NRC Inspection of the Licensee'S Implementation of Industry Initiative Associated with the Open Phase Condition Design... - Inspection Report Nos 05000528/2018010, 05000529/2018010, and 05000530/2018010

ML18103A157
Person / Time
Site:	Palo Verde
Issue date:	04/13/2018
From:	Greg Werner NRC/RGN-IV/DRS/EB-2
To:	Bement R Arizona Public Service Co
Werner G
References
IR 2018010
Download: ML18103A157 (38)
v • d • e

Text

April 13, 2018 Mr. Robert Executive Vice President Nuclear/

Chief Nuclear Officer Arizona Public Service Company P.O. Box 52034, MS 7602 Phoenix, AZ 85072-2034 SUBJECT: PALO VERDE NUCLEAR GENERATING STATION - NRC INSPECTION OF THE LICENSEES IMPLEMENTATION OF INDUSTRY INITIATIVE ASSOCIATED WITH THE OPEN PHASE CONDITION DESIGN VULNERABILITIES IN ELECTRIC POWER SYSTEMS - INSPECTION REPORT 05000528/2018010, 05000529/2018010, AND 05000530/2018010

Dear Mr. Bement:

On March 22, 2018, the U.S. Nuclear Regulatory Commission (NRC) completed an inspection at the Palo Verde Nuclear Generating Station. On March 22, 2018, the inspectors discussed the results of this inspection with Ms. M. Lacal, Senior Vice President Regulatory and Oversight, and other members of your staff. The results of this inspection are documented in the enclosed report.

The NRC inspectors did not identify any findings or violations of more than minor significance.

This letter, its enclosure, and your response (if any) will be made available for public inspection and copying at http://www.nrc.gov/reading-rm/adams.html, and at the NRC Public Document Room in accordance with 10 CFR 2.390, Public Inspections, Exemptions, Requests for Withholding.

Sincerely,

/RA James Drake Acting for/

Gregory E. Werner, Chief Engineering Branch 2 Division of Reactor Safety Docket Nos. 50-528, 50-529, and 50-530 License Nos. NPF-41, NPF-51, and NPF-74 Enclosure:

Inspection Report 05000528/2018010, 05000529/2018010, and 05000530/2018010 w/ Attachments: 1. Table 1 - Information Gathered for TI 2515/194 2. TI 2515/194 Inspection Documentation Request

U.S. NUCLEAR REGULATORY COMMISSION

Inspection Report

Docket Number(s): 05000528, 05000529, 05000530 License Number(s): NPF-41, NPF-51, NPF-74 Report Number(s): 05000528/2018010, 05000529/2018010, and 05000530/2018010 Enterprise Identifier: I-2018-010-0018 Licensee: Arizona Public Service Company Facility: Palo Verde Nuclear Generating Station Location: Tonopah, Arizona Inspection Dates: March 19, 2018, to March 22, 2018 Inspectors: S. Graves, Team Lead, Senior Reactor Inspector, Region IV B. Correll, Reactor Inspector, Region IV Accompanying K. Nguyen, Electrical Engineer, NRR/DE/EEOB Personnel: I. Kafeez, Reactor Inspector, Region III/DRS/EB3 H. Kodali, Electrical Engineer, NRR/DE/EEOB J. Quichocho, Chief, NRR/DE/EEOB Approved By: G. Werner, Branch Chief, Engineering Branch 2 Enclosure

SUMMARY

The U.S. Nuclear Regulatory Commission (NRC) continued monitoring licensees performance by conducting Temporary Instruction 2515/194, Inspection of the Licensees Implementation of Industry Initiative Associated with the Open Phase Condition Design Vulnerabilities in Electric Power Systems (NRC Bulletin 2012-01), at Palo Verde Nuclear Generating Station, in accordance with the Reactor Oversight Process. The Reactor Oversight Process is the Nuclear Regulatory Commission program for overseeing the safe operation of commercial nuclear power reactors. Refer to https://www.nrc.gov/reactors/operating/oversight.html for more information.

List of Findings and Violations None.

Additional Tracking Items None.

INSPECTION SCOPE

This inspection was conducted using Temporary Instruction 2515/194 (ADAMS Accession No. ML17137A416), dated October 31, 2017. The inspectors reviewed the licensees implementation of Nuclear Energy Institute Voluntary Industry Initiative in compliance with Commission guidance. The team discussed the licensees open phase condition system design and ongoing implementation plans with plant staff and vendor staff. The team reviewed licensee and vendor documentation, and performed system walkdowns to verify that the installed equipment was supported by the design documentation. The team verified that the licensee had completed the installation and testing of equipment (with the exception of the tripping functions), installed and tested alarming circuits both local and in the control room, and analyzed potential impacts associated with the design implementation on the current licensing basis.

OTHER ACTIVITIES

- TEMPORARY INSTRUCTIONS, INFREQUENT AND ABNORMAL Temporary Instruction 2515/194 - Inspection of the Licensees Implementation of Industry Initiative Associated with the Open Phase Condition Design Vulnerabilities in Electric Power Systems (NRC BULLETIN 2012-01)

The objective of Temporary Instruction 2515/194, is to verify that licensees have appropriately implemented the Nuclear Energy Institute Voluntary Industry Initiative including updating their licensing basis to reflect the need to protect against open phase conditions, and to gather the information necessary for Office of Nuclear Reactor Regulation staff to determine whether the licensees have adequately addressed potential open phase conditions.

Temporary Instruction 2515/194-03.01 - Voluntary Industry Initiative (Part 1)

Palo Verde Nuclear Generating Station selected the open phase detection system designed and manufactured by Power System Sentinel Technologies, LLC, as the design vendor for their open phase condition system. At the end of this inspection the power system sentinel technologies system was still in the monitoring mode of operation to facilitate continued data gathering of grid perturbations for evaluation of alarm and trip setpoints. The open phase condition equipment was installed on the startup transformers (SUTs) AE-NAN-X01, AE-NAN-X02, and AE-NAN-X03 which provide power to station busses, including the stations six engineered safety feature (ESF) busses. The licensee is scheduled to transition the power system sentinel technologies system to full implementation (tripping functions enabled) in December 2018. The licensee was preparing design modifications and associated documentation for this transition, however they were not available for review at the time of inspection.

Section 03.01 of the Temporary Instruction required the determination of whether the licensee appropriately implemented the voluntary industry initiative, dated March 16, 2015 (ADAMS Accession No. ML15075A454), by verifying the following:

a. Detection, Alarms and General Criteria 1. Either open phase conditions are detected and alarmed in the control room, or

(a) The licensee has demonstrated that open phase conditions do not prevent the functioning of important-to-safety systems, structures, and components,

(b) Open phase condition detection will occur within a reasonably short period of time (e.g., 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br />), and

(c) The licensee has established appropriate documentation regarding open phase condition detection and correction.

2. Either detection circuits are sensitive enough to identify an open phase condition for credited loading conditions (i.e., high and low loading), or if automatic detection may not be possible in very low or no loading conditions when offsite power transformers are in standby mode, automatic detection must happen as soon as loads are transferred to this standby source. Additionally, the licensee has established appropriate shiftly surveillance requirements to look for evidence of open phase conditions.

3. Open phase condition design/protective schemes minimize misoperation or spurious action in the range of voltage unbalance normally expected in the transmission system that could cause separation from an operable offsite power source.

Licensees have demonstrated that the actuation circuit design does not result in lower overall plant operation reliability.

4. New non-Class-1E circuits are not used to replace existing Class-1E circuits.

5. The Updated Final Safety Analysis Report (UFSAR) has been updated to discuss the design features and analyses related to the effects of, and protection for, any open phase condition design vulnerability.

b. Protective Actions 1. If the licensee determines there is no single credible failure that could cause an open phase condition, then verify that the licensee has developed and issued a full engineering evaluation to document the basis for open phase condition as a non-credited event. The Bruce Power and Forsmark operating experience must be considered as part of this analysis.

2. With open phase condition occurrence and no accident condition signal present, either an open phase condition does not adversely affect the function of important-to-safety system, structures, and components, or,

(a) Technical Specification Limiting Condition of Operations (LCOs) are maintained or the technical specification actions are met without entry into Technical Specification Limiting Condition of Operation 3.0.3 (or equivalent),and

(b) Important-to-safety equipment is not damaged by the open phase condition, and

(c) Shutdown safety is not compromised.

