, work prioritization, etc.
Knowledge of the process used to track inoperable alarms.
2.6 3.0 3
68 69 2
Knowledge of the process for controlling equipment configuration or status.
4.3 95 2
1 17
ES-401 Generic Knowledge and Abilities Outline (Tier 3)
Form ES-401-3 2.3.15 2.3.11 2.3.7
- 3. Radiation Control 2.3.4 2.3.5 Subtotal 2.4.34 2.4.39
- 4. Emergency Procedures I Plan 2.4.29 2.4.25 Subtotal Tier 3 Point Total:
Knowledge of radiation monitoring systems, such as fixed radiation monitors and alarms, portable survey instruments, personnel monitoring equipment, etc.
Ability to control radiation releases.
Ability to comply with radiation work permit requirements during normal or abnormal conditions.
2.9 3.8 3.5 70 71 74 Knowledge of radiation exposure limits under normal or emergency conditions.
Ability to use radiation monitoring systems, such as fixed radiation monitors and alarms, portable survey instruments, personnel monitoring equipment, etc.
3.7 2.9 96 99 Knowledge of RO tasks performed outside the main control room during an emergency and the resultant operational effects.
Knowledge of the RO's responsibilities in emergency plan implementation.
4.2 3.9 3
72 73 2
Knowledge of the emergency plan.
Knowledge of fire protection procedures.
4.4 3.7 97 100 2
10 2
7 18
ES-401 Record of Rejected KIA's Form ES-401-4 Randomly Selected Tier I Group Reason for Rejection KA 0271 AA2.05 1 11 replaced by 027 I Topic will result in excessive overlap with Question 86 AA2.15 027 I AK1.o1 1 11 replaced by 027 I Topic will result in excessive overlap with Question 9 AK1.03 E07 12.4.34 replaced There are no RO actions outside the control room related to this 1/2 by E07 1 2.4.1 EPE Topic selected is RO knowledge and inappropriate for SRO level.
061 12.4.49 replaced 2/1 Additionally. there are no immediate actions associated with this by 061 12.4.46 system 076 I A2.01 replaced 2/1 This topic is duplicated with SRO question 87 by 0761 A2.02 103 1 2.1.25 replaced No applicable references to support a test item for system 2/1 by 103 I 2.2.42 selected 0061 A2.o5 replaced 2/1 There is no guidance related to the topic selected by 0061 A2.12 071 12.4.6 replaced 2/2 There are no EOPs related to this system by 071 12.4.46 G3 12.3.4 replaced 3/3 Duplicated on SRO question 96 by G3 12.3.11 19
R.E. Ginna 2011 NRC Initial License Written Retake Examination Written Examination Outline Methodology The written examination outline was developed using a proprietary electronic random outline generator developed by Western Technical Services, Inc.
The software was designed to provide a written examination outline in accordance with the criteria contained in NUREG 1021, Revision 9, Supplement 1.
The application was developed using Visual Basic code, relying on a true random function based on the PC system clock. The random generator selects topics in a Microsoft Access Database containing Revision 2, Supplement 1 of the PWR K&A catalogue. The selected data is then written to a separate data table. The process for selection of topics is similar to the guidance in ES-401, Attachment 1.
The attached outline report is written directly from the data tables created by the software. Electronic copies of the data tables are on file, as well as a log file containing all activities related to generation of the outline.
The process used to develop the outlines is as follows:
For Tier 1 and Tier 2 generic items, only the items required to be included in accordance with ES-401, Section D.1.b are included in the generation process.
- Outline is generated for all topics with KA importance ~2.5.
- 25 SRO topics are randomly selected from Tier 1 AA2 and required generic items, Tier 2 A2 and required generic items. (including all System 034 topics) and Tier 3 generiC items (All with ties to 10CFR55.43). 75 RO topics are randomly selected to complete the outline, 100 topics total.
- The exam report generated lists the topic (Question) number in the far right column. RO topics are numbered 1-75. and SRO topics are numbered 76-100.
The SRO topics are written in red ink for ease of identification.
Items that are rejected after the initial generation process are placed on the rejected items page. Replacement topics are either randomly generated or are inserted upon direction of the Chief Examiner.
Disposition of any item randomly selected but not included in the outline is documented and included on ES-401-4.
- The outline log file tracks all manipulations of the outline, including topic deletions and random or manual topic additions. The log file is retained as a permanent record. Printouts are available upon request.
Topic Level Suppression:
EPE/APE:
SYSTEM:
025 GENERIC:
224223 Statement Level Suppression:
KA KA Beginning & End Statement EAPE/SYS Knowledge of the operational implications of the following concepts as they apply to Continuous Rod Withdrawal:
001 AK1.14 Interaction of ICS control stations as well as purpose, function, and modes of operation of ICS Ability to operate and lor monitor the following as they 003 AA1.04 apply to the Dropped Control Rod: Control rod drive safety rod out limit bypass switch or key Knowledge of the operational implications of the following 003 AK1.01 concepts as they apply to Dropped Control Rod: Reason for turbine following reactor on dropped rod event Knowledge of the operational implications of the following concepts as they apply to Dropped Control Rod:
003 AK1.13 Interaction of ICS control stations as well as purpose, function, and modes of operation of ICS Knowledge of the interrelations between the Dropped 003 AK2.03 Control Rod and the following: Metroscope Knowledge of the reasons for the following responses as they apply to the Dropped Control Rod: When ICS logic 003 AK3.01 has failed on a dropped rod, the load must be reduced until flux is within specified target bank Knowledge of the reasons for the following responses as 003 AK3.02 they apply to the Dropped Control Rod: Reactor runback with a dropped control rod Knowledge of the reasons for the following responses as 003 AK3.03 they apply to the Dropped Control Rod: Turbine automatic runback with reactor in order to balance power output Ability to operate and I or monitor the following as they 005 AA1.03 apply to the Inoperable I Stuck Control Rod: Metroscope Ability to determine and interpret the following as they apply to the Inoperable I Stuck Control Rod: Difference 005 AA2.02 between jog and run rod speeds, effect on CRDM of stuck rod Notes I
Knowledge of the interrelations between the Inoperable!
