Development of a reliable and adaptive multi-physics computational method for fluid-structure interactions encountered in ocean/coastal engineering

• Project/Area Number: 18K04368
• Research Category: Grant-in-Aid for Scientific Research (C)
• Allocation Type: Multi-year Fund
• Section: 一般
• Review Section: Basic Section 22040:Hydroengineering-related
• Research Institution: Kyoto University
• Principal Investigator: Khayyer Abbas 京都大学, 工学研究科, 准教授 (80534263)
• Project Period (FY): 2018-04-01 – 2022-03-31
• Project Status: Completed (Fiscal Year 2021)
• Budget Amount: ¥3,640,000 (Direct Cost: ¥2,800,000、Indirect Cost: ¥840,000); Fiscal Year 2021: ¥650,000 (Direct Cost: ¥500,000、Indirect Cost: ¥150,000); Fiscal Year 2020: ¥650,000 (Direct Cost: ¥500,000、Indirect Cost: ¥150,000); Fiscal Year 2019: ¥520,000 (Direct Cost: ¥400,000、Indirect Cost: ¥120,000); Fiscal Year 2018: ¥1,820,000 (Direct Cost: ¥1,400,000、Indirect Cost: ¥420,000)
• Keywords: particle method / FSI / hydroelastic / composite structures / adaptivity / anisotropic / multiphysics / multi-phase / elasticity / multiphase / boundary conditions / elastic structures / multi-physics / multi-resolution

Outline of Final Research Achievements

The target of this research, i.e. development of an advanced adaptive and multi-physics computational method for hydroelastic FSI, has been achieved through coherent and rigorous developments made with respect to aspects of reliability, adaptivity and generality. A computational method has been developed capable of reproducing hydroelastic FSI including those corresponding to anisotropic composite structures in both 2D and 3D.
The computational method provides possible selection of either Newtonian or Hamiltonian structure model as well as SPH or MPS formalism. With material discontinuities in composites, a robust Hamiltonian structure model was developed and coupled with a fluid model, resulting in ISPH-HSPH FSI solver as the first entirely Lagrangian meshfree method for hydroelastic FSI corresponding to composite structures. The solver was also extended to 3D and carefully modified for structural material anisotropy. These developments are published in a set of international journals.

Academic Significance and Societal Importance of the Research Achievements

持続可能な粘り強い海岸構造物の設計のためには複雑な流体と構造物の相互作用（FSI）に関する深い知見が不可欠である．本研究で提案した計算手法はメッシュフリーかつラグランジュ的な解析手法であり，流体・構造体およびその連成のモデル化を厳密な数学的・物理的背景に基づいて導出した，海岸工学FSI現象の高精度かつロバストな解析が可能な手法である．FSI現象の詳細なメカニズムを数値的に検討可能な高精度数値計算手法を開発したことに本研究の社会的意義がある．さらに学術的な意義として，近年世界中で盛んに研究される粒子法の更なる高精度化の実施およびマルチフィジックス現象への高い潜在的適応性の証示があげられる．