3. With open phase condition occurrence and an accident condition signal present, automatic detection and actuation will transfer loads required to mitigate postulated accidents to an alternate source and ensure that safety functions are preserved, as required by the current licensing bases, or the licensee has shown that all design basis accident acceptance criteria are met with the open phase condition, given other plant design features. Accident assumptions must include licensing provisions associated with single failures. Typically, licensing bases will not permit consideration of the open phase condition as the single failure since this failure is in a non-safety system.

4. Periodic tests, calibrations, setpoint verifications, or inspections (as applicable)have been established for any new protective features. The surveillance requirements have been added to the plant Technical Specifications if necessary to meet the provisions of 10 CFR 50.36.

Temporary Instruction 2515/194-03.02 - Information Gathering for Voluntary Industry Initiative Assessment (Part 2)

Section 03.02 of the Temporary Instruction required information gathering as part of the initial inspections to enable the Nuclear Reactor Regulation staff to determine whether the modifications implemented by the licensee of each unique open phase condition system design for the voluntary industry initiative adequately address potential open phase conditions. The information gathered for this section is tabulated in attachment, Table 1 - Information Gathered for TI 2515/194, to this report.

INSPECTION RESULTS

Based on interviews and discussions with the licensee and the vendor, review of available design, testing, grid data trending results documentation, and walkdowns of installed equipment, the team had reasonable assurance the licensee appropriately implemented, with noted exceptions discussed below, the voluntary industry initiative.

TI 2515/194-03.01 - Voluntary Industry Initiative (Part 1)a. Detection, Alarms and General Criteria

(1) The team determined by walkdowns and observation that open phase conditions will be detected and alarmed in the control room for each unit.

(2) The team determined that detection circuits were sensitive enough to identify an open phase condition for all credited loading conditions.

(3) No Class-1E circuits were replaced with non-Class 1E circuits in the design.

b. Protective Actions Criteria

(1) The team determined the licensee identified they were susceptible to an open phase condition and were implementing design changes to mitigate the effects.

(2) The team determined that with an open phase condition present and no accident condition signal, the power system sentinel technologies system would not adversely affect the function of important-to-safety systems, structures, and components. The licensees open phase condition design solution added a set of additional tripping inputs in parallel to the existing transformer isolation controls. This addition added a new tripping condition (open phase) to the electrical faults which result in loss of one preferred source of power to one train of ESF loads. The credited plant response would be the same regardless of the conditions that generated the isolation of the transformer.

No findings were identified, however the team identified the following exceptions to the Temporary Instruction criteria resulting from the incomplete design modifications:

c. Detection, Alarms and General Criteria Exceptions

(1) The licensees design was operating in the monitoring mode with vendor recommended setpoints enabled, to gather data to ensure the open phase condition design and protective schemes would minimize misoperation, or spurious actions in the range of voltage unbalance normally expected in the transmission system.

Because actual demonstration of this criterion requires the system to be in operation with final trip setpoints established, the team was not able to fully verify this criterion.

After discussions with licensee and vendor staff, design document and test results reviews, and historical monitoring date reviews, the team had reasonable assurance that the actuation circuit design would not result in lower overall plant operation reliability. The team did not identify any issues of concern.

(2) The Final Safety Analysis Report had not been updated to include information related to open phase conditions at the conclusion of the onsite inspection. The licensee provided and the team reviewed proposed changes to the licensing basis that discussed the design features and analyses related to the effects of, and protection for, any open phase condition design vulnerability. The team verified the proposed changes had been entered into the corrective action program as Condition Report CR NON 18-04437 to track the completion of the Updated Final Safety Analysis Report. The team did not identify any issues of concern.

d. Protective Actions Criteria Exceptions

(1) The licensees open phase condition design solution used the existing isolation and power scheme for safety-related accident loads; only a new tripping condition (open phase) had been added to the electrical faults which result in loss of one preferred source of power to one train of ESF loads. A loss of voltage, including a loss of voltage caused by isolation of the preferred source due to an open phase condition, on the affected ESF bus results in the affected train loading being automatically transferred to the onsite emergency power source, if available (single failure), or manually to a different SUT. While no changes to this configuration were planned due to the inclusion of the power system sentinel technologies system, actual demonstration of this criterion requires the system to be in full operation.

Through review of available design documents and discussions with plant and vendor staff, the team had reasonable assurance that with an open phase condition present and an accident condition signal, the power system sentinel technologies system automatic detection and actuation would isolate the affected transformer.

Due to the configuration of Palo Verde Nuclear Generating Stations electrical distribution system, a loss of a SUT would only affect one train of equipment, and loads required to mitigate postulated accidents would be available on the non-affected train ensuring that safety functions are preserved as required by the current licensing bases. The team did not identify any issues of concern.

(2) The licensee had not finalized documentation for periodic tests, calibrations, setpoint verifications, or inspection procedures for open phase condition-related components at the time of this inspection. The team held discussions with licensee and vendor staff and identified that the vendor guidance, including periodic tests, setpoint verification, and equipment maintenance and inspection would be integrated into plant procedures and processes.

The licensee had existing Condition Report CR-17-12228 which was written to establish maintenance strategies for the open phase protection equipment.

The licensee updated this condition report to develop additional strategies for the transformer neutral cables which are an integral part of the power system sentinel technologies system. The licensee created Condition Report CR-18-04542 to add additional inspection criteria to existing outside area operator log procedures for visual inspection of the transformer neutral cable, neutral bushing, and ground connection integrity. The team also held discussions about the licensees plans to include open phase condition-related components into the Maintenance Rule (10 CFR 50.65) program. The licensee generated Condition Report CR NON 18-04442 to create an enhancement action item which tracked the scoping process for inclusion into their maintenance rule program. Existing plant equipment will continue to be maintained according to the licensees current preventative maintenance program. The team did not identify any issues of concern.

EXIT MEETINGS AND DEBRIEFS

On March 22, 2018, the team presented the Temporary Instruction 2515/194 inspection results to Ms. M. Lacal, Senior Vice President Regulatory and Oversight, and other members of the licensee staff.

The inspectors verified no proprietary information was retained, however some material used by the team to document compliance was characterized as proprietary by the vendor.

DOCUMENTS REVIEWED

Inspection Procedure TI 2515/194

Condition Reports

18-04439

NON 18-04437*

18-04442*

NON 18-04542*

• Issued as a result of inspection activities.

