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    REG NASA-LLIS-3516-2010 Lessons Learned - Lithium-Ion Battery Fire.pdf

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    REG NASA-LLIS-3516-2010 Lessons Learned - Lithium-Ion Battery Fire.pdf

    1、 Public Lessons Learned Entry: 3516Lesson Info:a71 Lesson Number: 3516 a71 Lesson Date: 2010-05-18 a71 Submitting Organization: JPL a71 Submitted by: David Oberhettinger Subject: Lithium-Ion Battery Fire Abstract: A lithium-ion battery undergoing characterization testing in a basement laboratory ove

    2、rheated, caught fire, and detonated, funneling toxic fumes into the two upper floors of the office building and forcing its evacuation for several days. Conduct a hazard assessment specific to the battery type, assure that research-type battery testing and storage conforms to safety standards, reass

    3、ess the potential for exhaust systems to spread fumes throughout a building, and implement test configuration improvements for batteries to be used by flight projects. Description of Driving Event: During a lithium-ion (Li-ion) battery test on October 20, 2009, the battery overheated, caught fire, a

    4、nd detonated within an enclosed steel locker in a bunker attached to a multi-story, office/laboratory building at the NASA/Caltech Jet Propulsion Laboratory (JPL) (References (1) and (2). The bunker was specifically designed for the purpose of containing the effects of such a battery failure. An adj

    5、acent locker, containing an identical battery in a controlled test configuration (i.e., the control battery) began to experience sympathetic heating conditions due to the initial fire, such that a portion of it deflagrated and was partially consumed by fire. The 30V, 15Ah-rated Li-ion battery, desig

    6、ned as a workhorse (test) battery, was not destined for use on a specific spaceflight project. Instead, it was being tested under ambient conditions to establish performance characteristics when used with high frequency, high-current ripple, power systems typical of many low Earth orbit (LEO) spacec

    7、raft. The test batteries were placed inside sheet metal lockers, similar to a typical gym locker, with a ventilated hinged door (Figure 1). The lockers were arranged on the facility floor in sets of six, with wiring routed through an opening punched into the back of the locker (Figure 2). The incide

    8、nt occurred after the batteries had been under the same test setup and conditions for eighteen months and exhibiting nominal behavior. Figure 1. Battery test facility following the fire Figure 2. Close-up of metal lockers used for battery test When the battery fire erupted, smoke detectors actuated

    9、the fire alarm. The building occupants immediately evacuated the building without injury. There was no collateral fire damage because the JPL Fire Department provided a timely and effective response using a Metal-Ex fire extinguisher appropriate to dowsing a lithium fire. Because of the proximity of

    10、 the battery bunker to the building ventilation air intake, smoke and toxic fumes from the combustion of Li-ion cell materials were vented into the rest of the building. The entire building was inaccessible for several days until air quality samples could be analyzed and hazardous materials remediat

    11、ed throughout the building. The battery fire was caused by a faulty measurement of the battery terminal voltage, sent to the support equipment that controlled battery charging and discharge, that was intermittent instead of continuous (Reference (3). Loss of this measurement resulted in continuous c

    12、harging of the test battery until the temperatures and internal pressures within the 80 small individual cells led to detonation and fire. A JPL failure investigation attributed the root cause to inadequate knowledge and training of test personnel. Contributing causes were use of faulty EGSE and ina

    13、dequate battery thermal protection. A proximate cause of the contamination of adjacent facilities was the design of the facility ventilation and air intake systems. References: 1. JPL Mishap Report No. 1984, October 21, 2009. 2. NASA Incident Report No. S-2009-293-00007, October 20, 2009. 3. Stephen

    14、 S. Greenberg, “JPL Investigation of the name omitted Lithium Ion Battery Fire - Test Failure Analysis Technical Report,“ JPL Document No. D-64869, April 2, 2010. 4. “JPL Standard for System Safety (JPL D-560),“ Rev. D, JPL Document No. 34880, September 17, 2007. 5. “Process for Ensuring Personnel/F

    15、acility/Operational Safety During Research and Development Testing,“ JPL Corrective Action Notice (CAN) No. 1597, March 25, 2010. 6. “Procedures and Processes for the Testing and Storage of Various Type of Cells and Batteries,“ JPL Corrective Action Notice (CAN) No. 1594, March 25, 2010. 7. “Operati