005 AK2.03 Stuck Control Rod and the following: Metroscope Ability to operate and I or monitor the following as they 008 AA1.02 apply to the Pressurizer Vapor Space Accident: HPI pump to control PZR level/pressure Ability to determine and interpret the following as they 008 AA2.11 apply to the Pressurizer Vapor Space Accident: Turbine bypass header pressure indicators Ability to determine and interpret the following as they 008 AA2.14 apply to the Pressurizer Vapor Space Accident: Saturation temperature monitor Ability to determine and interpret the following as they 008 AA2.23 apply to the Pressurizer Vapor Space Accident: Criteria for throttlinQ hiQh-pressure injection after a small LOCA Ability to operate and monitor the following as they apply to 009 EA1.18 a small break LOCA: Balancing of HPI loop flows Ability to determine or interpret the following as they apply 009 EA2.12 to a small break LOCA: CharQing pump ammeter Ability to determine or interpret the following as they apply I 009 EA2.16 to a small break LOCA: CCWuction pressure gauge Ability to determine or interpret the following as they apply 009 EA2.17 to a small break LOCA: Total flow meter Ability to determine or interpret the following as they apply 009 EA2.22 to a small break LOCA: Charging flow trend recorder Ability to determine or interpret the following as they apply I
009 EA2.26 to a small break LOCA: Activity waste tank level gauges Ability to determine or interpret the following as they apply 009 EA2.27 to a small break LOCA: Activity waste tank trend recorders Ability to determine or interpret the following as they apply 009 EA2.30 to a small break LOCA: Tech Specs limits for plant operation with less than four loops Ability to determine or interpret the following as they apply 009 EA2.35 to a small break LOCA: Conditions for throttling or stopping reflux boiling spray Knowledge of the reasons for the following responses as the apply to the small break LOCA: CCW System 009 EK3.01 automatic isolation on high delta flow! temperature to RCP thermal barrier I
Knowledge of the reasons for the following responses as the apply to the small break LOCA: Manual 009 EK3.27 depressurization or HPI recirculation for sustained high I pressure Ability to operate and monitor the following as they apply to 011 EA1.02 a Large Break LOCA: Reflux boiling sump level indicators Ability to operate and monitor the following as they apply to 011 EA1.14 a Large Break LOCA: Subcooling margin monitors Ability to operate and monitor the following as they apply to 011 1.16 a Large Break LOCA: Balancing of HPJ loop flows Ability to determine or interpret the following as they apply 011 EA2.12 to a Large Break LOCA: Conditions for throttling or stopping reflux boiling spray Knowledge of the reasons for the following responses as 011 EK3.07 the apply to the Large Break LOCA: Stopping charging Ipump bypass flow
Ability to operate and I or monitor the following as they 015 AA1.04 apply to the Reactor Coolant Pump Malfunctions (Loss of RC Flow): RCP ventilation cooling fan run indicators Ability to operate and lor monitor the following as they 015 AA1.19 apply to the Reactor Coolant Pump Malfunctions (Loss of RC Flow): Power transfer confirm lamp Ability to determine and interpret the following as they apply to the Reactor Coolant Pump Malfunctions (Loss of 015 AA2.04 RC Flow): Temperature differential across the RCP air cooler Ability to determine and interpret the following as they apply to the Reactor Coolant Pump Malfunctions (Loss of 015 AA2.05 RC Flow): Relationship between RCP ammeter readings and RCS aver-age temperature Ability to determine and interpret the following as they apply to the Reactor Coolant Pump Malfunctions (Loss of 015 AA2.06 RC Flow): Relationship between cooling air flow and oil reservoir temperaturellevel for RCP Ability to determine and interpret the following as they apply to the Reactor Coolant Pump Malfunctions (Loss of 015 AA2.09 RC Flow): When to secure RCPs on high stator temperatures Knowledge of the reasons for the following responses as they apply to the Reactor Coolant Pump Malfunctions 015 AK3.05 (Loss of RC Flow) : Shift of T-ave. sensors to the loop with the highest flow Knowledge of the reasons for the following responses as they apply to the Reactor Coolant Pump Malfunctions 015 AK3.06 (Loss of RC Flow) : Performance of a core power map, calculations of quadrant power tilt, monitoring of core imbalance Ability to determine and interpret the following as they 022 AA2.03 apply to the Loss of Reactor Coolant Pump Makeup:
Failures of flow control valve or controller Knowledge of the operational implications of the following concepts as they apply to Loss of Reactor Coolant Pump 022 AK1.02 Makeup: Relationship of charging flow to pressure differential between charging and RCS Knowledge of the operational implications of the following concepts as they apply to Loss of Reactor Coolant Pump 022 AK1.04 Makeup: Reason for changing from manual to automatic control of charging flow valve controller Ability to operate and lor monitor the following as they 024 AA1.01 apply to the Emergency Soration: Use of spent fuel pool as backup to SWST Ability to operate and I or monitor the following as they 024 AA1.06 apply to the Emergency Soration: SWST temperature Ability to operate and I or monitor the following as they 024 AA1.07 apply to the Emergency Soration: SWST level Ability to operate and I or monitor the following as they 024 AA1.08 apply to the Emergency Soration: Pump speed controlled to protect pump seals Ability to operate and lor monitor the following as they 024 AA1.10 apply to the Emergency Soration: CVCS centrifugal charging pumps I
Ability to operate and / or monitor the following as they 024 M1.11 024 M1.21 024 M1.23 024 M1.24 024 M2.04 025 M1.05 025 M1.18 025 M1.19 025 M1.22 025 AK2.04 026 M1.03 026 M1.04 027 M1.04 027 M1.05 027 M2.17 027 AK3.02 028 M2.05 028 M2.13 apply to the Emergency Boration: BIT suction and recirculation valves Ability to operate and I or monitor the following as they apply to the Emergency Boration: CVCS charging pump miniflow isolation valves and indicators Ability to operate and / or monitor the following as they apply to the Emergency Boration: CVCS centrifugal charging pump switches and indicators Ability to operate and / or monitor the following as they apply to the Emergency Boration: BIT inlet and outlet valve switches and indicators Ability to determine and interpret the following as they apply to the Emergency Boration: Availability of BWST Ability to operate and / or monitor the following as they apply to the Loss of Residual Heat Removal System: Raw water or sea water pumps Ability to operate and / or monitor the following as they apply to the Loss of Residual Heat Removal System: LPI header cross-connect valve controller and indicators Ability to operate and / or monitor the following as they apply to the Loss of Residual Heat Removal System: Block orifice bypass valve controller and indicators Ability to operate and I or monitor the following as they apply to the Loss of Residual Heat Removal System:
Obtaining of water from BWST for LPI system Knowledge of the interrelations between the Loss of Residual Heat Removal System and the following: Raw water or sea water pumps Ability to operate and / or monitor the following as they apply to the Loss of Component Cooling Water: SWS as a backup to the CCWS Ability to operate and I or monitor the following as they apply to the Loss of Component Cooling Water: CRDM high-temperature alarm system Ability to operate and / or monitor the following as they apply to the Pressurizer Pressure Control Malfunctions:
Pressure recovery, using emergency-only heaters Ability to operate and / or monitor the following as they apply to the Pressurizer Pressure Control Malfunctions:
Transfer of heaters to backup power supply Ability to determine and interpret the following as they apply to the Pressurizer Pressure Control Malfunctions:
Allowable RCS temperature difference vs. reactor power Knowledge of the reasons for the following responses as they apply to the Pressurizer Pressure Control Malfunctions: Verification of alternate transmitter and/or Iplant computer prior to shifting flow chart transmitters Ability to determine and interpret the following as they apply to the Pressurizer Level Control Malfunctions: Flow control valve isolation valve indicator Ability to determine and interpret the following as they apply to the Pressurizer Level Control Malfunctions: The actual PZR level, given uncompensated level with an lappropriate graph I
Knowledge of the reasons for the following responses as they apply to the Pressurizer Level Control Malfunctions:
028 AK3.04 Change in PZR level with power change, even though RCS T-ave. constant, due to loop size difference Ability to operate and monitor the following as they apply to 029 EA1.04 a A TWS: BIT inlet valve switches Ability to operate and monitor the following as they apply to I 029 EA1.05 a ATWS: BIT outlet valve switches Ability to operate and monitor the following as they apply to 029 EA1.06 a ATWS: Operating switches for normal charging header isolation valves Ability to operate and monitor the following as they apply to 029 EA1.07 a A TWS: Operating switch for charging pump recirculation valve Ability to determine or interpret the following as they apply 029 EA2.03 to a A TWS: Centrifugal charging pump ammeter Ability to determine or interpret the following as they apply 029 EA2.04 to a ATWS: CVCS centrifugal charging pump operating indication Knowledge of the reasons for the following responses as 029 EK3.03 I
the apply to the A TWS: Opening BIT inlet and outlet valves Knowledge of the reasons for the following responses as 029 EK3.04 the apply to the ATWS: Closing the normal charging header isolation valves Knowledge of the reasons for the following responses as 029 EK3.05 the apply to the A TWS: Closing the centrifugal charging Ipump recirculation valve Knowledge of the reasons for the following responses as 029 EK3.09 the apply to the A TWS: Opening centrifugal charging pump suction valves from RWST Ability to determine and interpret the following as they apply to the Loss of Source Range Nuclear 032 M2.08 Instrumentation: Testing required if power lost, then restored Ability to determine and interpret the following as they apply to the Loss of Intermediate Range Nuclear 033 M2.13 Instrumentation: Testing required if power lost, then restored Ability to operate and I or monitor the following as they 037 M1.03 apply to the Steam Generator Tube Leak: Loop isolation valves Ability to operate and monitor the following as they apply to 038 EA1.26 a SGTR: High-head safety injection mini-flow valves and Iposition ind icators Ability to operate and monitor the following as they apply to 038 EA1.28 a SGTR: Interlock between MSIV and bypass valve Ability to operate and monitor the following as they apply to 038 EA1.42 a SGTR: Shutting of high-head safety injection mini-flow valves Knowledge of the reasons for the following responses as 038 EK3.07 the apply to the SGTR: RCS loop isolation values Ability to operate and I or monitor the following as they 040 M1.23 apply to the Steam Line Rupture: All pressure gauges per steam generator (for pressure drop)
Ability to operate and / or monitor the following as they 051 AA1.01 055 EA1.03 056 AA1.15 056 AA1.16 056 AA1.17 056 AA1.20 056 AA1.25 056 AA1.28 056 AA1.29 056 AA2.02 056 AA2.11 056 AA2.12 056 AA2.29 056 AA2.30 056 AA2.38 056 AA2.40 056 AA2.65 056 AA2.80 056 AA2.87 apply to the Loss of Condenser Vacuum: Condenser vacuum pump Ability to operate and monitor the following as they apply to a Station Blackout: Manual MT jacking Ability to operate and I or monitor the following as they apply to the Loss of Offsite Power: Service water booster pump Ability to operate and / or monitor the following as they apply to the Loss of Offsite Power: ESF switch gear room cooling unit Ability to operate and / or monitor the following as they apply to the Loss of Offsite Power: Service water building normal ventilation supply fan Ability to operate and / or monitor the following as they apply to the Loss of Offsite Power: Speed switch room ventilation fan Ability to operate and / or monitor the following as they apply to the Loss of Offsite Power: Main steam supply valve control switch Ability to operate and / or monitor the following as they apply to the Loss of Offsite Power: SWS flow control valve for the CCW cooler to control CCW outlet temperature Ability to operate and I or monitor the following as they apply to the Loss of Offsite Power: CCW heat exchanger temperature control valves Ability to determine and interpret the following as they apply to the Loss of Offsite Power: ESF load sequencer status lights Ability to determine and interpret the following as they apply to the Loss of Offsite Power: Operational status of service water booster pump Ability to determine and interpret the following as they apply to the Loss of Offsite Power: Operational status of ESF switch gear room cooling unit Ability to determine and interpret the following as they apply to the Loss of Offsite Power: Service water booster I pump ammeter and flowmeter Ability to determine and interpret the following as they apply to the Loss of Offsite Power: Switch gear room cooling unit run indicator Ability to determine and interpret the following as they apply to the Loss of Offsite Power: Load sequencer status lights Ability to determine and interpret the following as they apply to the Loss of Offsite Power: Service water pump ammeter and flowmeter Ability to determine and interpret the following as they apply to the Loss of Offsite Power: Screen wash pump Ability to determine and interpret the following as they apply to the Loss of Offsite Power: Input/output voltage alarm Ability to determine and interpret the following as they apply to the Loss of Offsite Power: Circulation water pump ammeter readings
057 AA1.03 057 AA2.01 059 AA1.03 062 AA1.03 062 AA1.04 062 AK3.01 062 AK3.04 065 AA2.02 065 AK3.05 068 AA1.09 068 AA1.18 068 AA1.20 068 AK3.04 068 AK3.05 074 EA1.03 074 EK3.09 Ability to operate and I or monitor the following as they apply to the Loss of Vital AC Instrument Bus: Feedwater I pump speed to control pressure and level in S/G Ability to determine and interpret the following as they apply to the Loss of Vital AC Instrument Bus: Safety injection tank pressure and level indicators Ability to operate and I or monitor the following as they apply to the Accidental Liquid Radwaste Release: Flow rate controller Ability to operate and I or monitor the following as they apply to the Loss of Nuclear Service Water: SWS as a backup to the CCWS Ability to operate and I or monitor the following as they apply to the Loss of Nuclear Service Water: CRDM high-temperature alarm system Knowledge of the reasons for the following responses as they apply to the Loss of Nuclear Service Water The conditions that will initiate the automatic opening and closing of the SWS isolation valves to the nuclear service water coolers Knowledge of the reasons for the following responses as they apply to the Loss of Nuclear Service Water Effect on the nuclear service water discharge flow header of a loss of CCW Ability to determine and interpret the following as they apply to the Loss of Instrument Air: Relationship of flow readings to system operation Knowledge of the reasons for the following responses as they apply to the Loss of I nstrument Air: Checking electric loads on a running compressor Ability to operate and lor monitor the following as they apply to the Control Room Evacuation: Synchroscope key Ability to operate and lor monitor the following as they apply to the Control Room Evacuation: Turbine automatic-stop oil pressure indicators and lights Ability to operate and I or monitor the following as they apply to the Control Room Evacuation: Indicators for operation of startup transformer Knowledge of the reasons for the following responses as they apply to the Control Room Evacuation: Filling the feedwater system and closing the AFW pump discharge valve Knowledge of the reasons for the following responses as they apply to the Control Room Evacuation: Repositioning valves to isolate and drain the AFW pump turbine and steam supply header Ability to operate and monitor the following as they apply to a Inadequate Core Cooling: The alternate control station for turbine bypass valve operation Knowledge of the reasons for the following responses as the apply to the Inadequate Core Cooling: Opening the cross-connect valve from the LPI to the HPI suction
Ability to predict and/or monitor changes in parameters (to prevent exceeding design limits) associated with operating 001 A1.08 the CROS controls including: Verification that CROS temperatures are within limits before starting Ability to predict and/or monitor changes in parameters (to prevent exceeding design limits) associated with operating 001 A1.10 the CROS controls including: Location and operation of controls and indications for CROS component cooling water Ability to predict and/or monitor changes in parameters (to prevent exceeding design limits) associated with operating 001 A1.13 the CROS controls including: Prepower dependent insertion limit and power dependent insertion limit, determined with metroscope Ability to (a) predict the impacts of the following malfunction or operations on the CROS* and (b) based on those 001 A2.04 predictions, use procedures to correct, control. or mitigate the consequences of those malfunctions or operations:
Positioning of axial shaping rods and their effect on SOM Ability to (a) predict the impacts of the following malfunction or operations on the CROS-and (b) based on those 001 A2.08 predictions, use procedures to correct, control, or mitigate the consequences of those malfunctions or operations:
Loss of CCW to CROS Ability to (a) predict the impacts of the following malfunction or operations on the CROS-and (b) based on those 001 A2.20 predictions, use procedures to correct, control, or mitigate the consequences of those malfunctions or operations:
Isolation of left coil on affected rod to prevent coil burnout Ability to manually operate and/or monitor in the control 001 A4.01 room: Controls for CCWS Ability to manually operate and/or monitor in the control 001 A4.04 room: Part-length rod position Ability to manually operate and/or monitor in the control 001 A4.09 I
room: CCWS Ability to manually operate and/or monitor in the control 001 A4.12 room: Stopping T/G load changes; only make minor adjustments to prevent coil burnout Knowledge of the physical connections and/or cause-effect 001 K1.01 relationships between the CROS and the following I
systems: CCW Knowledge of the physical connections and/or cause-effect 001 K1.02 relationships between the CROS and the following systems: CVCS Knowledge of the physical connections and/or cause-effect 001 K1.06 relationships between the CROS and the following systems: WGOS Knowledge of the physical connections and/or cause-effect 001 K1.07 relationships between the CROS and the following systems: Quench tank Knowledge of the physical connections and/or cause-effect relationships between the CROS and the following 001 K1.08 systems: CCWS: must be shut down to prevent condensation on CROM stators
001 K1.09 001 K2.08 001 K3.01 001 K3.03 001 K4.11 001 K4.1S 001 K5.71 001 K5.76 001 K5.79 002 A1.12 002 A4.01 002 K4.09 002 K5.03 002 K5.06 002 K5.16 003 K2.03 003 K3.05 003 K4.11 004 A4.22 Knowledge of the physical connections and/or cause-effect relationships between the CROS and the following systems: CCWS must be cut in before energizing CROS Knowledge of bus power supplies to the following:
Motors........
Knowledge of the effect that a loss or malfunction of the CROS will have on the following: CVCS Knowledge of the effect that a loss or malfunction of the CROS will have on the following: CCW Knowledge of CROS design feature(s) and/or interlock(s) which provide for the following: Resetting of CROM circuit breakers Knowledge of CROS design feature(s) and/or interlock(s) which provide for the following: Operation of latching controls for groups and individual rods Knowledge of the following operational implications as they apply to the CROS: Reason for maintaining cross-tie breaker between rod drive M/G sets; reliability of control rod drive trip breakers during operation of one M/G set Knowledge of the following operational implications as they apply to the CROS: Effects on power of inserting axial shaping rods Knowledge of the following operational implications as they apply to the CROS: Effects of positioning of axial shape rods on SOM Ability to predict and/or monitor changes in parameters (to prevent exceeding design limits) associated with operating the RCS controls including: Radioactivity level when vending CROS Ability to manually operate and/or monitor in the control room: RCS leakage calculation program using the computer Knowledge of RCS design feature(s) and/or interlock(s) which provide for the following: Operation of loop isolation valves.
Knowledge of the operational implications of the following concepts as they apply to the RCS: Oifference in pressure-temperature relationship between the water/steam system and the water/nitrogen system.
Knowledge of the operational implications of the following concepts as they apply to the RCS: Pressure, temperature, and volume relationships of nitrogen gas in association with water Knowledge of the operational implications of the following concepts as they apply to the RCS: Reason for automatic features of the Feedwater control system during total loss of reactor coolant flow Knowledge of bus power supplies to the following: RCP lube oil pumps Knowledge of the effect that a loss or malfunction of the RCPS will have on the following: ICS Knowledge of RCPS design feature(s) and/or interlock(s) _
which provide for the following: Isolation valve interlocks Ability to manually operate and/or monitor in the control room: Boronometer chart recorder
Knowledge of the physical connections and/or cause-effect 004 K1.03 relationships between the eves and the following systems: Operation, function and control of T/G Knowledge of the physical connections and/or cause-effect 004 K1.09 relationships between the eves and the following systems: Relationship between eves and RPIS Knowledge of the physical connections and/or cause-effect 004 K1.22 relationships between the eves and the following systems: BWST Knowledge of the physical connections and/or cause-effect relationships between the eves and the following 004 K1.25 systems: Interface between HPI flow path and excess letdown flow path Knowledge of the operational implications of the following 004 K5.33 concepts as they apply to the eves: Use of a boronometer Knowledge of the effect of a loss or malfunction on the 004 K6.11 following eves components: Recirculation valve on boric acid storage tank (why it is closed during functional test)
Knowledge of the effect of a loss or malfunction on the following eves components: Principle of recirculation 004 K6.12 valve: (permit emergency flow even if valve s blocked by crystallized boric acid)
Knowledge of the effect of a loss or malfunction on the 004 K6.14 following eves components: Recirculation path for charging pumps Knowledge of the operational implications of the following 004 K6.19 concepts as they apply to the eves: Purpose of centrifugal Ipump miniflows (recirculation)
Knowledge of the operational implications of the following 004 K6.33 concepts as they apply to the eves: Principles of boronometer Ability to manually operate and/or monitor in the control 005 A4.05 room: Position of RWST recirculation valve (locked when not in use, continuously monitored when in use).
Knowledge of the physical connections and/or cause-effect 005 K1.03 relationships between the RHRS and the following systems: Spent fuel pool cooling Knowledge of the effect of a loss or malfunction on the K6.02 following will have on the RHRS: Packless valves Ability to manually operate and/or monitor in the control 007 A4.06 room: Throttle valve Ability to manually operate and/or monitor in the control 007 A4.08 room: Location and interpretation of radioactive gas recorder Ability to monitor automatic operation of the ecws, 008 A3.09 including: Normal eRDM temperatures Ability to manually operate and/or monitor in the control 008 A4.03 room: Throttling of the eew pump discharge valve Ability to manually operate and/or monitor in the control 008 A4.06 room: Remote operation of hand-operated throttle valves to regulate eew flow rate Ability to manually operate and/or monitor in the control 008 A4.09 room: eew temperature control valve
008 A4.11 008 K3.02 008 K4.04 008 K4.06 008 K4.07 011 A2.08 011 K1.05 011 K5.02 013 K4.06 013 K4.14 013 K4.17 013 K4.18 013 K4.19 013 K4.20 013 K4.21 013 K4.24 Ability to manually operate and/or monitor in the control room: CCW pump recirculation valve and its three-way control switch Knowledge of the effect that a loss or malfunction of the CCWS will have on the following: CRDS Knowledge of CCWS design feature(s) and/or interlock(s) which provide for the following: Weir design aspect of the surge tank Knowledge of CCWS design feature(s) and/or interlock(s) which provide for the following: Auxiliary building CCWS isolation Knowledge of CCWS design feature(s) and/or interlock(s) which provide for the following: Operation of the CCW swing-bus power supply and its associated breakers and controls Ability to (a) predict the impacts of the following malfunctions or operations on the PZR LCS; and (b) based on those predictions, use procedures to correct, control, or mitigate the consequences of Loss of level compensation Knowledge of the physical connections and/or cause-effect relationships between the PZR LCS and the fol-Iowing systems: Reactor regulating system Knowledge of the operational implications of the following concepts as they apply to the PZR LCS Principle of operation for the charging pump electric pneumatic flow control valve Knowledge of ESFAS design feature(s) and/or intelock(s) which provide for the following Recirculation actuation system reset Knowledge of ESFAS design feature(s) and/or intelock(s) which provide for the following Upper head injection accumulator isolation Knowledge of ESFAS design feature(s) and/or intelock(s) which provide for the following Reason for stopping air coolers on train being tested Knowledge of ESFAS design feature(s) and/or intelock(s) which provide for the following Reason for jumping containment high-high-pressure signal to containment spray pump on train being tested Knowledge of ESFAS design feature(s) and/or intelock(s) which provide for the following Reason for opening breaker on high-head injection pump Knowledge of ESFAS design feature(s) and/or intelock(s) which provide for the following Reason for stopping CCW
!pump on train being tested Knowledge of ESFAS design feature(s) and/or intelock(s) which provide for the following Reason for starting an additional service water booster pump for train not being tested and stopping the pump on train under test Knowledge of ESFAS design feature(s) and/or intelock(s) which provide for the following Reason for disabling of BIT so it will not function during ESF sequencer test
