2015
DOI: 10.1016/j.compfluid.2014.09.050
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Parallel adaptive mesh refinement for large-eddy simulations of turbulent flows

Abstract: In this paper a parallel adaptive mesh refinement (AMR) strategy for large and accuracy of our methodology is shown on the numerical simulation of the turbulent flow around a square cylinder at Re = 22000 and the turbulent flow around two side-by-side square cylinders at Re = 21000.

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Cited by 38 publications
(39 citation statements)
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References 34 publications
(47 reference statements)
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“…In case of using Cartesian meshes, the adaptive mesh refinement strategy (AMR) is used to reduce consistently the grid spacing in the vicinity of the interface, thus, allowing an accurate representation of interface phenomena, both at the interface between liquid and gas and between fluids and solid. In particular, the quad/octree algorithm proposed by Antepara et al [13] and extended to multiphase flows in previous works [17,18] is here used. The strategy includes a particular treatment of the mass fluxes which allows the exact conservation of mass, momentum and kinetic energy (key element for the correct resolution of turbulent flows [19]).…”
Section: Adaptive Mesh Refinementmentioning
confidence: 99%
See 1 more Smart Citation
“…In case of using Cartesian meshes, the adaptive mesh refinement strategy (AMR) is used to reduce consistently the grid spacing in the vicinity of the interface, thus, allowing an accurate representation of interface phenomena, both at the interface between liquid and gas and between fluids and solid. In particular, the quad/octree algorithm proposed by Antepara et al [13] and extended to multiphase flows in previous works [17,18] is here used. The strategy includes a particular treatment of the mass fluxes which allows the exact conservation of mass, momentum and kinetic energy (key element for the correct resolution of turbulent flows [19]).…”
Section: Adaptive Mesh Refinementmentioning
confidence: 99%
“…The interface tracking is carried-out by means of a conservative LS method [11], while the interaction between solid and liquid is solved by means of direct forcing IBM [12]. An adaptive mesh refinement strategy (AMR) [13] is adopted in order to dynamically improve the mesh definition in the interface region and in zones where the basic mesh size is not sufficient to correctly solve the turbulent scales or the interfacial characteristic lengths. After presenting the numerical framework in Section 2, we propose two simple validation tests in Section 3.…”
Section: Introductionmentioning
confidence: 99%
“…We now briefly recall some of the recent works on unstructured grid methods. Antepara et al proposed a parallel adaptive mesh refinement strategy for LESs that achieves a parallel efficiency of 90% on 256 CPU‐cores. Su and Yu studied a parallel finite volume method for the LES of turbulent flows around the side mirror of a car.…”
Section: Introductionmentioning
confidence: 99%
“…The adaptive mesh refinement (AMR) strategy can be used to automatically modify the mesh density at much reduced cost compared to manually remeshing or the costly global mesh refinement. From the seminal work of Berger et al, [1][2][3] continuous researches have be conducted in this field and AMR has its wide application in many fields, including aerodynamics, [4][5][6][7] astrophysics, 8 combustion, 9,10 diffraction gratings, 11,12 electronic structures, 13,14 multiphase flow, 15,16 and many others. The AMR based on the Cartesian grid is most widely studied in the literature.…”
Section: Introductionmentioning
confidence: 99%