| title = Transmittal of Initial Startup Report to the United States Nuclear Regulatory Commission

| author name = Simmons P

{{#Wiki_filter:Tennessee Valley Authority, Post Office Box 2000, Spring City, Tennessee 37381-2000 November 10, 2016 10 cFR 50.4 ATTN: Document Contro! Desk U.S. Nuclear Regulatory Commission Washington, D.C. 20555-0001 Watts Bar Nuclear Plant, Unit 2 Facility Operating License No. NPF-96 NRC Docket No.50-391 Subject           Watts Bar Nuclear Plant, Unit 2, Transmittal of lnitial Startup Report to the United States Nuclear Regulatory Gommission ln accordance with the requirements of the Watts Bar Nuclear (WBN) Plant, Dual Unit Updated Final Safety Analysis Report (UFSAR), Chapter 14.2.6, 'Test Records," the Tennessee Valley Authority (TVA) is submitting the lnitial Startup Report for WBN Unit 2.

The enclosure to this letter provides the Final Startup Report for WBN Unit 2. lnitial fuel load, pre-critical testing, initial criticality, and low power physics testing, and power ascension testing are discussed in separate sections of the report. The report details the test objectives, methodology, test results, and problems noted for each of the tests performed.

The test objectives and methodology were developed using the graded approach based on criteria provided in Regulatory Guide (RG) 1.68, "lnitial Test Programs for Water-Cooled Nuclear Power Plants,' Revision 2. RG 1.68 was further utilized for the selection of plant structures, systems, and components (SSCs), and design features to be included in the test program. During the power ascension testing program, power ascension tests, surveillance instructions, and other permanent plant tests and technical instructions were performed to demonstrate satisfactory operation of SSCs.

The report addresses test activities and the results of tests performed during the period November 2015 through October 2016. The following table provides a summary of the key WBN Unit 2 milestones and associated dates.

 

U.S. Nuclear Regulatory Commission Page 2 November 10, 2016 Watts Bar Nuclear Plant, Unat2 - Milestone Activities Milestone                                      Date WBN Unit 2 Facility Operating License, NPF-96                    October 22,2015 lnitial Fuel Load Commencement                                  December 4, 2015 lnitial Criticality                                                  May 23,2016 Test Plateau, 30o/o Reactor Thermal Power (RTP)                    June 16, 2016 Test Plateau,    5Ao/o RTP                                          July 16, 2016 Test Plateau, 75o/o RTP                                              July 29,2016 Test Plateau, 90o/o RTP                                          August 29,2016 Test Plateau,    lOOo/o RTP                                      October  6 ,2016 Commercial Operation                                              October 19, 2016 The WBN Plant Operations Review Committee has reviewed the report.

There are no new regulatory commitments made in this letter. Please address any questions regarding this submittal to Gordon P. Arent d (d'23) 365-2004.

@rM; Paul R. Simmons Site Vice President, Watts Bar Nuclear Plant

lnitial Startup Report to the Nuclear Regulatory Commission, Facility Operating License No. NPF-96, NRC Docket No. 50-391, Final Report November 2015 through October 2016 cc (Enclosure):

NRC RegionalAdministrator - Region ll NRC Senior Resident lnspector - Watts Bar Nuclear Plant NRC Project Manager - Watts Bar Nuclear Plant

 

WATTS BAR NUCLEAR PLAhIT UNIT 2 INTTIAL STARTUP REPORT TO THE UNITED STATES NUCLEAR REGULATORY COMMISSION APPROVAL SHEET Power Ascension Test Manager:              ! lo"a/:

TRG Meeting No.  /06 TRG Chairmani Plant Manager:

 

TENNESSEE VALLEY AUTHORITY WATTS BARNUCLEARPLANT UNIT 2 INITIAL STARTUP REPORT TO THE UNITED STATES NUCLEAR REGULATORY COMMISSION FACILITY OPERATING LICENSE NO. NPF'.96 NRC Docket No. 50-391 Final Report November 2015 through October 2016

 

TABLE OF CONTENTS SECTION                                                                    PAGE NUMBER LIST OF  FIGURES                                                          ............... iv LIST OF ACRONYMS..............                                             ............ vii 1.0  TNTRODUCTTON                                                          ...................1 2.0  POWER ASCENSTON TEST PROGRAM (PATP)           OVERVIEW ................3 2.1 Administration of the Program .............                                   .........3 2.2 lmplementation of the Pro9ram..............                                     .......6 2.3 Summary                                                           ....................8 3.0  WATTS BAR UNIT 2 STARTUP CHRONOLOGY...                                   ..............10 4.0  INITIAL FUEL LOAD                                                             ..........25 4.1 Overview and Summary of lnitial Core Loading                             ...........25 4.2 lnitial Core Loading Sequence (2-PAT-2.0)........                         .........26 4.3 Reactor System Sampling for Core Load (2-PAT-2.1)......... .........28 4.4 Response Check of Core Load Instrumentation After 8 Hour Delay in Fuel Movement (2-PAT-2.2)...............                                   .....31 4.5 Pre-Power Escalation NIS Calibration Data (2-PET-102)..............................33 4.6 lnitial Core Loading (2-PET-105)                                   ................35 5.0  PRECRITTCAL TEST!NG..........                                               ...........41 5.1 Post Core Loading Precritical Test Sequence (2-PAT-3.0)...............                                       .................41 5.2 Control Rod Drive Mechanism Timing and CERPI lnitial Calibration (2-PAT-3.1)...............                                       .................4e 5.3 Pressurizer Spray Capability and Continuous Spray Flow Setting (2-PAT-3.2)...............                                       .................56 5.4 Rod Control and Rod Position lndication (CERPI) (2-PAT-3.4).....................61 5.5 Reactor Coolant Flow Coastdown (2-PAT-3.7)............... ..............69 5.6 Rod Drop Time Measurement and Stationary Gripper Release Timing (2-PAT-3.8)...............                                       .................71 a

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TABLE OF CONTENTS (continued)

SECTION                                                                          PAGE NUMBER 5.0 PRECRITICALTESTING(continued) 5.7   Reactor Trip System     (2-PAT-3.10)                                     .............75 5.8   Adjustment of Steam Flow Transmitters at Minimal Flow (2-PAT-3.11).............                                             .................7e 5.9   Control Rod Drive Mechanism Timing       (2-PET-106).............             .........81 6.0  INITIAL CRITICALITY AND LOW POWER PHYSICS               TESTING                   ...........84 6.1   lnitial Criticality and Low Power Test Sequence (2-PAT-4.0).........................84 6.2   Reactivity Computer (ADRC) (2-PET-103)       ............                       ......86 6.3   lnitial Criticality and Low Power Physics Testing (2-PET-201).......................88 7.0  POWER ASCENSTON TESTING           .............                               .............95 7.1 Test Sequence for 30% Plateau (2-PAT-5.0).........                                 ......95 7.1.1 Dynamic Automatic Steam Dump Control (2-PAT-5.1).....................99 7.1.2 Automatic Steam Generator Level Control Transients at Low Power   (2-PAT-5.3)............                                   ...108 7.1.3     Calibration of Steam and Feedwater Flow lnstruments at 30% Power (2-PAT-5.4)     ............                 ...................116 7.2 Test Sequence for 50% Plateau (2-PAT-6.0).........                                 ....120 7.2.1     Turbine Generator Trip with Coincident Loss of Offsite Power Test    (2-PAT-5.2).......                             ...................124 7.2.2     Automatic Reactor Control System (2-PAT-6.1)............... ..............129 7.2.3     Automatic Steam Generator Level Control Transients at 50% Power (2-PAT-6.2)     ...............                   ............141 7.2.4     Calibration of Steam and Feedwater Flow lnstruments at 50% Power (2-PAT-6.3)     ...............                   ............146 7.3 Test Sequence for 75o/o Plateau (2-PAT-7.0).........                               ....149 7.3.1     Calibration of Steam and Feedwater Flow lnstruments at75o/o Power (2-PAT-7.1)   ...............                   ............152 aa l- l-

 

TABLE OF CONTENTS (continued)

SECTION                                                                      PAGE NUMBER 7.0 POWER ASCENSION TESTING (continued) 7.4 Test Sequence for 100% Plateau     (2-PAT-8.0)...............       .............155 7.4.1 Load Swing Test (2-PAT-1 .2)............                         ...........159 7.4.2 Large Load Reduction Test (2-PAT-1.3)............. ...........162 7.4.3 Pipe Vibration Monitoring (2-PAT-1.4)......... ..................177 7.4.4 LoosePartsMonitoringSystem(2-PAT-1.5)............ .....182 7.4.5 Startup Adjustments of Reactor Control System (2-PAT-1.6).........185 7.4.6 Operational Alignment of Process Temperature lnstrumentation (2-PAT-1.7).........                       ................189 7.4.7 Thermal Expansion of Piping Systems (2-PAT-1.8).......................196 7.4.8 Automatic Steam Generator Level Control (2-PAT-1.9) ............ .....201 7.4.9 lntegrated Computer System (lCS) (2-PAT-1.10)...........................205 7.4.10 RVLlSPerformanceTest(2-PAT-1.11)..........                   ...............208 7.4.11 Common Q Post Accident Monitoring System (2-PAT-1.12)..........212 7.4.12 RCS Flow Measurement       (2-PAT-3.3).........       ...................215 7.4.13 Calibration of Steam and Feedwater Flow lnstruments at 100 % Power (2-PAT-8.4)     ...............                   .........217 7.4.14 Shutdown From Outside the Main Control Room (2-PAT-8.5)             .......221 7.4.15 Plant Trip Evaluation for Equivalency of Test Performance of 2-PAT-8.6, Plant Trip From 100o/o Power (Turbine Trip).................226 7.4.16 Core Power Distribution Factors (2-PET-301)............. ...................248 7.4.17 Operational Alignment of NIS (2-PET-304)     ............           .......253 7.4.18 Radiation Baseline Surveys (RCI-159)                               .........255 l-rl-aaa

 

LIST OF FIGURES FIGURE                                                        PAGE NUMBER 2.0-1    WBN PowerAscension Test Program Schedule  Overview    ..................9 4.6-1    U2Cl Core Load    Sequence                                ............39 4.6-2    Unit 2 Core Load ICCR                               ...................40 5.3-1    Pressurizer Spray Response                                 ...........60 6.3-1    ICRR vs Primary Water (N31, N32) ........                     .........94 7.1 .2-1 SG #2 FW Flow Oscillation                                 ...........115 7.2.2-1  RCS Auctioneered   T"* vs T6s Steady-State Operatioh..............                             ...132 7.2.2-2  RCS Auctioneered T"* vs T,"g lncreasing T"* Transient ..........                             ....133 7.2.2-3  RCS Auctioneered Trrs vs Tpg Decreasing T"r, Transient..........                               ...134 7.2.2-4  Rod Speed and Direction Demand lncreasing T"rs Transient ..........                             ....135 7.2.2-5  Rod Speed and Direction Demand Decreasing T"r, Transient..........                               ...136 7.2.2-6  Pressurizer Pressure lncreasing T"r, Transient ..........                             ....137 7.2.2-7  Pressurizer Pressure Decreasing T"r, Transient..........                               ...138 7.2.2-8  Pressurizer Level and Level Setpoint lncreasing T"rs Transient ..........                             ....139 7.2.2-9  Pressurizer Leve! and Level Setpoint Decreasing T"", Transient..........                               ...140 l-v a

 

LIST OF FIGURES (continued)

FIGURE                                                     PAGE NUMBER 7.4.2-1   Generator Output vs Time (Large Load Reduction)........                     .........105 7.4.2-2   NIS Power vs Time (Large Load Reduction)........                     .........1G0 7.4.2-3   Pressurizer Pressure vs Time (Large Load   Reduction)........                     .........1G7 7.4.24 Pressurizer     Level vs Time (Large Load   Reduction)........                     .........168 7.4.2-5   Control Bank D Position vs Time (Large Load   Reduction)........                     .........109 7.4.2-O   Tay6 vs Time (Large Load   Reduction)........                     .........170 7.4.2-T   Steam Dump Signal vs Time (Large Load Reduction)........                       .........171 7.4.2-8   Feedwater Pressure vs Time (Large Load   Reduction)........                     .........172 172 7.4.2-9   Steam Generator 1 Level vs Time (Large Load   Reduction)........                     .........173 7.4.2-10 Steam Generator 2 Level vs Time (Large Load   Reduction)........                     .........174 7.4.2-11 Steam Generator 3 Level vs Time (Large Load   Reduction)........                     .........175 7.4.2-12 Steam Generator 4 Level vs Time (Large Load   Reduction)........                     .........170 7.4.14-'l Main Control Room Abandonment 30 Minute Stability....                                   ....224 7.4.14-2 Main Control Room Abandonment Cooldown                                                   ...225 7.4.15-1 Representative RCCA Position vs Time (100% Trip) ........                               ..........232 7.4.15-2 Main Turbine Speed vs Time (100Yo Trip)........                               ..........233