014 A1.01 014 A2.07 014 A4.03 014 K2.01 014 K2.02 014 K4.01 014 K4.02 014 K4.04 014 K6.03 015 A3.06 015 K1.05 015 K3.04 015 K4.04 022 A2.03 022 A2.06 022 A4.02 022 K1.02 022 K1.03 022 K1.04 Ability to predict and/or monitor changes in parameters (to prevent exceeding design limits) associated with operating the RPIS controls, including: Metroscope reed switch display Ability to (a) predict the impacts of the following malfunctions or operations on the RPIS; and (b) based on those on those predictions, use procedures to correct, control, or mitigate the consequences of those malfunctions or operations: Loss of reed switch Ability to manually operate andlor monitor in the c room: Primary coil voltage measurement Knowledge of bus power supplies to the following: R switches Knowledge of bus power supplies to the following:
Metroscope Knowledge of RPIS design feature(s) and/or interlock(s) which provide for the following: Upper electrical limit Knowledge of RPIS design feature(s) and/or interlock(s) which provide for the following: Lower electrical limit Knowledge of RPIS design feature(s) andlor interlock(s) which provide for the following: Zone reference lights Knowledge of the affect if a loss or malfunction on the following will have on the RPIS: Metroscope Ability to monitor automatic operation of the NIS, including:
Interpretation of in-core flux density maps from in-core detectors Knowledge of the physical connections and/or cause-effect relationships between the NIS and the following systems:
ICS Knowledge of the effect that a loss or malfunction of the NIS will have on the following: ICS.
Knowledge of NIS design feature(s) andlor interlock(s)
I provide for the following: Slow response time of SPNDs Ability to (a) predict the impacts of the following malfunctions or operationson the CCS; and (b) based on those predictions, use procedures to correct, control, or mitigate the consequences of those malfunctions or operations: Fan motor thermal overload/high-speed operation Ability to (a) predict the impacts of the following malfunctions or operationson the CCS; and (b) based on those predictions, use procedures to correct, control, or mitigate the consequences of those malfunctions or operations: Loss of CCS pump Ability to manually operate and/or monitor in the control room: CCS pumps Knowledge of the physical connections andlor cause-effect relationships between the CCS and the following systems:
SEC/remote monitoring systems Knowledge of the physical connections andlor cause-effect relationships between the CCS and the following systems:
Auxiliary steam Knowledge of the physical connections andlor cause-effect relationships between the CCS and the following systems:
Chilled water I
022 K2.02 Knowledge of power supplies to the following: Chillers 022 K2.03 Knowledge of power supplies to the following: MOVs Knowledge of CCS design feature(s) and/or interlock(s) 022 K4.02 which provide for the following: Correlation of fan speed and flowpath changes with containment pressure Knowledge of CCS design feature(s) and/or interlock(s) 022 K4.03 which provide for the following: Automatic containment isolation Knowledge of CCS design feature(s) and/or interlock(s) 022 K4.06 which provide for the following: Containment pipe chase cooling Knowledge of the effect of a loss or malfunction of the 022 K6.04 following will have on the CCS components: Pumps Knowledge of the effect of a loss or malfunction of the 022 K6.07 following will have on the CCS components: Computers and calculators Ability to (a) predict the impacts of the following malfunctions or operations on the CSS; and (b) based on 026 A2.02 those predictions, use procedures to correct, control, or mitigate the consequences of those malfunctions or operations: Failure of automatic recirculation transfer Ability to (a) predict the impacts of the following malfunctions or operations on the CSS; and (b) based on 026 A2.09 those predictions, use procedures to correct, control, or mitigate the consequences of those malfunctions or operations: Radiation hazard potential of BWST Ability to monitor automatic operation of the CSS, including:
026 A3.02 Verification that cooling water is supplied to the containment spray heat echanger Ability to manually operate and/or monitor in the control room: The remote location and use of spool pieces and 026 A4.02 other equipment to set up portable recirculation pump for additive tank, including power supply Ability to manually operate and/or monitor in the control 026 A4.03 room: The remote location and use of the special tank needed for draining CSS i
Ability to manually operate and/or monitor in the control 026 A4.04 room: The remote sampling of the NaOH tank and RWST/BWST for chemical analysis Knowledge of CSS design feature(s) and/or interlock(s) which provide for the following: Automatic swapover to 026 K4.08 containment sump suction for recirculation phase after LOCA (RWST low-low level alarm)
Ability to manually operate and/or monitor in the control 028 A4.01 room: HRPS controls Knowledge of the physical connections and/or cause-effect relationships between the HRPS and the following 028 K1.01 systems: Containment annulus ventilation system (including pressure limits)
Ability to manually operate and/or monitor in the control 029 A4.01 room: Containment purge flow rate Ability to manually operate and/or monitor in the control 029 A4.03 i
room: Inlet filtration and heating system
Knowledge of bus power supplies to the following: Supply 029 K2.05 air heaters Knowledge of design feature(s) and/or interlock(s) which 029 K4.03 I provide for the following: Automatic purge isolation Knowledge of design feature(s) and/or interlock(s) which 029 K4.05 jprovide for the following: Temperature limits on dampers Knowledge of the effect of a loss or malfunction on the 029 K6.04 following will have on the Containment Purge System:
Pumps Ability to manually operate and/or monitor in the control 033 A4.01 room: SFPCS pumps Ability to manually operate and/or monitor in the control 033 A4.02 room: SFPCS valves Ability to manually operate and/or monitor in the control 033 A4.03 room: Support systems for fill and transfer of SFPCS water Knowledge of the physical connections and/or cause-effect 033 K1.02 relationships between the Spent Fuel Pool Cooling System and the following systems: RHRS Knowledge of the physical connections and/or cause-effect 033 K1.03 relationships between the Spent Fuel Pool Cooling System and the following systems: SIS Knowledge of the physical connections and/or cause-effect 033 K1.04 relationships between the Spent Fuel Pool Cooling System and the following systems: BWST Knowledge of the physical connections and/or cause-effect relationships between the Spent Fuel Pool Cooling System 033 K1.07 and the following systems: Emergency makeup water systems Ability to monitor automatic operation of the S/G including:
035 A3.02 MAD valves Ability to manually operate and/or monitor in the control 035 A4.07 room: Adjustment of cooling water flow rate from blowdown I
heat exchanger Ability to manually operate and/or monitor in the control 035 A4.09 room: Reason for using timed flow in filling top of S/G while going into wet lay-up I
Knowledge of the physical connections and/or cause-effect 1
035 K1.05 relationships between the S/GS and the following systems:
Nitrogen I
Knowledge of S/GS design feature(s) and/or interlock(s) 035 K4.09 which provide for the following: Maintenance of hydrostatic pressure by throttling AFW control valve Knowledge of operational implications of the following 035 K5.04 concepts as the apply to the S/GS: Purpose of using nitrogen blanket in S/G Knowledge of operational implications of the following 035 K5.05 concepts as the apply to the S/GS: Relationship between AFW pump speed and discharge Qressure during hydrotest Ability to manually operate and/or monitor in the control 039 A4.02 room: Remote operators to auxiliary steam Ability to manually operate and/or monitor in the control 039 A4.03 room: MFW pump turbines Knowledge of bus power supplies to the following: Moisture 039 K2.02 separator reheater valves
039 K4.02 039 K4.08 041 A4.01 041 A4.07 041 K2.01 041 K2.02 041 K4.01 41 K4.06 041 K4.08 041 K4.15 041 K6.04 045 A2.02 045 A4.04 045 K1.12 045 K1.14 045 K4.04 045 K4.08 045 K4.35 045 K4.44 Knowledge of MRSS design feature(s) and/or interlock(s) which provide for the following: Utilization of T-ave.
