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000874510 1001_ $$0P:(DE-Juel1)165948$$aLintermann, Andreas$$b0$$eCorresponding author
000874510 245__ $$aZonal Flow Solver (ZFS): a highly efficient multi-physics simulation framework
000874510 260__ $$aLondon [u.a.]$$bTaylor and Francis$$c2020
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000874510 520__ $$aMulti-physics simulations are at the heart of today's engineering applications. The trend is towards more realistic and detailed simulations, which demand highly resolved spatial and temporal scales of various physical mechanisms to solve engineering problems in a reasonable amount of time. As a consequence, numerical codes need to run efficiently on high-performance computers. Therefore, the framework Zonal Flow Solver (ZFS) featuring lattice-Boltzmann, finite-volume, discontinuous Galerkin, level set and Lagrange solvers has been developed. The solvers can be combined to simulate, e.g. quasi-incompressible and compressible flow, aeroacoustics, moving boundaries and particle dynamics. In this manuscript, the multi-physics implementation of the coupling mechanisms are presented. The parallelisation approach, the involved solvers and their scalability on state-of-the-art heterogeneous high-performance computers are discussed. Various multi-physics applications complement the discussion. The results show ZFS to be a highly efficient and flexible multi-purpose tool that can be used to solve varying classes of coupled problems.
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000874510 773__ $$0PERI:(DE-600)2007329-X$$a10.1080/10618562.2020.1742328$$gp. 1 - 28$$n7-8$$p458-485$$tInternational journal of computational fluid dynamics$$v34$$x1026-7417$$y2020
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