Research Products

• [Journal Article] An SPH-based fully-Lagrangian meshfree implicit FSI solver with high-order discretization terms (2022)
  • Author(s): Shimizu Yuma、Khayyer Abbas、Gotoh Hitoshi
  • Journal Title: Engineering Analysis with Boundary Elements Volume: 137 Pages: 160-181
  • DOI: 10.1016/j.enganabound.2021.10.023
  • Peer Reviewed
• [Journal Article] A 3D Lagrangian meshfree projection-based solver for hydroelastic Fluid Structure Interactions (2021)
  • Author(s): Khayyer Abbas、Gotoh Hitoshi、Shimizu Yuma、Nishijima Yusuke
  • Journal Title: Journal of Fluids and Structures Volume: 105 Pages: 103342-103342
  • DOI: 10.1016/j.jfluidstructs.2021.103342
  • Peer Reviewed
• [Journal Article] Entirely Lagrangian meshfree computational methods for hydroelastic fluid-structure interactions in ocean engineering - Reliability, adaptivity and generality (2021)
  • Author(s): Gotoh Hitoshi、Khayyer Abbas、Shimizu Yuma
  • Journal Title: Applied Ocean Research Volume: 115 Pages: 102822-102822
  • DOI: 10.1016/j.apor.2021.102822
  • Peer Reviewed
• [Journal Article] Particle methods in ocean and coastal engineering (2021)
  • Author(s): Luo Min、Khayyer Abbas、Lin Pengzhi
  • Journal Title: Applied Ocean Research Volume: 114 Pages: 102734-102734
  • DOI: 10.1016/j.apor.2021.102734
  • Peer Reviewed / Int'l Joint Research
• [Journal Article] A coupled incompressible SPH-Hamiltonian SPH solver for hydroelastic FSI corresponding to composite structures (2021)
  • Author(s): Abbas Khayyer, Yuma Shimizu, Hitoshi Gotoh, Ken Nagashima
  • Journal Title: Applied Mathematical Modelling Volume: 94 Pages: 242-271
  • DOI: 10.1016/j.apm.2021.01.011
  • Peer Reviewed
• [Journal Article] Multi-resolution ISPH-SPH for accurate and efficient simulation of hydroelastic fluid-structure interactions in ocean engineering (2021)
  • Author(s): Abbas Khayyer, Yuma Shimizu, Hitoshi Gotoh, Shunsuke Hattori
  • Journal Title: Ocean Engineering Volume: 226 Pages: 108652-108652
  • DOI: 10.1016/j.oceaneng.2021.108652
  • Peer Reviewed
• [Journal Article] 3D MPS-MPS coupled FSI solver for simulation of hydroelastic fluid-structure interactions in coastal engineering (2020)
  • Author(s): Abbas KHAYYER, Hitoshi GOTOH, Yuma SHIMIZU, Yusuke NISHIJIMA, Akari NAKANO
  • Journal Title: Journal of Japan Society of Civil Engineers, Ser. B2 (Coastal Engineering) Volume: 76 Issue: 2 Pages: I_37-I_42
  • DOI: 10.2208/kaigan.76.2_I_37
  • NAID: 130007935796
  • ISSN: 1883-8944, 1884-2399
• [Journal Article] Enhancement of pressure calculation in projection-based particle methods by incorporation of background mesh scheme (2019)
  • Author(s): Lizhu Wang, Abbas Khayyer, Hitoshi Gotoh, Qin Jiang, Changkuan Zhang
  • Journal Title: Applied Ocean Research Volume: 86 Pages: 320-339
  • DOI: 10.1016/j.apor.2019.01.017
  • Peer Reviewed / Int'l Joint Research
• [Journal Article] A projection-based particle method with optimized particle shifting for multiphase flows with large density ratios and discontinuous density fields (2019)
  • Author(s): Abbas Khayyer, Hitoshi Gotoh, Yuma Shimizu
  • Journal Title: Computers & Fluids Volume: 179 Pages: 356-371
  • DOI: 10.1016/j.compfluid.2018.10.018
  • Peer Reviewed
• [Journal Article] Multi-resolution MPS for incompressible fluid-elastic structure interactions in ocean engineering (2019)
  • Author(s): Abbas Khayyer, Naoki Tsuruta, Yuma Shimizu, Hitoshi Gotoh
  • Journal Title: Applied Ocean Research Volume: 82 Pages: 397-414
  • DOI: 10.1016/j.apor.2018.10.020
  • Peer Reviewed
• [Journal Article] An enhanced ISPH-SPH coupled method for simulation of incompressible fluid-elastic structure interactions (2018)