Drawings Number Title Revision

A0-E-NAB-008 Elementary Diagram 13.8 kV Non-Class 1E Power 11

System Startup XFMR A-E-NAN-X03 Tripping

A0-E-NAB-008, Elementary Diagram 13.8 kV Non-Class 1E Power 11

Sheet 2 System Startup XFMR A-E-NAN-X03 Tripping

A0-E-NAB-009 Elementary Diagram 13.8 kV Non-Class 1E Power 10

System Startup XFMR A-E-NAN-X03 Tripping

A0-E-NAF-008, Elementary Diagram 13.8 kV Non-Class 1E Power 4

Sheet 1 of 4 System Startup XFMR A-E-NAN-X03 Tripping

A0-E-NAF-008, Control Wiring Diagram 13.8kV Non-Class 1E Power 4

Sheet 2 System Startup XFMR A-E-NAN-X03 Tripping

A0-E-NAF-008, Control Wiring Diagram 13.8kV Non-Class 1E Power 4

Sheet 4 System Startup XFMR A-E-NAN-X03 Tripping

13-E-MAA-001 Main Single Line Diagram 31

Engineering Change Title Date

Numbers

LDCR 15-F029/15- Updated Final Safety Analysis Report, Section 8.2.2 January 25,

B011 and Technical Specification Bases Section 3.8.1 and 2018

3.8.2

DCN: IEGR-DD-184 Open Phase Protection System Non-Class 1E Open March 20,

Draft Phase Protection Settings, Palo Verde Nuclear 2018

Generating Station Startup Transformers (SUTs) AE-

NAN-X01, AE-NAN-X02, and AE-NAN-X03

Engineering Study Title Revision

Number

13-ES-A060 Engineering Study for Open Phase Condition on the 0

High Side of SUT Transformer

Miscellaneous Title Revision/Date

Documents Number

NLR17R050100 NLR17R050100 Required Reading August 9,

2017

3002004432 Interim Report: Electric Power Research Institute October 2014

(EPRI) Open-Phase Detection Method

13-NA-00001 PSSTech - Critical Digital Review and Related 0

Software Quality Assurance Report documents

0002282 Service Bulletin: One Phase Protection System February 21,

Injection Source Upgrade 2017

2944 Service Bulletin: Phoenix Contact QUINT- January 23,

PS/1AC/24DC/10 - 2866763 Direct Current (DC) 2018

Power Supplies and Phoenix Contact QUINT-

PS/1AC/24DC/20 - 2866776 DC Power Supplies

NA-1635 Design Input Requirements Checklist - Install Loss of 0

Phase Detection On SUTs

Engineering Disposition for ENG-DMWO # 4411244 February 01,

2018

Presentation - Palo Verde Nuclear Generating

Station Open Phase Protection for Offsite Power

Sources

Modifications Title Revision

Number

S-15-0116 50.59 Screening for DMWO 4411244 0

DMWO 4411244 NA-1635 Open Phase Detection System 0

Procedures Number Title Revision

40AL-9RK1B Panel B01B Alarm Responses 4

40AL-9MA01 Transformer Trouble Alarm Responses 42C

Vendor Documents

Number Title Revision/Date

2015APS5714 One Phase Protection System Operating and 0.0.3

Maintenance Manual

E003-00162 PSSTech - Open Phase Detection System Factory 0

Acceptance Test Report (FAT)

Cabinet S/N 7E0668419 (AENANX01 - Channel 1)

SB 0002282 One Phase Protection System Injection Source February 21,

Upgrade 2017

SB 2944 2866763 DC Power Supplies and Phoenix Contact January 23,

2018

Table 1 - Information Gathered for TI 2515/194

A Open Phase Condition Describe Observations/Comments

Detection and Alarm

Scheme

Are all credited offsite power Yes Palo Verde Nuclear Generating Station (PVNGS)

sources specified in UFSAR No UFSAR Section 8.1 states that six offsite sources of

Chapters 8.1, 8.2, and 8.3 power provide preferred power to the three units

and plant Technical through secondary windings of three startup

Specifications considered in transformers (SUTs).

the design of open phase

condition detection and The Updated Final Safety Analysis Report,

protection schemes? Section 8.2 states that the transmission system

associated with PVNGS supplies offsite air

conditioning (AC) power at 525 kV for startup, normal

operation, and safe shutdown of Units 1, 2, and 3.

Both 525 kV transmission system, which is the

credited offsite power source, and the SUT described

in the UFSAR were considered in the design of open

phase condition detection and protection schemes.

Are Open Phase Condition Yes The Power System Sentinel Technologies open

detection scheme(s) No phase condition detection scheme monitors the SUT

installed to monitor the connections through the SUT high side wye winding

qualified offsite power paths neutral. The detection scheme does not monitor the

to the ESF buses during all offsite power paths from the low side of the SUT to

modes of operation? the ESF buses.

The impact of an open phase occurring between the

SUT and the ESF transformer is documented in

Engineering Study 13-ES-A061, Open Phase

Condition on the High side of ESF Transformer,

Revision 0. There are no modifications planned to

install separate open phase detection systems on the

low side of the SUTs.

a. What is the scope of open a. The open phase condition scope includes the

phase conditions following:

considered by the

licensee? * Phase 1 (DM 4411244 Revision 0) - Installation

of open phase detection system designed and

made by PSSTech to monitor the SUT

connections through the SUT transformer high

side wye winding neutral. The system provides

alarms in the control room.

• Phase 2 (DM 4411244 Revision 1) - activation

of the tripping logic

b. Did the licensee exclude Yes b. The Palo Verde Nuclear Generating Station open

certain open phase No phase condition detection scheme does not

conditions (e.g., high monitor the power paths from the low side of the

voltage or low voltage SUT to the ESF buses. The impact of an open

side of power phase occurring between the SUT and the ESF

transformers), operating transformer is documented in Engineering Study

and loading configurations 13-ES-A061, Revision 0, and summarized below.

in their analyses? If so,

identify the technical For the steady state operation during normal,

justifications for any shutdown, and loss-of-coolant accident (LOCA)

exclusion. modes, the open phase condition on high side of

the ESF transformer resulted in notable voltage

unbalance conditions that were detected and

isolated by existing degraded voltage relay and

loss of voltage relay scheme. Only one gap of

protection was identified for the existing degraded

voltage relay and loss of voltage relay scheme

occurring during normal operation where the

inverse time delay of the loss of voltage relay

would not trip prior to the start of the spray pond

pump motor due to exposure to damaging

overheat conditions. To address this gap, the loss

of voltage relay was modified to the fixed-voltage

and time delay characteristics. The minimum loss

of voltage relay dropout occurs at 3220V with time

delay of 2.3 seconds. The steady state normal,

shutdown, or LOCA operating conditions modeled

with consideration of maximum and minimum

switchyard voltage would now be isolated within

the 2.3 seconds time frame ensuring that no

damage or lock-out of the Class-1E loads occur.

The ESF transformers local connection between

ENANS03/ENANS04 switchgear and ESF

transformer ENBNX03/ENBNX04 has no

underhung insulator. This connection is an

overhead copper bare wire mounted from top of

ESF transformer to top of switchgear that is of a

very short distance with a pole in between for

support. The insulators mounted on top of

structure transformer, pole, or switchgear. The

insulators support a very short distance of

500 MCM (thousands of circular mils) stranded

bare copper overhead that is bolted twice on each

end. A break anywhere in the path between the

switchgear and the transformer would result in a

loose bare energy conductor failing onto a

grounded enclosure. This type of fault will

separate the affected offsite source and start the

emergency diesel generator (EDG) and transfer

the ESF loads to the EDG automatically.

Therefore, this would not be an open phase

condition. The overhead line between

ENANS06/ENANS05 and ENANS04/ENANS03 is

a double connection with two conductors/phase.

An insulator failure would have to break both

conductors that are bolted on each end. A single

conductor is sufficient to provide the capacity for

the ESF loads.

Based on the PVNGS system configuration, an

open phase condition on the high side of ESF

would affect a single train of one unit. For

example, the open phase condition on the high

side of ESF NBNX04 transformer would only affect

Unit 1 B train. The Unit 1 A train is not affected

and can be supplied from its normal offsite circuit

feed SUT AENANX03 Z winding, the Unit 1 A

train has alternate supply from AENANX01 Y

winding, and lastly the EDG for the A train. Palo

Verde Nuclear Generating Station is not

susceptible to common train open phase condition

event as such a postulated open phase condition

on Unit 1 B train and EDG failure on the A train

would still allow for two offsite circuit paths to

provide power to the Unit 1 A train. Therefore an

open phase condition would not affect both trains.

The licensee concluded that the requirement for a

separate system that monitors for open phase

condition on the plant side does not appear to be

justified. Additionally, detecting open phase

conditions on low voltage side is not part of the

industry initiative.

Are the detection schemes Yes The open phase detection system consists of an

capable to identify open No active neutral injection detection element and passive

phase conditions under all neutral overcurrent detection element. The licensee

operating electrical system indicated that combination of active and passive

configurations and plant detection elements provides 100 percent coverage for

loading conditions? grounded open phases and full range of loading

conditions.

Draft SA07.S.01.15, Open Phase Protection System

Non-Class 1E open phase detection Protection

Settings, Startup Transformers AE-NAN-X01,

AE-NAN-X02, AE-NAN-X03, dated March 20, 2018,

includes the electromagnetic transients program

simulation results for the following open phase

conditions. All simulated conditions were detected

either by active or passive detection element.

