05000327/LER-2005-001
| Sequoyah Nuclear Plant (Son) - Unit 1 | |
| Event date: | |
|---|---|
| Report date: | |
| Reporting criterion: | 10 CFR 50.73(a)(2)(IV)(A) 10 CFR 50.73(a)(2)(v), Loss of Safety Function |
| Initial Reporting | |
| 3272005001R00 - NRC Website | |
I. PLANT CONDITION(S)
Unit 1 was in Power Operation (Mode 1) at approximately 100 percent thermal power.
II. DESCRIPTION OF EVENT
A. Event:
On April 9, 2005, at approximately 1111 Eastern daylight time (EDT), an automatic reactor trip occurred followed by a turbine trip. The reactor trip was initiated by low auto stop oil (ASO) pressure [EIIS Code TO] input to the reactor protection system [EIIS Code JC). The plant responded to the reactor and turbine trips as designed, including the automatic start of the auxiliary feedwater (AFW) system. The unit was operating with no abnormal indications prior to the trip.
B. Inoperable Structures, Components, or Systems that Contributed to the Event:
None.
C. Dates and Approximate Times of Major Occurrences:
April 1981� Unit 1 begins commercial operation.
September 1998� TVA requested and received vendor approval to allow the use of BUNA-N sheet gasket material in place of 0- rings to resolve oil seepage at the turbine protective trip block to turbine governor pedestal interface.
April 2003� Verbal concurrence was obtained from the vendor field services representative to use red rubber sheet gasket material.
November� A new red rubber sheet gasket material was installed 2004� during the Unit 1 Cycle 13 refueling outage.
April 9, 2005 at� Reactor and turbine trips as a result of low/loss of ASO —1111 EDT� pressure.
D. Other Systems or Secondary Functions Affected:
None.
E. Method of Discovery:
The reactor trip was annunciated on the main control panel [EIIS Code CBD].
F. Operator Actions:
Control room operators responded to the event in accordance with plant procedures. Following the automatic reactor and turbine trips, operators took actions necessary to stabilize the unit, and maintained the unit in Hot Standby, Mode 3.
G. Safety System Responses:
Main turbine ASO pressure is maintained by normally closed solenoid and mechanical dump valves. With no trip condition present, these valves block the ASO flow path to drain and maintain pressure on associated switches and devices keeping them in a "reset" state. If a trip condition is sensed, one or more of these valves open to depressurize the ASO system and initiates a turbine trip. ASO pressure on Unit 1 main turbine decreased to the point of initiating a reactor trip signal through switch inputs to the reactor protection system. The reactor trip initiated a turbine trip, as designed.
The plant responded to the reactor and turbine trips as designed and as described in the Final Safety Analysis Report (FSAR), including the automatic start of the AFW system. Reactor power remained within technical specifications (TSs) and FSAR analysis limits. Reactor coolant system (RCS) [EIIS Code AB] pressure remained within TS limits and responded as expected for the event conditions.
The pressurizer safety relief valves and power operated relief valves did not actuate. Operators reduced the flow of AFW following the reactor trip to mitigate a decrease in RCS average temperature. RCS temperature remained above 541 degrees Fahrenheit for the event. The rod position indication system [EIIS Code BWR] showed the rods fully inserted.
III.� CAUSE OF THE EVENT A.� Immediate Cause:
The immediate cause of the unit trip was loss of ASO pressure. The reactor trip was initiated by low ASO pressure input to the reactor protection system. ASO pressure loss occurred because of the failure of a red rubber gasket installed between the turbine protective trip block and the turbine governor pedestal.
B. Root Cause:
The root cause of the event is impioper machining of the turbine front pedestal oil ports during original manufacturing by Westinghouse Electric Company. This resulted in oil port misalignment and oil seepage between the turbine protective trip block and the turbine governor pedestal. Because of oil port misalignment, sheet gasket material had been used in place of the originally designed 0-rings to seal the mating surfaces.
C. Contributing Factor:
Contributing to the event was the failure to understand the cause of oil seepage at the turbine protective trip block and the turbine governor pedestal connection. As a result, actions were taken to change from 0-ring seals to sheet gasket material without full understanding of the connection design or the impact of material substitution.