 

FIGURE                                                                                  PAGE NUMBER 7 .4.15-3    Safety lnjection Alarm vs Time (100Yo  Trip)........                                                       ..........234 7.4.15-4 Steam Generator Safety Valve Position Loops 1 &2 vs Time (100%  Trip)........                                                       ..........29s 7 .4.1 5-5 Steam Generator Safety Valve Position Loops 3 & 4 vs Time (100Yo  Trip)........                                                       ..........236 7 .4.15-6    Pressurizer Safety Valve Outlet Temperature vs Time (100%  Trip)........                                                       ..........237 7.4.15-7    NIS Power vs Time (100%   Trip)........                                                       ..........238 7 .4.15-g    Hot Leg RTD Response vs Time (100o/o Trip)........                                                       ..........299 7 .4.1 5-g  Steam Generator Levels vs Time (100%   Trip)........                                                       ..........240 7 .4.1 5-1 0  Pressurizer Pressure vs Time (1)

(1 00% Trip).. .. . . . ... ...... t .. .. .. ...... .. . .                         241 7.4.15-11      Pressurizer Pressure vs Time (2)

(100%   Trip).........                                                       .......242 7.4.15-12      Pressurizer Level vs Time (100o/o Trip)........                                                         .......243 7 .4.1 5-1 3  Pressurizer Level Controller Output vs Time (100Yo Trip).........                                                       .......244 7.4.15-14      RQQ  Aryrage Temperature (Auctioneered) vs Time (100yo Trip).........                                                       .......245 7 .4.15-15 9lCqT Pqqp Demand and T"o vs Time (100o/o Trip).........                                                       .......246 7 .4.15-16    Main Feedwater Pump Flows and                               T"* vs Time (100Yo Trip).........                                                       .......247 vl-a

 

LIST OF ACRONYMS ADRC  Advanced Digital Reactivity Computer AFW    Auxiliary Feedwater AOI   Abnormal Operating lnstruction ARO   All Rods Out ASME  American Society of Mechanical Engineers AUX   Auxiliary BOL   Beginning of Life BYA    Bypass A (Reactor Trip Breaker A)

BYB   Bypass B (Reactor Trip Breaker B)

CBA   Control Bank A CBB    Control Bank B CBC    Control Bank C CBD    Control Bank D CERPI  Computer Enhanced Rod Position lndication CLA   Cold Leg Accumulator COTS   Channel Operational Tests CPS    Counts Per Second CR    Condition Report CRDM  Control Rod Drive Mechanism CTL   ChronologicalTest Log CV    Concurrent Verification CVCS   Chemical and Volume Control System DAS    Data Acquisition System DCN    Design Change Notice DCS    Distributed Contro! System DRWM  Digital Rod Worth Measurement eNuPOP Electronic Nuclear Parameters and Operations Package FATF  FuelAssembly Transfer Form FCV    Flow ControlValve FHI   Fuel Handling lnstruction F!     Flow lndicator FIC   Flow lndicating Controller FW     Feedwater GO     General Operating Instruction HFP   Hot Full Power HS    Hand Switch HVAC  Heating Ventilation and Air Conditioning HZP   Hot Zero Power ICRR  lnverse Count Rate Ratio ICS    lntegrated Computer System vt1 aa

 

LIST OF ACRONYMS (continued)

INPO lnstitute of Nuclear Power Operations IR   lntermediate Range ITC  lsothermalTemperature Coefficient lV   lndependent Verification KBH   Thousand Pounds Per Hour LC    Level Controller LCP   Loop Calculation Processor LCV   Level ControlValve LPMS Loose Parts Monitoring System LPPT  Low Power Physics Test LVDT  Linear Variable Differential Transformer M&TE Measuring and Test Equipment MCD   Maximum Channel Deviation MCR   Main Control Room MED  Maximum Expected Deviation MFP   Main Feedwater Pump MFPT  Main Feedwater Pump Turbine MFW  Main Feedwater MMI   Man Machine lnterface MPPH Million Pounds Per Hour MSIV  Main Steam lsolation Valve MSV  Main Steam Valve MTC  Moderator Temperature Coefficient Nl   Nuclear lnstrumentation NIS   Nuclear lnstrumentation System NOB  Nuclear Operating Book NOTP  Normal Operating Temperature & Pressure NPG  Nuclear Power Group NRC  Nuclear Regulatory Commission NSSS Nuclear Steam Supply System NuPOP Nuclear Parameters and Operations Package OPC  Overspeed Protection Controller OPDP NPG Standard Department Procedure (Operations)

OPSP Over Power Setpoint OTDT  Overtemperature Delta Temperature OTSP Over Temperature Setpoint PAT  Power Ascension Test PATP  Power Ascension Test Program PDMS  Power Distribution Monitoring System PET  Power Escalation Test PIC  Pressure lndicating Controller vl- l- l-aaa

 

LIST OF ACRONYMS (continued)

PID  Point Identification PLS  Precautions, Limitations and Setpoints PMT  Post Maintenance Test PORC  Plant Operations Review Committee PR    Power Range psi  Pounds per square inch psia  Pounds per square inch absolute psid  Pounds per square inch differential psig  Pounds per square inch gauge PTI  Preoperational Test I nstruction PZR  Pressurizer QPTR  Quadrant Power Tilt Ratio RBSS  Rod Bank Select Switch RCCA  Rod Cluster Control Assembly RCI  Radiological Control I nstruction RCP  Reactor Coolant Pump RCS  Reactor Coolant System RDTC  Rod Drop Test Computer Reg  Regulating RHR  Residual Heat Removal RPI  Rod Position lndicator RSA  Redundant Sensor Algorithm RT    Reactor Trip RTA  Reactor Trip Breaker A RTB  Reactor Trip Breaker B RTD  Resistance Tem perature Detector RTP  Rated Thermal Power RVLIS Reactor Vessel Level lnstrumentation System RWP  Radiological Work Permit RWST  Refueling Water Storage Tank SAR  Safety Analysis Report SBA  Shutdown Bank A SBB  Shutdown Bank B SBC  Shutdown Bank C SBD  Shutdown Bank D SE    Site Engineering SEQ  Sequence SFP  Spent Fuel Pool SG    Steam Generator SGBD  Steam Generator Blowdown SI    Surveillance I nstruction IX a

 

LIST OF ACRONYMS (continued)

SOI   System Operating lnstruction SR    Source Range SRF  Statistical Reliability Factor SSP  Site Standard Practice SSPS  Solid State Protection System SWIF  Seal Water lnjection Filter TE    Temperature Element Tl    Technical lnstruction TR    Temperature Recorder TRG  Test Review Group TRI  Technical Requirements lnstruction TTD  Time Trip Delay TVA  Tennessee Valley Authority UC    Urgent Change UFSAR Updated Final Safety Analysis Report USNRC United States Nuclear Regulatory Commission VCT  Volume Control Tank WBN  Watts Bar Nuclear WO    Work Order

The lnitial Startup Report for the Watts Bar Unit 2 nuclear plant discusses the results of testing performed from initial core load through full power operation.

This report address each of the power ascension tests identified in Chapter 14 of the WBN Unit 2 UFSAR and other license commitments. The report includes a description of the measured values of the operating conditions or characteristics obtained during the testing program and a comparison of these values with design predictions and specifications. Any corrective actions that were required to obtain satisfactory operation are also described.

WBN Unit 2 UFSAR Chapter 14.2.6, Test Records, requires the Startup Report be submitted within:

(1) 90 days following completion of the Startup Test Program, (2) 90 days following resumption or commencement of commercial power operation, or (3) 9 months following initial criticality, whichever is earliest.

lf the Startup Report does not cover all three events (i.e., initial criticality, completion of Startup Test Program, and resumption or commencement of commercial power operation), supplementary reports shall be submitted at least every 3 months until allthree events have been completed.

Item (1) is being satisfied since the Power Ascension Test Program was completed on October 6, 2016.

WBN Unit 2 Facility Operating License No. NPF-96 was issued on October 22, 2015. lnitial Fuel load commenced with movement of the first fuel assembly at 20:49 on December 4, 2015. Core loading was completed at 02:10 on December 8, 2015. lnitial criticality was achieved at 02:16 on May 23,2016. Further testing was successfully completed at the following plateaus:

Test Plateou, % RTP                      Date Completed 30                              June 16, 2016 50                              July 16, 2016 75                              July 29,2016 90                            August 29,2016 100                            October  6 ,2016 lnitial Fuel load, precritical testing, initial criticality and low power physics testing, and power ascension testing are discussed in separate sections of the report.

The report details the test objectives, methodology, test results, and problems noted for each of the tests performed.

Acceptance Criteria is defined as safety related performance parameters defined in the Design Output, vendor documents, TVA or vendor drawings, NRC commitments, other licensing and design documents, and so forth, that must be exhibited during the performance of a PAT or PET. Failure to meet an acceptance criterion is considered to be a safety related issue.

A 10CFR50.59 Evaluation per NPG-SPP-09.4, 10 CFR 50.59 Evaluations of Changes, Tests, and Experiments or a Technical Evaluation per NPG-SPP-09.3, Plant Modifications and Engineering Change Control, may be required and testing may be stopped. The subsequent course of action will be determined by the nature of the discrepancy and applicable Technical Specifications. Failure to meet Acceptance Criteria will be documented in a Condition Report (CR).

Review Criteria encompasses other performance parameters defined in the UFSAR, design criteria, vendor documents, drawings (TVA or vendor), other licensing, design, setpoint and operational documents that are expected to be exhibited during performance of a PAT or PET. These criteria should be viewed as a guide to possible measurement or design errors. Failure to meet these criteria do not by themselves constitute problems. While prudent measures should be taken to resolve any conflict between measurements and predictions, failure of these criteria do not require 10CFR50.59 Evaluations, per NPG-SPP-09.4, and do not require testing or power ascension to be stopped for resolution.

 

2.0 POWER ASCENSTON TEST PROGRAM (pATp) OVERVTEW The PATP was developed from testing described in Chapter 14 of the WBN Unit 2 UFSAR and requirements specified in Regulatory Guide 1.68, Revision 2, "lnitial Test Programs for Water-Cooled Nuclear Power Plants". Testing of the NSSS followed Westinghouse test methodology.

2.1 Administration of the Program The Site Vice President had the overall responsibility for the PATP.

Overall management of the PATP was directed by the Plant Manager who was responsible for:

o   Development and implementation of the PATP to ensure the PATP was conducted in a safe and efficient manner while complying with license provisions and other commitments.

        . Establishing the Power Ascension Testing Organization.

o   Advising senior management on PATP activities.

o   Establishing a Technical Review Group (TRG) as a subcommittee of the PORC to review PATP activities.

o   Providing final approval of Power Ascension Tests (PATs) and selected other procedures.

o   Ensuring the PATP was conducted in accordance with applicable WBN Administrative Procedures.

o   Providing approvalto proceed to the next PATP test plateau.

o   Providing final approval of all each test package and the Startup Report.

The Power Ascension Test Manager was responsible for:

o   Notifoing the plant manager of major problems and of the completion of each major test phase (i.e., test sequence) of the program.

        . Ensuring the PATs and the PETs were available for NRC review a minimum of 60 days before the scheduled fuel load date.

o   Ensuring the technicaljustification and schedule, including power level for completion of delaying preoperational tests, were provided to the NRC staff prior to fuel Ioad.

 

2.1 Administration of the Program (continued) o Ensuring the requirements of TVA-SPP-30.010, lnitial Synchronization of TVA Generating Assets to TVA's Transmission System, were met.

      . Developing and implementing plans and schedules for the PATP.

      . Ensuring testing activities, including planning and scheduling, resulted in safe plant operations and that were not dependent on the performance of untested systems.

      . Coordinating and directing overall PATP testing and related activities and requirements with appropriate support groups.

      . Supervising test personnel assigned to the power ascension testing group.

o Assigning responsibilities to organizations for specific testing requirements.

o Participating in the review activities of the TRG, and acting as Chairman of the TRG.

o Ensuring the test procedures were reviewed by the TRG.

o Ensuring the Startup Report was reviewed by the TRG.

o Ensuring additional startup Reports were prepared, reviewed, approved and transmitted to the NRC as needed.

o Ensuring the post-performance test results (i.e., test packages) were reviewed by TRG.

o Ensuring test directors for the PATP were qualified, and met the minimum qualifications of ltem 1 and either ltem 2 or ltem 3 below and ensuring other required individuals (e.9. lndependent Verifiers (lV) and Concurrent Verifiers (CV) were qualified to perform the tasks assigned:

: 1. Knowledgeable of the test program administration, the system design and operational requirements, and expected plant operational characteristics during the test, and Trained as test coordinators in accordance with NPG-SPP-06.9.1, Conduct of Testing.