  • Author(s): Abbas Khayyer, Hitoshi Gotoh, Hosein Falahaty, Yuma Shimizu
  • Journal Title: Computer Physics Communications Volume: 232 Pages: 139-164
  • DOI: 10.1016/j.cpc.2018.05.012
  • Peer Reviewed
• [Presentation] Development of an accurate updated Lagrangian SPH structure model for simulation of laminated composite structures (2022)
  • Author(s): Abbas Khayyer, Hitoshi Gotoh, Yuma Shimizu
  • Organizer: 2022 SPHERIC Xi'an International Workshop
  • Int'l Joint Research
• [Presentation] Entirely Lagrangian Meshfree Methods for Hydroelastic Fluid-Structure Interactions - Recent Advances and Future Perspectives (2022)
  • Author(s): Abbas Khayyer
  • Organizer: The 5th CMHL International Symposium 2022
  • Int'l Joint Research / Invited
• [Presentation] A novel 3D entirely Lagrangian meshfree hydroelastic FSI solver for anisotropic composite structures (2021)
  • Author(s): Abbas Khayyer, Yuma Shimizu, Hitoshi Gotoh, Shunsuke Hattori
  • Organizer: 15th SPHERIC International Workshop
  • Int'l Joint Research
• [Presentation] A coupled Incompressible SPH-Hamiltonian SPH solver for hydroelastic FSI corresponding to composite structures (2021)
  • Author(s): Abbas Khayyer, Yuma Shimizu, Hitoshi Gotoh, Ken Nagashima
  • Organizer: 第68回海岸工学講演会
• [Presentation] Development of entirely lagrangian meshfree hydroelastic FSI solvers - reliability, adaptivity and generality (2020)
  • Author(s): Abbas Khayyer
  • Organizer: Second International Workshop of Numerical Modelling of Wave-Structure Interaction
  • Int'l Joint Research / Invited
• [Presentation] Towards development of entirely Lagrangian meshfree computational methods for hydroelastic fluid-structure interactions in coastal engineering (2020)
  • Author(s): Abbas Khayyer
  • Organizer: 8th International Conference on the Application of Physical Modelling in Coastal and Port Engineering and Science (Coastlab 2020)
  • Int'l Joint Research / Invited
• [Presentation] A 3D Fully Lagrangian Meshfree Hydroelastic Solver; 3D ISPH-SPH (2020)
  • Author(s): Abbas Khayyer, Hitoshi Gotoh, Yuma Shimizu, Hiroshi Sasagawa, Akari Nakano
  • Organizer: The 30th International Ocean and Polar Engineering Conference
  • Int'l Joint Research
• [Presentation] Multi-resolution ISPH-SPH for accurate and efficient simulation of hydroelastic fluid-structure interactions in coastal engineering (2019)
  • Author(s): Abbas Khayyer, Yuma Shimizu, Hitoshi Gotoh, Shunsuke Hattori
  • Organizer: 第66回海岸工学講演会
• [Presentation] Development of 3D fully Lagrangian meshfree solvers for hydroelastic fluid-structure interactions (2019)
  • Author(s): Khayyer, A., Gotoh, H., Shimizu, Y., Nishijima, Y.
  • Organizer: SPHERIC 2019 International Workshop
  • Int'l Joint Research
• [Presentation] Development of consistent, conservative and accurate multi-resolution projection-based particle methods for hydroelastic fluid-structure interactions (2018)
  • Author(s): Khayyer, A., Gotoh, H., Shimizu, Y., Tsuruta, N. and Sasagawa, H.
  • Organizer: 13th International SPHERIC Workshop
  • Int'l Joint Research
• [Presentation] Key Aspects for Development of Reliable and Efficient Fully-Lagrangian Computational Methods for Hydroelastic Fluid-Structure Interactions (2018)
  • Author(s): Khayyer, A., Gotoh, H., Falahaty, H., Shimizu, Y.
  • Organizer: The 8th International Conference on Hydroelasticity in Marine Technology
• [Presentation] Advanced Fully-Lagrangian Mesh-Free Computational Methods for Hydroelastic Fluid-Structure Interactions in Ocean Engineering (2018)
  • Author(s): Khayyer, A. and Gotoh, H.
  • Organizer: The Thirteenth ISOPE Pacific/Asia Offshore Mechanics Symposium (PACOMS 2018)
  • Int'l Joint Research / Invited