- Single Open Phase Ungrounded - SUT unloaded

- Double Open Phase Ungrounded - SUT

unloaded

- Double Open Phase with 0 ground on one

phase - SUT unloaded

- Single Open Phase with 0 ground - SUT

unloaded

- Double Open Phase with 0 ground on both

open phases - SUT unloaded

- Single Open Phase Ungrounded - SUT loaded

with 70 MVA motor load

- Double Open Phase Ungrounded - SUT loaded

with 70 MVA motor load

- Single Open Phase with 8,000 ground - SUT

unloaded

- Single Open Phase with 25,000 ground - SUT

unloaded

- Double Open Phase with 4,000 ground on both

phases- SUT unloaded

- Double Open Phase with 12,500 ground on

both phases - SUT unloaded

- Single Open Phase Ungrounded - SUT loaded

with 13 MVA motor load

- Single Open Phase Ungrounded - SUT loaded

with 20 MVA motor load

- Double Open Phase Ungrounded - SUT loaded

with 8 MVA motor load

- Double Open Phase Ungrounded - SUT loaded

with 70 MVA motor load

The above electromagnetic transients program

simulations were performed as the test cases to verify

the open phase condition detection with the open

phase detection algorithm.

a. If the licensee determined Yes a. Palo Verde Nuclear Generating Station has

that open phase condition No determined that open phase condition detection

detection and alarm and alarm scheme is needed. The PSSTech open

scheme was not needed, phase detection system will detect open phase

did the licensee provide conditions and generate alarms in Main Control

adequate calculational Room (MCR).

bases or test data?

b. Are all open phase Yes b. Engineering Study 13-ES-A060, Open Phase

conditions detected and No Condition on the High side of SUT transformer,

alarmed in the MCR with Revision 0, shows that a single open phase

the existing relays? occurring on the high side of the SUT connections

would be undetected by the existing relays. The

study concluded that there is a need for a separate

open phase detection system. To address this

condition, Modification DMWO 4411244 installed

PSSTech open phase detection system to detect

and alarm in MCR.

a. Are the detection and Yes a. The wiring of the alarm circuit is separate and

alarm circuits independent No independent of the actuation circuit.

of actuation (protection)

circuits? The MCR alarm wiring circuit ends at the PSSTech

open phase detection cabinet alarm lock-out relay

for each channel. The alarm wiring is parallel to

initiate the MCR SUT common trouble alarm

window. The alarm will also trigger a computer

point to signify that an open phase condition has

been detected.

The trip wiring uses a separate wire that is looped

between the PSSTech open phase detection

cabinet trip lock-out relay contacts and existing

transformer lock-out relays. After the trip is

enabled, tripping of the exiting transformer lock-out

relays will also illuminate an existing MCR alarm

SUT protection trip.

b. If the detection, alarm, Yes b. The detection alarm and actuation circuits are non-

and actuation circuits are No Class-1E (non-safety). The non-safety protection

non-Class 1E, was there scheme has no interface with Class-1E circuits.

any interface with Class The trip output is wired to existing SUT tripping

1E systems? circuitry, which is also non-safety. In addition, the

alarm is wired to existing transformer trouble alarm,

which is also non-safety.

When the open phase detection system detects an

open phase, it will isolate the affected SUT. This

removes power from a single safety-related train in

the unit that is connected to each secondary

winding of the affected SUT. The safety-related

train then mitigates the loss of power (LOP) per the

existing design (transferring to onsite power).

There is no direct interface between the new open

phase detection system and existing safety-related

systems.

a. Did the manufacturer Yes a. The open phase detection system consists of an

provide any No active neutral injection detection element and

information/data for the passive neutral overcurrent detection element.

capability of installed

relays to detect The open phase detection system detects by either

conditions, such as a) detecting changes in zero sequence impedance

unbalanced voltage and as measured by the change in an active injection

current, negative current (the active detection element), or b) by

sequence current, detecting unbalanced current (i.e. zero sequence

subharmonic current, or current) as measured in the transformer neutral

other parameters used to (the passive detection element). The open phase

detect open phase detection system does not measure unbalanced

condition in the offsite voltage, negative sequence current, or

power system? subharmonic currents.

b. What are the analyses b. Engineering Study 13-ES-A061, Revision 0,

and criteria used by the describes the impact of the power system

licensee to identify the unbalance due to an open phase as below.

power system unbalance

due to open phase The open phase detection conditions on the high

conditions; and loading side of the ESF transformer results in voltage

and operating unbalance that exceeds the existing bus negative

configurations considered sequence alarms setpoint, which are set at

for all loading conditions 5 percent negative sequence. The resulting line-to-

which involve plant trip line 4.16 kV ESF bus voltages for open phase

followed by bus transfer condition on high side of the ESF transformer under

condition? no load condition, and nominal (525 kV) or

maximum switchyard voltage (535.5 kV) will fall just

outside of the degraded voltage relays and loss of

voltage relays detection capabilities. Specifically,

the high side open phase condition for unloaded

ESF transformer, resulted in line-to-line voltages of

3762V (Vab), 3762V (Vbc), 0V (Vac) respectively

on the ESF bus that are above the minimum

degraded voltage relay drop out of 3690

V.

However, the open phase condition with ESF

transformer unloaded results in the worst case for

calculated unbalance. Since the open phase

condition for unloaded ESF transformer triggers the

existing 5 percent negative sequence alarm,

operators would be dispatched to determine the

cause of the alarm. The ESF transformers are not

operated unloaded and the transformers normally

supply Class-1E loads that are energized during

normal operation including some non-1E loads that

are fed from a Class-1

E. Therefore, there is no

potential for the open phase condition to go

undetected and not recognized for an extended

period of time.

c. If certain conditions Yes c. According to the licensee, there are no open phase

cannot be detected, did No conditions that cannot be detected with the installed

the licensee document the N/A system. There are no conditions that would result

technical basis for its in spurious actuation of the system. The open

acceptability? phase condition detection scheme is designed

based on the following thresholds.

• Active detection setting - concurrence of

5th harmonic that must go up to 8 dB and excess

preset time delay. The required condition would

preclude spurious trip actuation.

• Passive detection setting - must be greater than

the neutral current resulting from maximum

allowable system voltage unbalance and excess

preset time delay.

There are no normal/abnormal plant conditions

that would defeat the open phase condition based

on the setpoints coordinating with existing relays

and transformer relays.

d. Did the licensee perform Yes d. Functional testing is documented in the factory

functional testing to No acceptance test, site acceptance test, and

validate limitations commissioning test which reflect the plant condition

specified by the and settings including the relay settings.

manufacturer of the

relays?

a. Do open phase condition Yes a. The PSSTech open phase detection system

detection circuit design No includes the following design features to minimize

features minimize spurious detections:

spurious detections due to

voltage perturbations * Digital signal controller implements both active

observed during events and passive detection schemes. The

which are normally PSSTech active detection element is primarily

expected in the intended for the no-load/light-load condition

transmission system? where the neutral current may not be

detectable by the passive detection.

• The active detection algorithm implements a

truth table based on the injection current,

5th harmonic of the neutral current, and the

injection voltage inputs. The active detection

element requires a combination of parameters

to be true before actuating a trip. The active

injection signal level must fall below its setpoint

concurrent with the 5th harmonic signal level

rising above its setpoint and the injection

voltage level must be within its allowable

voltage level band. All three of these

conditions must be met concurrently before the

active detection element actuates.

Additionally, the active detection element is

continually monitored for normal conditions

pertaining to the active injection signal level,

5th harmonic signal level, and injection voltage

level. If the active detection element goes

abnormal, actuation is blocked until the

element returns to normal.

• Time delay is selected above the passive

detection timer for coordination.

• Passive neutral overcurrent (50N) detection is

used when there is higher load on transformer

or when the open phase has a ground.

• The passive detection is based on current

magnitude.

• The detection element is an instantaneous

overcurrent element.

• The instantaneous element is supervised by a

definite-time timing function.

• Time delay selected to coordinate with high

side and low side transformer ground fault

clearing.

According to the licensee, to date, no spurious trips

have been noted in the monitoring period.

b. Identify whether the b. The licensee considered alarm/trip settings

licensee considered coordination with other electric power system

alarm/trip settings relays including transmission system protection

coordination with other features setup to avoid false indications

electric power system or unnecessary alarms. According to

relays including Draft SA07.S.01.15, the open phase detection

transmission system system active and passive detection elements

protection features setup must coordinate with existing relaying on the

to avoid false indications primary and secondary of the SUT, as well as

or unnecessary alarms.

other open phase detection systems on adjacent

or parallel SUTs. The open phase detection

system time delay setting is used to provide

coordination with existing relaying. The setting

coordination includes:

• Passive Protection Setting

The passive detection element pickup (50N)

will coordinate with:

- Maximum neutral current resulting from

system voltage unbalance.

- Maximum neutral current resulting from

open phase condition on adjacent SUTs.

- Maximum neutral current resulting from

low-side ground fault.

The passive detection element timer (50NDT)

will coordinate with:

- Trip time for existing relaying for high-side

ground fault

- Trip time for existing relaying for low-side

ground fault

- Transformer damage curve for grounded

open phase on high side

- Existing relaying for the main transformer

- the main transformer protection will pick

up instantaneously and will clear the

faulted main transformer before the open

phase detection system operates on any

of the protected transformers.

- Motor damage - will be set to limit motor

damages based on the overcurrent trip

setting of High Pressure Safety Injection

(HPSI) pump motor setting.

• Active Protection Setting

The active detection element will coordinate

with:

- Switching configurations - Coordinated

with 50ND relay to provide 100 percent

coverage during all fault conditions.

The active detection element timer will

coordinate with:

- The passive detection element timer - will

be greater than the passive detection

element timer setting.

- Transmission Zone 2 protection

Identify how the alarm The open phase detection digital controller initiates

features provided in the both the alarm and tripping circuit signals. The alarm

MCR including setpoints are signal is routed to the MCR alarm window while the

maintained, calibrated, and tripping signal will be tied to the existing transformer

controlled. tripping circuit. The controller output will start

external hardware timers, either the open phase

detection or neutral current detection (50NDT). Once

the timeout of the open phase detection or the 50NDT

occurs, the MCR will receive an alarm.

According to PSSTech, the detection algorithm does

not require calibration unless it is determined through

monitoring period that it misoperated for undesired

conditions.

The manufacturer (National Instruments)

recommends that the NI 9229 analog input module

and NI 9263 analog output module be calibrated

periodically. These modules can be swapped out

with the transformer in service in order to facilitate

calibration; however, open phase protection will be

unavailable while the modules are being swapped.

No other controller components require periodic

calibration.

Palo Verde Nuclear Generating Station is developing

the overall calibration and maintenance strategy as

part of the phase 2 of the modification. This activity is

still in progress.

The open phase condition detection settings are

maintained and controlled by the plant configuration

management and by the relay setting sheets (RSSs).

The approved RSSs at PVNGS are used by

protective relaying group to make setpoint changes.

The final settings for the open phase detection will be

documented on the RSSs.

After the modification is closed out, changes to the

setpoint will require the PVNGS design change

process to be followed. This process used to make

changes to controlled documents such as RSSs.

Does the open phase Yes The digital control system supply power is converted

condition detection scheme No to DC inside the system cabinet. The supply power

consider subharmonics in harmonics will have no impact.

the supply power or offsite

power system? Current readings are digitally filtered to only respond

to the 60Hz current, 5th harmonic current, and the

frequency of the injected current (approx. 90Hz).

Offsite power system subharmonics have no impact

to the open phase detection system.

Are open phase condition Yes System will be scoped into the maintenance rule.

detection and alarm circuit No The licensee generated a Condition Report

components scoped into the CR-18-04442 to track the implementation.

licensees maintenance rule

program?

B Open Phase Condition Yes/No Describe Observations/Comments

Protection scheme

Record location of the Location: The sensing occurs on the neutral of the

sensing of the protection primary winding that is wye-grounded, on the SU

T.

scheme (e.g., high voltage

or low voltage side of the

transformer, ESF bus, etc.)

Classification: Safety / Non-Safety (circle one)

a. Record the classification a. Non-Safety. The non-safety protection scheme has

of the protection scheme, no interface with Class-1E circuits. The trip output

safety or non-safety. is wired to existing SUT tripping circuitry, which is

also non-safety. In addition, the alarm is wired to

existing transformer trouble alarm, which is also

non-safety.

b. Did the licensee consider Yes b. When the open phase detection system detects an

the interface requirements No open phase, it will isolate the SUT. This removes

for non-safety with safety- power from a single safety-related train in the unit

related circuits? that is connected to each secondary winding of the

affected SUT. The safety-related train then reacts

to the LOP per the existing design (transfers to

onsite power). There is no direct interface between

the new open phase detection system and existing

safety-related systems.

Type: Digital / Non-Digital (circle one)

a. Record the type of the a. Digital

protection scheme, digital

or non-digital.

b. Are cyber security Yes b. Cyber security initial review was conducted by the

requirements specified for No licensee on the new installed cabinets. The

digital detection scheme? N/A equipment has physical protection as they are

installed in a controlled area (i.e., startup yard) and

locked. Key has to be obtained to open the

cabinet.

System has no Wi-Fi capability. System has a

keypad which is used to access the system locally.

The keypad provides three levels of access to the

digital controller. Levels 0 and 1 provide read-only

to monitor parameters while level 2 is used to

change the system monitoring setpoints, and is

restricted with a programmable 4-digit alpha

numeric code entry prior to access.

Also, accessing to level 2 will initiate system alarm

to alert any potential changes to the system

setpoints.

In addition, all open USB ports are blocked as

required per Specification 13-JN-1022, Cyber

Security Installation Specification.

Did the licensee consider Yes The PSSTech open phase detection system includes

any design features to No the following design features to prevent the system

prevent protective functional failures:

failures for open phase

condition protection system? * Redundancy:

- Two redundant open phase detection channels

are provided for each SUT.

- Redundant Primary (DC) and Backup (AC)

power sources are provided for each open

phase detection cabinet.

• Independence:

- The primary power source for each open phase

detection cabinet is from a different 125VDC

source. The DC source is provided by the

existing station non-class 1E batteries. Each

open phase detection channels 125VDC

source is independent of other channels. The

system also has a 120VAC backup source.

The AC source is from different AC power

panels that are also on different bus line-ups.

Each open phase detection channels 125VAC

source is independent of other channel.

- Within a single channel, different injection

source Current Transformers (CTs) are used for

measuring the current probes. The active

detection element uses a low current probe and

the passive detection element uses a different

high current probe. The sensors are

independent.

- The wiring of the alarm circuit is separate and

independent of the actuation circuit.

• Diversity:

- The main controller that houses the detection

algorithm is diverse between the redundant

open phase detection channels. Channel 1 has

cRIO 9068 controller, which is a non-Intel based

processor and utilizes Linux Real-Time.

Channel 2 has cRIO 9081 - Intel based

processor utilizes Windows Embedded

Standard 7 Runtime Operating System.

- DC (primary) and AC (backup) power sources

are provided for each open phase detection

cabinet.

• Monitoring, Alerting, and Self-Diagnostic:

- The main controller monitors and detects

abnormal conditions and provides alarms of

input failures. There is one condition

considered normal and one condition

considered as a valid open phase. If any input

fails high or low the system will provide an

injection abnormal alarm. The single channel

failure modes and effects analysis postulates

such failure, and shows the system would

provide abnormal alarm.

- The channel 1 and channel 2 general alarms

are wired in series and initiate the SUT common

trouble alarm window in the MCR. The alarm

will also trigger a computer point that is different

from the open phase condition computer point

to alert operator of cabinet trouble/failure.

Since the general alarms include alarms other

than those important to functionality, the

specific alarm would be identified locally at the

cabinet.

- The open phase detection system employed a

self-diagnostic feature to alert the channel

failures. Alert includes non-functional alarms

and channel general alarms. The following

alarms are functionally important.

Controller Watchdog Timeout

Injection Source Failure

Channel Injection Abnormal

Cabinet Temperature or Heating, ventilation,

and air conditioning Compressor

Malfunction Alarm

Channel Function Switch in OFF Position

Open Phase Alarm Lockout Relay Actuation

Inverter Failure Alarm

Identify the number of Modification DM 4411244 installed two redundant

channels provided per open phase detection channels per SUT to monitor

offsite power source, and if SUT connections through the SUT transformer high

there is independence side neutral. These channels are independent of

between channels and each other. Each channel has its own CTs for

sensors. sensing the neutral current.

a. What is the safety a. Power supply to each open phase detection

classification of power channel is non-safety. If the protection scheme of a

supply for the protection single channel losses power, the channel will fail in

scheme? a non-tripped state. The failed channel initiates a

non-functional alarm and a channel general alarm.