program control when steam dumping hrough atmospheric relief/dump valves, including T-ave. limits Knowledge of MRSS design feature(s) and/or interlock(s) which provide for the following: Interlocks on MSIV and bypass valves Ability to manually operate and/or monitor in the control room: ICS voltage inverter Ability to manually operate and/or monitor in the control room: Remote gagging of stuck open-relief valves Knowledge of bus power supplies to the following: ICS, normal and alternate power supply Knowledge of bus power supplies to the following: ICS inverter breakers Knowledge of SOS design feature(s) and/or interlock(s) which provide for the following: RRG/ICS system Knowledge of SOS design feature(s) and/or interlock(s) which provide for the following: MFW and AFW systems Knowledge of SOS design feature(s) and/or interlock(s) which provide for the following: Control rod index Knowledge of SOS design feature(s) and/or interlock(s) which provide for the following: Measured variable readings on ICS hand-automatic stations and required action if reading is out of the acceptable band Knowledge of the effect of a loss or malfunction on the following will have on the SOS: Main feed pumps, including effect on capacity of internal wear Ability to (a) predict the impacts of the following malfunctions or operation on the MT/G system; and (b) based on those predictions, use procedures to correct, control, or mitigate the consequences of those malfunctions or operations: Generator stator cooling water screen becoming clogged Ability to manually operate and/or monitor in the control room: Exhaust hood spray system for temperature control Knowledge of the physical connections and/or cause-effect relationships between the MT/G system and the following systems: Load control system in "following mode" Knowledge of the physical connections and/or cause-effect relationships between the MT/G system and the following systems: Bearing lift oil pump Knowledge of MT/G system design feature(s) and/or inter lock(s) which provide for the following: Turbine load-following mode of operation Knowledge of MT/G system design feature(s) and/or inter lock(s) which provide for the following: The reactor bailey station and reactor diamond station in integrated control circuitry Knowledge of MT/G system design feature(s) and/or inter lock(s) which provide for the following: Operation of reactor in the load-following mode above 15% power Knowledge of MT/G system design feature(s) and/or inter lock(s) which provide for the following: Impulse pressure mode control of steam dumps
045 K4.45 045 K5.21 045 K6.01 045 K6.06 055 A3.01 055 A3.03 055 A4.01 055 A4.02 055 A4.03 055 K1.07 055 K1.08 055 K1.09 055 K2.01 055 K3.04 055 K6.02 056 A3.10 056 A4.02 056 A4.04 056 A4.05 056 A4.06 056 A4.07 056 A4.09 Knowledge of MT/G system design feature(s) and/or inter lock(s) which provide for the following: Operation of low-pressure steam dump to prevent T/G overs peed Knowledge of the operational implications of the following concepts as the apply to the MT/B System: Purpose of turbine lube oil lift pump (to hold T/G off main bearing at low rotation speeds)
Knowledge of the effect of a loss or malfunction on the following will have on the MT/G system components:
Generator stator cooling (turbine building CCVV)
Knowledge of the effect of a loss or malfunction on the following will have on the MT/G system components:
Generator amplidyne balance system Ability to monitor automatic operation of the CARS, including: Air removal pump Ability to monitor automatic operation of the CARS, including: Automatic diversion of CARS exhaust Ability to manually operate and monitor in the control room:
Sealing steam Ability to manually operate and monitor in the control room:
Vacuum pumps Ability to manually operate and monitor in the control room:
Steam to CARS Knowledge of the physical connections and/or cause effect relationships between the CARS and the following systems: WGDS Knowledge of the physical connections and/or cause effect relationships between the CARS and the following systems: Containment Knowledge of the physical connections and/or cause effect relationships between the CARS and the following systems: Auxiliary steam Knowledge of bus power supplies to the following: Vacuum pump(s)
Knowledge of the effect that a loss or malfunction of the CARS will have on the following: MFW pumps (steam driven)
Knowledge of the effect of a loss or malfunction of the following will have on the CARS components: Vacuum Ipumps Ability to monitor automatic operation of the Condensate System including: Upper surge tank flow meter Ability to manually operate and monitor in the control room:
Condensate demineralizer bypass valve and precoat by pass Ability to manually operate and monitor in the control room:
Cleanup Valve Ability to manually operate and monitor in the control room:
Valve between upper surge tank and hotwell Ability to manually operate and monitor in the control room:
Condensate demineralizer bypass valve controller Ability to manually operate and monitor in the control room:
Hotwell pumps Ability to manually operate and monitor in the control room:
Demineralizer flow control valve
056 A4.10 056 A4.11 056 A4.14 056 K1.11 056 K3.07 056 K4.09 056 K4.18 OS6 KS.14 OS9 A1.07 059 A2.07 059 A2.09 059 A3.01 059 A3.04 059 A3.07 059 A4.01 059 A4.02 059 A4.04 059 A4.05 059 A4.06 059 A4.07 Ability to manually operate and monitor in the control room:
Low-pressure and high-pressure cleanup valves Ability to manually operate and monitor in the control room:
Setpoints on polish demineralizer bypass valve controllers Ability to manually operate and monitor in the control room:
y oil pumps for booster pumps Knowledge of the physical connections and/or cause-effect relationships between the Condensate System and the following systems: Stator cooling Knowledge of the effect that a loss or malfunction of the Condensate System will have on the following: Stator coolant Knowledge of Condensate System design feature(s) and/or interlock(s) which provide for the following: Feedwater Ipump turbine windmill protection Knowledge of Condensate System design feature(s) andlor interlock(s) which provide for the following: Interlocks between booster pumps and auxiliary oil pumps.