 

2.1 Administration of the Program (continued)

: 2. Possessed a bachelor degree in engineering or physical science, and Had two years experience in power plant testing or operation.

Included in the two years was one year nuclear power plant testing, operating or training on a nuclear facility.

: 3. Possessed a high school diploma or equivalent, and Had five years experience in power plant testing. lncluded in the five years were two years of nuclear power plant experience.

Credit for up to two years of related technical experience could be substituted for experience on a one-for-one basis.

Technical and administrative oversight of the PATP was performed by TRG which was composed of one representative, or their alternates, from each of the following organizations:

o Plant Operations o Reactor Engineering o Site Engineering

        . Corporate Nuclear Fuels o  Power Ascension Testing o  Westinghouse TRG was charged with reviewing PATP testing activities for technical adequacy and affecUimpact on nuclear safety, and advising PORC and the plant manager on the disposition of those items reviewed. The responsibilities of TRG included final review and recommendation of approval of al! PATP test procedures, revisions, and test results.

Following completion of testing at each major test sequence of the PATP, test results were reviewed by TRG to ensure required tests had been performed.

TRG also ensured Acceptance Criteria were satisfied; test deficiencies had proper dispositions, appropriate retesting had been completed, and test results had been reviewed by appropriate designated personnel prior to proceeding to the next major test sequence. This review ensured that all required systems were operating properly and that testing for the next major test sequence could be conducted in a safe and efficient manner.

 

2.2 Implementation of the Program The WBN PATP utilized information gained from operating and testing experience at other nuclear plants. This information was used in the development of the PATP test procedures and schedules and to alert personnel to potential problem areas.

Test procedures were developed utilizing information obtained from Operating Experience (OE) database. The TVA Operating Experience Program identifies and evaluates experience gained from other TVA nuclear plants, INPO, NRC, equipment suppliers, and from other utilities. Significant operational experience and events were reviewed and integrated into appropriate PATP test procedures to ensure nuclear safety and reliability. To the extent practical, simulator-based training and trial use of the PATP test procedures were performed on the WBN simulator to familiarize personnel with systems and plant operation and to assure technical adequacy of the procedures under simulated plant conditions prior to field use during power operation.

The testing program was conducted by qualified personnel using approved plant administrative, test, and operating procedures. The plant was taken from core load to full power in a highly controlled, conservative, and documented manner which demonstrated, where practical:

The plant is ready to operate in a manner which will not endanger the health and safety of the public.

The plant has been properly constructed, and plant performance is satisfactory in terms of established design criteria.

The plant meets licensing requirements and provides assurance of plant reliability for operation.

o   The plant is capable of withstanding anticipated transients and postulated accidents.

 

The description of the testing is documented in the section (plateau) in which it was completed.

2.0     Test Methods Pre-requisite actions started on 11119/15, prior to entry into Mode 6 to establish prerequisite conditions in support of commencement of initial core loading. The test continued through verification of core loading and was field complete on 1218115, prior to the reassembly of the reactor vessel in preparation for Mode 5 entry.

The major pre-requisites included the following:

o Verification all Preoperational Test completed and test results approved or technicaljustifications for delaying tests unti! after fuel load were approved by the Plant Manager o Verification 2-PET-102,Pre-Power Escalation NIS Calibration Data, was successfully completed to the extent necessary o RCI-159 Radiation Baseline Surveys commenced for the pre-fuel load survey 26

 

4.2 lnitial Core Loading Sequence (2-PAT-2.0) (continued) o   2-PAT-2.1, Reactor System Sampling for Core Load, started o  Visual lnspection of the reactor vessel core support plate in accordance with 2-PET-105, lnitial Core Loading completed Testing included the following:

o   2-PAT-2.1, Reactor System Sampling for Core Load, completed on 1214115 with all criteria met.

o   2-PAT-2.2, Response Check of Core Load lnstrumentation After 8 Hour Delay in Fuel Movement, completed on 1215115 with all criteria met o  2-PET-102, Pre-Power Escalation NIS Calibration Data, applicable sections completed with all criteria met o  2-PET-105, lnitial Core Loading completed on 1218115 with all criteria met.

o   RCI-159, Radiation Baseline Surveys, completed on 1213115.

There was no Acceptance or Review Criteria associated with this procedure.

3.0     Test Results AllAcceptance/Review Criteria were contained within the tests sequenced by this test.

4.0     Problems Problems encountered are addressed in the following discussions of each test sequenced by 2-PAf-2.0.

21

 

4.3 Reactor System Sampling for Gore Load (2-PAT-2.11 This test was performed as part of test sequence 2-PAT-2.0, lnitial Core Loading.

Testing was started on 11119115 and field work completed on 1214115.

1.0     Test Obiectives The objectives of this test were to:

1.1   Verify the boron concentrations in the Reactor Coolant System (RCS), Residual Heat Removal (RHR) system and other directly connected portions of auxiliary systems are uniformly borated to prevent inadvertent dilution during core loading.

1.2   Verify un-borated water sources are configured to prevent inadvertent dilution during core loading.

1.3   Satisfy the requirements of UFSAR Table 14.2-2, Sheet 4, Reactor System Sampling For Core Loading Test Summary.

2.0   Test Methods The preliminary actions of 2-PAT-2.1 researched logs and procedurally driven Unit 2 activities that were completed and that were associated with the preparations of the unit 2 water systems for entering Mode 6. The research started with ensuring the RWST was borated to (3100 to 3300) ppm. Actual recorded samples of the RWST were 3326 ppm on 0910712015 and 3224 ppm on 1'112112015. This confirms a correctly borated RWST. This RWST water was subsequently used to fill the RCS and partially fill the Refueling Cana! and Cavity. Later boron sample results showed Refueling Canal at 3290 ppm and Refueling Cavity at3281 ppm.

Following the proper boration of the RWST and water transfer to the RCS, unit activities were verified that circulated water through:

Both RHR A-A and B-B pump miniflows Both RHR pumps RHR to CVCS Letdown Both Charging pumps Both Containment Spray pumps (re-circulated borated RWST)

Refueling Water Purification Pump B Refueling Water Purification Pump A was found to be tagged with a Caution Order 0-CO-2015-0048 stating that the pump has high vibration.

WO 116318322 was previously written to address this issue. The volume of potentially diluted water was conservatively calculated to be 13 gals.

This small volume did not pose any risk to challenging any criteria listed in this PAT.

28

 

4.3 Reactor System Sampling for Core Load (2-PAT-2.1) (continued)

The Boron lnjection Tank (BlT) was verified to have been borated and mixed via the performance of 2-5l-63-905, Boron lnjection Check Valve Flow During Refueling Outages.

It was verified that both trains of Safety lnjection were circulated during the performance of 2-Sl-63-906, Safety !njection Check Valve Full Flow Testing During Refueling Outages, on 1112512015.

All4 Cold Leg Accumulators were verified by sample to be corectly borated with the lowest reading 3175 ppm and the highest reading 3206 ppm.

The water in the Holdup Tank B (HUT B) was recirculated and sampled for boron concentration on 11104115 and found to be 3204 ppm boron; this water was used to fill the Fuel Transfer Canal. The Spent Fuel Pool (SFp) was sampled for boron concentration on 11123115 and found to be 3261 ppm boron. Boric Acid Tanks B and C were sampled for boron concentration on 11121115 and found to be 6919 and 6808 ppm boron respectively.

Problems encountered while running 2-Sl-63-905 and 2-5!-63-906 resulted in a partial drain down moving water back to the RWST. This same water was again used to fill the Refueling Cavity and Chemistry re-performed 2-Sl-78-1, Reactor Coolant System and Refueling Canal Refueling Operations Boron Determination, to document compliance with the refueling boron concentration requirements.

Watts Bar Unit 2 systems connected to the Reactor Coolant System (RCS) were adequately borated and mixed to prevent a dilution event in support of the initial core loading operations.

2-PAT-2.1, Reactor System Sampling For Core Load, supported this conclusion from research of the chemistry and operation logs.

configuration contro! measures were in place to ensure that the RCS and connected systems remain adequately borated for support of the initial core loading operations. The Unit 2 Refueling Water Storage Tank (RWST) was at approximately 16.9% and based on calculations of recent makeup to the RWST it was determined that the tank was adequately borated. Technical Specifications required Operations to validate compliance with the RWST boron concentration and level prior to Mode 6.

Technical Specifications required Watts Bar Unit 2 to maintain Mode 6 surveillance instructions in frequency. Therefore, no additional sampling or mixing was required for 2-PAT-2.1.

29

 

4.3 Reactor System Sampling for Gore Load (2-PAT-2.1) (continued) 3.0 Test Results AllAcceptance/Review Criteria were met or resolved as delineated below.

Acceotance Criteria 3.1     Boron Concentration of samples meet requirements of the Technical Specifications.

3.1.1 The RCS Boron concentration     is greater than or equal to 3100 ppm and less than or equal to 3300 ppm.

The RCS Boron as measured in the RHR TRAIN B system was 3284 ppm.

3.1.2 The boron concentration final samples obtained from the designated sample points identified are uniformly borated between 3100 ppm and 3300 ppm.

The boron concentration for sample points met the requirements.

3.1.3 The boron concentration of samples obtained from the Boric Acid Tanks (BAT B and BAT C) are within the limits ot 6120

                        < Ce < 6990 ppm.

Boron concentrations were 6919 ppm in BAT B and 6808 ppm in BAT C.

3.1.4 Un-borated water sources are configured to prevent inadvertent dilution during core loading.

2-Sl-62-1, Uncontrolled Boron Dilution Paths, was satisfactorily completed for Mode 6.

Review Criteria 3.2     The boron concentrations for the Reactor Coolant System (RCS) and directly connected portions of the auxiliary systems are greater than or equal to 3100 ppm and less than or equal to 3300 ppm.

Boron concentrations for the RCS and directly connected portions of the auxiliary systems met the requirement.

4.0 Problems There were no significant problems encountered during the performance of this test.

30

 

4.4 Response Check of Core Load lnstrumentation After 8 Hour Delay in Fuel Movement (2-P AT -2.21 This test was performed as part of test sequence 2-PAT-2.0, lnitial Core Loading Sequence. Testing was started and completed on 1215115.

1.0   Test Obiectives The objective of this test was to:

1.1     Verify response of the Source Range Channels prior to resumption of fuel loading following a delay of eight (8) hours or more.

2.0   Test Methods Three methods of testing were available for use:

2.1     Statistical Evaluation Method using the Scaler Timer 2.2     Statistical Evaluation Method using the Source Range Count Rate indications.

2.3     Response Check of Core Load lnstrumentation Using Primary Source Bearing Fuel Assembly Movement.

The Statistical Evaluation Method using the Scaler Timer provided the verification of the Acceptance Criteria for resumption of fuel movement.

3.0   Test Results AllAcceptance/Review Criteria were met or resolved as delineated below.

Acceotance Criteria 3.1     The Source Range instrumentation for both channel N-31 and N-32 were evaluated and determined to be acceptable for continuation of fuel loading by meeting at least one Review Criteria.

Review Criteria 3.2, below 31

 

4.4 Response Check of Gore Load Instrumentation After 8 Hour Delay in Fuel Movement (2-P AT -2.2) (continued)

Review Criteria 3.2   Statistical Evaluation Method using the Scaler Timer:

Statistical Reliability Factor (SRF) for Source Range Channels shall be > 0.5 and 3 1.4.

Results indicated the SRF for Source Range Channel N-31 was 1.2395 and SRF for Source Range Channel N-32 was 0.8609.

3.3   Statistical Evaluation Method using the Source Range Count Rate indications:

: 1.     The Student F Distribution Test shall be satisfied by having Fexp s 3.179.

: 2.     The Student T Distribution Test shall be satisfied by having Texp s 2.101.

This method was originally chosen, however, problems were encountered. See Problems below.

3.4   Neutron instrumentation (Source Range Channels N-31 and N-32) are operational and indicates a positive (negative) change in count rate as the neutron level detected from a source is increased (decreased).

This method was not used.

4.0   Problems t1l  No CR initiated:

Section 6.2, Statistical Evaluation Using Source Range Count Rate lndications, method was attempted four (4) times with unsuccessful results. Based on only three assemblies loaded at the time of performance, low counts appeared to cause data scatter which was observed in monitored count rates. This failure of Section 6.2 method resulted in the transition to Section 6.1, Statistical Evaluation Method using the Scaler-Timer. Section 6.1 method was acceptable. No CR was initiated since this was a potential scenario and the test provided alternative methods.