Both open phase alarm and trip lockout relays are

blocked. The failure modes and effects analysis

considered bounding conditions such as loss of

24VDC supply breaker to the main controller and

SEL-2411.

b. Was a LOP to the Yes b. Loss of power to the channel protection scheme

protection scheme No results in the following:

considered?

• Shutdown of all DC powered devices

• Channel Functional green LED extinguishes

• Channel Non-functional alarm relay

de-energizes and alerts operator

• SEL2411 alarm relay de-energizes and alerts

operator

The wiring of the non-functional alarm and

SEL-2411 alarm are wired in series and opening of

either contact would initiate the MCR SUT common

trouble alarm window. This is a potential failure of

the channel considered as shown in the PSSTech

single channel failure modes and effects analysis.

However, each of redundant open phase detection

cabinets powered is by the redundant,

independent, and diverse power sources (AC and

DC). For each SUT the primary power source for

the open phase detection cabinets are from

different 125VDC sources. Similarly, the backup

power source are from different AC power panels

that are on different bus line-ups.

Upon a loss of primary power to an open phase

detection channel, the dedicated inverter for that

channel will transfer the power to the backup power

source. The inverter sends an alarm to the MCR

for LOP or failure to transfer.

Identify if the licensee Malfunctions and failures were considered. For a

considered the failure or a malfunction of either channel, the MCR

consequences of a failure or will receive an alarm. However, both channels of the

malfunction of a channel. open phase detection system for each SUT have to

send a trip signal to make up the 2-out-of-2 tripping

logic.

• Failure:

A failure is defined as the inability of the trip signal

to function on a valid open phase. There are

numerous internal diagnostics, when a problem is

detected, an alarm signal is sent to the MCR and

the trip function is disabled. The consequence is

that the trip is disabled until the cause of the

alarm is identified and corrected. However, the

tripping logic can be changed to 1-out-of-1 logic

scheme to allow the unaffected channel to initiate

trip. Alternate compensatory measures can also

be established.

• Malfunction:

A malfunction is defined as the generation of a trip

signal with no valid open phase. When this

occurs, only one of two required trip signals would

be present. It will cause an alarm in the MCR but

will not cause the SUT to be isolated. If a valid

open phase were to occur, the remaining channel

would complete the 2-out-of-2 logic and isolate the

SU

T.

Did the design consider the Yes Based on the plant configuration, the redundant trains

single failure criteria as No for each unit at PVNGS are on different SUTs and

outlined in the general connection to the offsite sources.

design criteria or the

principle design criteria An open phase condition on the high side of any

specified in the Updated single SUT would affect a single train of two different

Final Safety Analysis units. For example, an open phase condition on the

Report? high side of SUT AENANX02 would affect Unit 1 B

train from the Y secondary winding and Unit 3 A

train from the Z secondary winding. The unit 1 A

train is not affected and can be supplied from its

normal offsite circuit feed, SUT AENANX03Z winding,

alternate offsite circuit supply from AENANX01 Y

winding, and lastly the EDG for the A train.

Therefore, an open phase condition on high side of

any single SUT would not affect both trains

simultaneously.

In addition, each phase connected to the high voltage

side of the SUT has two conductors coupled with the

design features such as redundancy (two open phase

detection channels per SUT and multiple power

sources), independence, diversity (different controller

types), and scoping the system into the maintenance

rule will ensure availability of the open phase

detection system.

The open phase detection system is a non-safety

related system and the loss of a single SUT due to

open phase condition would not preclude the onsite

electrical power system from being able to perform its

safety function. A loss of a SUT would only affect

one train of equipment and loads required to mitigate

postulated accidents would be available on the non-

affected train ensuring that safety functions are

preserved as required by the current licensing bases.

a. Did the licensee identify Yes a. N/A for PVNGS. An open phase event is a single

the industry standards No train issue at PVNG

S. Accordance to the licensee,

and criteria to verify N/A

power quality issues there is no open phase condition event that affects

caused by open phase redundant ESF buses.

conditions that affect

redundant ESF buses?

b. What industry standards b. The Electric Power Research Institute Condition

were used to develop the Report CR-03002010688 concluded that the stator

acceptance criteria for current in an induction motor never exceeds the

open phase condition trip locked-rotor current for all voltage unbalance

setpoint or analytical conditions examined. Therefore, it would be a

limit? conservative estimate to use the locked-rotor

thermal limit to determine the exposure time for

motors to unbalanced conditions. Since the

4.16 kV motors over-current relaying have been

coordinated with the safe stall times per

Class-1E protection calculations 01-EC-PB-0200,

2-EC-PB-0200, and 03-EC-PB-0200, the

overcurrent would always trip prior to motor

damage. (Based on ANSI C37.96-1988: Guide for

AC Motor Protection)

What are the analytical limits A concurrent open phase condition and safety

or criteria used for setpoints injection actuations Signal (SIAS) event is assumed

of the actuation/protection to be the worst case event. The SIAS condition

scheme to provide adequate would initiate the start of the HPSI pump motor.

protection for motors and Assuming the HPSI motor stalls due to the open

sensitive equipment? phase condition event, an overcurrent trip of

5.6 seconds for rated locked rotor and settings for

HPSI A (1MSIAP02) and 5.1 seconds based on

overcurrent setting of HPSI B (1MSIBP02) would

occur. The open phase detection system will be

installed with the tripping time of ~4.5 seconds or less

to provide for coordination with the HPSI motor. This

would provide at least a 0.5 second margin between

open phase detection system trip and HPSI motor

overcurrent trip.

The 4.5 second time delay will also provide sufficient

time to allow for transmission system clearing of

faults, and for existing transformer high side and low

side clearing.

The HPSI motor has the second fastest trip time,

relative to stall conditions. The electronically

commutated motor is the most limiting and the

overcurrent protection will trip in ~3.3 seconds under

stall conditions. However, this motor is energized

later in the sequence, at 25 seconds; the open phase

detection system would have isolated the affected

transformer well before this time. Therefore, it is not

considered in selection of the open phase detection

trip time to meet the requirement of the industry

initiative.

In addition, the PSSTech protection scheme will

detect and trip from no load to full load levels, and

varying ground fault impedance. Combination of

active and passive detection provides 100 percent

coverage for all loading levels.

The time delay ensures no equipment damage

occurs.

- The passive trip is set to 4.5 seconds.

- The active trip is set to 5 seconds.

The time delays were set to coordinate with existing

transformer high side and low side ground relaying.

What are the design The open phase detection system includes the

features provided to following design features to preclude spurious trips of

preclude spurious trips of the offsite power source:

the offsite power source

(e.g. coincidence logic)? * The active detection element requires a

combination of parameters to be true before

actuating a trip. The active injection signal level

must fall below its setpoint concurrent with the

5th harmonic signal level rising above its setpoint,

and the injection voltage level must be within its

allowable voltage level band. All three of these

conditions must be met concurrently before the

active detection element actuates. Additionally,

the active detection element is continually

monitored for normal conditions pertaining to the

active injection signal level, 5th harmonic signal

level, and injection voltage level. If the active

detection element goes abnormal, actuation is

blocked until the element returns to normal.

• The active detection element is supervised by an

external timer relay to prevent non-open phase

condition transients from initiating a trip output.

• The passive detection element only responds to

fundamental frequency (i.e. 60 Hz) current as

measured in the neutral of the transformer. The

passive detection element pickup is set to exclude

unbalanced currents associated with normal grid

imbalances.

• The passive detection element is supervised by an

external timer relay to prevent non-open phase

condition transients from initiating a trip output.

• The 2-channel system with 2-out-of-2 trip logic

where both channels have to send a trip signal to

isolate the SUT if an open phase condition is

detected.

• Loss of power to the open phase detection system

will not cause a spurious trip.

