基于FM-1密封材料低温性能研究
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摘要
氟醚材料因其优良性能,广泛地应用于航天产品密封,文章选取火工装置常用的FM-1密封材料作为研究对象,着重研究了其低温性能数据。通过设计试验测量了低温下FM-1材料密封圈的回弹性数据和回弹量随时间变化的曲线,并通过进一步计算得出了低温下的FM-1材料密封圈压缩率远低于设计值的结论,这会对密封性造成较大影响。最后,结合火工装置实例分析了低温下密封圈对火工装置工作性能的影响,通过研究发现虽然低温对密封圈回弹性有较大影响,但对整体密封性影响有限。
This paper studies the low-temperature characteristics of pyrotechnic devices seal ring,such as tensile strength at low temperatures and compression coefficient of cold-resistant,contrasted compression coef-ficients of cold-resistant of different materials,selects FM-1 seal ring as an object of study,and focuses on its low temperature performance data.Through experiments,the resiliency of FM-1 seal ring gradually decreased with decreasing temperature,and by further calculation,the compression rate of FM-1 seal ring in low tem-peratures is much lower than the designed value which would affect the seal property greatly.Finally,this paper also analyzes the effect of low temperature seals on pyrotechnic devices performance combined with experi-ments.The study finds that although the low temperature affects seal ring resilience greatly,but it puts a limited impact on the seal of the entire experiment device.
This paper studies the low-temperature characteristics of pyrotechnic devices seal ring,such as tensile strength at low temperatures and compression coefficient of cold-resistant,contrasted compression coef-ficients of cold-resistant of different materials,selects FM-1 seal ring as an object of study,and focuses on its low temperature performance data.Through experiments,the resiliency of FM-1 seal ring gradually decreased with decreasing temperature,and by further calculation,the compression rate of FM-1 seal ring in low tem-peratures is much lower than the designed value which would affect the seal property greatly.Finally,this paper also analyzes the effect of low temperature seals on pyrotechnic devices performance combined with experi-ments.The study finds that although the low temperature affects seal ring resilience greatly,but it puts a limited impact on the seal of the entire experiment device.
引文
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[9]Lach C L.Effect of Temperature and O-ring Gland Finish on Sealing Ability of Vitom,V747-75[R].NASATP-3391,1993.
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[2]蔡瑞娇.火工品设计原理[M].北京:北京理工大学出版社,1999.CAI Ruijiao.Pyrotechnics Design Principles[M].Beijing:Beijing Institute of Technology Press,1999.(in Chinese)
[3]王珍.氟醚橡胶的结构和高低温性能研究[J].世界橡胶工业,2005,39(5):22–25.WANG Zhen.The Desflurane Rubber Structure,and High and Low Temperature Performance Research[J].The World theRubber Industry,2005,39(5):22–25.(in Chinese).
[4]高滨.火工作动装置设计参数的敏感性分析[J].航天返回与遥感,2006,27(3):57–60.GAO Bin.The Pyrotechnic Device Design Parameter Sensitivity Analysis[J].Spacecraft Recovery and Remote Sensing,2006,27(3):57–60.(in Chinese)
[5]卢黎明.O形密封圈的压缩率对其密封性能的影响[J].华东交通大学学报,2003,20(2):9–11.LU Liming.Compression Rate of the O-ring Sealing Performance Impact[J].East China Jiaotong University,2003,20(2):9–11.(in Chinese)
[6]冯连胜.固体发动机O形橡胶圈密封性能试验研究[J].固体火箭技术,1993,20(3):90–96.FENG Liansheng.Solid Engine Rubber O-ring Seal Performance Test Study[J].Solid Rocket Technology,1993,20(3):90–96.(in Chinese)
[7]王广振.空间O型固密封泄漏率实验研究[J].空间科学学报,2001,21(4):45–48.WANG Guangzhen.Space O-ring Sealing Leakage Rate of Experimental Research of Space Science[J].Chinese Journal ofSpace Science,2001,21(4):45–48.(in Chinese)
[8]Scott R S.Seat Material Selection,Design and Performance-advancements from the Space Shuttle Booster Redesign[R].AIAA89-2774 198931.
[9]Lach C L.Effect of Temperature and O-ring Gland Finish on Sealing Ability of Vitom,V747-75[R].NASATP-3391,1993.
[10]Rodriguez P L,Markovitch R.Space Station Greedom Deal Leakage Rate Analysis and Testing Summary:Air Leaks in Ambi-ent Versus Vacuum Exit Condition[R].NASA TM-103604,1992.
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