Knowledge of the operational implications of the following concepts as the apply to the Condensate system: Purpose of valve between upper surge tank and hotwell Ability to predict and/or monitor changes in parameters (to prevent exceeding design limits) associated with operating the MFW controls including: Feed Pump speed, including normal control speed for ICS Ability to (a) predict the impacts of the following malfunctions or operations on the MFW; and (b) based on those predictions, use procedures to correct, control, or mitigate the consequences of those malfunctions or operations: Tripping of MFW pump turbine Ability to (a) predict the impacts of the following malfunctions or operations on the MFW; and (b) based on those predictions, use procedures to correct, control. or mitigate the consequences of those malfunctions or operations: Overs peed on turning gear Ability to monitor automatic operation of the MFW, including: Valve timer display Ability to monitor automatic operation of the MFW, including: Turbine driven feed pump Ability to monitor automatic operation of the MFW.
including: ICS Ability to manually operate and monitor in the control room:
MFW turbine trip indication Ability to manually operate and monitor in the control room:
Null out MVW pump DIP differences Ability to manually operate and monitor in the control room:
Reset MFW overs peed trip Ability to manually operate and monitor in the control room:
MFW pump oil cooler, cooling water outlet valve controller Ability to manually operate and monitor in the control room:
MFW pump turbine reset switch Ability to manually operate and monitor in the control room:
Valve timer reset pushbutton
059 A4.09 059 A4.10 059 K1.07 059 K4.05 059 K4.06 059 K4.10 059 K4.11 059 K5.03 059 K5.05 059 K5.07 059 K5.11 059 K5.12 059 KS.14 059 K6.09 061 A1.03 061 A2.02 061 A3.04 Ability to manually operate and monitor in the control room:
Remote determination of operating feedwater pump turning gear Ability to manually operate and monitor in the control room:
ICS Knowledge of the physical connections and/or cause-effect relationships between the MFW and the following systems:
ICS Knowledge of MFW design feature(s) and/or interlock(s) which provide for the following: Control of speed of MFW Ipump turbine Knowledge of MFW design feature(s) and/or interlock(s) which provide for the following: Comparison of actual D/P, between main steam and MFW pump discharge pressure, to programmed DIP when placing MFW pump in automatic mode Knowledge of MFW design feature(s) and/or interlock(s) which provide for the following: Bearing oil signal to the turning gear start sequence Knowledge of MFW design feature(s) andlor interlock(s) which provide for the following: Porting Oil Knowledge of the operational implications of the following concepts as the apply to the MFW: Reason for maintenance of minimum DIP between main steam and MFW pump discharge pressure Knowledge of the operational implications of the following concepts as the apply to the MFW: Reason for balancing MFW pump loads Knowledge of the operational implications of the following concepts as the apply to the MFW: Relationship between feedwater pump speed and feedwater regulating valve I position Knowledge of the operational implications of the following concepts as the apply to the MFW: Definition of turbine windmilling Knowledge of the operational implications of the following concepts as the apply to the MFW: Increased MFW pump discharge with increased turbine speed Knowledge of the operational implications of the following concepts as the apply to the MFW: Quadrant power tilt Knowledge of the effect of a loss or malfunction of the following will have on the MFW components: MFW pump speed and flow regulating valves (reason for adjusting position of both)
Ability to predict and/or monitor changes in parameters (to prevent exceeding design limits) associated with operating the AFW controls including: Interactions when multi unit systems are cross tied Ability to (a) predict the impacts of the following malfunctions or operations on the AFW; and (b) based on those predictions, use procedures to correct, control, or mitigate the consequences of those malfunctions or operations: Loss of air to steam supply valve 1:monitor automatic operation of the AFW,
- Automatic AFW isolation
061 K1.09 061 K1.10 061 K2.03 061 K4.05 061 K4.09 061 K4.11 061 K5.04 062 K1.01 062 K4.06 064 A3.08 064 A3.09 064 A3.11 064 A4.04 068 A4.01 071 A1.05 071 A1.07 071 A4.01 071 A4.02 Knowledge of the physical connections and/or cause-effect relationships between the AFW and the following systems:
PRMS Knowledge of the physical connections and/or cause-effect relationships between the AFW and the following systems:
Diesel fuel oil Knowledge of bus power supplies to the following: AFW diesel driven pump Knowledge of AFW design feature(s) and/or interlock(s) which provide for the following: Prevention of MFW swapover to AFW suction pressure is low Knowledge of AFW design feature(s) and/or interlock(s) which provide for the following: Crossties between multi unit station Knowledge of AFW design feature(s) and/or interlock(s) which provide for the following: Automatic level control Knowledge of the operational implications of the following concepts as the apply to the AFW: Reason for warming up turbine prior to turbine startup Knowledge of the physical connections and/or cause-effect relationships between the ac distribution system and the following systems: C02 deluge Knowledge of ac distribution system design feature(s) and/or interlock(s) which provide for the following: One-line diagram of 6.9kV distribution, including sources of normal and alternative power Ability to monitor automatic operation of the ED/G system, including: Consequences of automatic transfer to automatic I position after the ED/G is stopped Ability to monitor automatic operation of the ED/G system, including: Functions (modes) of automatic transfer switch (to a startup bank)
Ability to monitor automatic operation of the ED/G system, including: Function of ED/G megawatt load controller Ability to manually operate and/or monitor in the control room: Remote operation of the air compressor switch (different modes)
Ability to manually operate and/or monitor in the control room: Control board for boron recovery Ability to predict and/or monitor changes in parameters(to prevent exceeding design limits) associated with Waste Gas Disposal System operating the controls including:
Decay tank pressure vs. liquid levels Ability to predict and/or monitor changes in parameters{to prevent exceeding design limits) associated with Waste Gas Disposal System operating the controls including:
Surge tank pressure and level Ability to manually operate and/or monitor in the control room: Valve to put the holdup tank into service; indications of valve positions and tank pressure Ability to manually operate and/or monitor in the control room: Waste-gas compressor, including control switch, unloading valve. and drain valve
Ability to manually operate and/or monitor in the control 071 A4.03 room: Valves and indications for sealing water to the gas compressor shaft Ability to manually operate and/or monitor in the control 071 A4.04 room: Radwaste liquid transfer pumps Ability to manually operate and/or monitor in the control 071 A4.05 room: Gas decay tanks, including valves, indicators, and sample line Ability to manually operate and/or monitor in the control 071 A4.07 room: Waste gas release flow meter Ability to manually operate and/or monitor in the control 071 A4.08 I
room: Nitrogen gas addition Ability to manually operate and/or monitor in the control 071 A4.10 room: WGDS sampling Ability to manually operate and/or monitor in the control 071 A4.11 room: WGDS startup and shutdown Ability to manually operate and/or monitor in the control 071 A4.12 room: Air purge of WGDS release radiation monitors Ability to manually operate and/or monitor in the control 071 A4.15 room: Procedure for putting the waste gas compressor inservice and for removing it from service Ability to manually operate and/or monitor in the control 071 A4.16 room: Waste gas decay tank shifts Ability to manually operate and/or monitor in the control 071 A4.17 room: Stopping transfer of radioactive liquids to WGDS decay tank Ability to manually operate and/or monitor in the control 071 A4.18 room: Operation of radwaste liquid transfer pumps Ability to manually operate and/or monitor in the control 071 A4.19 room: Bringing an empty WDGS decay tank on line and shutting down a full tank Ability to manually operate and/or monitor in the control 071 A4.20 room: Placing WGDS gas compressors in automatic operation Ability to manually operate and/or monitor in the control 071 A4.21 room: Valve lineup for returning gas to the eves holdup tank from a waste gas decay tank Ability to manually operate and/or monitor in the control 071 A4.22 room: Use of recycle gas header Ability to manually operate and/or monitor in the control 071 A4.23 room: Procedure for regulating pressure in eves holdup tanks Ability to manually operate and/or monitor in the control 071 A4.27 room: Opening and closing of the decay tank discharge control valve Ability to manually operate and/or monitor in the control 071 A4.28 room: Nitrogen additions to the decay tank, and knowledge of limits Ability to manually operate and/or monitor in the control 071 A4.29 room: Sampling oxygen, hydrogen and nitrogen concentrations in WDGS decay tank; knowledge of limits Ability to manually operate and/or monitor in the control 071 A4.30 room: Water drainage from the WGOS decay tanks Knowledge of design feature(s) and/or interlock(s) which 071 K4.03 provide for the following: Tank loop seals
i 073 K4.02 075 M.05 075 A2.04 075 A2.09 075 A2.10 075 A3.06 075 A3.07 075 A4.04 075 A4.06 075 A4.07 075 A4.08 075 A4.13 075 A4.14 075 A4.20 075 K1.06 075 K1.07 Knowledge of PRM system design feature(s} and/or interlocks which provide for the following: Letdown isolation on high-RCS activity Ability to predict and/or monitor changes in parameters (to prevent exceeding design limits) associated with operating the circulating water system controls including: Lube oil ature and pressure Ability to (a) predict the impacts of the following malfunctions or operations on the circulating water system; and (b) based on those predictions, use procedures to correct, control, or mitigate the consequences of those malfunctions or operations: Effects of extremes in ambient temperature on cooling tower operation Ability to (a) predict the impacts of the following malfunctions or operations on the circulating water system; and (b) based on those predictions, use procedures to correct, control, or mitigate the consequences of those malfunctions or operations: Operation of amertap ball collector flaps and screens in normal, backwash, and emergency backwash modes Ability to (a) predict the impacts of the following malfunctions or operations on the circulating water system; and (b) based on those predictions, use procedures to correct. control, or mitigate the consequences of those malfunctions or operations: Automatic startup mode of water box priming pumps relative to specified minimum vacuum Ability to monitor automatic operation of the circulating water system, including: Normal and abnormal collector flap differential pressures and setpoints Ability to monitor automatic operation of the circulating water system, including: Makeup flow control valve controller and indicator..
