TY - GEN
T1 - Effects of Coupling Strategy on Performance of Overlapping Particle Technology for SPH Method
AU - Luo, Jianqiao
AU - Yu, Ning
AU - Meng, Junhui
N1 - Publisher Copyright:
© The Author(s), under exclusive license to Springer Nature Switzerland AG 2025.
PY - 2025
Y1 - 2025
N2 - The Smoothed Particle Hydrodynamics (SPH) method has been widely applied to study complex flows with free surfaces for its capability to accurately capture large deformations. However, fully exploiting its advantages requires a sufficiently fine resolution, which can be computationally intensive. The Overlapping Particle Technique (OPT) divides the original problem domain into multiple sub-domains, allowing for variable resolutions and avoiding interactions among particles of different masses, thereby reducing computational efforts. The coupling between the sub-domains is the primary factor that affects the accuracy and stability of the solution. In this paper, a one-way OPT framework is presented for dam-break flow to investigate the inherent relationship between coupling strategy and computational performance. Two sub-domains are utilized to model the entire physical fields, in which the one with higher resolution is fully covered by the other, and an inlet-outlet boundary is added at the overlapping region to maintain the coupling. To improve computational efficiency, the position-based Verlet integration scheme is employed, and time marching is controlled by dual time-stepping criteria. Through numerical simulations based on the Weak Compressible SPH scheme, the effects of interpolation formulas, particle generation positions, and the resolution ratio between sub-domains on the solutions of 2D dam-break flow are explored and analyzed. The results demonstrate that the corrected interpolation formula outperforms the conventional formula in nearly all cases. Moreover, a smaller spacing of particle generation positions typically results in higher accuracy, while a sparsely distributed candidate position may lead to the formation of non-physical cavities near the inlet-outlet boundary. Additionally, the resolution ratio has a relatively minor impact when the corrected interpolation is adopted, whereas a large resolution ratio can reduce the error via the smoothing effect when the interpolation is based on the conventional formula. This work can provide a valuable reference for the research and application of the OPT for the SPH method.
AB - The Smoothed Particle Hydrodynamics (SPH) method has been widely applied to study complex flows with free surfaces for its capability to accurately capture large deformations. However, fully exploiting its advantages requires a sufficiently fine resolution, which can be computationally intensive. The Overlapping Particle Technique (OPT) divides the original problem domain into multiple sub-domains, allowing for variable resolutions and avoiding interactions among particles of different masses, thereby reducing computational efforts. The coupling between the sub-domains is the primary factor that affects the accuracy and stability of the solution. In this paper, a one-way OPT framework is presented for dam-break flow to investigate the inherent relationship between coupling strategy and computational performance. Two sub-domains are utilized to model the entire physical fields, in which the one with higher resolution is fully covered by the other, and an inlet-outlet boundary is added at the overlapping region to maintain the coupling. To improve computational efficiency, the position-based Verlet integration scheme is employed, and time marching is controlled by dual time-stepping criteria. Through numerical simulations based on the Weak Compressible SPH scheme, the effects of interpolation formulas, particle generation positions, and the resolution ratio between sub-domains on the solutions of 2D dam-break flow are explored and analyzed. The results demonstrate that the corrected interpolation formula outperforms the conventional formula in nearly all cases. Moreover, a smaller spacing of particle generation positions typically results in higher accuracy, while a sparsely distributed candidate position may lead to the formation of non-physical cavities near the inlet-outlet boundary. Additionally, the resolution ratio has a relatively minor impact when the corrected interpolation is adopted, whereas a large resolution ratio can reduce the error via the smoothing effect when the interpolation is based on the conventional formula. This work can provide a valuable reference for the research and application of the OPT for the SPH method.
KW - Dam-break flow
KW - Interpolation formula
KW - Multi-resolution
KW - Overlapping particle technique
KW - Particle generation
KW - Smoothed particle hydrodynamics
UR - http://www.scopus.com/inward/record.url?scp=85215566396&partnerID=8YFLogxK
U2 - 10.1007/978-3-031-81673-4_67
DO - 10.1007/978-3-031-81673-4_67
M3 - Conference contribution
AN - SCOPUS:85215566396
SN - 9783031816727
T3 - Mechanisms and Machine Science
SP - 911
EP - 931
BT - Computational and Experimental Simulations in Engineering - Proceedings of ICCES 2024 — International Conference on Computational and Experimental Engineering and Sciences ICCES
A2 - Zhou, Kun
PB - Springer Science and Business Media B.V.
T2 - 30th International Conference on Computational and Experimental Engineering and Sciences, ICCES 2024
Y2 - 3 August 2024 through 6 August 2024
ER -