弹膛偏移对小口径埋头枪弹挤进动态响应的影响

doi:10.12382/bgxb.2022.0380

摘要/Abstract

摘要： 为研究弹膛偏移对埋头弹挤进过程动态响应的影响，以小口径埋头枪弹为研究对象，考虑聚合物弹帽与枪管对弹头的共同作用，采用显式动力学方法，耦合经典内弹道方程，建立了动态挤进过程弹-枪相互作用数值仿真模型。分析弹膛偏移量对弹头质心偏量、膛内偏角和挤进阻力的影响，开展了弹帽结构优化设计，利用多参数同步测量技术进行埋头弹姿态和精度试验，验证了设计方案的有效性。研究结果表明，随着弹膛偏移量的增加，弹头挤进结束时质心偏量、膛内偏角和最大挤进阻力均增大，降低了埋头弹-枪系统的精度，影响了系统寿命和安全性，通过优化弹帽结构，可大幅度减小膛内运动质心偏量，改善弹头偏角和最大挤进阻力。研究成果为埋头弹-枪系统设计及优化提供了技术支撑。

关键词: 埋头弹, 弹-枪匹配, 动态挤进, 膛内姿态, 挤进阻力

Abstract: To study the effects of chamber offset on the dynamic response of small-caliber cased telescoped ammunition during engraving, we use explicit dynamic methods and couple classical internal ballistic equations while considering the combined effects of the polymer projectile cap and the barrel on the projectile. A numerical simulation model of bullet-barrel interactions during the dynamic engraving process is established. The effects of the chamber offset on the centroid offset, the in-bore declination angle, and the engraving resistance of the projectile are analyzed. The design of the projectile cap structure is optimized. Using multi-parameter synchronous measurement, the attitude measurement and accuracy experiments of the projectile are carried out, and the effectiveness of the optimization is verified. The results show that, with the increase of the chamber offset, the centroid offset, the in-bore declination angle, and the engraving resistance of the projectile all increase. Yet, the accuracy of the bullet/gun system will be reduced, and the system life and safety adversely affected. By optimizing the structure of the projectile cap, the in-bore centroid offset of the projectile can be significantly reduced, and the deviation angle and maximum engraving resistance reduced. The results can provide technical support for the design and optimization of the cased telescoped ammunition and gun system.

Key words: casedtelescopedammunition, bullet-barrelinteractions, dynamicengraving, projectilein-boreattitude, engravingresistance

中图分类号:

TJ203

许辉, 张瑞洁, 蒋明飞, 刘坤, 吴志林. 弹膛偏移对小口径埋头枪弹挤进动态响应的影响[J]. 兵工学报, 2022, 43(9): 2219-2230.

XU Hui, ZHANG Ruijie, JIANG Mingfei, LIU Kun, WU Zhilin. Effects of Chamber Offset on Dynamic Response of Small-caliber Cased Telescoped Ammunition During Engraving[J]. Acta Armamentarii, 2022, 43(9): 2219-2230.

