Fluid-Solid Coupling in Kinetic Two-Phase Flow Simulation

Wei Li, M. Desbrun
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引用次数: 3

Abstract

Real-life flows exhibit complex and visually appealing behaviors such as bubbling, splashing, glugging and wetting that simulation techniques in graphics have attempted to capture for years. While early approaches were not capable of reproducing multiphase flow phenomena due to their excessive numerical viscosity and low accuracy, kinetic solvers based on the lattice Boltzmann method have recently demonstrated the ability to simulate water-air interaction at high Reynolds numbers in a massively-parallel fashion. However, robust and accurate handling of fluid-solid coupling has remained elusive: be it for CG or CFD solvers, as soon as the motion of immersed objects is too fast or too sudden, pressures near boundaries and interfacial forces exhibit spurious oscillations leading to blowups. Built upon a phase-field and velocity-distribution based lattice-Boltzmann solver for multiphase flows, this paper spells out a series of numerical improvements in momentum exchange, interfacial forces, and two-way coupling to drastically reduce these typical artifacts, thus significantly expanding the types of fluid-solid coupling that we can efficiently simulate. We highlight the numerical benefits of our solver through various challenging simulation results, including comparisons to previous work and real footage.
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动态两相流仿真中的流固耦合
现实生活中的水流表现出复杂且具有视觉吸引力的行为,如冒泡、飞溅、汩汩和湿润,这些都是图形模拟技术多年来一直试图捕捉的。早期的方法由于数值黏度高和精度低而无法再现多相流现象,但基于晶格玻尔兹曼方法的动力学求解器最近证明了以大规模平行方式模拟高雷诺数下水-空气相互作用的能力。然而,对于流固耦合的稳健和精确处理仍然是难以捉摸的:无论是CG还是CFD求解器,只要浸入物体的运动太快或太突然,边界附近的压力和界面力就会表现出虚假的振荡,导致爆炸。基于相场和速度分布的多相流晶格-玻尔兹曼解算器,本文阐述了一系列在动量交换、界面力和双向耦合方面的数值改进,以大大减少这些典型的伪影,从而大大扩展了我们可以有效模拟的流固耦合类型。我们通过各种具有挑战性的模拟结果,包括与以前的工作和真实镜头的比较,突出了我们的求解器的数值优势。
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