Information Notice 2013-14, Potential Design Deficiency in Motor-Operated Valve Control Circuitry

ML13144A834 August 23, 2013 NRC INFORMATION NOTICE 2013-14: POTENTIAL DESIGN DEFICIENCY IN MOTOR-OPERATED VALVE CONTROL CIRCUITRY

ADDRESSEES

All holders of and applicants for an operating license or construction permit for a nuclear power reactor 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 vesse All holders of and applicants for a nuclear power reactor early site permit, combined license, standard design certification, standard design approval, or manufacturing license 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 alert addressees to a potential control circuit design deficiency in motor-operated valves (MOVs) that could result in incorrect valve position indication with the valve in an improper position during a loss-of-coolant accident (LOCA). The NRC expects that recipients will review the information for applicability to their facilities and consider actions, as appropriate, to avoid similar problem Suggestions contained in this IN are not NRC requirements; therefore, no specific action or written response is require

DESCRIPTION OF CIRCUMSTANCES

In an event report dated September 21, 2012, Exelon Generation Company notified the NRC that several MOVs at Limerick Generating Station, Units 1 and 2 could remain partially open following the initiation of an automatic isolation signal in response to a design-basis LOC Specifically, when power is interrupted to the actuator of certain MOVs during the shedding of loads associated with the plant's as-designed LOCA response, the MOVs may not automatically resume operation once power was restore Additionally, the valve position indicating lights would incorrectly indicate that the valves were fully closed when the actual valve position could be as much as 15 percent ope Multiple primary containment isolation valves (PCIVs) in different systems at Limerick, Units 1 and 2, were susceptible to this conditio

BACKGROUND

With IN 1985-20, "Motor-Operated Valve Failures due to Hammering Effect," the NRC staff summarized a design deficiency in which certain MOVs repeatedly cycled at the end of their operating trave The IN described a phenomenon-known as "hammering"-during which relaxation of the gearing within the actuator of a closed MOV could lead to repeated attempts to further close the valve as long as the MOV continued to receive a valve-close demand signa Such a continuing signal might occur during a sealed-in accident signal (e.g., containment isolation signal) or if a plant operator held the control switch in the closed positio MOV hammering can lead to burn-out of the MOV motor or damage to the valve and actuato MOV hammering can also force the valve disc into the seat such that re-opening of the valve is difficul Supplement 1 to IN 1985-20 describes certain types of MOVs that are susceptible to hammerin In particular, MOVs with low gear ratios that are commonly used in applications requiring high-speed valve actuation are susceptible to hammerin After these MOVs are closed and their torque switch contacts open, internal forces exerted through the torque switch pinion and Belleville washer assembly within the MOV actuator can cause the torque switch to reclose and resupply power to the MOV motor because the actuator gearing does not provide sufficient resistance to motio Consequently, MOVs that use these gear sets are characterized as "nonlocking." Conversely, MOVs with high gear ratios can resist the internal forces on the actuator gearing; therefore, they do not allow the torque switch to re-close and re-supply power to the moto MOVs with high gear ratios are not susceptible to hammering and are characterized as "locking."

IN 93-98, "Motor Brakes on Valve Actuator Motors," the NRC staff summarized an MOV issue related to motor brakes installed in MOVs to minimize the inertial loads during valve closure after control switch tri Motor brakes can be used to help avoid hammering in MOVs with nonlocking gear mechanism However, improper sizing and operation of motor brakes might not prevent hammering, and can result in problems with the performance of the MOV as discussed in IN 93-9