参考文献

［1］ DIMITROY M.Analysis on the next generation assault rifles and ammunition designed for the US Army[J].Problemy Mechatroniki:Uzbrojenie，Lotnictwo，In[KG-*9]z·ynieria Bezpieczeństwa，2021，12（2）:91-109.
[2］ JENZEN-JONES N R，FITCH N.Cased telescoped ammunition: a technical and historical overview[R].Perth，Australia:Armament Research Services (ARES)，2019.
[3］ SPIEGEL K，SHIPLEY P.Lightweight small arms technologies[R].NJ，US:Army Armament Research Development and Engineering Center Picatinny Arsenal，2006.
[4］ CHEN C L，XU H，HUANG C L，et al. An experiment evaluating how the tiny mass eccentricities in spin-stabilized projectiles affect the position of impact points[J］.Defence Technology，2021，17(3): 948-960.
[5］ CHEN C L，XU H，HUANG C L，et al.Aerodynamic loading induced by muzzle flows on small caliber spin stabilized projectiles[J].Journal of Fluids Engineering，2020，142(2):021501.
[6］ GKRITZAPIS D N，PANAGIOTOPOULOS E E.In-bore yaw effects on lateral throw-off and aerodynamic jump behavior for small caliber projectiles firing sidewise from air vehicles[J].Journal of Applied Mechanics，2011，78(5):051017.
[7］ LU X，ZHOU Y H，YU Y G.Experimental study and numerical simulation of propellant ignition and combustion for cased telescoped ammunition in chamber[J].Journal of Applied Mechanics，2010，77(5):051402.
[8］ NUSCA M J，HORST A W，NEWILL J F.Multidimensional，two-phase simulations of notional telescoped ammunition propelling charge:ARL-TR-3673[R].MD，US:Army Research Lab Aberdeen Proving Ground，2004.
[9］ NUSCA M J，HORST A W.Progress in modeling ignition in a solid propellant charge for telescoped ammunition:ARL-TR-3673[R].MD，US:Army Research Lab Aberdeen Proving Ground，2005.
[10］ WANG J G，YU Y G，ZHOU L L，et al.Numerical simulation and optimized design of cased telescoped ammunition interior ballistic[J].Defence Technology，2018，14(2):119-125.
[11］ CAO Y J，YUE W L，LI X S，et al.Experimental study on initial ballistic characteristics of cased telescoped ammunition[J].Journal of Physics:Conference Series，2020，1507(10):102036.
[12］ CORRIVEAU D，PETRE C F.Influence of chamber misalignment on cased telescoped(CT) ammunition accuracy[J].Defence Technology，2016，12(2):117-123.
[13］王惠源，唐晨萍，程斌，等.枪弹不同姿态挤进膛内运动及枪口扰动分析[J].兵器装备工程学报，2021，42(1):14-19.
WANG H Y，TANG C P，CHENG B，et al.Analysis of bullet motion and muzzle disturbance in different concentricity[J].Journal of Ordnance Equipment Engineering，2021，42(1):14-19. (in Chinese)
[14］陆野，周克栋，赫雷，等.坡膛结构参数对枪械内弹道挤进时期的影响研究[J].兵工学报，2015，36(7):1363-1369.
LU Y，ZHOU K D，HE L，et al.Influence of structure parameters of forcing cone on small arms interior ballistics during engraving[J].Acta Armamentarii，2015，36(7):1363-1369.(in Chinese)
[15］刘国庆，徐诚.狙击步枪弹准静态弹头挤进力研究[J].兵工学报，2014，35(10):1528-1535.
LIU G Q，XU C.Research on quasi-static engraving force of sniper rifle bullet[J].Acta Armamentarii，2014，35(10):1528-1535. (in Chinese)
[16］ JOHNSON G R，COOK W H.Fracture characteristics of three metals subjected to various strains， strain rates，temperatures and pressures[J].Engineering Fracture Mechanics，1985，21(1):31-48.
[17］ LI J M，YAN W M，LU D B，et al.Sensitivity analysis of factors affecting for the engraving of rifle projectile[J]. Journal of Physics:Conference Series，2021，1721(1): 012050.
[18］ YANG Y Z，ZHANG X Y，XU C，et al.Dynamic stress analysis of anisotropic gun barrel under coupled thermo-mechanical loads via finite element method[J].Latin American Journal of Solids and Structures，2020，17(1):e243.
[19］ JOHNSON G R，COOK W H.A constitutive model and data for metals subjected to large strains，high strain rates and high temperatures[J].Engineering Fracture Mechanics，1983，21:541-548.
[20］刘国庆，徐诚，丁传俊.狙击步枪弹/枪相互作用数值研究[J].振动与冲击，2017，36(19):1-7.
LIU G Q，XU C，DING C J.Numerical calculation on the interaction between bullet and sniper rifle[J].Journal of Vibration and Shock，2017，36(19):1-7.(in Chinese)
[21］杨宇召，张晓云，徐诚.冷热枪状态下弹枪相互作用的热力耦合分析[J].振动与冲击 2020，39(10):44-51.
YANG Y Z，ZHANG X Y，XU C.The interaction between copper jacket projectile and barrel under different temperature based on thermo-mechanical coupling finite element model[J].Journal of Vibration and Shock，2020，39(10): 44-51. (in Chinese)
[22］周彦煌，王升晨.实用两相流内弹道学[M].北京:兵器工业出版社，1990.
ZHOU Y H，WANG S C.The study of two-phase flow property of interior ballistics[M].Beijing:Publishing House of Ordnance Industry，1990.(in Chinese)
[23］陈川琳，黄陈磊，许辉，等.小口径步枪弹头后效期运动特性试验与数值研究[J].兵工学报，2019，40(2):265-275.
CHEN C L，HUANG C L，XU H，et al.Experimental and numerical research on motion characteristics of a small caliber bullet in muzzle flows[J].Acta Armamentarii，2019， 40(2):265-275. (in Chinese)
[24］沈超，周克栋，陆野，等.某大口径机枪内膛损伤对弹头挤进过程的影响研究[J].兵工学报，2018，39(12):2320-2329.
SHEN C，ZHOU K D，LU Y，et al.Research on the influence of damaged bore of a large caliber machine gun on bullet engraving progress[J].Acta Armamentarii，2018，39(12):2320-2329. (in Chinese)
[25］梁昊，丁亚军，李世影，等.钝感双基发射药迁移失效评价方法[J].兵工学报，2022，43(2):297-304.
LIANG H，DING Y J，LI S Y，et al.Evaluation method for migration invalidation of deterred double-base gun propellants[J].Acta Armamentarii，2022，43(2):297-304. (in Chinese)
[26］赵其林，周宏伟，陈春林，等.轻武器用钝感发射药功能失效阈值预估方法[J].火炸药学报，2021，44(1):101-105.
ZHAO Q L，ZHOU H W，CHEN C L，et al. Prediction methodology of function failure threshold value of deterred gun propellant for firearms[J].Chinese Journal of Explosives and Propellants，2021，44(1):101-105.(in Chinese)

[1]	许辉，黄陈磊，王希阔，刘坤，李忠新，吴志林. 枪弹动态挤进阻力理论与实验研究[J]. 兵工学报, 2022, 43(9): 2263-2273.
[2]	李淼，钱林方，孙河洋. 某大口径火炮弹带热力耦合挤进动力学数值模拟研究[J]. 兵工学报, 2016, 37(10): 1803-1811.
[3]	孙全兆，杨国来，王鹏，葛建立，谢润. 某大口径榴弹炮弹带挤进过程数值模拟研究[J]. 兵工学报, 2015, 36(2): 206-213.