AN EXTENDED k-ε MODEL FOR NUMERICAL SIMULATION OF WIND FLOW AROUND BUILDINGS

Applied Mathematics and Mechanics (English Edition) ›› 1998, Vol. 19 ›› Issue (1): 95-100.

• 论文 • 上一篇

AN EXTENDED k-ε MODEL FOR NUMERICAL SIMULATION OF WIND FLOW AROUND BUILDINGS

陈水福, 孙炳楠, 唐锦春

Department of Civil Engineering, Zhejiang University, Hangzhou 310027, P. R. China

收稿日期:1996-09-02 出版日期:1998-01-18 发布日期:1998-01-18

AN EXTENDED k-ε MODEL FOR NUMERICAL SIMULATION OF WIND FLOW AROUND BUILDINGS

Chen Shuifu, Sun Bingnan, Tang Jinchun

Department of Civil Engineering, Zhejiang University, Hangzhou 310027, P. R. China

Received:1996-09-02 Online:1998-01-18 Published:1998-01-18

摘要/Abstract

摘要： It is assumed in this paper that for a high Reynolds number nearly homogeneouswind flow, the Reynolds stresses are uniquely related to the mean velocity gradientsand the two independent turbulent scaling parameters k and E. By applying dimensionalanalysis and owing to the Cayley-Hamilton theorem for tensors, a new turbulenceenclosure model so-called the axtended k-ε model has been developed. The coefficientsof the model expression were detemined by the wind tunnel experimental data ofhomogeneous shear turbulent flow. The model was compared with the standard k-εmodel in in composition and the prediction of the Reynold’s normal Stresses. Using thenew model the numerical simulation of wind flow around a square cross-section tallbuilding was performed. The results show that the extended k-ε model improves theprediction of wind velocities around the building the building and wind pressures on the buildingenvelope.

关键词: turbulence model, Reynolds stress, wind flow, numerical simulation

Abstract: It is assumed in this paper that for a high Reynolds number nearly homogeneouswind flow, the Reynolds stresses are uniquely related to the mean velocity gradientsand the two independent turbulent scaling parameters k and E. By applying dimensionalanalysis and owing to the Cayley-Hamilton theorem for tensors, a new turbulenceenclosure model so-called the axtended k-ε model has been developed. The coefficientsof the model expression were detemined by the wind tunnel experimental data ofhomogeneous shear turbulent flow. The model was compared with the standard k-εmodel in in composition and the prediction of the Reynold’s normal Stresses. Using thenew model the numerical simulation of wind flow around a square cross-section tallbuilding was performed. The results show that the extended k-ε model improves theprediction of wind velocities around the building the building and wind pressures on the buildingenvelope.

Key words: turbulence model, Reynolds stress, wind flow, numerical simulation

陈水福;孙炳楠;唐锦春. AN EXTENDED k-ε MODEL FOR NUMERICAL SIMULATION OF WIND FLOW AROUND BUILDINGS[J]. Applied Mathematics and Mechanics (English Edition), 1998, 19(1): 95-100.

Chen Shuifu;Sun Bingnan;Tang Jinchun . AN EXTENDED k-ε MODEL FOR NUMERICAL SIMULATION OF WIND FLOW AROUND BUILDINGS[J]. Applied Mathematics and Mechanics (English Edition), 1998, 19(1): 95-100.

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AN EXTENDED k-ε MODEL FOR NUMERICAL SIMULATION OF WIND FLOW AROUND BUILDINGS

AN EXTENDED k-ε MODEL FOR NUMERICAL SIMULATION OF WIND FLOW AROUND BUILDINGS

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