DISCUSSION

Certain system designs may require high-speed valve actuation and, thus, necessitate the application of MOVs with actuator gearing that is nonlockin In these cases, licensees or vendors may have designed features within the MOV circuitry to avoid the hammering issu One approach to avoid MOV hammering, such as implemented at Limerick, relies on a limit switch contact to serve as an "isolation permissive" functio When the isolation permissive limit switch contact is closed, a sealed-in signal to close the valve (e.g., containment isolation) would be allowed to energize the valve close circui Once the valve reaches a certain position in its travel, the isolation permissive limit switch contact open During the continued MOV operation, the MOV circuitry is designed to allow current to flow around the open limit switch contac After the torque switch opens, power is interrupted to the MOV motor and the valve travel stop If the torque switch re-closes inadvertently (such as by relaxation of the actuator gearing), the MOV circuitry does not allow the current to flow around the open limit switch contact, and power is not restored to the MOV moto The MOV circuitry can be designed to allow power to be restored to the MOV motor when valve operation is needed, such as by use of the MOV hand switch in the control roo In a recent 10 CFR 50.72 "Immediate Notification Requirements for Operating Nuclear Power Reactors," event notification (EN No. 48334), Exelon reported that several MOVs at Limerick, Units 1 and 2, that used an isolation permissive limit switch could potentially remain partially open during the plant's designed response to a LOC The followup 10 CFR 50.73 "License Event Report System," licensee event report (LER No. 05000352-2012007, Agencywide Documents Access and Management System (ADAMS) Accession No. ML12293A100) provides further details on the MOV vulnerability that was discovered during a licensee-led evaluation of electrical system voltage that would be expected to occur during a LOC The evaluation identified that the MOVs with an isolation permissive limit switch setting were set to a value of 5 percent to 15 percent of open trave This represents a "dead zone" in the valve close circuitr The licensee determined that if power is interrupted to the affected valve actuators after the isolation permissive limit switch contact opened, but before the valve reached its closed position, the affected PCIVs could potentially remain as much as 15 percent ope This condition could occur if, during the plant's designed response to a LOCA, the load shed sequence occurred when a valve was within the dead zon In this case, once power was sequenced back to the MOV, it would not resume motion because the isolation permissive limit switch contact would be open, thus, preventing the actuation signal from reaching the MOV moto Furthermore, the valve indicating lights would indicate fully closed because the close position indicating light contacts share the same limit switch rotor as the isolation permissive limit switch contacts, and the valve would indicate closed when entering the set dead zon The conditions just described could leave a valve open by as much as 15 percent, although the valve position indication would indicate close Upon discovery of this condition, the licensee declared the PCIVs inoperable and implemented design changes to remove this vulnerability in MOVs at Limerick, Units 1 and The licensee's corrective actions are described in the referenced LER 05000352-201200 This LER provides further details on this issue and the licensee's respons The licensee is considering long-term corrective action to modify the MOV gearing for the affected MOVs to install locking gear sets to prevent potential torque switch hammering and to allow removal of the limit switch permissive circuitr This would allow the MOVs to restart during a LOCA power restoration sequence to fully close the valves and to provide accurate valve position indicatio This design change would also obviate the need for the affected limit switch contacts for these valves, thereby eliminating the "dead zone" and the root cause of the issu This issue and LER were reviewed by NRC inspectors and dispositioned as a licensee-identified, non-cited violation, of very low safety significance. This LER was closed in the Limerick Generating Station NRC Integrated Inspection Report 05000352/2012005 and 05000353/2012005, dated February 5, 2013; see page 35, section 4OA3.2 and page 40, section 4OA7 of the inspection report for more details (ADAMS Accession No. ML13036A364). In this licensee's particular situation, the issue was determined to be of very low safety significanc However, similar problems at other licensees might have greater safety significanc The NRC expects that recipients will review the information, links, and references provided in this IN for applicability and consider actions, as appropriate for their facilities to avoid similar problem However, no specific action or written response to the NRC is required for this I

CONTACT

This information notice does not require any specific action or written response. If you have any questions about the information in this notice, please contact the technical contact listed below or the appropriate NRC project manage /RA/ /RA/

Laura A. Dudes, Director Lawrence E. Kokajko, Director Division of Construction Inspection Division of Policy and Rulemaking and Operational Programs Office of Nuclear Reactor Regulation Office of New Reactors

Technical Contact:

Michael Farnan, NRR 301-415-1486 E-mail: Michael.Farnan@nrc.gov Note: NRC generic communications may be found on the NRC's public Web site, http://www.nrc.gov, under NRC Library/Document Collection IN 2012-14