The combination of the design of the system and

requiring 2-out-of-2 trip logic will minimize spurious

trips.

a. What analyses have been a. Engineering Study 13-ES-A061, Revision 0,

performed by the licensee provides the analysis with respect to the impact of

which demonstrates that open phase condition to the function(s) of

the open phase conditions important-to-safety equipment required for safe

do not adversely affect shutdown during anticipated operational

the function(s) of occurrences, design basis events, and accidents.

important-to-safety Below is the summary of the analysis.

equipment required for

safe shutdown during The Electromagnetic Transients Program

anticipated operational simulation of steady state running conditions

occurrences, design basis during LOCA case with any postulated open phase

events, and accidents? If condition impedance resulted in ESF transformer

an analyses was not secondary voltage below loss of voltage relays,

performed, what and transferred the ESF loads to the EDG within

justification was provided? 2.3 seconds for both minimum and maximum grid

conditions. The electromagnetic transients

program simulations of double open phase

condition results in a complete collapse of the

secondary voltages and trip of loss of voltage

relays. Thus there is no vulnerability gap for

double open phase condition. The double open

phase condition is considered as a result of

operating experience from the Forsmark event.

The Electric Power Research Institute Condition

Report CR-03002010688, Induction Motor

Unbalanced Voltage, concluded that the stator

current in an induction motor never exceeds the

locked rotor current for all voltage unbalance

conditions examined. Therefore, it would be a

conservative estimate to use the locked-rotor

thermal limit to determine the exposure time for

motors to unbalanced conditions. Since the

4.16 kV motors over-current relaying have been

coordinated with the safe stall times per

Class-1E protection calculations 01-EC-PB-0200,

2-EC-PB-0200, and 03-EC-PB-0200, the

overcurrent would always trip prior to motor

damage.

If an open phase condition occurs exactly at the

same time as the SIAS, the 4.16 kV motors will

stall during initiated LOCA sequence and lock-out

on overcurrent protection. Under the existing

degraded voltage relays and loss of voltage relays

scheme the entire sequence of 4.16 kV motors

would trip and lock-out on overcurrent. Under the

modified degraded voltage relays and loss of

voltage relays scheme, the electromagnetic

transients program result showed that only the

HPSI pump motor would lock-out and trip when

considering the new degraded voltage relays and

loss of voltage relays scheme. The new degraded

voltage relays and loss of voltage relays scheme

reduced degraded voltage relay timeout delay for

SIAS conditions from maximum of 35 seconds to

8.5 seconds.

The overall risk of simultaneous occurrence of an

open phase condition and SIAS is small. The Palo

Verde Nuclear Generating Station internal

evaluation of risk from an open phase condition on

the high side of an ESF transformer was

determined negligible. The Palo Verde Nuclear

Generating Station internal risk-assessment

modeled the impact of simultaneous open phase

condition and a SIAS as unavailability of a single

class bus (PBAS03 or PBBS04), during and after

sequencing, which is conservative. The risk

incurred by a random open phase condition event

that results in an unrecoverable failure of a single

class bus is as follows:

Risk Metric Value

Delta CDF due to random open 2.5E-8/yr

phase condition

Delta LERF due to random open 4.35E-9/yr

phase condition

b. Are bus transfer schemes Yes b. An open phase condition at PVNGS is a single train

and associated time No event. If an open phase is detected, the affected

delays considered? SUT is isolated and the safety train connected to

the low voltage winding will detect a LOP and react

according to the existing design. This occurs within

the start time of the diesel, therefore the

assumptions of the accident analysis are not

affected. Bus transfer schemes do not apply. The

Class 1E busses are always connected to the SUT.

Are open phase condition Yes The open phase detection system will be scoped into

protection/actuation circuit No the maintenance rule program. The licensee initiated

components scoped, as Condition Report CR NON 18-04442 for tracking this

appropriate, into the implementation.

licensees maintenance rule

program?

C Updated Final Safety Yes Describe Observations/Comments:

Analysis Report Updates to No

Reflect the Need to Protect According to the licensee, Section 8.2.2 of the

Against Open Phase UFSAR appears to be an appropriate location to add

Conditions: Using items 1 to the open phase condition description as this section

below as examples, is intended to describe interfaces with the offsite

identify whether the licensee power grid and potential sources of outages. General

has updated the UFSAR discussion of the open phase detection system will be

(and supporting documents added to the UFSAR, Section 8.2.2. Condition

such as calculations of Report CR NON 18-04437 was generated to track the

record, design change implementation of LDCR 15-F029 in conjunction with

modifications, etc.) to Revision 1 of the modification package.

ensure plant-specific

licensing basis/requirements An open phase condition is not a new accident, so it

include discussions of the is does not need to be added to either Chapters 6 or

design features and 15 of the UFSA

R. The details of the system design,

analyses related to the including the failure modes and effects analysis which

effects of, and protection for, is part of the design modification package, will not be

any open phase condition included in the proposed UFSAR general description

design vulnerability. change. This is due to Regulatory Guide 1.70,

Revision 3, to which Arizona Public Service is

committed in UFSAR, Section 1.8, does not require a

description of design details.

The plant-specific analysis Palo Verde Nuclear Generating Station has verified

and documentation that by ETAP analysis that a single open phase occurring

established the resolution of on the high side of the SUTs would go undetected by

the open phase condition existing plant relaying. The resolution for the open

design vulnerability, phase conditions on the high side of the SUTs for

including the failure mode PVNGS is a design change DMWO 4411244 that

analysis performed. installed a 2 channel PSSTech open phase detection

system per SUT to detect, alarm in MCR, and isolate

the SUT upon an open phase condition is detected.

Reference: Engineering Study 13-ES-A060,

Revision 0.

The single channel failure modes and effects analysis

postulates failures and malfunctions, and shows the

open phase protection system end effects and failure

states. Reference: IEGR-AD-297, Open Phase

Protection System Single Channel System Failure

Modes and Effects Analysis.

Description of open phase The PSSTech open phase detection system consists

condition automatic of an active neutral injection detection element and

detection scheme, including passive neutral overcurrent detection element.

how offsite power system Combination of active and passive detection provides

open phase conditions are 100 percent coverage for grounded open phases and

detected from sensing to full range of loading conditions. For a single channel,

alarm devices (loss of one the alarm and tripping are based on or logic between

or two phases of the three the active detection and passive detection; i.e., 1-out-

phases of the offsite power of-2 logic. For each open phase detection system,

circuit both with and without the alarm and tripping are based on 2-out-of-2 logic.

a high-impedance ground

fault condition on the

high-voltage side of all

credited qualified offsite

power sources under all

loading and operating

configurations; and loss of

one or two phases of three

phases of switchyard

breakers that feed offsite

power circuits to

transformers without ground.

Detection circuit design See A.8

features to minimize

spurious indications for an

operable offsite power

source in the range of

voltage perturbations, such

as switching surges,

transformer inrush currents,

load or generation

variations, and lightning

strikes, normally expected in

the transmission system.

Alarm features provided in The ESF trains of a unit are aligned to different SUT

the MCR. Discuss the ESF windings. The new open phase detection system will

bus alignment during normal initiate a common SUT trouble alarm in MCR. New

plant operation and the computer points will be created that will distinguish

operating procedures in the open phase detection cabinet open phase alarm

place to address open and open phase detection system cabinet

phase conditions. If the failure/trouble alarm.

plant auxiliaries are supplied

from the main generator and The following are operating procedures that are in

the offsite power circuit to place to address open phase conditions:

the ESF bus is configured

as a standby power source, * The area rounds Procedure 40DP-9OPA9,

then open phase conditions Revision 14, has been revised to provide

should be alarmed in the instructions to verify working state of

MCR for operators to take SUT A-E-NAN-X03, Loss of Phase Detection

corrective action within a Cabinets.

reasonable time.

• The general transformer trouble alarm response

Procedure 40AL-9RK1B was revised to include the

new open phase detection cabinet alarms.

• The local alarm response Procedure 40AL-9MA01

was revised to provide guidance for operator

response to PSSTech system general alarms.

Describe the automatic The tripping logic is based on detecting changes in

protection scheme provided zero sequence impedance as measured by the

for open phase conditions change in an active injection current (the active

including applicable industry detection element), and by detecting unbalanced

standards used for current, i.e. zero sequence current, as measured in

designing the scheme. the transformer neutral (the passive detection

Design features to minimize element).

spurious actuations for an

operable offsite power The trip output is wired independently from the alarm

source in the range of circuit and is looped between the PSSTech open

voltage perturbations, such phase protection cabinet trip lock-out relay contacts

as switching surges, and SUT lock-out relays.

transformer inrush currents,

load or generation The system will be configured with 2-out-of-2

variations, and lightning tripping logic required from both open phase

strikes, normally expected in detection channel lock-out relays to trip the lock-out

the transmission system relays. Tripping of either lock-out relays will trip all

should be described. normal and alternate 13.8 kV breakers on the low

side and 525 kV breakers on the high side.

