Information Notice 2010-11, Potential for Steam Voiding Causing Residual Heat Removal System Inoperability

ML100640465 UNITED STATES

NUCLEAR REGULATORY COMMISSION

OFFICE OF NUCLEAR REACTOR REGULATION

OFFICE OF NEW REACTORS

WASHINGTON, DC 20555-0001

June 16, 2010

NRC INFORMATION NOTICE 2010-11:

POTENTIAL FOR STEAM VOIDING CAUSING

RESIDUAL HEAT REMOVAL SYSTEM

INOPERABILITY

ADDRESSEES

All holders of or applicants for an operating license or construction permit for a nuclear power

reactor issued under Title 10 of the Code of Federal Regulations (10 CFR) Part 50, Domestic

Licensing of Production and Utilization Facilities, except those that have permanently ceased

operations and have certified that fuel has been permanently removed from the reactor vessel.

All holders of or applicants for a standard design certification, standard design approval, manufacturing license, or combined license issued under 10 CFR Part 52, Licenses, Certifications, and Approvals for Nuclear Power Plants.

PURPOSE

The U.S. Nuclear Regulatory Commission (NRC) is issuing this information notice (IN) to inform

addressees of an issue at three pressurized-water reactor (PWR) plants where on multiple

occasions, their residual heat removal (RHR) systems were inoperable because of the potential

for steam voids at the RHR pump suction piping. Recipients should review the information for

applicability to their facilities and consider actions to avoid similar occurrences. The

suggestions contained in this IN are not NRC requirements, and no specific action or written

response is required.

DESCRIPTION OF CIRCUMSTANCES

In 2008 and 2009, the licensees at the Shearon Harris Nuclear Power Plant, Prairie Island

Nuclear Generating Plants, and Wolf Creek Generating Station discovered that their RHR

systems were potentially inoperable during shutdown periods because of elevated system

temperatures at the RHR pump suctions. The elevated system temperatures resulted from the

licensees lack of adequate procedures to ensure RHR system operability during all modes of

operation. At each of these plants, the fluid in the piping between the reactor coolant system

(RCS) hot leg to RHR system connection and the RHR minimum-flow line return connection

remained stagnant and at elevated temperatures following forced cooling as a result of

unrecognized system flow characteristics; namely, forced flow did not occur in that section of

pipe. Consequently, each licensee concluded incorrectly that the RHR system was properly

cooled, prior to shifting the RHR system to Emergency Core Cooling System (ECCS) injection

mode, when the system temperature was actually such that the affected RHR systems could

have incurred steam voiding if they had been used for emergency core cooling purposes. Additional information is available on the Wolf Creek Generating Station in the NRC Focused

Baseline Inspection Report 05000482/2009006, dated August 12, 2009; the Wolf Creek

Licensee Event Report (LER) 50-482/2008-008-02, dated August 25, 2009; the Shearon Harris

LER 50-400/2009-002, dated December 15, 2009; and the Prairie Island LER 50-282/2009-004, dated June 5, 2009. These documents can be found on the NRCs public Web site under

Agencywide Documents Access and Management System (ADAMS) Accession

Nos. ML092240087, ML092450426, ML093580024, and ML091560611, respectively.

BACKGROUND

Gas accumulation in ECCS is an enduring issue associated with commercial nuclear power

plant operations. To address this problem the NRC issued Generic Letter 2008-01, Managing

Gas Accumulation in Emergency Core Cooling, Decay Heat Removal, and Containment Spray

Systems (ADAMS Accession No. ML072910759). During system reviews in response to the

generic letter, several PWR licensees discovered the potential for their RHR systems to become

inoperable during certain shutdown cooling evolutions.

When an RHR train is used for cooling the reactor coolant system, the temperature of the water

in that RHR train can reach 350 degrees Fahrenheit (F) (Mode 4 upper temperature limit). With

the temperature of the water in the RHR train as high as 350 degrees F, if its suction source is

switched from the RCS hot leg to the refueling water storage tank (e.g., during ECCS operation

in response to a loss-of-coolant accident) or to the containment sump (e.g., during extended

response to a loss-of-coolant accident), conditions at the suction of the RHR pump would result

in steam voiding since the temperature at the RHR pump suction would exceed the saturation

temperature. Steam voiding can result in binding of an RHR pump and the refueling water

storage tank discharge check valve, system flow interruptions, and water hammer; potentially

inhibiting the capability of the RHR system to fulfill its ECCS function. Some PWR plants

occasionally use multiple RHR trains to perform plant cooldowns. In such cases, multiple RHR

trains can become simultaneously inoperable for emergency core cooling.

The pressure and temperature at the suction of the RHR pump depends on the RHR system

lineup and the as-built system configuration. For example, when the RHR system is aligned for

shutdown cooling, the RHR pump suction pressure is the same as RCS pressure; during safety

injection and containment sump recirculation operations, the pressure at the suction of an RHR

pump is equal to the static head pressure created by the refueling water storage tank and the

containment sump, respectively. In all system lineups, the as-built configuration also

determines the head loss associated with different system configurations. The range of

possible pump suction pressures makes the RHR system susceptible to steam voiding and

water hammer during system lineup changes with suction temperatures above certain values.

Since the pressure and corresponding saturation temperature at the suction of an RHR pump

depends on RHR system design and as-built configuration, it is important that each licensee

ensure that its particular RHR operating procedures are tailored to their specific systems and

include parameters validated as plant-specific to ensure RHR systems required by Technical

Specifications remain operable.

DISCUSSION

Industry operating experience and guidance has shown that effective methods of maintaining

RHR system temperature within appropriate limits exist. For example, licensees can isolate the

RHR system, or a single train of the RHR system, from the RCS at a low enough temperature

so that the fluid at the RHR pump suction remains below the saturation temperature

corresponding to the pressure at the suction of a running RHR pump.

Another method of maintaining RHR system temperature is forced cooling through the

minimum-flow line. The main function of the RHR minimum-flow line is to allow RHR pump

operation during a safety injection signal when RCS pressure is still above the pumps shutoff

head. A typical minimum-flow line flow path takes suction from the discharge of the RHR pump, after flow has passed through the RHR heat exchanger, and returns flow to the suction of the

RHR pump. Neglecting minor conduction heat transfer, the amount of RHR piping that can be

cooled through the minimum-flow recirculation method is dependent on the location of the

minimum-flow return connection. Specifically, the RHR pipe upstream of this connection would

not be cooled due to there being little to no flow through this section of pipe.

Some licensees incorrectly assumed that using the minimum-flow recirculation method of

cooling their RHR system was sufficient when, in fact, the as-built configuration of the plant did

not allow for complete RHR system cooldown using this method. For example, approximately

140 feet of Wolf Creeks RHR system piping is not subject to minimum-flow recirculation

because it is located upstream of the minimum-flow return connection. The stagnant water

inside this 140 foot section of RHR pipe can only cool through ambient losses; therefore, it

remains at elevated temperatures for extended periods of time, possibly exceeding 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br />.

Nevertheless, station procedures allowed the RHR system to be realigned to the ECCS injection

mode of operation under these conditions and resulted in both trains of the RHR system being

inoperable during periods of operation in Modes 3 and 4. Sharon Harris and Prairie Island

plants discovered a similar condition occurred in their plants with the length of affected pipe

being the primary variable.

Other licensees may be susceptible to a similar issue in that their plants may contain piping runs

that are not able to be effectively cooled using the forced cooling method; yet their station

procedures may allow them to shift the RHR system to ECCS injection mode during elevated

system temperatures.

Licensees should consider this operating experience to ensure that their RHR system

procedures address their plant specific configurations and that they provide adequate methods

for satisfying the plants RHR system operability requirements as stated in the plants Technical

Specifications.

CONTACT

This IN requires no specific action or written response. Please direct any questions about this

matter to the technical contacts listed below or the appropriate Office of Nuclear Reactor

Regulation (NRR) project manager.

/RA/

/RA by MShuaibi for/

Timothy McGinty, Director

Glenn Tracy, Director

Division of Policy and Rulemaking

Division of Construction Inspection and

Office of Nuclear Reactor Regulation

Operational Programs

Office of New Reactors

Technical Contacts: David Garmon, NRR

301-415-3512 E-mail: david.garmon-candelaria@nrc.gov

Warren Lyon, NRR

301-415-2897 E-mail: warren.lyon@nrc.gov

Note: NRC generic communications may be found on the NRC public Web site, http://www.nrc.gov, under Electronic Reading Room/Document Collections.

CONTACT

This IN requires no specific action or written response. Please direct any questions about this

matter to the technical contacts listed below or the appropriate Office of Nuclear Reactor

Regulation (NRR) project manager.

/RA/

/RA by MShuaibi for/

Timothy McGinty, Director

Glenn Tracy, Director

Division of Policy and Rulemaking

Division of Construction Inspection and

Office of Nuclear Reactor Regulation

Operational Programs

Office of New Reactors

Technical Contacts: David Garmon, NRR

301-415-3512 E-mail: David.Garmon-Candelaria@nrc.gov

Warren Lyon, NRR

301-415-2897

E-mail: Warren.Lyon@nrc.gov

Note: NRC generic communications may be found on the NRC public Web site, http://www.nrc.gov, under Electronic Reading Room/Document Collections.

ADAMS Accession Number: ML100640465

TAC ME3411 OFFICE

DIRS/IOEB

Tech Editor

BC/DIRS/IOEB

DSS/SRXB

BC/DSS/SRXB

NAME

DGarmon

KAzariah-Kribbs

JThorp

WLyon

AUlses

DATE

5/13/10

04/05/10 e-mail

05/14/10 e-mail

05/13/10

5/14/10 e-mail

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DPR/PGCB

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WRuland

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DBeaulieu

SStuchell (Acting)

DATE

05/26/10

05/18/10 e-mail

6/10/10

05/27/10

6/11/2010

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D/DPR/PGCB

NAME

GTracy (MShuaibi

for)

TMcGinty

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6/15/2010

6/16/2010

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