Journal of Ocean Engineering and Technology (한국해양공학회지)

Korean Society of Ocean Engineers (한국해양공학회)
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Simulation of Soil Behavior due to Dam Break Using Moving Particle Simulation

댐 붕괴에 의한 토양 거동 시뮬레이션

  • Kim, Kyung Sung (School of Naval Architecture and Ocean Engineering, Tongmyong University) ;
  • Park, Dong-Woo (School of Naval Architecture and Ocean Engineering, Tongmyong University)
  • 김경성 (동명대학교 조선해양공학부) ;
  • 박동우 (동명대학교 조선해양공학부)
  • Received : 2017.04.29
  • Accepted : 2017.10.30
  • Published : 2017.12.31
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Abstract

A Lagrangian approach based computational fluid dynamics (CFD) was used to simulate large and/or sharp deformations and fragmentations of interfaces, including free surfaces, through tracing each particle with physical quantities. According to the concept of the particle-based CFD method, it is possible to apply it to both fluid particles and solid particles such as sand, gravel, and rock. However, the presence of more than two different phases in the same domain can make it complicated to calculate the interaction between different phases. In order to solve multiphase problems, particle interaction models for multiphase problems, including surface tension, buoyancy-correction, and interface boundary condition models, were newly adopted into the moving particle semi-implicit (MPS) method. The newly developed MPS method was used to simulate a typical validation problem involving dam breaking. Because the soil and other particles, excluding the water, may have different viscosities, various viscosity coefficients were applied in the simulations for validation. The newly developed and validated MPS method was used to simulate the mobile beds induced by broken dam flows. The effects of the viscosity on soil particles were also investigated.

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References

  1. Gotoh, H., Fredsoe, J.R., 2000. Lagrangian Two-phase Flow Model of the Settling Behavior of Fine Sediment Dumped into Water. Coastal Engineering, 2000, 3906-3919.
  2. Janosi, I.M., Jan, D., Szabo, K.G., Tel, T., 2004. Turbulent Drag Reduction in Dam Break Flows. Experiments in Fluids, 37(2), 219-229. https://doi.org/10.1007/s00348-004-0804-4
  3. Khayyer, A., Gotoh, H., 2013. Enhancement of Performance and Stability of MPS Mesh-free Particle Method for Multiphase Flows Characterized by High Density Ratios. Journal of Computational Physics, 242, 211-233. https://doi.org/10.1016/j.jcp.2013.02.002
  4. Kim, H.S., Chen, H. C., 2014. Three-Dimensional Numerical Analysis of Sediment Transport Around Abutment in Channel Bend. Coastal Engineering Proceedings, 1(24), 21.
  5. Kim, K.S., Kim, M.H., Park, J.C., 2014. Development of Moving Particle Simulation Method for Multiliquid-Layer Sloshing, Mathematical Problems in Engineering, 2014, 350165.
  6. Koshizuka, S., Oka, Y., 1996. Moving-particle Semi-implicit Method for Fragmentation of Incompressible Fluid. Nuclear Science and Engineering, 123(3), 421-434. https://doi.org/10.13182/NSE96-A24205
  7. Lee, B.H., Park, J.C., Kim, M.H., Hwang, S.C., 2011. Step-by-step Improvement of MPS Method in Simulating Violent Free-surface Motions and Impact-loads. Computer Methods in Applied Mechanics and Engineering, 200(9), 1113-1125. https://doi.org/10.1016/j.cma.2010.12.001
  8. Monaghan, J.J., 1994. Simulating Free Surface Flows with SPH. Journal of Computational Physics, 110.2, 399-406. https://doi.org/10.1006/jcph.1994.1034
  9. Tanaka, M., Masunaga, T., 2010. Stabilization and Smoothing of Pressure in MPS Method by Quasi-compressibility. Journal of Computational Physics, 229(11), 4279-4290. https://doi.org/10.1016/j.jcp.2010.02.011
  10. Xu, R., Stansby, P., Laurence, D., 2009. Accuracy and Stability in Incompressible SPH(ISPH) Based on the Projection Method and a New Approach. Journal of Computational Physics, 228(18), 6703-6725. https://doi.org/10.1016/j.jcp.2009.05.032