Modeling and simulation of muzzle flow field of railgun with metal vapor and arc 被引量：4

下载PDF

导出

摘要 During the electromagnetic railgun launching process,there will be a complex flow field with high temperature in the muzzle area because of the high-speed friction,transition and seco ndary arc-ignition.This paper models the muzzle area of railgun when the projectile is far away from the muzzle,and the dynamic simulation of the flow field with secondary arc in the muzzle area is carried out based on the magneto hydrodynamic equations.Meanwhile,a multi-component plasma transport model is used to analyze the muzzle arc plasma flow process of the mixed gas of Al vapor and the air.Furthermore,the pressure boundary conditions are fitted by the dynamic mesh simulation results.The current and voltage of the muzzle are obtained through the emission experiment of the railgun experimental prototype.We load the current data into the simulation model and the voltage of experiments and simulations are compared,which proves the accuracy of the simulation.Then the plasma temperature and the composition of Al vapor in the muzzle flow process are analyzed in-depth.

作者 Yuan Gao Yan-jie Ni Zhao-xin Wang Ying-tao Xu Yong Jin Bao-ming Li

机构地区 National Key Laboratory of Transient Physics China Academy of Ordnance

出处《Defence Technology（防务技术）》 SCIE EI CAS CSCD 2020年第4期802-810,共9页 Defence Technology

关键词 RAILGUN Flow field MUZZLE PLASMA SIMULATION Al vapor

分类号 TJ866 [兵器科学与技术—武器系统与运用工程]

引文网络
相关文献

参考文献2

1Yu-tao LOU,Hai-yuan LI,Bao-ming LI.Research on proximity effect of electromagnetic railgun[J].Defence Technology（防务技术）,2016,12(3):223-226. 被引量：7
2何勇,宋盛义,关永超,程诚,高贵山,李业勋,仇旭.电磁轨道炮高速滑动接触电阻的定量表征[J].强激光与粒子束,2014,26(4):81-84. 被引量：11

二级参考文献29

1Marshall R A,Ying W. Railguns:Their science and technology[M].Beijing:China Mach Press,2004.
2Bauer D P. Achieving high efficiency with conventional railgun launchers[J].IEEE Transactions on Magnetics,1995,(01):263-266.
3Barber J P,Bauer D P,Jamison K. A survey of armature transition mechanisms[J].IEEE Transactions on Magnetics,2003,(01):47-51.
4Haugh DC,Hainsworth MG. Why"C" armatures work (and why they don't!)[J].IEEETransonMagn,2003,(01):52-55.
5Siaenen T,Schneider M,Zacharias P. Rail gun muzzle velocity control with high accuracy[J].IEEE Transactions on Plasma Science,2012,(12):133-137.
6He Y,Guan Y C,Gap G S. Efficiency analysis of an electromagnetic railgun with a full circuit model[J].IEEE Transactions on Plasma Science,2011,(12):3425-3428.
7Engel T G,Neri JM,Verackav M J. Characterization of the velocity skin effect in the surface layer of a railgun sliding contact[J].IEEE Transactions on Magnetics,2008,(07):1837-1844.
8Barber J P,Dreizin Y. Model of contact transitioning with realistic armature-rail interface[J].IEEE Transactions on Magnetics,1995,(01):96-100.
9Parks B. Current melt wave model for transitioning solid armatures[J].Journal of Applied Physics,1990,(07):3511-3516.
10Stefani F,Parker J V. Experiments to measure wear in aluminum armatures[J].IEEE Transactions on Magnetics,1999,(01):100-106.

共引文献16

1何勇,程诚,宋盛义,关永超,高贵山,李业勋,仇旭.电磁轨道发射中炮口电弧的抑制[J].强激光与粒子束,2016,28(2):145-148. 被引量：7
2徐伟东,袁伟群,成文凭,付荣耀,张东东,严萍.小口径电磁轨道发射装置重复发射试验的不确定性[J].高电压技术,2016,42(9):2835-2842. 被引量：6
3张豪,谢龙,高俊杰,何勇.电磁轨道炮轨道形状对电流分布的影响[J].火炮发射与控制学报,2016,37(4):48-53. 被引量：8
4吴金国,李海元,程年凯,李龙,栗保明.电磁轨道炮电枢馈电位置研究[J].兵工学报,2017,38(6):1052-1058. 被引量：3
5王志恒,万敏,李小将.轨道炮电枢电动力转捩形成机理与仿真分析[J].系统仿真学报,2018,30(3):1090-1095. 被引量：4
6王振春,鲍志勇,曹海要,刘福才,战再吉,王大正.增强型电磁轨道炮电枢轨道接触特性研究[J].兵工学报,2018,39(3):451-456. 被引量：19
7Wei He,Xiangzhong Bai,Song Chen.Mechanical Analyses of Rails and Panels in a Rectangular Electromagnetic Rail Launcher[J].Journal of Harbin Institute of Technology(New Series),2018,25(5):53-60.
8Hong-cheng Xiao,Dong-mei Yin,Bao-ming Li.Electrodynamic response study on railgun launcher based on electromechanical coupling model[J].Defence Technology（防务技术）,2019,15(4):655-665. 被引量：2
9郝国成,李芯瑶,肖文历,马睿,金亚睿,杨文.数字化创新型趋肤效应验证仪设计[J].实验技术与管理,2019,36(12):90-93. 被引量：1
10王振春,董宗豪,鲍志勇,张玉婷,刘福才.电枢膛内高速运动控制仿真与试验[J].强激光与粒子束,2020,32(7):140-146.