32

 

4.5 Pre-Power Escalation NIS Calibration Data (2-PET-1021 This test was performed as part of the test sequence 2-PAT-2.0, lnitial Core Loading Sequence. The performance of 2-PET-102 was conducted via WO 116884907. The WO started 0812512015 and was complete on 04112116with calibration of all Power Range and lntermediate Range detectors.

1.0     Test Obiectives The objectives of this test were to:

1.1     Provide Nuclear lnstrumentation System (NlS) Power Range (PR) and lntermediate Range (lR) excore detector calibration data.

1.2     lnitiate an adjustment of the NIS before startup for a new fuel cycle.

Note: The calculation methodology in 2-PET-102 applied to the changes expected to occur due to a refueling outage. This procedure accommodated the calibrations to be performed for Cycle 1.

2.0   Test Methods The normal method for determining calibration data after fuel reload and prior to startup is to ratio the sum of selected weighted assembly predicted powers from the Beginning of Life (BOL) of the previous fuel cycle (Unit 1 Cycle 1 was used as the reference condition) to the BOL of the upcoming cycle. This ensures a ratio based upon similar BOL core conditions including the neutron energy spectrum and a nearly cosine axial flux shape. This provides the most accurate excore Axial Offset indications for the power range channels. This same methodology results in the most accurate power indications for the intermediate range channels.

This same methodology was used to predict the lntermediate Range and Power Range calibration setpoints for the Unit 2 Cyclel startup, except that Unit 1 Cycle 1 is used as the reference condition. ln this case, average composite values for the channels were used.

3.0   Test Results All Acceptance/Review Criteria were met or resolved as delineated below.

33

 

4.5 Pre-Power Escalation NIS Calibration Data (2-PET-102) (continued)

Acceptance Criteria 3.1     Power Range Channel calibrations have been completed.

The Power Range channel calibrations were completed via:

o WO 115898162 o WO 115898208 o WO 115898252 o WO 115899187 3.2     lntermediate Range Channel predicted full power adjustments have been completed.

lntermediate Range Channel predicted full power adjustments were performed. lR Gain Adjustment potentiometers were set to the values calculated in the PET via steps in Section 7.0 of the PET.

3.3     lntermediate Range Channel OperationalTests (COTs) have been completed.

The lntermediate Range channel COTs were completed via:

o WO 117499181 o WO 117499184 Review Criteria None 4.0   Problems There were no significant problems encountered during the performance of this test.

34

 

4.6 lnitia! Core Loading (2-PET-1 05)

This test was performed as part of test sequence 2-PAT-2.0, lnitial Core Loading Sequence. 2-PET-105 testing via WO 117370408 started on 1112312015 with the verification of Unit 2fuel assemblies and component inserts in the Spent Fuel Pool and completed on 1210812015 with the completion of fuel load and core load verification.

1.0     Test Obiectives The objectives of this test were to:

1.1     ldentify the activities and requirements for fuel loading which ensure fuel loading is conducted in a cautious and controlled manner:

1.1.1 Specify the sequence for loading fuel assemblies into the reactor vessel such that the final core configuration is consistent with that specified in the NuPOP for current fuel cycle. See Figure 4.6-1, U2C1 Core Load Sequence.

1.1.2 Specify the fuel assembly identification number and type of insert for each core location.

1.1.3 Establish the requirements for periodic and continuous neutron monitoring during each step of the core loading process.

1.1.4 Prescribe the steps necessary for obtaining and evaluating neutron monitoring data during core loading.

1.1.5 ldentify the neutron monitoring channels to be used during each step of the core loading sequence to ensure subcritical conditions are maintained.

1.2     Satisfied the requirements of UFSAR Table 14.2-2, Sheet 3, lnitial Fuel Loading Test Summary.

2.0     Test Methods Only data from "responding" detectors identified by the data package was used in evaluating the safety of continued core loading. Prior to completing the loading of the initial nucleus of eight fuel assemblies, significant changes in the ICRR data were expected to occur due to geometry effects arising from changes in detector-to-fuel assembly coupling. Therefore, the ICRR values were re-normalized following movement of source bearing fuel assemblies from the baffle wall to their final location(s) in the core.

35

 

4.6 lnitial Core Loading (2-PET-1 05) (continued)

All fuel movement was performed in accordance with 2-FHl-7, Fuel Handling and Movement.

The core status display in the main control room was updated, as required, to reflect the actual physical location of all fuel assemblies and fuel related components at alltimes during the core loading evolution.

3.0     Test Results All Acceptance/Review Criteria were met or resolved as delineated below.

Note: Unit 2 Core Load ICRR plot is provided in Figure 4.6-2.

Acceotance Criteria 3.1     The core was successfully loaded in accordance with the Unit 2 Cycle 1 Westinghouse Core Load Plan.

Verification of successful core loading was provided via 2-Tl-28, Physical Verification of Core Load Prior to Vessel Closure, (WO 117370592.) See Figure 4.6-1.

3.2     At completion of each mini-core, the final count rate from any detector shall not unexpectedly double from the initial count rate before the assembly was inserted.

Neutron count rates observed during fuel movement did not unexpectedly double at any time.

3.3   At completion of each mini-core the ICRR response from any detector shall not be less than 0.5 as each fuel assembly is inserted.

Neutron count rates observed during fuel movement did not unexpectedly double at any time and ICRR remained above 0.5, see Figure 4.6-2.

3.4   Core loading operations are required to be immediately stopped and the Containment Building evacuated if any of the following conditions occur during core Ioading. Movements of an active source bearing assembly, or detectorto-fuel assembly neutronic coupling are anticipated type changes.

36

 

4.6 Initial Core Loading (2-PET-1 05) (continued) 3.4.1 An unanticipated simultaneous increase       in the neutron count rate by a factor of > 2 on all "responding" neutron monitoring channels.

3.4.2 An unanticipated simultaneous increase       in the neutron count rate on any individual "responding neutron monitoring channel by a factor of > 5.

Neutron count rates were acceptable and did not meet either criteria to warrant suspension of core loading operations or evacuation of the Containment Building.

Review Criteria Al! required Review criteria for this test were met as delineated below:

3.5   Assessment of the ICRR response should be based on the predicted ICRR response.

ICRR plots maintained during core loading activities contained both actual plant lcRR data as well as predicted ICRR data from the fuer vendor, see Figure 4.6-2.

3.6     Placement of initialfuel assemblies up to placement of primary source assemblies in final core location should be detected by the ICRR response.

ICRR monitoring was maintained at all times during core loading, including loading of the first "mini-cores" and final movement of primary source bearing fuel assemblies.

3.7   ICRR response should not be less than 0.8 for any fuel assembty after the primary source assemblies have been placed in their final locations.

ICRR data during core loading was determined to be less than 0.8 following final placement of the two source bearing assemblies. CR 1112886 was initiated to document violation of this Review Criterion. Violation of this criterion does not represent a failure of this test, as it only requires further evaluation by the fuel vendor.

The fuel vendor was notified and agreed that the data was acceptable.

31

 

4.6 Initial Core Loading (2-PET-1 05) (continued) 4.0     Problems t1]   CR 1112049 was written to document a labeling issue. Source Range labeling difference was noted between 2-PET-105 and the Unit 2 Main Control Room. Urgent Change 1 was processed for 2-PET-105 to correct the labeling issue.

l2l   CR 1 112886 was initiated to document violation of the 0.8 ICRR limit during core loading, as described in Section 3.7.

t3l   CR 11 12204 was initiated to document foreign material, later determined to be glue, on the bottom nozzles on multiple fuel assemblies during initial core load. All assemblies noted to have debris were cleaned prior to being loaded in the reactor.

Efforts to remove the debris caused schedule delays.

38

 

4.6 lnitial Core Loading (2-PET-1 05) (continued)

FIGURE 4.6.1 U2C1 Core Load Sequence UZC1 Core Load Sequence PERFORMED BY I 39

 

4.6      Initial Core Loading (2-PET-1 05) (continued)

FIGURE 4.6.2 Unatz Core Load ICRR Unit  2 Core Load Inverse Count Rate Ratio     (ICRR)

L,2 1.1 1.0 0.9 0.0 0.7 il U 0.6 o !{-31 H                                                            . t{-32 0.5                                                      rll-31   Fredicted rll-32   Fredicted 0.1 0.3 0.2 0.1 0.0 80 100 120 1a0 ll&ber of nrel tage&lies 40

 

5.0 PRECRITICAL TESTING 5.1 Post Gore Loading Precritical Test Sequence (2-PAT-3.0)

This test started on 121912015 and was completed on 05 115116.

1.0   Test Obiectives The objectives of this test were to:

1.1     Serve as controlling document for establishing the required pre-requislte conditions to permit testing following the completion of 2-PAT-2.0.

1.2     Govern the sequence of tests performed in Mode 6 through Mode 3.

1.3     lmplement testing deferred from Pre-Operational Test lnstruction, 2-PTl-062-03, HFT Charging and Letdown documented in CR 1075347 and CR 1085430.

The following PATs/PETs/RCl were sequenced for performance by 2-PAT-3.0:

o   2-PAT-1.4

* Pipe Vibration Monitoring o   2-PAT-1.6

* Startup Adjustments of Reactor Control System o  2-PAT-1.7

* OperationalAlignment of Process Temperature lnstrumentation o   2-PAT-1.8

* Thermal Expansion of Piping Systems o  2-PAT-1.11* RVLIS Performance Test o  2-PAT-1.12* Common Q Post Accident Monitoring System o  2-PAT-3.1 Control Rod Drive Mechanism Timing and CERPI

                                  !nitial Calibration o   2-PAT-3.2 Pressurizer Spray Capability and Continuous Spray Flow Setting o  2-PAT-3.3

* RCS Flow Measurement o   2-PAT-3.4 Rod Control and Rod Position lndication (CERPI) o   2-PAT-3.7 Reactor Coolant Flow Coastdown o   2-PAT-3.8 Rod Drop Time Measurement and Stationary Gripper Release Timing

              . 2-PAT-3.10 Reactor Trip System c  2-PAT-3.11 Adjustment of Steam Flow Transmitters at Minimal Flow o  2-PAT-5.1

* Dynamic Automatic Steam Dump Control o  2-PET-106 Control Rod Drive Mechanism Timing o

* RCI-159 Radiation Baseline Surveys 4L

 

5.1 Post Core Loading Precritical Test Sequence (2-PAT-3.0) (continued)

Note:

The description of the testing is documented in the section (plateau) in which it was completed.

2.0  Test Methods Prerequisite actions for this Power Ascension Test (PAT) started on 121912015 and completed on 1211112015 and included verification of the following major items:

o   2-PAT-2.0 lnitial Core Loading Sequence completed.

o   2-GO-7 Refueling Operations performed concurrently with 2-PAT-3.0.

o   2-GO-10 Reactor Coolant System Drain and Fill Operation performed concurrently with 2-PAT-3.0.

o   RCI-159 Radiation Baseline Surveys, commenced for post-fuel load activities.

Testing was performed at eight defined plateaus including, ambient

(<105'F), 250"F, 300'F, 360'F,400'F,450"F, 500'F, and 557'F.

This report is a summary therefore see individual test packages for specific details at each plateau.

Ambient Plateau testing included the following:

o RCI-159, Radiation Baseline Surveys, Post Fuel Load Survey - field work complete on 12112115. No Acceptance or Review Criteria was associated with this procedure.

o 2-PAT-1.8, Thermal Expansion of Piping Systems, field work complete for applicable sections on 12l16/15 with all criteria met.

o 2-PAT-5.1, Dynamic Automatic Steam Dump Control, field work complete for applicable sections on 1/16/16. There was no Acceptance or Review Criteria for this portion of testing.

o 2-PAT-3.10, Reactor Trip System, field work complete on 1120116 with all criteria met.

o PAT-3.1, Control Rod Drive Mechanism and CERPI lnitial Calibration, field work complete on 1124116 with all Acceptance Criteria met after evaluation of current amplitudes on twelve lift coils determined the results to be acceptable for the designed operation of the rod control system. CR 1128950 was written for high current amplitudes and closed following Westinghouse evaluation that determined the measurements to be acceptable. There was no Review Criteria for this PAT.

42

 

5.1 Post Core Loading Precritical Test Sequence (2-PAT-3.0) (continued) o 2-PAT-3.8, Rod Drop Time Measurement and Stationary Gripper Release Timing, Mode 5 Performance, field work complete for applicable sections on 1124116 with allAcceptance Criteria met. CR 1128964 was written due to the RDTC plots for each rod were inverted from the expected response. This did not impact performance of the test and was resolved prior to the Mode 3 performance. There was no Review Criteria for this test.

