MA Hui-ming1,2, ZHANG Ya1, LI Shi-zhong1
(1. School of Mechatronic Engineering, North University of China, Taiyuan 030051, China; 2. School of Information and Communication Engineering, North University of China, Taiyuan 030051, China)
Abstract: In order to ensure the ballistic safety of fusible alloy fuze at reliable delay arming, melting point of fusible alloy needs to be calculated based on projectile velocity at safe time and distance. Taking shrapnel KZVD fuze of Switzerland oerlikon 2ZLa/353 35 mm double barrel self-propelled antiaircraft artillery as an example, based on the aerodynamics heating theory, the calculation of theory model and simulation of projectile head stagnation point temperature were done in initial stage of simplified exterior ballistic from engineering viewpoint when the initial projectile velocity was 1 175 m/s and the error was ±15 m/s. The melting point of fusible alloy in the safe distance was obtained by analyzing the temperature of projectile head stagnation point at corresponding projectile velocity. The simulated results indicate that the melting point of fusible alloy derived by theoretical calculation is identical with the result of simulation at the velocity range of 1 160 to 1 190 m/s. So the aerothermodynamics model can be applied to design the fusible alloy fuze of corresponding melting point based on the requirement of safe distance. This method can be taken as the reference in studying the thermodynamic question of projectile flying at high speed.
Key words: fusible alloy; fuze; ballistic safety; projectile head temperature; aerothermodynamics
CLD number: TJ431.3Document code: A
Article ID: 1674-8042(2016)04-0324-08 doi:10.3969/j.issn.1674-8042-2016-04-003
References
[1]ZHAO Tian-chan, ZHONG Ou-yang. Composition and melting point of low melting point alloy. Machinery Manufacturing Engineer, 1996(8): 21.
[2]WU Xi-zhe, LI Yun-kang. Low melting point alloy. Rare Metal Materials and Engineering, 1984(1): 53-56.
[3]SHEN Guo-yong. Property, use and development of low melting point alloy. Materials for Mechanical Engineering,1981, (4): 29-33.
[4]WANG Ji-hui, YANG Ya-qun, LI Qun-ying, et al. Design and properties of Bi-Sn-In ternary fusible alloys. The Chinese Journal of Nonferrous Metals, 2006, 16(10): 1653-1659.
[5]WANG Ji-hui, YANG Ya-qun, LI Qun-ying, et al.Design and properties of Bi-Pb-Sn-Cd fusible alloys. Development and Application of Materials, 2005, 20(1): 1-3.
[6]YANG Ya-qun. Design and properties of new fusible alloys. Tianjin: Tianjin University, 2005.
[7]FANG Zhi-sen. Study on fuze thermal characteristic and development of virtual test analysis system. Nanjing: Nanjing University of Science and Technology, 2011.
[8]LI Zhong-liang. Study on utilization and analysis of fuze arming environment based on low setback and non-rotating. Nanjing: Nanjing University of Science and Technology, 2009.
[9]SHI Geng-chen, LI Hua. Fuze’s MEMS delay arming device.Journal of Detection and Control, 2008, 30(3): 1-4.
[10]CHEN Qing-sheng. Analysis of movement of ball rotor. Acta Armamentarii, 1980, (3): 45-55.
[11]ZHANG Jian, ZHANG De-zhi, WANG Jian, et al. Several considerations on the materials for the fuse and their technology .Journal of Shenyang Institute of Technology, 1999, 18(4): 38-42.
[12]HAN Zhi-li, LIU Jian-gnan, LI Gao-hong. The application of shape memory alloys in fuze-safety system. Journal of Detection and Control, 2005, 27(5): 5-7.
[13]MA Bao-hua. Structure and function of fuze. Beijing: National Defense Industry Press, 1984.
[14]ZHU Bian-yi. Ammunition Series of Switzerland oerlikon 35 mm. Modern Weaponry, 1986, (6): 31-37.
[15]JIANG Cai-yun. Analysis on ammunition of oerlikon 35 mm. Modern Weaponry, 1989, (7): 23-27.
[16]LIU Qing-cheng, LI Xing-guo. Simulation study of stagnation characteristics of heat flux and temperature millimeter wave fuze antenna radome.Acta Armamentarii, 2008, 29(8): 907-910.
[17]Editing Work Committee for Military Training Teaching Material of Chinese PLA General Armament Department. Aerodynamic heating and thermal protection of hypersonic. Beijing: National Defense Industry Press, 2003.
[18]JIANG Gui-qing, LIU Lian-yuan. Heat transfor of hypersonic gas and ablation thermal protection. Beijing: National Defense Industry Press, 2003.
[19]CHEN Tao. Aerodynamic heating research for the head of hypersonic projectile. Nanjing: Nanjing University of Science and Technology, 2006.
[20]LOU Wen-zhong, ZHOU Yu, XU Xiang-hong, et al. Numerical simulation for aerodynamic heating and heat transfer laws of warhead fuze.Journal of North University of China(Natural Science Edition), 2008, 29(4): 316-320.
[21]YANG Kai, GAO Xiao-wei. Engineering algorithm for aeroheating environment of hypersonic aircrafts. Missiles and Space Vehicles, 2010, (4): 19-23.
[22]JI Chu-qun, FU Zhi-xiang, ZENG Guang-cun. Missile aerodynamics. Beijing: China Astronautic Publishing House, 1996.
[23]LV Li-li. Study on engineering algorithms for aerodynamic heating of hypersonic.Xi’an: Northwestern Polytechnical University, 2005.
[24]ZOU Xiao-fei. Aeroheating of re-entry warhead and analysis of heat response. Changsha: National University of Defense Technology, 2009.
易熔合金引信弹道安全的气动热力学建模仿真
马慧明1,2, 张亚1, 李世中1
(1. 中北大学 机电工程学院, 山西 太原 030051; 2. 中北大学 信息与通信工程学院, 山西 太原 030051)
摘要: 为使易熔合金引信可靠延期解除保险以保证弹道安全,需要根据弹丸速度确定在安全时间和距离内引信易熔合金的熔点。 以瑞士厄利空2ZLa/353式35 mm双管自行高射炮爆破燃烧榴弹KZVD引信为例, 从工程的角度出发,简化了外弹道, 在初始弹速为1 175 m/s和误差范围为±15 m/s的条件下, 采用气动加热理论对榴弹外弹道起始阶段弹头驻点的温度进行了理论建模计算和仿真验证,通过分析相应弹速下的弹头驻点温度确定出满足安全距离要求的易熔合金熔点温度。 仿真结果表明, 理论计算与仿真试验确定出1 160-1 190 m/s初始弹速范围内的易熔合金熔点温度的结果一致, 因此可以利用该热力学模型并根据弹道安全要求来设计相应熔点的易熔合金引信,所用方法可以为高速飞行弹体的热力学研究提供参考。
关键词: 易熔合金; 引信; 弹道安全; 弹头驻点温度; 气动热力学
引用格式:MA Hui-ming, ZHANG Ya, LI Shi-zhong. Simulation of aerothermodynamics model on ballistic safety of fusible alloy fuze. Journal of Measurement Science and Instrumentation, 2016, 7(4): 324-331. [doi: 10.3969/j.issn.1674-8042.2016-04-003]