2020
DOI: 10.1063/5.0021105
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Transport phenomena in a differentially heated lid-driven cavity: A study using multi-relaxation-time thermal lattice Boltzmann modeling

Abstract: In this study, investigation of mixed convection phenomena in a lid driven square cavity with heated side walls is carried out. The left and right walls are maintained at different constant temperatures, while the upper and bottom walls are thermally insulated. The left wall temperature is higher than the cavity fluid temperature, and the right wall is maintained at the initial fluid temperature. Transport phenomena inside the cavity within a wide parametric range are investigated. The parameters include the R… Show more

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Cited by 28 publications
(1 citation statement)
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“…Other utility is that the method builds recursively the steady-state ADE with the non-uniform, global-mass conserving sources; the ADE is closed by an impermeable Neumann boundary or periodic interface, and its symbolic solutions are available 37,94 for benchmarking purpose. 38 The flow and the associated heat transport are often modeled with the so-called (multiple-relaxation-time thermal) MRT-TLBM, e.g., in a very recent work 78 using the BB and ABB straight-wall rules. However, the MRT-TLBM operates the d2q9 flow collision with only two distinctive relaxation rates: the symmetric one for the fluid viscosity and the anti-symmetric one for the second-order BB accuracy using the exact Poiseuille flow solution, 20,22 whereas the energy conservation equation is modeled with the d2q5 isotropic MRT-ADE.…”
mentioning
confidence: 99%
“…Other utility is that the method builds recursively the steady-state ADE with the non-uniform, global-mass conserving sources; the ADE is closed by an impermeable Neumann boundary or periodic interface, and its symbolic solutions are available 37,94 for benchmarking purpose. 38 The flow and the associated heat transport are often modeled with the so-called (multiple-relaxation-time thermal) MRT-TLBM, e.g., in a very recent work 78 using the BB and ABB straight-wall rules. However, the MRT-TLBM operates the d2q9 flow collision with only two distinctive relaxation rates: the symmetric one for the fluid viscosity and the anti-symmetric one for the second-order BB accuracy using the exact Poiseuille flow solution, 20,22 whereas the energy conservation equation is modeled with the d2q5 isotropic MRT-ADE.…”
mentioning
confidence: 99%