              . 2-PAT-1.4, Pipe Vibration Monitoring, field work complete for applicable sections on211l16 with all criteria met.

PAT testing on the plant primary side was suspended on 1126116 until plant conditions and surveillance completions allowed further testing.

Condensate was placed on modified long cycle which allowed the completion of the applicable portions of 2-PAT-1.4.

On 3/15/16 preparations began for entering Mode 4 and PAT Test Coordinators began reviewing and completing pre-requisites for Mode 4 testing. Mode 4, RCS temperature >200'F and <350'F, entry was made on 3/19/16.

The 250"F Plateau included the following:

o   2-PAT-'1.12, Common Q Post Accident Monitoring System, field work complete for applicable section on 3121116 with all criteria met.

There is no Review Criteria associated with this PAT.

The 300"F Plateau included the following:

            . 2-PAT-1.11, RVLIS Performance Test, field work complete for applicable sections on 3125116 with al! criteria met.

            . The plant entered Mode 3, RCS temperature ) 350"F, on 3/30/16 at 23:14 to allow further Power Ascension Testing.

The 360"F Plateau included the following:

o   2-PAT-1.11, RVLIS Performance Test, field work complete for applicable sections on 3/31/16 with all criteria met.

o   2-PAT-1.12, Common Q Post Accident Monitoring System, field work complete for applicable section on 3/31/16 with all criteria met.

            . 2-PAT-1.8, Thermal Expansion of Piping Systems, field work complete for applicable sections on 3/31/16 with all criteria acceptable for continued heat-up.

Plant heat-up to 400 degrees was initiated on 411116 at01:14.

43

 

5.1 Post Gore Loading Precritical Test Sequence (2-PAT-3.0) (continued)

o 2-PAT-1.11, RVLIS Performance Test, field work complete for applicable sections on 411116. CR 1156311 documented some test data was not taken with the RCP start but was collected satisfactorily from the plant computer. Review criteria was not met on the Reactor Coolant Pump Combination testing, The RVLIS system was updated with the new constants supplied by Westinghouse to correct the abnormality and documented in cR 1156425.

o 2-PAT-1.12, Common Q Post Accident Monitoring System, field work complete for applicable sections on 411116 with all criteria met.

After completion of the 400'F Plateau testing, plant heat-up to 450"F was initiated at 09:45 and completed at 12:16 on 411116.

The 450"F Plateau inctuded the following:

o 2-PAT-1.11, RVLIS Performance Test, field work complete for applicable sections on 411116 with all criteria met.

o 2-PAT-1.12, Common Q PostAccident Monitoring System, field work complete for applicable section on 411116 with all criteria met.

o 2-PAT-1.8, Thermal Expansion of Piping Systems - field work complete for applicable sections on 4/1/16. Problem Report #1 was initiated within the test for seven snubbers not performing as expected. Results indicated no issue with the snubbers and approvalwas received to continue to next plateau testing.

Due to plant issues concerning check valve leakage, the decision was made on 412116 to cool down the RCS and make entry into Mode 4 to allow repairs. Mode 4 entry was made on 412116 at 06:29. Additionally, repairs on two RCS RTDs were made.

Mode 3 re-entry was made on 418116 at 12:44.

Plant condition of RCS temperature at 500'F was met on 4110116.

The 500'F Plateau included the following:

              . 2-PAT-1.11, RVLIS Performance Test, field work complete for applicable sections on 4110116 with all criteria met.

44

 

5.1 Post Core Loading Precritical Test Sequence (2-PAT-3.0) (continued)

Plant heatup to 557'F was completed at 15:30 on 4113116 with normal operating pressure reached at 01:30 on 4114116. On 4117116 at 03:38 the unit was placed in Mode 4 for repairs to the Auxiliary Feedwater Pumps and replacement ol PD07-2 shim determined to require adjustment. The Unit was returned to Mode 3 on 5/1/16 at 17:36 and normal operating temperature and pressures on 512116 at 23:00.

The 557'F Plateau included the following:

c 2-PAT-1.11, RVLIS Performance Test, field work complete for applicable section of 557'F data taking only on 4113116 with all criteria met for steady state data collection. Additionally, Section 6.1.3, Pump Combinations at 557'F, was field work complete on 518116. Results (Section 6.1.4) indicated Acceptance Criteria would not be met. The system was updated with the new RVLIS constants supplied by Westinghouse to correct the abnormality and documented in CR 1171130.

o 2-PAT-1.12, Common Q Post Accident Monitoring System, field work complete for Data Collection Section 6.7 on 4113116 with all criteria met. Section 6.8, Pump Contact Data Collection at 557'F was completed on 518116 with all criteria met.

              . 2-PAT-1.8, Thermal Expansion of Piping Systems, field work complete for applicable sections on 4114116 with one issue outside containment on PD07-2 which also required evaluation of PD07-1.

Problem Report #2was initiated to resolve the issue with PD07-2 and investigate any possible issues with PD07-1. Additionally Problem Report #3 was written to evaluate components not moving as expected. Both Problem Reports were closed and conditions were acceptable to continue testing.

o 2-PAT-1.4,Ptpe Vibration Monitoring, field work complete for Section 6.5.1 Pressurizer Surge - Mode 3, on 4114116 with all criteria met for that section. Section 6.5.2, Main Feedwater Pump 2A Start and Steady State Operation on Recirc., was field work complete on 4113116 with velocity and displacement Acceptance Criteria not met. CR 1161783 was initiated for an engineering evaluation which concluded acceptable as is. Section 6.5.3, Main Feedwater Pump 28 Start and Steady State Operation on Recirc.,

was field work complete 5/5/16 with steady state velocity and displacement exceeding the Acceptance Criteria. CR 1168287 was written for an engineering evaluation and resulted in adjustment of a loose hanger and a retest. The retest was completed on 5113116 with satisfactory results. Section 6.5.4, Turbine Bypass Valve 2-FCV-1-105 Transient was completed on 5112116 with all criteria met. Section 6.5.5, Turbine Bypass Valve 2-FCV-1-111 Transient was completed on 5112116 and re-tested on 5/13/16. Engineering evaluation of the retest indicated satisfactory results.

45

 

5.1 Post Core Loading Precritical Test Sequence (2-PAT-3.0) (continued)

CR 1170319 documents engineering evaluation to accept-as-is following the retest. Section 6.5.7 Condensate - Long Cycle was field work complete on2l1116 with all criteria met. There was no Review Criteria for 2-PAT-1.4.

2-PAT-3.2, Pressurizer Spray Capability and Continuous Spray Flow Setting - Section 6.1, Adjustment of the Pressurizer Manual Spray Bypass Valves, was completed on 4116116. AllAcceptance Criteria was met. Review criteria for MCR alarms was not met with CRs 1161382 and 1160969 written. A Westinghouse evaluation determined the PAT met the operability and design requirements for the pressurizer spray system. Additionally, CR 1161789 was written for proportional heater band not within the specified requirement which was not an Acceptance Criteria.

2-PAT-3.3, RCS Flow Measurement, field work complete on 5/3/16 with all criteria met.

2-P AT -1. 7, Operational AI g n ment of Process Te m peratu re i

lnstrumentation, field work complete on 5/6/16 with allAcceptance Criteria met. One Review Criteria was not met and CR 1168641 was initiated.

2-PAT-1.6, Startup Adjustments of Reactor Control System, field work complete for Mode 3 on 514116. This performance was data taking only.

2-PAT-3.4, Rod Control and Rod Position lndication (CERPI), field work complete on 5113116. The Acceptance Criteria was not met in Sections 6.4 and 6.10. CRs 1 168845, 1168881, and 1169602 were written to document failure to meet criteria. The criteria was re-evaluated and it was determined the acceptance criteria should be changed to require each Rod Position lndication to indicate rod motion consistent with the group demand indication for the full range of rod travel. A change to the Westinghouse Acceptance Criteria and SAR Change Package No. U2-019 were approved and an urgent change to the procedure incorporated the revised Acceptance Criteria. All Acceptance Criteria for the final package were met.

2-PAT-3.0, Attachment't,Testing Deferred from 2-PTl-062-03,

              - field work complete on 517116 with allAcceptance Criteria met.

CR 1168487 was written to document alternate charging flow was not within anticipated range, however, it had no affect on the test acceptance.

2-PAT-3.8, Rod Drop Time Measurement and Stationary Gripper Release Timing, field work complete on 5/11116. CR 1169659 was written for two rods failing a two sigma statistical evaluation. Three additional rod drops were performed and allAcceptance Criteria was met. There was no Review Criteria for this test.

46

 

5.1 Post Core Loading Precritical rest sequence (2-PAT-3.0) (continued) o   2-PAT-3.11, Adjustment of Steam Flow Transmitters at Minima!

Flow, field work complete on 517116 with all Review Criteria met.

There was no Acceptance Criteria associated with this performance.

o   2-PAT-3.7, Reactor Coolant Flow Coastdown, field work complete on 5/8/16 with all criteria met. CR 1169224 was written to document during removal of an instrument recorder a blown fuse caused alarms in the Main Control Room.

o   2-PAT-5.1, Dynamic Automatic Steam Dump Control, field work complete on 5112116 with all criteria met after a volume booster adjustment with CR 1170159 and retest on 2-FCV-1-108.

3.0   Test Results Acceptance/Review Criteria were contained within the test sequenced by this test, except for Attachment 1, Testing Deferred from 2-PTl-062-03.

Attachment 1 required Acceptance Criteria were met as delineated below.

Acceotance Criteria 3.1     Sum of RCP seal injection flow s 40 gpm, (6-13 gpm for each RCp).

A. 2-Fl-62-1A = 9.0 gpm (6.6-12.4 gpm)

B. 2-Ft-62-14A= 9.2 gpm (6.6-12.4 gpm)

C. 2-Ft-62-2tA= 9.3 gpm (6.6-12.4 gpm)

D. 2-Ft-62-40A = 9.2 gpm (6.6-12.4 gpm)

Total Seal lnjection Flow Rate in gpm. = A + B + C + D =

9.0+ 9.2 + 9.3 + 9.2 = 36.7 gpm 3.2     The differential pressure across the following component at the given flowrate:

Description           UNID      FIow Rate        AP      Actual (GIean)     AP Seal            2-FLTR-62-96     16-40 gpm    s7 psid    6.0 psid lnjection Filter B 3.3     lndication light 2-Xl-62-93 in MCR illuminated when 2-HIC-62-93B was in manual.

41

 

5.1 Post Gore Loading Precritical Test Sequence (2-PAT.3.0) (continued) 3.4   2-FM-62-93E prevented 2-FCV-62-93 from going fully closed to ensure Sea! Water flow rate of 33.5 11.5 gpm (32-35 gpm).

Flow was 32.2 gpm.

Review Criteria None 4.0   Problems t1l    CR 1168487 was written on 2-PAT-3.0, Attachment 1, Step 27.

Although not Acceptance Criteria, alternate charging header flow was anticipated to be approximately 89-103 gpm. Actual flow was 82.7 gpm. This information was forwarded to engineering for evaluation, however, it had no affect on the acceptance of this test.

Engineering evaluation calculated the minimum requirement at the regenerative heat exchanger temperature to be 74 gpm. The 82.7 gpm exceeds this amount. At the current conditions the test was acceptable and met the design specified criteria.

48

 

5.2 Gontrol Rod Drive Mechanism Timing and CERPI Initia! Calibration (2-PAr-3.1)

Performance of this test was directed by 2-PAT-3.0, Post Core Loading Pre-criticalTest Sequence, during the period from 1121116to 1124116. The test was performed in Mode 5 at a RCS temperature of approximately 175'F.

1.0   Test Obiectives The objectives of this test were to:

1.1   Verify the functionality of each CRDM for shutdown and control rods in Mode 5 by:

1.1.1 Verify each rod control system slave cycler provides its associated power cabinet with the appropriate command signal to obtain proper sequence timing of current supplied to the CRDM coils.

1.1.2 Verify CRDM coil current amplitudes are within acceptable ranges.

1.1.3 Verify the functionality of each shutdown and control rod drive mechanism.

1.1.4 Verify manual mode stepping rate for shutdown and control rods are within acceptable ranges.

1.2   Verify the control bank overlap function in manual with minimal overlap.

1.3   Perform the initial calibration of the RPI in accordance with vendor proced  u re WNA-TP-02576-WBT, C E RP I Calibration Proced ure.

1.4   Partially satisfu the requirements of UFSAR Table 14.2-2, Sheet 7, Control Rod Drive Mechanism Timing Test Summary, and fully satisfo it for Mode 5.

2.0   Test Methods The CRDM functionality was verified by stepping ouUin each rod bank by approximately 10 steps in individual bank select mode. CRDM current timing and amplitude measurements were taken during rod motion.

