한국CDE학회논문집 (Korean Journal of Computational Design and Engineering)

  • 제18권6호
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  • Pages.461-469
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  • 2013
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  • 2508-4003(pISSN)
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  • 2508-402X(eISSN)
한국CDE학회 (Society for Computational Design and Engineering)
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폭발현상 해석을 위한 적응적 요소망 생성

Adaptive Mesh Refinement for Dealing with Shock Wave Analysis

  • 전용태 (세종대학교 기계공학과) ;
  • 이민형 (세종대학교 기계공학과)
  • Jun, Yongtae (Department of Mechanical Engineering, Sejong University) ;
  • Lee, Minhyung (Department of Mechanical Engineering, Sejong University)
  • 투고 : 2013.07.15
  • 심사 : 2013.11.04
  • 발행 : 2013.12.01
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초록

Computer simulation with FEM is very useful to analyze hypervelocity impact phenomena that are tremendously expensive or otherwise too impractical to analyze experimentally. Shock physics can be efficiently handled by mesh adaptation which allows finite element mesh to be locally optimized to resolve moving shock wave in explosion. In this paper, an adaptive meshing technique based upon quadtree data structure was applied to resolve ballistic impact phenomena. The technique can adaptively refine a mesh in the neighborhood of a shock and coarsen the mesh for the smooth flow behind the shock according to a criterion. The criterion for refinement and coarsening is based upon the standard deviation of the gradient of shock pressure on the associated field. Shock simulation starts with the rough mesh of the pressure field and mesh density is increased locally under the criterion at each time step. The results show that the mesh adaptation enables to minimize the global computation error of FEM and to increase storage and computational saving compared to the fixed resolution of the conventional static mesh approach.

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참고문헌

  1. Kim, I. and Baek, M.S., 2006, Explosion Phenomenon and High Pressure Physics, Physics and High Technology, January/February, 15, pp.31-35.
  2. Kim, Y.M., 2011, Dynamic Behavior Analysis of Tunnel Structure under Gas Explosion Load, Journal of Korean Tunneling and Underground Space Association, 13(5), pp.413-430.
  3. Youn, C. and Jeong, Y.C., 2005, Adaptive Generation for Dynamic Finite Element Analysis, Journal of Korean Society of Civil Engineers, 25(6A), pp.989-998.
  4. Berger, M.J., 1984, Adaptive Mesh Refinement for Hyperbolic Partial Differential Equations, Journal of Computational Physics, 53, pp.484-512. https://doi.org/10.1016/0021-9991(84)90073-1
  5. Berger, M.J., 1989, Local Adaptive Mesh Refinement for Shock Hydrodynamics, Journal of Computational Physics, 82, pp.64-84. https://doi.org/10.1016/0021-9991(89)90035-1
  6. Jung, M.K. and Kwon, O.J., 2011, Development of a 2-dimensional Flow Solver using Hybrid Unstructured and Adaptive Cartesian Meshes, Proceedings Korean Society of Computational Fluids Engineering, Jeju, Korea, pp.294-301.
  7. De Zeeuw, D.L., 1993, Topological Structures for Geometric Modeling A Quadtree-based Adaptively-Refined Cartesian-Grid Algorithm for Solution of the Euler Equations, Ph.D. Thesis, University of Michigan.
  8. Franke, D., Duster, A., Nubel, V. and Rank, E., 2010, A Comparison of the h-, p-, hp-, and rp-Version of the FEM for the Solution of the 2D Hertzian Contact Problem, Computational Mechanics, 45, pp.513-522. https://doi.org/10.1007/s00466-009-0464-6
  9. Department of the US Army, 1986, Fundamentals of Protective Design for Conventional Weapons, Technical Manual, TM 5-855-1.