【 摘 要 】

A methodology for computation of flow around circular cylinders is developed and tested using prominent commercial and open-source solvers; ANSYS (R) CFX-13.0 and OpenFOAM (R) 1.7.1 respectively. A range of diameters and flow conditions are accounted for by generating solutions for flows at Reynolds numbers ranging from 40 to 10(6). To maintain practical solve times a 2D Unsteady Reynolds-Averaged Navier-Stokes (URANS) approach is taken. Furthermore, to maximise accuracy a tightly controlled meshing methodology, suitable adaptive timestepping, and appropriate turbulence modelling, are assembled. The resulting data is presented for lift and drag forces, Strouhal frequency, time accuracy and boundary layer correlation. Despite closely matching case definitions, significant differences are found in the results between solvers; OpenFOAM displays high correlation with experimental data at low to sub-critical values, whereas ANSYS proves to be more effective in the high sub-critical and critical regions. This variance demonstrates the sensitivity of the case to solver specific mathematical constraints and that for practical engineering a parameter study is essential. By removing many common variances associated with grid and transient components of URANS computations the developed methodology can be used as a benchmark case for further codes solving cylindrical structures. (C) 2014 Elsevier Ltd. All rights reserved.

【 授权许可】

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10_1016_j_oceaneng_2014_04_017.pdf	2339KB	PDF	download