REG NASA-LLIS-0802--2000 Lessons Learned Battery Verification Through Long-Term Simulation.pdf

1、Best Practices Entry: Best Practice Info:a71 Committee Approval Date: 2000-04-17a71 Center Point of Contact: MSFCa71 Submitted by: Wil HarkinsSubject: Battery Verification Through Long-Term Simulation Practice: Conduct highly instrumented real-time long term tests and accelerated testing of space fl

2、ight batteries using automated systems that simulate prelaunch, launch, mission, and post mission environments to verify suitability for the mission, to confirm the acceptability of design configurations, to resolve mission anomalies, and to improve reliability.Programs that Certify Usage: This prac

3、tice has been used on Hubble Space Telescope (HST), Advanced x-ray Astrophysics Facility (AXAF), External Tank (ET), Solid Rocket Booster (SRB), Inertial Upper Stage (IUS), and Combined Release and Radiation Effects Satellite (CRRES).Center to Contact for Information: MSFCImplementation Method: This

4、 Lesson Learned is based on Reliability Practice number PT-TE-1434 from NASA Technical Memorandum 4322A, NASA Reliability Preferred Practices for Design and Test.Benefit:Since the operational readiness and future performance of space flight batteries at any point in a mission are strongly dependent

5、upon past power cycles and environments, thoroughly instrumented and analyzed ground testing of space flight batteries identical to flight configurations will ensure Provided by IHSNot for ResaleNo reproduction or networking permitted without license from IHS-,-,-predictable performance and high rel

6、iability of flight batteries.Implementation Method:Real-time, long term mission, power cycle simulations of space flight batteries in ground facility test beds provide an excellent indication of expected performance in flight. Complete verification of a full real-time mission is not possible with lo

7、ng-term missions due to the test lead time. Instead of accelerating the test, the test engineers should “lead“ the actual mission by a year or two (as long a lead-time as possible while still being able to use flight designs and configurations). This verification is in addition to qualification step

8、s for the designs. Accelerated testing is not common for low earth orbit (LEO) missions but is used for non-LEO missions.The cells are interconnected in the anticipated flight condition and are housed in a thermally controlled chamber which is purged with an inert gas. Preprogramed, computer control

9、led power supplies and load banks cycle the batteries through the same dormant, power drain, and charging cycles that they would encounter in the space operation. Shading of solar arrays during eclipse periods is simulated by absence of charging current, and charge cycles are simulated during exposu

10、re to the sun. Table 1 lists the principal purposes and features of long-term battery simulations.refer to D descriptionD Table 1. Principal Purposes and Features of Long-Term Battery Simulation All cells are instrumented at various locations for current, voltage, temperature, and pressure. Ambient

11、temperature in the chamber is constantly monitored. Voltage and current values are available in real time through digital readouts. Voltage, current, pressure, and temperature are recorded constantly on strip charts. Data are sampled by computer programs which compute and analyze ongoing performance

12、. Table 2 shows the parameters usually recorded and/or computed for Provided by IHSNot for ResaleNo reproduction or networking permitted without license from IHS-,-,-each battery cell from sampled data. Ground testing of batteries and their associated power systems has proven to be a valuable asset

13、for the resolution of in-flight anomalies. Limits testing can be safely simulated on the ground to verify or explore variations in flight performance.refer to D descriptionD Table 2. Recorded and Computed Data Parameters for Each Cell Safety precautions are important in testing of all battery system

14、s because leakage of electrolytes or effluents can be hazardous. Typical precautions and safeguards for nickel-hydrogen (Ni-H2) batteries are shown in Table 3.refer to D descriptionD Table 3. Typical Precautions/Safeguards for Ni-H2Battery Testing Provided by IHSNot for ResaleNo reproduction or netw

15、orking permitted without license from IHS-,-,-An important action that will help to ensure a successful test effort is the preparation of a comprehensive test plan before the test begins. The test plan should describe the overall scope and approach to the test operation, and provide a detailed test

16、sequence including the test set up parameters, data handling requirements, and test procedures. The test setup description should include the cell specifications and method of packaging into the battery configuration, the data acquisition and control procedures, and the thermal control system requir

17、ements. Test procedures should include cell characterization testing procedures (assuming that the cells have already passed through acceptance testing prior to receipt at the test site), launch scenario simulation procedures, mission simulation procedures, and mission capacity test and reconditioni

18、ng procedures if required.Technical Rationale:MSFC has conducted multi-year testing of silver-zinc, nickel-cadmium, and nickel-hydrogen batteries since 1986. Some tests that were started in 1986 are still underway at this writing. Test durations are over eight years and counting. MSFC is conducting

19、8 to 10 tests simultaneously, with up to 400 channels of instrumentation on some tests. To support the Hubble Space Telescope, diode bypass relays on two batteries were opened to simulate an in-flight anomaly. The HST ground tests indicated that strong performance should continue from the HST flight

20、 batteries despite the in-flight anomaly.References:1. Whitt, Thomas and Lorna Jackson: “Battery and Cell Testing at Marshall Space Flight Center,“ (a presentation), NASA/MSFC, EB12, Huntsville, AL, 1988.2. Brewer, Jeffrey, John Pajak, and Lorna Jackson: “Test Plan for AXAF-I Ni-H2Battery Mission Si

21、mulation Testing,“ NASA/MSFC, EB71, Huntsville, AL, March 30, 1994.3. Brewer, Jeffrey, and Thomas Whitt: “HST Ni-H2Flight Spare Battery Test,“ NASA/MSFC, EB12, Huntsville, AL, Huntsville, AL, October 6, 1989.4. Whitt, Thomas, and Charles Hall: “HST Ni-H2Six Battery Mission Simulation Test,“ NASA/MSF

22、C, EB12, Huntsville, AL, November 2, 1989.5. Whitt, Thomas, and Jeffrey Brewer: “Fifth Semi-Annual Report on HST Ni-H2Six Battery and Flight Spare Battery Test,“ NASA/MSFC, Huntsville, AL, August 8, 1993.Impact of Non-Practice: Failure to perform long term mission simulations will result in inadequa

23、te knowledge of long duration performance characteristics and could result in the retention of undesirable battery characteristics or failure modes that would result in mission failure.Provided by IHSNot for ResaleNo reproduction or networking permitted without license from IHS-,-,-Related Practices: N/AAdditional Info: Approval Info: a71 Approval Date: 2000-04-17a71 Approval Name: Eric Raynora71 Approval Organization: QSa71 Approval Phone Number: 202-358-4738Provided by IHSNot for ResaleNo reproduction or networking permitted without license from IHS-,-,-