In 1998, in an attempt to stop the oil seepage, TVA personnel requested and Siemens Westinghouse approved the use of sheet gasket material as a replacement for 0-rings. Maintenance was concerned with the recommended BUNA-N gasket material because it tended to slip out of position and/or extrude under pressure during tightening. The protective trip block bolting pattern did not ensure sheet gasket material would maintain position. This was a concern because the space between the supply and drain oil ports was approximately 0.130 inch. In subsequent outages, Maintenance substituted the BUNA-N material with red rubber sheet gasket material. This change was performed with verbal concurrence of Siemens Westinghouse without performing a material compatibility evaluation. Red rubber was found not to be fully compatible with the turbine oil.
Failure of 1/16-inch thick gasket material created sufficient area to allow oil to bypass the protective trip block and flow from the supply port directly to the drain port. This bypass flow resulted in the loss of ASO pressure and initiation of the reactor and turbine trips.
External oil seepage and bypass oil leakage can be minimized when 0-rings are used. The protective trip block, designed to use 0-ring seals, contains counter bores that retain the 0-rings in position in a positive pressure application. With the flow ports in alignment, the full 0-ring face is compressed and provides an effective seal. With the oil ports not fully aligned, the full 0-ring face was not compressed resulting in oil seepage. Additionally, with metal to metal contact between the protective trip block and the turbine pedestal, there is insufficient cross sectional area to allow significant bypass oil flow in the event of 0-ring failure. If a sheet gasket is in use and it fails, the thickness of the gasket allows a significantly larger amount of oil to flow directly to the drain and reduce ASO pressure. Therefore, the use of any gasket was an inappropriate action.
IV. ANALYSIS OF THE EVENT
This event is bounded by the analyzed turbine trip event in the FSAR, with plant safety systems operating as designed during and following the reactor trip.
Prior to the event, the plant was in Mode 1 with the following conditions: RCS pressure was approximately 2235 pounds per square inch (psig) with an average temperature near program value of 578.2 degrees F; pressurizer [EIIS Code PZR] level was on program at approximately 60 percent; secondary side steam pressure was approximately 865 psig with normal main feedwater.supply and nominal full power steam flow; and steam generator (SG) levels were at 44 percent narrow range (NR).
Following the automatic reactor trip, the RCS pressure decreased to 2022 psig as a result of RCS temperature decrease and coolant volume shrinkage. The loss of nuclear heat generation and the introduction of cold AFW resulted in a decrease in RCS temperature to 541°F. Main control room operators took action to minimize RCS cooldown by taking manual control of AFW. Pressurizer level decreased to 25 percent and stabilized near 30 percent following the trip. After the trip, steam pressure increased to approximately 985 psig when the turbine stop valves closed. The atmospheric relief valves (ARVs) [EIIS Code RV] on SG Nos. 1, 3, and 4 opened as designed, the ARV on SG No. 2 opened below setpoint. The SGs' safety relief valves did not open. Steam dumps to the condenser [EIIS Code COND] operated as designed and remained available. AFW system actuated as designed on the SG low-low level signal, recovering the SG water levels following the reactor trip.
V. ASSESSMENT OF SAFETY CONSEQUENCES
Based on the above "Analysis of The Event," this event did not adversely affect the health and safety of plant personnel or the general public.
VI.CCORRECTIVE ACTIONS A. Immediate Corrective Actions:
The Unit 1 turbine protective trip block was reassembled using the original 0-ring configuration with a light coating of gasket sealant on the metal to metal surfaces. The gasket sealant was applied to ensure leakage between the faces was minimized. A follow-up inspection found the interface to be leak free.
B. Corrective Actions to Prevent Recurrence:
Data was taken confirming misalignment of the oil ports on Unit 2. The misalignment was large enough to allow part of the 0-ring to fall into the supply oil port in the pedestal. The Unit 2 protective trip block was machined to increase the 0-ring counter bore such that a larger sized 0-ring will fully seal the oil port.
At the next Unit 1 refueling outage, the Unit 1 trip protective block will be machined to assure proper 0-ring mating surfaces by increasing the 0-ring counter bore and installation of appropriately sized 0-rings.
VII. ADDITIONAL INFORMATION
A. Failed Components:
Commercial grade red rubber sheet gasket material.
B. Previous LERs on Similar Events:
A review of previous reportable events for the past three years did not identify any
- previous similar events.
C. Additional Information:
Contributing factors discussed in this LER are being addressed within the Corrective Action Program under Problem Evaluation Report Number 80518.
D. Safety System Functional Failure:
This event did not result in a safety system functional failure in accordance with 10 CFR 50.73(a)(2)(v).