LBM is an effective computational technique for fluid dynamics based on kinetic theory. In recent years, transient and turbulent flow simulation by using this new class of computational fluid dynamics method has attracted more attention. In this paper a two dimensional lid driven cavity flows at different Reynolds number (1000-7500) are simulated by using multi-relaxation Lattice Boltzmann (MRT-LBM) and single relaxation time (SRT) model in the LBGK method. The results are compared with previous published papers which solve the Navier-Stokes equation directly. The model predicts the flow characteristics, such as circulating flow and velocity successfully. The comparisons between the simulated results show that the lattice Boltzmann method has the capacity to solve the complex flows with reasonable accuracy and reliability.
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H. Yu, S. S. Girimaji, L. S. Luo, DNS and LES of decaying isotropic turbulence with and without frame rotation using lattice Boltzmann method, Journal of Computational Physics, Vol. 209, n. 2, pp. 599-616, 2005.

S. -W. Kim, Near-wall turbulence model and its application to fully developed turbulent channel and pipe flows, Numerical Heat Transfer, Vol. 17, n. 1, pp. 101-122, 1990.

L. Jahanshaloo, N. A. C. Sidik, K. E. Pouryazdanpanah, A review on application of lattice Boltzmann method for turbulent flow simulation, Numerical Heat Transfer, Part A, 2013.

H. Kameli, F. Kowsary, Solution of inverse heat conduction problem using the lattice Boltzmann method, International Communications in Heat and Mass Transfer, 2012.

Zin, M.R.M., Sidik, N.A.C., An accurate numerical method to predict fluid flow in a shear driven cavity, (2010) International Review of Mechanical Engineering (IREME), 4 (6), pp. 719-725.

R. Benzi, S. Succi, Two-dimensional turbulence with the lattice Boltzmann equation, Journal of Physics A: Mathematical and General, Vol. 23, n. 1, pp. L1-L5, 1990.

Mussa, M.A., Abdullah, S., Nor Azwadi, C.S., Zulkifli, R., Lattice boltzmann simulation of cavity flows at various reynolds numbers, (2011) International Review on Modelling and Simulations (IREMOS), 4 (4), pp. 1909-1919.

Z. Guo, B. Shi, N. Wang, Lattice BGK model for incompressible Navier–Stokes equation, Journal of Computational Physics, Vol. 165, n. 1, pp. 288-306, 2000.

H. Liu, Z. Chun, B. Shi, Z. Tian, L. ZHnag, C. Zheng, Thermal lattice-BGK model based on large-eddy simulation of turbulent natural convection due to internal heat generation, International Journal of Heat and Mass Transfer, Vol. 49, n. 23, pp. 4672-4680, 2006.

K. N. Premnath, M. J. Pattison, S. Banerjee, Generalized lattice Boltzmann equation with forcing term for computation of wall-bounded turbulent flows, Physical Review E, Vol. 79, n. 2, pp. 26703, 2009.

J. -S. Wu, Y. -L. Shao, Simulation of lid-driven cavity flows by parallel lattice Boltzmann method using multi-relaxation-time scheme, International Journal for Numerical Methods in Fluids, Vol. 46, n. 9, pp. 921-937, 2004.

D. V. Patil, K. N. Lakshmisha, B. Rogg, Lattice Boltzmann simulation of lid-driven flow in deep cavities, Computers & Fluids, Vol. 35, n. 10, pp. 1116-1125, 2006.

N. A. C. Sidik, L. Jahanshaloo, Lattice Boltzmann numerical scheme for transient hydrodynamics of solid particles in an enclosure, CFD Letters, Vol. 4, n. 3.

Sidik, N.A.C., Jahanshaloo, L., Prediction of dynamics of solid particles using lattice Boltzmann method, (2011) International Review of Mechanical Engineering (IREME), 5 (7), pp. 1235-1240.

P. Lallemand, L. -S. Luo, Theory of the lattice Boltzmann method: Dispersion, dissipation, isotropy, Galilean invariance, and stability, Physical Review E, Vol. 61, n. 6, pp. 6546, 2000.

E. Erturk, T.C. Corke, C. Gökçöl, Numerical solutions of 2-D steady incompressible driven cavity flow at high Reynolds numbers, International Journal for Numerical Methods in Fluids, Vol. 48, n. 7, pp. 747-774, 2005.