Investigation into Charge Height Ratio of Micro-Detonator on the Output Detonation Pressure
-
摘要: 为了适应MEMS引信微型传爆序列的需求,针对微型雷管装药高度比对输出威力的影响开展了专门研究。改变装药直径为0.9 mm、装药高度为3 mm的微型雷管中起爆药与猛炸药装药高度比,用猛铜压阻传感器对爆轰输出压力进行测定,得到微型雷管中起爆药的临界高度为0.36 mm。当起爆药高度为1.65 mm时,微型雷管爆轰压力值最大,为10.3 GPa;当起爆药高度小于1.65 mm,HMX炸药高度大于1.35 mm时,随着起爆药高度的减小,猛炸药高度的增加,微型雷管的爆压值减小;当起爆药高度大于1.65 mm、HMX炸药高度小于1.35 mm时,随着起爆药高度的增加,猛炸药高度的减小,微型雷管的爆压值也减小。初步得出了羧铅起爆药和猛炸药的最佳高度比范围为0.69~2.26。Abstract: In order to accommodate to the needs of micro-explosive train in MEMS fuze, this paper carried out a specific study about the influence of charge height on the output detonation pressure in micro-detonator. The charge diameter is 0.9 mm, total height is 3 mm. The charge ratio of primary explosive and high explosive was to be changed. The output detonation pressure was measured by manganin piezoresistance method. In the micro-detonator, the critical height of primary explosive PbN6 is 0.36 mm. When the primary explosive PbN6 height is 1.65 mm, the micro-detonator has the maximal output detonation pressure 10.3 GPa. When the primary explosive PbN6 height is less than or more than 1.65 mm, the high explosive HMX height is less than or more than 1.35 mm, and the output detonation pressure of the micro-detonator is reduced. The range of the primary explosive PbN6 and the high explosive HMX is 0.69~2.26.
-
Key words:
- micro-detonator /
- detonation pressure /
- critical height /
- best height ratio /
- MEMS explosive train
-
Robinson C H. MEMS Safety and Arming Device for OICW [A]//NDIA Small Arms Conference [C]. Little Rock, 2001. Robinson C H. Development and Demonstration of a MEMS-based Safety and Arming Device for the 20 mm OICW Fuze [A]//NDIA Joint Services Small Arms Conference [C]. Atlantic City, 2002: 27. Sanchez A C. MEMS Based Safe Arm Development for the XM29 (OICW) Weapon System Update [A]//2003 Joint Services Small Arms Section Symposium [C]. USA, 2003: 18. Sanchez A C.MEMS Based SA Development for 25 mm HEAB Munitions [A]//NDIA 50th Annual Joint Services Small Arms Symposium [C]. USA, 2004: 23. Cope R D. Naval Air Warfare Center Weapons Division [A]//NDIA 48th Annual Fuze Conference [C]. USA, 2004: 20. Cai R J. Explosive Initiator Design Principle [M]. Beijing: Beijing Institute of Technology Press, 1999: 181-214. (in Chinese) 蔡瑞娇. 火工品设计原理 [M]. 北京: 北京理工大学出版社, 1999: 181-214. Chen F M. Theory and Design of Explosive [M]. Beijing: Weapon Industry Press, 1990: 112-138. (in Chinese) 陈福梅. 火工品原理与设计 [M]. 北京: 兵器工业出版社, 1990: 112-138. Wang K W, Yang Z C, Wang D, et al. Influence of the Height Ratio of Micro Charge on the Output Detonation Pressure [J]. Initiators Pyrotechnics, 2008, 10(5): 31-33. (in Chinese) 王科伟, 杨正才, 王端, 等. 微型装药药高比对输出爆压的影响 [J]. 火工品, 2008, 10(5): 31-33. Claridge R P, Vine T A, Leggett A J. Investigations into MEMS Scale Detonators [A]//The Proceedings of the International Pyrotechnics Seminars [C]. Colorado, 2008: 175-179 (in USA) Xu X C, Jiao Q J, Cao X, et al. Attenuation Regularity of Detonation Waves of Small Charge in PMMA [J]. Energetic Materials, 2009, 17(4): 431-435. (in Chinese) 徐新春, 焦清介, 曹雄, 等. 小尺寸装药爆轰在有机玻璃隔板中的衰减规律 [J]. 含能材料, 2009, 17(4): 431-435. -
点击查看大图
计量
- 文章访问数: 8569
- HTML全文浏览量: 613
- PDF下载量: 705
下载:
