基于电流丝法的多级同步感应线圈炮电枢温升计算

针对同步感应线圈炮常用的导体圆筒式电枢,结合电流丝法,建立了电枢温升计算模型；通过搭建三级同步感应线圈炮试验平台,验证了计算模型的正确性,并分析了电枢材料和剖分设置对电枢温升计算的影响。结果表明：发射过程中电枢的最高温升位于其底部外侧,电枢前端也有较高温升；当调节载荷使铜、铝电枢等质量时,前者的温升虽然更高,但温升对其发射效率的影响却小于后者,这是因为铜的电阻率温度系数小于铝；电枢的剖分设置对电枢温升的计算的影响比较明显。因此从电枢温升对发射过程的影响来看,铜电枢比铝电枢更适合用于高速发射。

Abstract

The conductor cylinder armature is commonly used in synchronous induction coilgun. A model is developed to calculate the temperature rise of the armature based on the current filament method. The correctness of the model is verified by setting up a 3-stage synchronous induction coilgun test platform. The influence of the armature material and division setting on the temperature rise is analyzed. The result shows that the maximum temperature rise of the armature concentrates in the exterior surface of the tail, and there is a high temperature rise in the front of the armature. When the payload is adjusted to make the quality of the copper armature and the aluminum armature equal, the temperature rise of the former is higher while the influence of the temperature rise on its emission efficiency is lesser than the latter, because the temperature coefficient of resistivity of copper is less than that of aluminum. In addition, the influence of division setting on the calculation results is obvious. From the point of view of influence of the temperature rise on the emission process, the copper armature is more suitable for high-speed emission than aluminum armature.

参考文献

[1] 王莹,肖峰．电炮原理［M］．北京: 国防工业出版社,1995：93-97．

Wang Ying, Xiao Feng. Theory of electric gun. Beijing: National Defense Industry Press, 1995: 93-97

[2] Kou B Q, Huang X Z, Wu H X, et al. Thrust and thermal characteristics of electromagnetic launcher based on permanent magnet linear synchronous motors［J］. IEEE Trans on Magnetics, 2009, 45(1): 358-362.

[3] Engel T G, Nunnally W C, Gahl J M. High-efficiency helical coil electromagnetic launcher［R］. Directorate for Information Operations and Reports, Dept of Electrical Engineering, College of Engineering, University of Missouri, Columbia, 2006.

[4] Aubuchon M S, Lockner T R, Turman B N. Results from Sandia National Laboratories/Lockheed Martin electromagnetic missile launcher (EMML) ［J］. IEEE Trans on Magnetics, 2005, 41(1): 75-78.

[5] Marder B. SLINGSHOT—a coilgun design code［R］. SAND2001-1780, 2001.

[6] Zhang Y D, Ruan J J, Wang Y, et al. Armature performance comparison of an induction coil launcher［J］. IEEE Trans on Plasma Science, 2011, 39(1): 471-475.

[7] 张朝伟,邓启斌,汤磊,等. 同步感应线圈炮电枢特性分析［J］. 火炮发射与控制学报, 2011, 17(3)：14-18.

Zhang Chaowei, Deng Qibin, Tang Lei, et al. Armature characteristics analysis of synchronous induction coilgun. Journal of Gun Launch & Control, 2011, 17(3): 14-18

[8] Barmada S, Musolino A, Raugi M, et al. Analysis of the performance of a multi-stage pulsed linear induction launcher［J］. IEEE Trans on Magnetics, 2001, 37(1): 111-115.

[9] 邹本贵,曹延杰,王成学,等. 单级同步感应线圈炮电枢的磁场-温度场有限元分析［J］. 电机与控制学报,2011, 15（2）: 42-46.

Zou Bengui, Cao Yanjie, Wang Chengxue, et al. Finite element analysis of magnetic-thermal fields for armature in single-stage synchronous induction coilgun. Electric Machines and Control, 2011, 15(2): 42-46

[10] 关晓存,李治源,赵然,等. 线圈炮电枢电磁-热耦合仿真分析［J］. 强激光与粒子束, 2011, 23(8): 2267-2271.

Guan Xiaocun, Li Zhiyuan, Zhao Ran, et al. Magnetic-thermal coupling simulation analysis for armature in coilgun. High Power Laser and Particle Beams, 2011, 23(8): 2267-2271

[11] Liu S B, Ruan J J, Peng Y, et al. Improvement of current filament method and its application in performance analysis of induction coilgun［J］. IEEE Trans on Plasma Science, 2011, 39(1): 382-389.

[12] 赵科义,李治源,程树康,等.同步感应线圈炮内磁场及涡流场的有限元分析［J］. 高电压技术, 2008, 34(3): 492-495.

Zhao Keyi, Li Zhiyuan, Cheng Shukang, et al. Finite element analysis of magnetic field and eddy field in synchronous induction coilgun. High Voltage Engineering, 2008, 34(3): 492-495

牛小波, 刘开培, 张亚东, 周亮, 令狐选霞. 基于电流丝法的多级同步感应线圈炮电枢温升计算[J]. 强激光与粒子束, 2015, 27(9): 095001. Niu Xiaobo, Liu Kaipei, Zhang Yadong, Zhou Liang, Linghu Xuanxia. Calculation of temperature rise of armature in multi-stage synchronous inductive coilgun based on current filament method[J]. High Power Laser and Particle Beams, 2015, 27(9): 095001.

基于电流丝法的多级同步感应线圈炮电枢温升计算

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