Twelve of the CRDM amplitudes were outside the upper Acceptance Criteria of the lift coil reduced current, however, the amplitudes were evaluated as acceptable by Westinghouse.

49

 

5.2 Gontrol Rod Drive Mechanism Timing and CERPI lnitial Galibration (2-PAT-3.1 ) (continued)

The bank overlap circuitry was verified at minimal settings. Minimal settings were set by adjusting the bank overlap thumbwheel switches such that control bank tip-to-tip distance was 15 steps and the all-rods-out position was 25 steps withdrawn for each control bank. The bank overlap circuitry functioned as designed and no issues were encountered. Note that the bank overlap circuitry was also exercised during the performance of the initial RPI calibration with the all-rods-out position set to 230 steps withdrawn. The bank overlap circuitry functioned as designed with no issues.

The initial RPI calibration was performed. First the bank zero adjustments were performed with all rods fully inserted. Next all shutdown and control rods were withdrawn to the full out position of 230 steps withdrawn. The shutdown banks were withdrawn first in individua! bank select and the control rods were withdrawn in bank overlap. The bank position span calibration and temperature null adjustments were performed with the rods fully withdrawn. Next all control and shutdown rods were inserted to specific demanded positions and data for each rod was obtained. Lastly, linearization adjustments were calculated based on the recorded data.

The initia! RPI calibration was completed when the new linearization adjustments were uploaded to train A and B of the RPI system. Note that prior to the linearization adjustment and during the insertion of Control Bank B, the K14 and P6 rods had a 13 step rod-to-rod deviation while inserted between CBB demanded positions of 170 steps withdrawn to 126 steps withdrawn. The RPI system was not yet calibrated, therefore, the initial calibration corrected the issue. Also note that 2-PAT-3.8 was performed following the initial RPI calibration and all rods were pulled to approximately 50 steps withdrawn. All rods were within t2 steps of the demanded position.

3.0   Test Results AllAcceptance/Review Criteria were met or resolved as delineated below.

Acceotance Criteria 3.1     Contro! Rod Drive Mechanism Timing 3.1.1 Current Order Timing The times at which the lift, movable, and stationary current orders change, after the start of rod motion, are within 10 msec. of the expected times during rod withdrawal and insertion operations.

50

 

5.2 Control Rod Drive Mechanism Timing and CERPI lnitial Calibration (2-PAT-3.1 ) (continued)

Each CRDM current order timing was reviewed and all current order timings were within 10 msec. of the expected times.

3.1.2 Coil Current Amplitudes Stationary, movable, and lift currents are regulated by circuitry internal to each power cabinet. The reduced and full current nominal values are not critical, cannot be adjusted, but could be an indication of a regulation failure.

Measured values outside the nominal ranges should be evaluated and documented by the system engineer.

Lift Coil - Full            Nominal 4A amperes (35 to 47 .2 amperes)

(equivalent to 438 to 590 mVdc measured across a 0.0125 ohm resistor)

Lift Coil - Reduced        Nominal 16 amperes (13 to 19.7 amperes)

(equivalent to 163 to 246 mVdc measured across a 0.0125 ohm resistor)

Movable Gripper Coil     - Nominal 8 amperes Full                        (7 to 9.2 amperes)

(equivalent to 438 to 575 mVdc measured across a 0.0625 ohm resistor)

Stationary Gripper Coil    Nominal 8 amperes Full                        (7 to 9.2 amperes)

(equivalent to 438 to 575 mVdc measured across a 0.0625 ohm resistor)

Stationary Gripper Coil - Nominal 4.4 amperes Reduced                    (3.8 to 4.8 amperes)

(equivalent to 238 to 300 mVdc measured across a 0.0625 ohm resistor) 51

 

5.2 Control Rod Drive Mechanism Timing and CERPI Initial Galibration (2-PAT-3. 1 ) (continued)

Each current amplitude recorded in the test package were reviewed. All current amplitudes were within the Acceptance Criteria with the exception of twelve CRDMs for the lift coil reduced current. The twelve lift coi! reduced current amplitudes were evaluated and determined to be acceptable for the designed operation of the rod control system.

CR 1128950 was closed.

3.1.3 Rod Withdrawal Speed Shutdown bank withdrawal speed nominal value is 64 (62 to

: 66) steps per minute.

Control bank withdrawal speed nominal value is 48 (46 to 50) steps per minute.

The Shutdown and Control banks withdrawal speeds met their Acceptance Criteria and were recorded as 63.9 steps/min and 48.0 steps/min respectively.

Control rod drive mechanisms operate with no indications of problems during the withdrawal and insertion stepping.

Each CRDM current trace was reviewed. Alltraces operated normally and no abnormalities, such as movable/stationary gripper dragging or rod misstepping, were identified.

3.2     Control Bank Overlap Demonstration 3.2.1 The control rod bank overlap circuitry functions properly during the sequential withdrawal and insertion of Control Banks in MANUAL mode.

The control bank overlap circuitry functioned as designed.

52

 

5.2 Contro! Rod Drive Mechanism Timing and GERPI lnitial Calibration (2-PAT-3. 1 ) (continued )

3.2.2 The MCR rod speed demand display functions properly         and indicates the rod stepping rate was within the range of 46 to 50 steps/minute for Control Banks in Manual mode.

The MCR rod speed demand display functioned as designed at 48.0 steps/min.

3.2.3 The MCR group step counters function properly to indicate group position and direction of rod motion during rod withdrawal and insertion operations.

3.2.4 The MCR     RPI functions properly to indicate individua! rod direction of motion during rod withdrawal and insertion operations.

The MCR RPls indicated the proper direction of motion during rod withdrawal and insertion operations.

3.2.5 The MCR rod direction indicator lights function properly to indicate the rod movement status and direction of rod motion during rod withdrawal and insertion operations.

The MCR rod direction indicator lights functioned as designed.

Review Criteria None 4.0   Problems t1]     During the performance of the CRDM timing and amplitude measurements, the 1AC power cabinet- stationary group A coil amplitudes were lower than the expected value. WO 111522924 was performed to inspect and reform backplane connector and card edge pins for the 1AC power cabinet - stationary group A firing, regulation, and phase control cards. The issue was corrected and testing continued.

s3

 

5.2 Control Rod Drive Mechanism Timing and CERPI lnitial Calibration (2-PAT-3. I ) (conti nued )

l2l      Step 6.3.3[7.1], WNA-TP-02576-WBT, Revision 2, Step 2.4.2.5,the all-rods-out position was 230 steps withdrawn, however, the compensated position in the software was hardcoded to 231 steps withdrawn. The performance of Step 2.4.2.5 was not impacted because it listed 230 steps t1 step. CR 1128373 was written and concluded no changes to 2-PAT-3.1 were required.

t3l      CR 1128918: Step 6.3.4[62], WNA-TP-02576-WBT, Revision 2, Appendix A.1 and A.2 forms were used for the linearization adjustments. The "X Table C1" column values were not Watts Bar U2 specific values. The Watts Bar U2 plant specific "X Table C1" values were used for the linearization adjustments. CR 1128918 was written. Resolution was for Westinghouse to revise WNA-TP-02576-WBT.

l4I      CR 1128950 Two rod amplitude measurements (F14 and D08) failed the procedure Acceptance Criteria and do not meet the Westinghouse expanded acceptance criteria in WBT-D-il20.

documenting their evaluation and the acceptability for the 2 rod locations that exceeded the Acceptance Criteria of 20 amps.

Note that additional rod measurements were outside of the Reduced Lift Current procedure Acceptance Criteria of 19.7 amps, however, WBT-D-5420 has been issued by Westinghouse that states reduce lift currents up to 20.0 amps are acceptable.

2-PAT-3.1, Rev. 2, allows for evaluation of the currents outside of the Acceptance Criteria for successful completion of 2-PAT-3.1.

Current orders outside of the Acceptance Criteria were evaluated and deemed acceptable per Westinghouse. Also additional measurements were obtained in Mode 3.

t5I      During the performance of 2-TRl-85-1, Reactivity Control Systems Movable ControlAssemblies (Modes 3, 4 and 5), rods common to the 2BD power cabinet would not withdraw. Troubleshooting determined an issue with the 2BD movable gripper current amplitudes. The firing and regulation cards for the 2BD movable grippers were replaced with spares and the issue was corrected.

No problems with this power cabinet occurred during 2-PAT-3.1 testing.

 

5.2 Control Rod Drive Mechanism Timing and CERPI Initial Calibration (2-PAT-3.1 ) (continued)

Step 6.1l12lof Appendix E, rods common to the 1AC power cabinet - stationary group A did not have the expected reduced stationary gripper currents when the CRDM-DAQ was first connected. Under CR 1126661 and WO 117522924, the stationary group A firing, regulation, and phase cards were removed and both backplane connector and card edge pins were reformed. The issue was corrected and testing was completed. No other problems with this power cabinet occurred during 2-PAT-3.1 testing.

t6I    During the performance of 2-TRl-85-1 with the 2-RBSS in the SBC and SBD positions, the CERPI monitor indicated 72 steps/min. The actual speed of the SBC and SBD groups is approximately 64 steps/min and is set at the SCD power cabinet. The indication did not invalidate the performance of this test. CR 1126783 was written and closed to WO 115966328.

17I    Step 6.3.4[3], during SBD insertion, the SBC demand position on both the ICS and RPI monitors followed the SBD demand position.

The problem was due to communication issues between the rod control system and the ICS. Testing continued because this issue did not invalidate the performance of this test. CR 1128318 was written, and Post lssuance Change (PlC) 66181 was issued and implemented by WO 117546244.

t8l    Step 4.3[10]A, the 28 MG Set failed to sync in parallel with the 2A MG Set. The issue did not invalidate the performance of 2-PAT-3.1 because only one MG set was required for the performance of this test. CR 1126798 was written, and closed to WO 117531764.

 

5.3 Pressurizer Spray Capability and Continuous Spray Flow Setting (2-PAr-3.2)

Performance of this test was directed by 2-PAT-3.0, Post Core Loading Pre-critical Test Sequence, during the period from 4115116to 514116.

1.0   Test Obiectives The objectives of this test were to:

1.1   Verify the pressure response to the opening of both normal Pressurizer Spray Valves was within the allowable range specified by NSSS performance curyes.

1.2   Verify the Pressurizer Bypass Spray Valves were throttled to an optimum position such that during steady state operation:

1.2.1 Spray line temperature was high enough to prevent the PZR SPRAY TEMP LO alarm from actuating.

1.2.2 The equilibrium temperature for each spray line was greater than or equal to 540F.

1.2.3 Pressurizer control bank heaters can maintain RCS pressure above 2220 psig without backup heater operation.

1.2.4 Surge line temperature was high enough to prevent the PZR SURGE LINE TEMP LO alarm from actuating.

1.3     Verify the PZR SPRAY TEMP LO alarm would actuate on decreasing spray line temperature of approximately 530F.

1.4     Satisfy the requirements of UFSAR Table 14.2-2, Sheet 13, Pressurizer Spray Capability And Continuous Spray Flow Setting Test Summary.

55

 

5.3 Pressurizer Spray Capability and Continuous Spray FIow Setring (2-P AT -3.2) (conti nued )

2.0   Test Methods This test established the optimal throttle positions for the Pressurizer Spray Manual Bypass Valves, and also ensured the effectiveness of the normal pressurizer spray by initiating full spray to reduce RCS pressure by approximately 250 psi and compared the time to reduce pressure with Westinghouse performance curyes. During the performance of Section 6.2, the validated RCS pressure DCS computer point being used to monitor the depressurization of the RCS stopped updating at acceptable rate. Because of this the RCS narrow range indicators on the control board were used to determine when RCS pressure reached the trigger value of 2000 psig. Subsequent review also determined that this point deviated further from the actual RCS pressure after it was no longer being monitored. This did not affect the ability to meet the Acceptance Criteria of the test as ICS computer points were collected for use to analyze compliance with Acceptance Criteria for the spray capability test. CR 1168255 documents this issue.

The spray line temperature low alarm was unable to be verified as intended during the performance of this test due to slight leakage past either the spray line FCV's or the spray bypass manual valves. This occurred on both loops 1 and 2. This condition prevented meeting the Review Criteria associated with the spray line temperatures. The operation of the spray line temperature switches for each loop were subsequently verified to be operating correctly by utilizing trend data from the plant computer. CRs 1 160969 and 1 161382 document this issue.

3.0    Test Results AllAcceptance/Review Criteria were met or resolved as delineated below.

Acceptance Criteria 3.1    Pressurizer pressure response to opening both Normal Pressurizer Spray Valves is within the allowable range specified by NSSS performance curves.

The pressurizer spray response data was within the allotted response time as depicted on Figure 5.3-1.

51

 

5.3 Pressurizer Spray Capability and Continuous Spray Flow Setting (2-P AT -3.2) (conti nued )

Review Criteria 3.2     Pressurizer Manual Spray Bypass Valves 2-BW-68-552 and 2-BW-68-555 are throttled to an optimum position during steady-state operation.

All procedural criteria was met:

: 1.     Spray line equilibrium temperature is high enough to prevent Annunciator 2-><A-55-5A-89E, PZR SPRAY TEMP LO from actuating.

2-XA-55-5A-89E, PZR SPRAY TEMP LO, did not actuate.

: 2.      Equilibrium temperature for each spray line is greater than or equal to 550'F:

Loop 1 Spray Line Temperature (lCS PID T0484A)

Loop 2 Spray Line Temperature (lCS PID T0483A)

Spray Iine equilibrium temperatures were > 550oF.

: 3.      Pressurazer control bank heaters can maintain RCS pressure above 2220 psig without any Backup Heater operation.

Backup Heater operation was not required to maintain pressure.

: 4.      Surge line equilibrium temperature is high enough to prevent Annunciator Alarm 2-XA-55-5A/89D, PZR SURGE LINE TEMP LO, from actuating.

2-KA-55-5A/89D, PzR SURGE LINE TEMP Lo, did not actuate.

3.3     Annunciator Alarm 2-XA-55-5A/89E, PZR SPRAY TEMP LO actuates on decreasing spray line temperature of approximately 530'F (525"F to 535'F).

Loop 1 spray line temperature would not decrease sufficiently to allow the low spray line temperature alarm to actuate. See CR 1 160969.

Loop 2 spray line temperature would not decrease sufficiently to allow the low spray line temperature alarm to actuate. See CR 1161382.

58

 

5.3 Pressurizer Spray Capability and Continuous Spray Flow Setting (2-P AT -3.2) (conti nued )

4.0   Problems t1]     CR 1160969 was written because the loop 1 spray line temperature would not decrease sufficiently to allow the Iow spray line temperature alarm to actuate. Westinghouse evaluation was obtained which concluded that 2-PAT-3.2 met operability and design requirements for the pressurizer spray system.

l2l     CR 1161382 was written because the loop 2 spray line temperature would not decrease sufficiently to allow the low spray line temperature alarm to actuate. Westinghouse evaluation was obtained which concluded that 2-PAT-3.2 met operability and design requirements for the pressurizer spray system.

13]     CR 1161789 was written due to the master pressure controller output being less than the desired range while setting the loop 2 spray line bypass valve. The controller output was 37 percent while the desired range was a minimum of 46 percent. Performance of Section 6.1.3 which performed the final setting of the spray bypass valves, allowed the output of the master controller to be placed in the desired range of the procedure.

t4]     CR 1168255 was written to document the issues experienced with the ICS computer point for Validated Pressurizer Pressure (DCS0426) during the performance of Section 6.2.

59

 

5.3     Pressurizer Spray Capability and Continuous Spray Flow Setting (2-PAT.2) (continued)

FIGURE 5.3.1 Pressurizer Spray Response 2-PAT-3.2 Pressu rizer Spray                           Ca pa   bility

      -50      \

  .I

      -10o t:

I l-I r

                            -'-1                     \ \

                                                            \

                              \                               l-o F

N LT                             \ \

                                      \\\

                                            \-i\ N                          \

r            ri                            \ \                          L

      -200

:\-;           \ \                         1il

                                                                  }} rjj i r\

                                                                      \                  - ---l. -- -{

i--i---:       \i                                             !L ----- i l

                                                          ,,\           \r                                 \l

 

5.4 Rod Gontrol and Rod Position lndication (CERPI) (2-PAT-3.4)

This test was performed in Mode 3 at NOTP as directed by 2-PAT-3.0, Post Core Loading Precritical Test Sequence. lt performed the initial hot calibration of the Computer Enhanced Rod Position lndication (CERPI) system and functional testing of the Rod Control System. The performance of Section 6.0 of this test was commenced on 05/05/16 and was completed on 05113116.

1.0    Test Obiectives The objectives of this test were to:

1.1    Perform the lnitial Hot Calibration of the Computer Enhanced Rod Position lndications (CERPI) system.

1.2    Verify the Computer Enhanced Rod Position lndication system (CERPI) performs required indication function satisfactorily for each shutdown and control rod over their entire range of travel and to verifo the rod position indication system alarm functions operate properly. (UFSAR Table 14.2-2, Sheet 8, Rod Position lndication System Test Summary).

1.3   Demonstrate that the rod control system satisfactorily performs the required control and indication functions, as required by UFSAR Table 14.2-2, Sheet 10, Rod Control System Test Summary.

2.0    Test Methods The rod position indication system completed the initial hot calibration using vendor instructions and 2-SI-85-3, Calibration of Computer Enhanced Rod lndication Channels and Full Range Verification. The CERPI system operated over the full length of travel and can operate without actuating rod-to-rod and rodto-bank deviation alarms by making adjustments to the CERPI tunable parameters. This was consistent with vendor and Unit 1 operating experience. Therefore, the vendor CERPI Acceptance Criteria was revised and Urgent Change (UC) 2 was processed for this test procedure to veriff that each rod indicates rod motion consistent with the group demand over the full length of trave!.

The Rod Control System and CERPI functionaltesting included controls and indications. The functional testing included rod-to-bank and rod-to-rod deviation alarms, the C-11 annunciator, lntegrated Computer System (lCS) generated alarms, rod bottom bistables, rod bottom bypass bistables, rod control urgent and non-urgent alarms, main control room displays, rod insertion limits, and control rod bank overlap circuitry.

This test also documented 5 complete rod excursions (i.e., fullwithdrawal and insertions) of all shutdown and control rods per CR 234483. All 5 excursions were successfully completed.

6L

 

5.4 Rod Control and Rod Position lndication (CERPI) (2-PAT-3.4) (continued) 3.0 Test Results AllAcceptance/Review Criteria were met or resolved as delineated below.

Acceptance Criteria 3.1   CERPI Calibration 3.1.1   WNA-TP-02576-WBT, Watts Bar 2 ARPI System Upgrade CERPI Calibration Procedure, Section 2.6, lNlTlAL HOT CALIBRATION, was successfully completed and the linearity is within +12 steps at the steps checked in the procedure.

The initial hot calibration was successfully completed and the linearity was demonstrated to be 112 steps at the steps checked in the procedure.

3.1.2   2-Sl-85-3, Calibration of Computer Enhanced Rod lndication Channels and Full Range Verification, was successfully completed.

3.2   Rod Control and lndication 3.2.1   2.XA-55-4A.64F, C11 BANK D AUTO WITHDMWAL BLOCKED, alarm window in control room was LIT when Control Bank D was withdrawn above 220 steps.

2-XA-55-4A-64F, C-11 alarm window annunciated at220 steps.

3.2.2   CERPI monitor alarm for:

(1)     Rod to Rod Deviation between two rods in a bank The rod to rod deviation CERPI alarm was at 12 steps.

(2)     Rod to Bank Deviation corresponding to > 12 steps.

The Rod to Bank Deviation alarm was at 12 steps.

52

 

5.4 Rod Control and Rod Position lndication (GERPI) (2-PAT-3.4) (continued) 3.2.3  2-><A-55-4B-83D, PLANT COMPUTER GENERATED ALARM (SEE ICS), alarm window in control room was LIT when ICS Computer detects the following conditions:

(1)     Deviation between rod position indicator for a rod and corresponding bank demand positi on >12 steps.

The deviation between ICS rod position and bank demand was 12 steps.

(2)     Deviation between rod position indicator for a rod and average rod position >12 steps.

The deviation between ICS rod position and average rod position was 13 steps.

3.2.4  Rod bottom bistable indicators actuate at correct setpoint setting (below 20 steps withdrawn) as indicated by RPI indicators and rod bottom indicators on CERPI on 2-M-4.

Each rod bottom bistable for all rods actuated below 20 steps (20 to 19 steps) withdrawn.

3.2.5  CERPI bypass indication for Control Banks B, C, and D actuate at correct setpoint setting (below 35 steps withdrawn) as indicated by CERPI Bank Demand digital display.

CERPI bypass indication for Control Banks B, C, and D actuated at 31 steps withdrawn.

3.2.6  An Urgent Failure induced in a Power Cabinet and Logic Cabinet caused local urgent failure alarm indicator lamp at the respective cabinet and 2-Xl\-55-48-86A, CONTROL ROD URGENT FAILURE, ohnunciator window to light.

The Power Cabinet and Logic Cabinet local urgent failure alarm indicator lamp and 2-><A-55-48-86A annunciator window functioned as designed and met all applicable Acceptance Criteria.

 

5.4 Rod Control and Rod Position lndication (GERPI) (2-PAT-3.4) (continued) 3.2.7  A Non-Urgent Failure induced in each of the Power Cabinets and Logic Cabinet causes local non-urgent failure alarm indicator lamp at respective cabinets and 2-XI\-55.48-868, CONTROL ROD NON-URGENT FAILURE, ?rnunciator window to light.

The Power Cabinet and Logic Cabinet local non-urgent failure alarm indicator lamp and 2-)<A-55-48-868 annunciator windows functioned as designed and met all applicable Acceptance Criteria.

3,2.9  A failure induced in the CERPI racks caused 2-><A-55-4B-86C, CERPI TROUBLE, ?rnunciator window to be LIT or REFLASH.

The 2-><A-55-4B-86C annunciator window functioned as designed and met all applicable Acceptance Criteria.

3.2.9  For shutdown and control rod banks having two groups, the group step counter for group 1 shall be 0 or 1 step above grou p 2 step counter over their full length of travel (i.e., 231 steps).

The group step counters for group 1 were 0 or 1 step above grou p 2 step counters over their full length of travel for shutdown and control rod banks having two groups. All applicable Acceptance Criteria were met.

3.2.10  2-><A-55-4B-87D, RODS AT BOTTOM, ornunciator window was lit when one or more rods in CBA were inserted in the normal sequence. Also, RODS AT BOTTOM, ornunciator window is not lit when control rods were inserted or withdrawn in their normal sequence.

2-xl\-55-4B -87 D annunciator window functioned as designed and met all applicable Acceptance Criteria.

3.2.11  Each RPI indicated rod motion consistent with the group demand indication for the full range of rod travel.

The RPI indicators for each rod indicated rod motion consistent with the group demand indication for the full range of rod travel.

 

5.4 Rod Control and Rod Position lndication (GERPI) (2-PAT-3.4) (continued) 3.2.12 The MCR rod speed demand display functions properly and indicated the rod stepping rate (ROD SPEED) was within the range of 62 to 66 steps/minute for Shutdown Banks A and B in bank select mode.

The MCR rod speed demand display indicated 64 steps/min for both Shutdown Banks A and B.

3.2.'13 The MCR rod speed demand display functions properly and indicates the rod stepping rate (ROD SPEED) was within the range of 46 to 50 steps/minute for Control Banks in bank select and in MANUAL mode.

The MCR rod speed demand display indicated 48 steps/min for all Control Banks in bank select and in Manual mode.

3.2.14 The MCR rod direction indicator lights functioned properly to indicate the rod movement status and direction of rod motion during rod withdrawal and insertion operations.

The MCR rod direction indicator lights functioned as designed and met all applicable Acceptance Criteria.

3.2.15 The MCR group step counters functioned properly to indicate group position and direction of rod motion during rod withdrawal and insertion operations.

The MCR group step counters as designed during both withdrawal and insertion.

3.2.16 The MCR Computer Enhanced Rod Position lndicators (CERP!) function properly to indicate individual rod position and direction of motion during rod withdrawal and insertion operations.

The CERPI indicators functioned as designed to indicate individual rod position and direction of motion during withdrawa! and insertion. All applicable Acceptance Criteria were met.

3.2.17 The rod insertion limits LO-LO upper limit was set to 211 steps (Control Bank A)

The rod insertion limits LO-LO upper limit was found to be set at2ll steps (Control Bank A).

65

 

5.4 Rod Gontro! and Rod Position lndication (GERPI) (2-PAT-3.4) (continued) 3.2.18     The rod insertion limits LO alarm actuated below 10 steps above the insertion limit for any control bank.

The rod insertion limits LO alarm actuated at 10 steps above the insertion limit for any control bank.

3.2.19     The rod insertion limits LO-LO alarm actuated below 0 steps above the insertion limit for any control bank.

The rod insertion limits LO-LO alarm actuated at 0 steps above the insertion limit for any control bank.

3.2.20     The control rod bank overlap circuitry functioned properly during the sequential withdrawal and insertion of Contro!

