期刊文献+

矩形截面轨道发射器电感梯度影响因素研究 被引量:7

Influencing Factors Research of Rectangular Cross-Sectional Rail Launcher Inductance Gradient
下载PDF
导出
摘要 电感梯度是影响轨道发射器性能的重要指标之一,针对轨道发射器电感梯度影响因素众多的问题,对其进行合理的设计能够使轨道炮性能达到优化的效果,从毕奥-萨法尔定律出发,建立了矩形截面轨道发射器模型并求得电感梯度解析表达式;运用单参数灵敏度方法对模型中几种影响因素进行仿真分析并与常见电感梯度计算方法进行对比。结果表明:与常规计算电感梯度方法相比,该模型结果较为理想,验证了准确性;与常规方法的不同点在于引入电枢位置作为电感梯度影响因素之一并说明其影响方式。该研究可为轨道发射器设计提供一定参考。 The inductance gradient is one of the important indexes affecting rail launcher performance. For rail launcher inductance gradient many influence factors, carries on the reasonable design can make the railgun performance to achieve optimal results. A rectangular cross-sectional rail launcher model was built based on the Biot-Savart law in this paper. Furthermore, the analytical expression of inductance gradient can be obtained by this model. The single parameter sensitivity analysis method was employed to analyze several factors of the inductance gradient. The result shows that:compared with common methods, this paper performs well in both the height and the space between rails;the reason why it is different in the factor of thickness is shown. The armature position which regarded as one of the factors is introduced in the analytical expression of inductance gradient, and some details are done to explain how does it affects. This can provide reference for future design.
出处 《兵工自动化》 2013年第11期16-19,共4页 Ordnance Industry Automation
关键词 电感梯度 影响因素 单参数灵敏度分析 inductance gradient influencing factors single parameter sensitivity analysis
  • 相关文献

参考文献10

  • 1Keshtkar A. Effect of rail dimension on current distribution and inductance gradient[J]. IEEE Transactions on Magnetics, 2005, 41(1): 383-386.
  • 2Keshtkar A, BayatiS. Effect of rail's material on railgun inductance gradient and losses[C]. Victoria: 14th Symposium on Electromagnetic Launch Technology Proceedings, Canada, 2008: 130-133.
  • 3Yuan W Q, Sun L Q. Investigation on the time varying inductance gradient of railgun[C]. Victoria: 14th Symposium on Electromagnetic Launch Technology Proceedings, Canada, 2008: 569-572.
  • 4聂建新,韩晶晶,焦清介,金兆鑫,张锋.电磁轨道发射器的几何尺寸对电感梯度的影响[J].高电压技术,2010,36(3):728-732. 被引量:22
  • 5周媛,严萍,袁伟群,孙立强.电磁轨道发射装置中导轨几何参数对电感梯度的影响[J].电工电能新技术,2009,28(3):23-27. 被引量:22
  • 6Kerrisk. J F. Current distribution and inductance calculations for railgun conductors[R]. New Mexico, USA Los Alamos National Laboratory, 1981: 2-3.
  • 7Grover F W. Inductance calculations: working formulas and tables[M]. New York, USA: Dover Publications, 1962 28-66.
  • 8Batteh J H. Momentum equation for arc-driven railguns[J]. Journal of Applied Physics, 1984, 56(11): 3182-3186.
  • 9Marshall, R. A. Ying W. Railguns: their science and technology[M]. Beijing: China Machine Press, 2004: 12-14.
  • 10胡玉伟,马萍,杨明,焦松,王子才.一种电磁轨道炮系统的仿真模型[J].兵工自动化,2012,31(9):54-58. 被引量:8

二级参考文献37

  • 1R A Marshall, W Ying, Railguns: their science and technology [M] . Beijing: China Machine Press, 2004.
  • 2Kerrisk J F. Current diffusion and inductance calculations for rail-gun conductors [R]. Report LA-9092-MS, UC 34, Los Alamos National Laboratory, New Mexico, USA, 1981.
  • 3K T Hsieh, B K Kim. International railgun modleling effort [J]. IEEE Trans. Magn., 1997, 33(1): 245-248.
  • 4J Gallant. Parametric study of an augmented railgun [J] . IEEE Trans. Magn., 2003, 39(1): 451-456.
  • 5B K Kim, K T Hsieh. Effect of rail/armature geometry on current density distribution and inductance gradient [J]. IEEE Trans. Magn. 1999, 35(1): 413-416.
  • 6R Mumgan, K Udayakumax. Effect of raft dimensions on rail gun design parameters [A]. IEEE Indieon 2005 Conference [ C]. Chennai, India, 2005. 623-626.
  • 7Asghar Keshtkar. Effect of rail dimension on current distribution and inductance gradient [ J]. IEEE Trans. Magn., 2005, 41 ( 1 ) : 383-386.
  • 8Marshall R A, Wang Y. Railguns: their science and technology [M]. Beijing: China Machine Press, 2004.
  • 9Kim B K, Hsieh K T. Effects of rail/armature geometry on current density distribution and inductance gradient [J]. IEEE Transactions on Magnetics, 1998, 35(1): 413 -416.
  • 10Keshtkar A, Effect of rail dimension on current distribution and inductance gradient [ J ]. IEEE Transactions on Magnetics, 2005, 41(1): 383-386.

共引文献43

同被引文献31

  • 1陶孟仙,任兆杏.“503”轨道炮等离子体电枢发射的仿真计算[J].火炮发射与控制学报,1999,0(4):61-64. 被引量:3
  • 2Marshall R. A., Ying W. Railguns: their science and technology[M]. Beijing: China Machine Press, 2004: 12-14.
  • 3Tzeng J T, Sun W. Dynamic Response of Cantilevered Rail Guns Attributed to Projectile GunInteraction Theory[J]. IEEE Transactions on Magnetic, 2007, 43(1): 207-213.
  • 4王磊磊.电磁轨道炮电路暂态特性分析及发射组件优化和解析计算[D].秦皇岛:燕山大学,2012:16-23.
  • 5耿彦波.电磁轨道发射系统动力学研究[D].秦皇岛:燕山大学,2012:13-19.
  • 6POLTANOV A E’KONDRATENKO A K’GLINOV AP. Multi-turn railguns : concept analysis and experimentalresults[J]. IEEE Trans. on Magnetics, 2001, 37 ( 1) : 457-.
  • 7KESHTKAR A,GHARIB L, BAYATI M S, et al.Simulation of a two-turn railgun and comparisonbetween a conventional railgun and a two-turn railgunby 3-D FEM[J]. IEEE Trans, on Magnetics,2013, 41(5):1392-1397.
  • 8KESHTKAR A. Effect of rail dimension on currentdistribution and inductance gradient[J]. IEEE Trans, onMagnetics,2005 ,41(1) :383-386.
  • 9ELLIS R L’POYNOR J C, McGLASSON B T,et al.Influence of bore and rail geometry on an electromagneticnaval railgun system[J]. IEEE Trans. on Magnetics, 2005.41(1):182-187.
  • 10COBB K K,NGN YEN V A. Experimental determination ofsquare bore and parallel configuration EML rail inductanceper unit length [J]. IEEE Trans. on Magnetics, 1991,27(1):207-211.

引证文献7

二级引证文献21

相关作者

内容加载中请稍等...

相关机构

内容加载中请稍等...

相关主题

内容加载中请稍等...

浏览历史

内容加载中请稍等...
;
使用帮助 返回顶部