Ability to manually operate and/or monitor in the control room: Air eductor system Ability to manually operate and/or monitor in the control room: Water box vacuum priming isolation valves, control switches, and indicators Ability to manually operate and/or monitor in the control room: Vacuum priming tank/priming compressor controller Ability to manually operate and/or monitor in the control room: Gland seal water supply system Ability to manually operate and/or monitor in the control room: Cooling tower operations Ability to manually operate and/or monitor in the control room: Lube oil pumps for circulating water pump Ability to manually operate and/or monitor in the control room: Blowout preventers Knowledge of the physical connections and/or cause-effect relationships between the circulating water system and the following systems: Cooling towers Knowledge of the physical connections and/or cause-effect relationships between the circulating water system and the following systems: Recirculation spray system
075 K2.04 075 K3.05 075 K4.03 075 K4.04 075 K4.05 075 K4.07 075 K5.05 075 K5.06 076 A1.02 076 K1.03 076 K1.04 076 K1.06 076 K1.07 076 K1.09 076 K1.10 076 K1.21 Knowledge of bus power supplies to the following: Lube oil pumps Knowledge of the effect that a loss or malfunctions of the circulating water system will have on the following:
Recirculation spray system Knowledge of circulating water system design feature(s) and interlock(s) which provide for the following: Interlocks between circulating water system pumps and cooling tower pumps Knowledge of circulating water system design feature(s) and interlock(s) which provide for the following: Automatic IPickup of backup lube oil pumps (ac and dc)
Knowledge of circulating water system design feature(s) and interlock(s) which provide for the following: Operation of condenser tube cleaning system Knowledge of circulating water system design feature(s) and interlock(s) which provide for the following:
Relationship between water box inlet valve position and circulating pump logic (including switching time required to close waterbox inlet valve switch)
Knowledge of the operational implications of the following concepts as they apply to the circulating water system:
Principle of operation of the cooling towers Knowledge of the operational implications of the following concepts as they apply to the circulating water system:
Principle of cooling by evaporation Ability to predict and/or monitor changes in parameters (to prevent exceeding design limits) associated with operating the SWS controls including: Reactor and turbine building closed cooling water temperatures.
Knowledge of the physical connections and/or cause-effect relationships between the SWS and the following systems:
Relationship of SWS to raw water filtration (RWF) system and location of SWS supply pump to RWF system Knowledge of the physical connections and/or cause-effect relationships between the SWS and the following systems:
Relationship of domestic water to lube water for SWS Ipumps Knowledge of the physical connections and/or cause-effect relationships between the SWS and the following systems:
Switch gear room coolers Knowledge of the physical connections and/or cause-effect relationships between the SWS and the following systems:
Secondary closed cooling water Knowledge of the physical connections and/or cause-effect relationships between the SWS and the followrng systems:
Reactor buildinQ closed cooling water Knowledge of the physical connections and/or cause-effect relationships between the SWS and the following systems:
Turbine building closed cooling water Knowledge of the physical connections and/or cause-effect relationships between the SWS and the following systems:
Auxiliary backup SWS
076 K1.23 076 K1.25 076 K2.03 076 K2.04 076 K2.05 076 K3.02 076 K3.03 076 K3.04 076 K4.03 076 K4.04 076 K6.08 079 K1.02 079 K3.01 086 K1.01 086 K4.Uo 086 K5.01 103 A4.06 103 A4.07 103 A4.09 103 K1.03 Knowledge of the physical connections and/or cause-effect relationships between the SWS and the following systems:
Spent fuel pool makeup Knowledge of the physical connections and/or cause-effect relationships between the SWS and the following systems:
Heat sink pond makeup Knowledge of bus power supplies to the following:
Secondary closed cooling water Knowledge of bus power supplies to the following: Reactor ed cooling water Knowledge of bus power supplies to the following: Turbine building closed cooling water Knowledge of the effect that a loss or malfunction of the SWS will have on the following: Secondary closed cooling water Knowledge of the effect that a loss or malfunction of the SWS will have on the following: Reactor building closed cooling water Knowledge of the effect that a loss or malfunction of the SWS will have on the following: Turbine building closed cooling water Knowledge of SWS design feature(s) and/or interlock(s}
which provide for the following: Automatic opening features associated with SWS isolation valves to CCW heat exchanges Knowledge of SWS design feature(s) and/or interlock(s) which provide for the following: River intake water level recorders Knowledge of the effects of a loss or malfunction of the following will have on the SWS components: Cooling towers Knowledge of the physical connections and/or cause-effect relationships between the SAS and the following systems:
Cooling water to compressor Knowledge of the effect that a loss or malfunction of the SAS will have on the following: Ventilation system Knowledge of the physical connections and/or cause-effect relationships between the Fire Protection System and the
~
systems: High-pressure service water of design feature(s) and/or interlock(s) which I provide for the following: CO2 Knowledge of the operational implication of the following concepts as they apply to the Fire Protection System:
Effect of C02 on fire Ability to manually operate and/or monitor in the control room: Operation of the containment personnel airlock door Ability to manually operate and/or monitor in the control room: Use of the air lock rate test panel Ability to manually operate and/or monitor in the control room: Containment vacuum system Knowledge of the physical connections and/or cause-effect relationships between the containment system and the following systems: Shield building vent system
103 K1.06 103 K1.07 103 K4.01 Knowledge of the physical connections and/or cause-effect relationships between the containment system and the following systems: Subsurface drain system Knowledge of the physical connections and/or cause-effect relationships between the containment system and the following systems: Containment vacuum system Knowledge of containment system design feature(s) and/or interlock(s) which provide for the following: Vacuum breaker protection