同被引文献33

1党园,姜东飞,谷倩倩,周刚捷,马永吉,金立军.基于COMSOL热流固耦合的金属氧化物避雷器密封结构优化[J].高电压技术,2020,46(3):852-859. 被引量：7
2何柏林,孙佳.陶瓷基复合材料增韧技术的研究进展[J].粉末冶金工业,2009,19(4):48-53. 被引量：20
3王宝元,马春茂.国外火炮动力学发展综述[J].火炮发射与控制学报,2009,30(3):93-96. 被引量：7
4郭景坤.关于先进结构陶瓷的研究[J].无机材料学报,1999,14(2):193-202. 被引量：54
5王宝元.中大口径火炮射击密集度研究综述[J].火炮发射与控制学报,2015,36(2):82-87. 被引量：14
6何勇,程诚,宋盛义,关永超,高贵山,李业勋,仇旭.电磁轨道发射中炮口电弧的抑制[J].强激光与粒子束,2016,28(2):145-148. 被引量：7
7李丹,徐蓉,袁伟群,严萍.电磁发射装置绝缘支撑结构多场特性研究[J].电工电能新技术,2016,35(8):36-39. 被引量：7
8曹荣刚,苏明,李士忠,张庆霞,刘培柱,李军.脉冲大电流高速滑动电接触下轨道槽蚀现象的总结与分析[J].高电压技术,2016,42(9):2822-2829. 被引量：11
9林灵淑,赵莹,袁伟群,严萍.电磁轨道发射的瞬态温度效应[J].高电压技术,2016,42(9):2864-2869. 被引量：23
10王丽群,杨国来,刘俊民,葛建立.面向火炮射击密集度的随机因素稳健设计[J].兵工学报,2016,37(11):1983-1988. 被引量：9

引证文献4

1Bo Tang,Qing-hua Lin,Bao-ming Li.An optimization method for passive muzzle arc control devices in augmented railguns[J].Defence Technology（防务技术）,2022,18(2):271-279.
2Linfang Qian,Guangsong Chen,Minghao Tong,Jinsong Tang.General design principle of artillery for firing accuracy[J].Defence Technology（防务技术）,2022,18(12):2125-2140. 被引量：1
3胡鑫凯,鲁军勇,李白,谭赛,张嘉炜.瞬态条件下电磁轨道发射装置绝缘体热损伤分析[J].电工技术学报,2023,38(21):5673-5681.
4鲁军勇,胡鑫凯,谭赛,李白.电磁轨道发射装置绝缘支撑体研究现状及展望[J].华中科技大学学报（自然科学版）,2023,51(10):84-93.

二级引证文献1

1朱金达,董建国,张卫民,霍宁,郑明,黄风山.一种基于光电自准直法的装甲战车原位校炮系统[J].河北工业科技,2024,41(2):148-153.

1Uzu-Kuei Hsu,Pong-Jeu Lu.Dynamic Simulation and Hemolysis Evaluation of the Regurgitant Flow over a Tilting-Disc Mechanical Heart Valve in Pulsatile Flow[J].World Journal of Mechanics,2013,3(3):160-168. 被引量：1
2LI Zijie,WANG Hao.Influence of Different Velocities on Muzzle Flow Field[J].Transactions of Nanjing University of Aeronautics and Astronautics,2019,36(1):88-97.
3Zhuo Changfei,Feng Feng,Wu Xiaosong.Development process of muzzle flows including a gun-launched missile[J].Chinese Journal of Aeronautics,2015,28(2):385-386. 被引量：8
4Shiping Liu,Shujuan Zheng.Semi-Automatic Modeling Technique of Torque Converter Flow Passage[J].Modern Mechanical Engineering,2013,3(2):59-68. 被引量：3
5林启富,赵彦君,段文学,倪国华,靳兴月,隋思源,谢洪兵,孟月东.Characteristics of non-thermal AC arcs in multi-arc generator[J].Chinese Physics B,2019,28(12):255-267. 被引量：2
6Qing-hua Lin,Bao-ming Li.Numerical simulation of dynamic large deformation and fracture damage for solid armature in electromagnetic railgun[J].Defence Technology（防务技术）,2020,16(2):348-353. 被引量：8
7尹健宁,刘顺贵,唐峰,吕启深,李兴文.Convection effect on an arc plasma evolution process in a two parallel contact system[J].Plasma Science and Technology,2020,22(4):55-63.
8Shelbi Christgen,David E.Place,Thirumala-Devi Kanneganti.Toward targeting inflammasomes: insights into their regulation and activation[J].Cell Research,2020,30(4):315-327. 被引量：17
9GongNI,DingdingXIN,等.Two Optical Techniques Appropriate for Visualizing the Steady/Unsteady VorticalFlow past a Highly Swept Delta-Wing Equipped with Double Vortex-Flaps in Low and High Speed Wind-TUnnel[J].Communications in Nonlinear Science and Numerical Simulation,1998,3(3):167-172.
10潘子晗,叶雷,钱树楼,孙强,王城,叶桃红,夏维东.Comparison of Reynolds average Navier-Stokes turbulence models in numerical simulations of the DC arc plasma torch[J].Plasma Science and Technology,2020,22(2):60-72. 被引量：2

Defence Technology（防务技术）

2020年第4期

浏览历史

内容加载中请稍等...