The open phase condition protection scheme has

been designed to the following standards:

• ANSI Stds C37 and C57

• IEEE C57.13

• EMI/RFI qualification EPRI 102323

• Surge withstand IEEE C62.45

• Electrostatic Discharge IEEE C63.16

• NEI 08-09, Revision 6

• IEEE 1012

Brief discussion of the Bus transfer schemes do not apply. The Class 1E

licensees analyses busses are always connected to the SUT.

performed for accident

condition concurrent open

phase conditions which

demonstrate that the

actuation scheme will

transfer ESF loads required

to mitigate postulated

accidents to an alternate

source consistent with

accident analyses

assumptions to ensure that

safety functions are

preserved, as required by

the licensing bases.

D Technical Specifications Describe Observations/Comments:

Surveillance Requirements

and LCO for Equipment

Used for Open Phase

Condition Mitigation

a. Are Technical Yes a. Palo Verde Nuclear Generating Station followed

Specifications No the suggested changes described in TSTF-556-T,

Surveillance Revision 0. The Technical Specifications Task

Requirements and LCO Force (TSTF) Evaluation was performed to support

for equipment used for the changing Technical Specification 3.8.1 and

mitigation of open phase Technical Specification 3.8.2 bases to address an

condition identified and open phase condition.

implemented consistent

with the operability The licensee generated Condition Report

requirements specified in CR NON 18-04439 to track the implementation

the plant Technical of LDCR 15-B011.

Specifications?

b. If the licensee determined Yes b. The Technical Specification Bases will be revised

that Technical No for surveillance requirement 3.8.1.1 to include

Specifications are verification of continuity of 3 phases to the SUTs.

unaffected because open plant surveillance procedures, will be modified to

phase condition is being reflect the operation of the system, and credit the

addressed by system as one means of confirming that the

licensee-controlled required offsite power circuits are operable, in that

programs, is the technical there is no indication of an open phase condition

justification adequate? (SR 3.8.1.1). No license amendment is required to

implement the modification.

Impacted procedures will be updated in the

modification process.

E Provide a brief summary The licensee answered No to all eight questions in the draft

of the Open Phase 10 CFR 50.59 evaluation. The 10 CFR 50.59 evaluation

Condition plant modification concludes that no NRC review is required. The evaluation is

performed under summarized below:

CFR 50.59.

The open phase detection system will isolate a SUT that has a

valid open phase condition detected. This will result in one

safety train from two different PVNGS units to register a LOP

and transfer the affected safety train to onsite power. The

design and testing of the open phase detection system are

sufficient to produce a reliable design such that there is not

more than a minimal increase in the likelihood of a malfunction

or spurious trip. The open phase detection system is

configured in a 2-out-of-2 logic scheme to prevent against

inadvertent trips. The open phase detection system for each

SUT is independent from the others. The open phase detection

system is designed such that no failure, such as a processor

failure, loss of AC or DC power, or failure of the injection source

will cause the open phase detection system to generate a trip

signal.

In case the open phase detection system is malfunction and

generates a spurious trip, the system isolates the SUT, causing

a single safety train in two separate units to transfer to onsite

power. In other words, the open phase detection system

activates a trip when offsite power is still available and

capable. This is an undesired event, challenges the onsite

power safety system, but has no real nor significant

consequence to the plant.

The open phase detection system can also be malfunction, in

such, there is an open phase on the high voltage side of the

SUT and the open phase detection system fails to isolate the

SUT concurrent with an ESF actuation signal, the offsite power

may not be capable of powering all of the safety-related loads

(on a single safety train in a unit) required to respond to the

ESF actuation signal. For this case to impact a unit, there has

to be simultaneously an open phase, a failure or malfunction of

the open phase detection system to operate, and there has to

be a concurrent ESF actuation signal demand. The probability

of all three events occurring simultaneously is relatively small.

TI 2515/194 Inspection Documentation Request

Please provide the following documentation (Items 1 - 6) to the lead inspector prior to the onsite

inspection date, preferably no later than March 5, 2018. Whenever practical, please provide

copies electronically (IMS/CERTREC is preferred). Please provide an index of the requested

documents which includes a brief description of the document and the numerical heading

associated with the request (i.e., where it can be found in the list of documents requested).

Sam Graves, Lead Inspector

RIV/DRS/EB2

1600 E. Lamar Blvd.

Arlington, TX 76011

817-200-1102

samuel.graves@nrc.gov

1. Copies of any calculations, analyses, and/or test reports performed to support the

implementation of your open phase condition solution. If, in your implementation, open

phase conditions are not detected and alarmed in the control room please include

documentation that: a) demonstrates the open phase condition will not prevent functioning

of important-to-safety system, structures, and components; and b) detection of an open

phase condition will occur within a short period of time (e.g., 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br />).

2. Copies of any modification packages, including 10 CFR 50.59 evaluations if performed,

used for or planned for the implementation of your open phase condition solution.

3. Copies of periodic maintenance, surveillance, setpoint calibration, and/or test procedures

implemented or planned, for your open phase condition solution.

4. Copies of your licensing basis changes to Updated Final Safety Analysis Report (UFSAR)

and/or Technical Specifications (TS), as applicable, which discuss the design features and

analyses related to the effects of, and protection for, any open phase condition design

vulnerability.

5. Copies of any procurement specifications and acceptance testing documents related to the

installation of your open phase condition solution.

6. Copies of any site training the team will need to accomplish to gain access to areas with, or

planned, major electrical equipment used in your open phase condition solution (i.e.

switchyard).

Please provide the following documentation to the team when they arrive onsite. Whenever

practical, please provide copies electronically, except for drawings. Drawings should be

provided as paper copies of sufficient size (ANSI C or D) such that all details are legible.

7. A brief presentation describing your electric power system design and typical electrical

transmission and distribution system alignments; open phase condition design schemes

installed to detect, alarm and actuate; bus transfer schemes; and maintenance and

surveillance requirements. This presentation should be a general overview of your system.

Please schedule the overview shortly after the entrance meeting.

8. Plant layout and equipment drawings for areas that identify: (a) the physical plant locations

of major electrical equipment used in your open phase condition solution; (b) the locations of

detection and indication equipment used in the open phase condition sensing circuits.

9. If open phase condition actuation circuits are required, provide documentation that

demonstrates continued coordination with the other protective devices in both the offsite

electrical system (within Palo Verde Nuclear Generating Station area of responsibility) and

the onsite electrical systems.

10. Access to locations in which open phase condition equipment is installed or planned (i.e.

switchyard, transformer yard, etc.)

11. Copies of documentation or testing that demonstrates your open phase condition solution

minimizes spurious actuation or misoperation in the range of voltage imbalance normally

expected in the transmission system that could cause undesired separation from an

operable offsite power source.

This document does not contain new or amended information collection requirements

subject to the Paperwork Reduction Act of 1995 (44 U.S.C. 3501 et seq.). Existing

information collection requirements were approved by the Office of Management and

Budget, Control Number 31500011. The NRC may not conduct or sponsor, and a person

is not required to respond to, a request for information or an information collection

requirement unless the requesting document displays a currently valid Office of

Management and Budget control number.

This document will be made available for public inspection and copying at

http://www.nrc.gov/reading-rm/adams.html and at the NRC Public document Room in

accordance with 10 CFR 2.390, Public Inspections, Exemptions, Requests for

Withholding.

ML18103A157

SUNSI Review Non-Sensitive Publicly Available Keyword:

By: STG Sensitive Non-Publicly Available NRC-002

OFFICE SRI:EB2 RI:EB2 C:EB2 C:PBD C:EB2

NAME SGraves BCorrell GWerner GMiller GWerner

SIGNATURE /RA/ /RA/ /RA JFD for/ /RA/ /RA JFD for/

DATE 04/07/18 04/11/18 04/11/18 04/13/18 04/13/18