Abstract
To explore the impact destruction process of blade missiles hitting automobile targets, the model including a blade missile and a car is established based on the structural characteristics and the combat environment. According to the Mie-Grüneisen equation of state, the Johnson–cook material constitutive and damage failure model are used for the blade missile and automobile. Then, finite element software is applied to analyze the penetration process, and the dynamic response of the blade missile hitting a car is calculated with different initial velocities and incidence angles. The results show that the penetration area is positively correlated with the incident angle at a certain velocity. However, the energy carried is still great after completing penetration at high initial velocity of the missile. these results provide an important theoretical basis for the development of the blade missile.
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References
**n Z, Zhang X, Jiang R et al (2022) Influence of warhead angular velocity and penetration angle on damage performance of aluminum alloy sheet. J Ballistics 34(04):23–29
Chen Y, Tan C, Guo Y (2022) Comparative study of numerical simulations of projectile penetration into metal targets. Explosion Shock Waves 42(04):111-127
Du H, Zhang X, Liu C et al (2021) Trajectory characteristics of projectile obliquely penetrating into steel target with multi-layer S-pace structure. Acta Armamentarii 42(06):1204–1214
Wang J, Zhao J, Zhang J et al (2021) Research on mechanism and model of penetration into metallic thick target finite in radial extent by rigid projectile. Eng Mech 38(07):239–247
Johnson GR, Cook WHA (1983) Constitutive model and data for metals subjected to large strains, high strain rates and high temperatures. In: Proceeding of the 7th international symposium ballistics 541–547
**n C, Xue Z, Tu J et al (2020) Finite element analysis common material parameter manual. China Machine Press, Bei**g
Zhou X (2014) Missile damage effectiveness and assessment. National Defense Industry Press, Bei**g
Holmquist TJ, Johnson GR (1993) A computational constitutive model for concrete subjected to large strains, high strain rates, and high pressures. In: 14th international symposium on ballistics, Quebec City, Canada, pp 591–600
David L, Littlefield, Charles E et al (1997) The penetration of steel targets finite in radial extent. Int J Impact Eng 19(1):49–62
Robbins JR, Ding JL, Gupta YM (2004) Load spreading and penetration resistance of layered structures-A numerical study. Int J Impact Eng 30(6):593–615
Gupta NK, Ansari R, Gupta SK (2001) Normal impact of ogive nosed projectiles on thin plates. Int J Impact Eng 25:641–660
Huang J, Xu X (2007) Numerical simulations for perforation of aircraft thin plate structures. Ordnance Mater Sci Eng 30(2):17–22
Wu X, Liu J, Zhang L et al (2018) Numerical simulation analysis of petaling formation process of plate penetrated by sharp-nosed missile. Chin J Ship Res 13(3):110–117
Acknowledgements
This work is supported by the Ministry of Education Chunhui Program Cooperative Research Project of China (No. HZKY20220517) and Natural Science Basic Research Plan in Shaanxi Province of China (No. 2022JQ-021).
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Zhang, M., Huang, S., Yang, W., Ma, G., Jia, J. (2024). Impact Effect Analysis of a Special Blade Missile Hitting a Car Target. In: Rui, X., Liu, C. (eds) Proceedings of the 2nd International Conference on Mechanical System Dynamics. ICMSD 2023. Lecture Notes in Mechanical Engineering. Springer, Singapore. https://doi.org/10.1007/978-981-99-8048-2_271
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DOI: https://doi.org/10.1007/978-981-99-8048-2_271
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