    16、on of Exhaust and Ventilation Systems to be Assessed for the Safe Exhausting of Products in the Event of a Battery Fire in Labs 277-120, 125 and B25/26,“ JPL Corrective Action Notice (CAN) No. 1595, March 15, 2010.Lesson(s) Learned: 1. The potential hazards of battery testing and storage suggest tha

    17、t the handling of batteries undergoing research and development should meet safety standards similar to those governing handling of flight batteries. There may be other hazardous research and development testing at JPL where test personnel are not aware of, or not trained in, the assessment of safet

    18、y risks. The battery test was a research and development activity and not the flight hardware validation that is explicitly governed by Reference (4). 2. Battery fires are not unusual occurrences, as batteries are sometimes tested to failure. However, the hazardous battery test procedures that led t

    19、o the incident did not have adequate fault protection controls. 3. The fire alarm triggered the evacuation of the office building. Combustion products from the battery fire in the bunker entered the ventilation intakes for the upper floors of the office building. 4. In addition to facility lessons l

    20、earned, the incident suggests test configuration improvements for implementation by flight projects that wish to use similar Li-ion batteries.Recommendation(s): 1. Where warranted by the severity of the potential hazards, augment the pre-operational safety review (OSR) for a test facility with a haz

    21、ard assessment specific to the type of test article (i.e., battery type) and type of test. (See Reference (5). Assess risk and communicate the risk posture to line management. 2. Battery testing and storage procedures and processes must assure the safety of personnel, facilities, and hardware, and c

    22、onform to safety standards. (See Reference (6).) Verify EGSE (battery charger, controller, etc.) has appropriate fault protection in place, and demonstrate that it operates as specified to bring the test to a safe condition. Provided by IHSNot for ResaleNo reproduction or networking permitted withou

    23、t license from IHS-,-,-3. Reassess building ventilation system intakes in proximity to the exhaust from co-located or nearby laboratories that handle or store hazardous materials. (See Reference (7).) 4. NASA flight projects that wish to use such Li-ion batteries should consider test configuration i

    24、mprovements: o Verify the operation of redundant voltage taps. (Redundant voltage taps are not provided on workhorse batteries. More important, test engineers should recognize when equipment becomes faulty and remove it from test until the equipment is repaired or replaced.) o Verify the as-built ba

    25、ttery thermal conductance implementation. (Not a feature on the involved workhorse battery. Test engineers should recognize that thermal management is a consideration in future testing and account for it with appropriate test setup design/ventilation provisions.) o Review the implementation of batte

    26、ry charge and conditioning management, including worst case thermal environments, faulty charge equipment, and faulty sensors. o Conduct a hazards assessment that addresses worst-case events occurring throughout the entire battery charge/discharge cycle, and verifies that appropriate mitigation meas

    27、ures are in place for each worst-case event.Evidence of Recurrence Control Effectiveness: JPL Corrective Action Notices (References (5), (6), and (7) call for improvements to battery testing, storage, and hazard assessment, and for re-assessment of ventilation systems that exhaust air from the JPL b

    28、attery laboratories. Documents Related to Lesson: N/A Mission Directorate(s): a71 Aeronautics Research a71 Science a71 Exploration Systems Additional Key Phrase(s): a71 Additional Categories.Ground Equipment a71 Additional Categories.Hardware a71 Additional Categories.Hazardous/Toxic Waste/Materials

    29、 a71 Additional Categories.Energetic Materials - Explosive/Propellant/Pyrotechnic a71 Additional Categories.Accident Investigation a71 Safety and Mission Assurance.Product Assurance a71 Additional Categories.Occupational Health a71 Engineering Design (Phase C/D).Environmental Control and Life Suppor

    30、t Systems a71 Engineering Design (Phase C/D).Power a71 Engineering Design (Phase C/D).Spacecraft and Spacecraft Instruments a71 Safety and Mission Assurance.Advanced planning of safety systems a71 Safety and Mission Assurance.Early requirements and standards definition a71 Additional Categories.Fire

    31、 Protection a71 Additional Categories.Test Article a71 Additional Categories.Safety & Mission Assurance a71 Additional Categories.Risk Management/Assessment a71 Additional Categories.Test Facility a71 Additional Categories.Facilities Additional Info: a71 Project: N/A (R&D task) Approval Info: a71 Approval Date: 2010-10-13 a71 Approval Name: mbell a71 Approval Organization: HQ Provided by IHSNot for ResaleNo reproduction or networking permitted without license from IHS-,-,-


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