Banks in MANUAL mode.

The contro! bank overlap circuitry functioned as designed during the sequential withdrawal and insertion of Control Banks in MANUAL mode.

3.2.21     Each RPI indicated rod motion consistent with the group demand indication for the ful! range of rod travel.

The RPI indictors for each rod indicated rod motion consistent with the group demand indication for the full range of rod travel.

3.2.22     All rods were fully withdrawn and inserted five times.

The test exercised all rods to fully withdrawn and fully inserted five times.

Review Criteria None 4.0 Problerns t1l   CR 1168845 - Steps 6.4.3[20] and 6.4.4.1201, Acceptance Criteria for RPI indication agreeing within t12 steps was not satisfied for Shutdown Banks C and D for the full length of travel. This Acceptance Criteria was later changed by Urgent Change 2. See UC-2 description in this test report for further information.

55

 

5.4 Rod Control and Rod Position lndication (GERPI) (2-PAT-3.4) (continued) l2l    CR 1168881 - Section 6.4.5, Rod position indications for rods in Control Banks A and B were at 12 steps from the demand position at some positions over the full length of travel. Although not a failure in the Acceptance Criteria of Step 6.4.5[20] of within 12 steps of the demand position, the rod-to-rod deviation alarms were actuated at certain positions over the length of travel. This CR anticipated not meeting Steps 6.10[2.15]and 6.10[2.16]. The acceptance of rod-to-rod deviations was later changed by Urgent Change 2. See UC-2 description in this test report for further information.

13I    CR 1169602 - Steps 6.10[2.15] and 6.10[2.16] Acceptance Criteria of no rodto-rod and rodto-bank deviation alarms was not met for all 57 rods over the full length of travel. These steps were later changed by Urgent Change 2. See UC-2 description in this test report for further information.

l4l    CR 1 1692'17 - Step 6.4.6[1]C verified the C-1 1 Bank D Auto Withdrawal Block annunciator cleared during Control Bank D insertion between 219 and 214 steps on the step counters. The recorded step counter position for Control Bank D was 212 steps when the C-11 annunciator cleared. Step 6.4.6[1]C is not Acceptance Criteria and the value at which the annunciator cleared is reasonable. Based on the CR evaluation, the vendor manual description of operation demonstrates (as well as the test engineer evaluation) there was not a problem encountered during 2-PAT-3.4 performance with Control Rod Bank D permissive C-11. No Further Action Required.

t5I    CR 1169282 - Step 6.7.2l7lcould not be performed as written because the performance of Step 6.7.2[6] cleared the urgent alarm upon seating the 4104 card. The card interlock is the only urgent alarm in the rod control system that clears upon restoring the system configuration. Step 6.7.2171was to verify rod motion would not occur with a standing urgent alarm. These steps were not Acceptance Criteria and had no impact on successful completion of this test. Additionally, CR 1171247 was created to address and provide justification associated with not performing the steps cited in CR 1169282.

t6I    CR 1171254 - This CR was written to document certain steps and portions of sections which were repeated during testing performance based on engineering judgment. These additional performances were used as a means to perform additional calibration of CERPI as specified in the Westinghouse CERPI calibration procedure or as a means to restore from current testing 51

 

5.4 Rod Gontrol and Rod Position lndication (CERPI) (2-PAT-3.4) (continued) conditions and then later return. Section 6.1, Steps 6.1[1] through 6.1111.19lwere repeated and Section 6.6, Steps 6.6[1]through 6.6[9.5]were repeated one or more times. Section 6.6, Steps 6.6[48] through 6.6[54] were repeated.

This CR was created for documentation purposes only and has no impact on the actual test results or verification of Acceptance Criteria.

l7l   CR 1168538 - During performance of Section 6.1, Shutdown Bank A was inserted to 118 steps demand position for CERPI hot calibration. M14 indication drifted excessively for a couple of hours until a stable rod position indication was reached.

The PAT team and Westinghouse reviewed the M14 coil resistance values identified that the M14 drift was associated with a large transient in coil resistance (i.e., change in coil stack temperature) and a larger value for the T_GAIN parameter for M14.

Drift is a phenomena that occurs for ARPI/CERP! indication systems due to the analog coil stacks and their associated temperature dynamics and does not represent an actual change in rod position. This does not represent a deficiency in the design.

Adjustments to the CERPltunable parameters were made to minimize drift. Therefore, this CR did not impact the successful completion of this test procedure.

l8l   CR 1168899 - Step 6.4.5[8], the 2-)G-55-4B-87D, RODS AT BOTTOM, annunciator cleared as expected. However, the bell in the MCR did not alarm. CR was closed to previously identified work.

tgl   UC-1 was written to ensure that group step counters for Shutdown Bank A, group 1, step counters displayed 56 steps prior to withdraw of Rod D-02 in Step 6.6 [40]. This allowed the group step counter to be updated to match the current rod position for rod that was currently capability of motion.

t10]   UC-2 was processed to revise Acceptance Criteria 5.2K and 5.2U and related steps based on updated criteria provided by Westinghouse in WBT-D-5666, CERPI Acceptance Criteria, Revision 1, and a revision to UFSAR Table 14.2-2, Sheet 8.

The update criteria stated "Each RPI indicates rod motion consistent with the group demand indication for the full range of rod travel."

68

 

5.5 Reactor Coolant Flow Goastdown (2-PAT-3.7)

This test was performed as directed by 2-PAT-3.0, Post Core Loading Precritical Test Sequence, in Mode 3 at normaloperating temperature and pressure. The test was started and field work completed on 518116.

1.0    Test Obiectives The objectives of this test were to:

1.1     Measure the rate at which reactor coolant flow changes subsequent to a simultaneous trip of all four reactor coolant pumps. The measured Flow Coastdown Time Constant is determined from the flow versus time data and compared to the Design Flow Coastdown Time Constant.

1.2    Measure the delay time associated with the low flow reactor trip and compare it to that value assumed in the accident analysis.

1.3    Record the RCP Motor voltage decay during the transient for information only.

1.4     This test satisfied the requirements of UFSAR Table 14.2-2, Sheet 15, Reactor Coolant FIow Coastdown Test Summary.

2.0   Test Methods All four reactor coolant pumps were simultaneously tripped, causing the reactor trip breakers to open on Low RCS Flow. Measurements were made by recording reactor coolant loop elbow tap differentia! pressures (d/p), RCS low flow bistable state, reactor trip breaker position, reactor coolant pump breaker position and reactor coolant pump motor voltage decay data. Also recorded for information was the time of the undervoltage relay and associated time delay timer in the RCPs undervoltage circuit.

3.0    Test Results All Acceptance/Review Criteria were met or resolved as delineated below.

Acceotance Criteria 3.1     The Acceptance Criterion for core flow coastdown following the simultaneous trip of the four reactor coolant pumps from full flow conditions, was that the measured flow coastdown time constant (TAUru) was greater than (>) design flow coastdown time constant (TAUD) of 11.72 seconds.

Results indicated TAUu = 12.762 seconds 69

 

5.5 Reactor Coolant Flow Coastdown (2-PAT-3.7) (continued) 3.2 Acceptance criterion for the Total Low Flow Trip Delay Time is less than (<) 1.2 seconds.

Results indicated Low Flow Trip Delay Time, Tr_r = 0.994 seconds 3.3 Acceptance criterion for simultaneous trip of four reactor coolant pumps was that allfour pumps trip within (<) 100 msec. of each other.

Allfour pumps tripped within 20 msec.

Review Criteria 3.4 Review Criterion for coastdown   flow data quality is that data from at least 2 out of 3 flow transmitters in each RCS loop falls within Chauvenet's Criterion.

4.0 Problems t1]   CR 1169224 - During performance of 2-PAT-3.7 post performance activities, Step 7.0[5], removing the test recorders from the Aux lnstrument Room, 8 out of 12 RCS low flow trip status lights lit in the control room. Post event investigation revealed bistable fuses associated with the affected flow loops (2-LPF-68-6A, 2-LPF-08-6B, 2-L p F-69-29 A, 2-LpF-68-29 B, 2-Lp F-68-29D, 2-LPF-6848B, 2-LPF-68-71A, 2-LPF-68-71 B) blew during recorder disconnection because of human performance issues.

Since this was a post performance activity and all data was recorded during Section 6.0, there was no impact to the test results of 2-PAT-3.7.

10

 

5.6 Rod Drop Time Measurement and stationary Gripper Release Timing (2-PAr-3.8)

Portions of this test were performed in Mode 5 and again in Mode 3 as directed by 2-PAT-3.0, Post Core Loading Precritical Test Sequence.

ln Mode 3 this test was performed in conjunction with the norma! Surveillance lnstruction 2-Sl-85-10, Rod Drop Time Measurement Using CERPI Rod Drop Test Computer, to calculate the standard deviation of the rod drops and to direct required additional rod drops for CR corrective actions and potential two-sigma deviations.

Prerequisites were started on 1122116 and the test was field work completed on 1124116 for the Mode 5 performance. The Mode 3 performance was started on 5111116 and completed on 5111116.

1.0    Test Obiectives The objectives of this test were to:

1.1    ln Mode 5, Section 6.2 of this Power Ascension Test (PAT) partially withdrew al! shutdown and control rods and demonstrated that all CRDMs unlatch and all rods fully insert into the core when the reactor trip breakers were opened.

1.2    ln Mode 5, measured the Stationary Gripper Release times for each control and shutdown rod.

1.3    ln Mode 3, at Hot Standby conditions with full Reactor Coolant System (RCS) flow, measured the rod drop time and stationary gripper release time for each control and shutdown rod. WBN Unit 2 Technical Specifications require rod drop time measurements, therefore, the normal Surveillance lnstruction 2-Sl-85-10, Rod Drop Time Measurement Using CERPI Rod Drop Test Computer was utilized.

1.4    Meet the Mode 3 testing as required by UFSAR Table 14.2-2, Sheet 9, Rod Drop Time Measurement And Stationary Gripper Release Timing Test Summary o  Measure the stationary gripper release time for each control and shutdown rod. This measurement was performed in Mode 5 and then repeated in Mode 3.

 

5.6 Rod Drop Time Measurement and Stationary Gripper Release Timing (2-PAT-3.8) (continued)

                      . Evaluate the data from rod drop time testing in the area of the dash pot entry looking for proper performance of the decelerating devices (i.e. dashpots). This evaluation was performed in Mode 3 with the data collected during the performance of 2-Sl-85-10, Rod Drop Time Measurement Using CERPI Rod Drop Test Computer.

                      . Evaluate all 57 rod drop times in Mode 3 with the data collected during the performance of 2-SI-85-10, Rod Drop Time Measurement Using CERPI Rod Drop Test Computer.

1.5    Ensure that four rod drops were performed in Mode 3 as required by corrective actions from Condition Repoft234483 action 003 related to INPO SER 1-10.

2.0  Test Methods This PAT was written to supplement the norma! operating surveillance 2-Sl-85-10, Rod Drop Time Measurement Using CERPI Rod Drop Test Computer and evaluated the rod drop time data.

All rod drop times were used to calculate the standard deviation of the rod drop times. Two-sigma limits (i.e. plus or minus two times the standard deviation) were used to evaluate drop times of the 57 rods. Those drop times that were outside of the two-sigma limits were re-measured 3 (or more) times and evaluated for consistency (i.e. within 50 milliseconds).

Retesting the rods that fell outside of the two-sigma limits an additional 3 (or more) times provided reasonable assurance of their proper performance during subsequent plant operations.

This PAT measured the Stationary Gripper Release Time for each control and shutdown rod. The Stationary Gripper Release Time is a combination of a Trip Signal Delay Time (i.e. Delay between Reactor Trip Breaker opening and the trip signal to the RDTC) and the delay between power interruption (i.e. trip signal to the RDTC) and the rod's initiation of its free fal!. The PAT evaluated the traces from the RDTC looking for a delay of each rod's initiation of free fall the RDTC's trip signal. The PAT also measured the "Trip Signal Delay Time" while in Mode 5.

This PAT also evaluated the traces from the rod drops in the area of the decelerating devices (i.e. dash pots) entry looking for proper performance of the dash pots.

12

 

5.6 Rod Drop Time Measurement and Stationary Gripper Release Timing (2-PAT-3.8) (conti nued) 3.0   Test Results AllAcceptance/Review Criteria were met or resolved as delineated below.

Acceotance Criteria 3.1     Each CRDM unlatches upon opening the Reactor Trip Breakers.

Testing confirmed that each CRDM unlatched upon opening the Reactor Trip Breakers in Mode 5 and Mode 3.

3.2   The rod drop times for all shutdown and control rods, dropped from the fully withdrawn position, are within the limits specified in the Techn ical Specifi cations.