DOI QR코드

DOI QR Code

전투차량의 피해 정도를 계산하기 위한 수치해석적 접근법

Numerical Analysis Approach to Calculate the Damage Degree of the Combat Vehicle

  • 조아현 (명지대학교 기계공학과) ;
  • 박강 (명지대학교 기계공학과) ;
  • 김건인 (건국대학교 방위사업학과)
  • Cho, A Hyoun (Dept. of Mechanical Engineering, Myong-ji Univ.) ;
  • Park, Kang (School of Mechanical Engineering, Myong-ji Univ.) ;
  • Kim, Gun In (Dept. of Defense of Business, Konkuk Univ.)
  • 투고 : 2016.12.16
  • 심사 : 2017.02.28
  • 발행 : 2017.06.01

초록

In order to reduce the number of casualties by improving the survivability of the combat vehicle, the vulnerability analysis of the combat vehicle is needed. However, the actual test for the vulnerability analysis requires large experimental space and expensive equipment costs long time and large expense. It is needed to develop a new method that can replace the actual test. In the paper, we suggested a new approach to analyzing the vulnerability using the M&S method instead of the actual test. To analyze the vulnerability, the shot line analysis is performed to find out which part is penetrated by the bullet. The component of the parts is simplified to "Single-Target", "Double-Target", "Air gapped-Target" and can be performed the penetration analysis using the ANSYS Explicit Dynamics. The penetration depth and the residual velocity of the bullet are calculated by analyzing penetration of each part of the combat vehicle. The penetration data calculated the penetration analysis can be used to define the damage level of the combat vehicle. The purpose of this paper is to collect penetration data for various targets and bullets. And "7.62mmAP" is used as the bullet, "7075-T6" is used as a target.

키워드

참고문헌

  1. Jine, G.-C. and Choe, C., 1992, The Vulnerability Analysis of the Combat Vehicle and Reduction Techniques, National Defense and Technique, No.166, pp.48-55.
  2. Hwang, H.-G., Lee, J.-W., Lee, J.-S., and Park, J.-S., 2015, A Development of 3D Penetration Analysis Program for Survivability Analysis of Combat System: Focused on Tank Model, The Korea Institute of Information and Communication Engineering, Vol.19.
  3. Forrestal, M.J., Borvik, T. and Warren, T.L., 2010, Perforation of 7075-T651 Aluminum Armor Plates with 7.62mm APM2 Bullets. Experimental Mechanics October, 50(8), pp.1245-1251.
  4. Yoo, C. and Jang, E.-S., 2015, The Target Modeling and the Shot Line Analysis System to Assess Vulnerability of the Ground Combat Vehicle, Korean Journal of Computational Design and Engineering, 20(3), pp.238-245. https://doi.org/10.7315/CADCAM.2015.238
  5. Namuwiki manual, (https://namu.wiki/w/%ED%94%BC%EB%AA%A8%EC%B2%A0%EA%B0%91%ED%83%84)
  6. FEM Bank manual, (http://www.geocities.ws/hiteace/Intro/Principal/Mesh_Density.html)
  7. ANSYS manual, (http://www.ansys.com/ko-KR/Products/Structures)
  8. Kim, H.-G. and Kim, S.C., 2012, Numerical Simulation of Bullet Impact for Fuel Cell of Rotorcraft, Journal of the Computational Structural Engineering Institute of Korea, 25(5), pp.405-411. https://doi.org/10.7734/COSEIK.2012.25.5.405
  9. Naury K., Birnbbaum, Malcolm Cowler., 1996, Numerical Simulation of Impact Using Autodyn. In proceedings.
  10. Krishnan, K. and Sockalingam, S., 2010, Numerical Simulation of Ceramic Composite Armor Subjected to Ballistic Impact, ELSEVIER, 41(8), pp.583-593.