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| Numerical simulation of stress wave penetrating a water tank using the ghost material method |
| SHI Ruchao1,2,SUN Xiaowang3 |
1. College of Science, Jiangsu Ocean University, Lianyungang 222005, China;
2. Lianyungang Zhongfu Lianzhong Composites Group Co., Ltd., Lianyungang 222023, China;
3. School of Mechanical Engineering, Nanjing University of Science and Technology, Nanjing 210094, China |
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Abstract The ghost material method was extended to the interaction between stress wave and fluid-solid interface. An interfacial calculation algorithm based on modified ghost fluid method (MGFM) was proposed for stress wave refraction on fluid-solid interface. On this basis, we used the Zwas scheme and the WENO scheme, respectively, to discretize solid and fluid governing equations to numerically simulate stress wave penetrating water tanks. Numerical test shows that the ghost material method was convergent when applied for stress wave impacting at fluid-solid interface. The presented calculation algorithm has first order numerical accuracy. 1D numerical results coincide well with the exact solutions. This verifies the feasibility of the extension of the Ghost Material Method to stress wave reflection and transmission on fluid-solid interface. Numerical results of stress wave penetrating the water tank show that (i) the results by the ghost material method are closed to those by the arbitrary-Lagrangian-Eulerian (ALE) method, (ii) the intensity of the transmitted wave increases to some extent after increasing the pressure of water tank, (iii) stress wave refractions in the vicinity of fluid-solid interface are very closed under different pressures. The conclusions are practically significant to ship defense and design.
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Received: 14 August 2019
Published: 28 April 2021
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[1]任鹏,张伟,黄威,等. 非药式水下爆炸冲击波加载装置研究[J]. 爆炸与冲击,2014, 34(3): 334-349.
REN Peng, ZHANG Wei, HUANG Wei, et al. Research on non-explosive underwater shock loading device [J]. Explosion and Shock Waves, 2014, 34(3): 334-349.
[2]任鹏,张伟,刘建华,等. 高强度水下爆炸等效冲击波加载特性研究[J]. 兵工学报,2015,36(4): 716-722.
REN Peng, ZHANG Wei, LIU Jianhua, et al. Characterisitcs of high strength underwater explosion equivalent shock loading [J]. Acta Armamentarii, 2015, 36(4):716-722.
[3]王长利,周刚,马坤,等. 典型含水复合结构在聚能装药水下爆炸作用下的毁伤[J]. 船舶力学,2018, 22(8): 1001-1010.
WANG Changli, ZHOU Gang, MA Kun, et al. Damage analysis of typical water partitioned structure under shaped charge underwater explosion [J]. Journal of Ship Mechanics, 2018, 22(8): 1001-1010.
[4]ANTOCI C, GALLATI M, SIBILLA S. Numerical simulation of fluid-structure interaction by SPH[J]. Computers and Structures, 2007, 85 (11/13/14): 879-890.
[5]HIRT C W, AMSDEN A A, COOK J L. An arbitrary Lagrangian-Eulerian computing method for all flow speeds[J]. Journal of Computational Physics, 1974, 14 (3): 227-253.
[6]LIU T G, HO J, KHOO B C, et al. Numerical simulation of fluid-structure interaction using modified ghost fluid method and naviers equations[J]. Journal of Scientific Computing, 2008, 38: 45-68.
[7]KABOUDIAN A, KHOO B C. The ghost solid method for the elastic solid-solid interface[J]. Journal of Computational Physics, 2014, 257 (2): 102-125.
[8]FEDKIW R, ASLAM T, MERRIMAN B. A non-oscillatory Eulerian approach to interfaces in multimaterial flows (the ghost fluid method) [J]. Journal of Computational Physics, 1999, 52: 457-492.
[9]LIU T G, KHOO B C, YEO K S. Ghost fluid method for strong shock impacting on material interface[J]. Journal of Computational Physics, 2003, 190 (2) :651-681.
[10]WANG C W, LIU T G, KHOO B C. A real ghost fluid method for the simulation of multimedium compressible flow[J].SIAM Journal on Scientific Computing, 2005, 128: 278-232.
[11]XU L, LIU T. The modified ghost fluid method as applied to fluid-plate interaction [J]. Advances in Applied Mathematics and Mechanics, 2014, 6 (1): 24-48.
[12]FENG Z, RONG J, KABOUDIAN A, et al. The modified ghost method for compressible multi-medium interaction with elastic-plastic solid[J]. Communications in Computational Physics, 2017, 22(5): 1258-1285.
[13]SHI R, QU Y, BATRA R C. Numerical simulation of underwater explosion wave propagation in water-solid-air/water system using ghost fluid/solid method[J]. Journal of Fluids and Structures, 2019, 90: 354-378.
[14]ASLAM T. A partial differential equation approach to multidimensional extrapolation[J]. Journal of Computational Physics, 2004, 193: 349-355.
[15]EILON B, GOTTLIEB D, ZWAS G. Numerical stabilizers and computing time for second-order accurate schemes [J]. Journal of Computational Physics, 1972, 9: 387-397.
[16]SHU C W. Essentially non-oscillatory and weighted essentially non-oscillatory schemes for hyperbolic conservation laws: ICASE-97-65[R]. Providence: Brown University, 1997.
[17]童秉纲. 气体动力学[M]. 北京:高等教育出版社,2012.
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