Multiple-relaxation-time Lattice Boltzmann model for flow and convective heat transfer in lid driven cavity with porous obstacle

Abstract: In this work, we study numerically a problem of mixed convection in lid driven square cavity, filled with air (Pr = 0.71), whose upper wall is movable and kept at constant cold temperature TC. The cavity contains a porous obstacle of height h and width b, placed on the bottom wall maintained at a constant hot temperature TH. The side walls are adiabatic. Darcy-Brinkmann-forchheimer model is used for modelling the momentum equations in porous medium. This numerical study is based on the multiple relaxation time… Show more

“…Boltzmann model combined with the pseudopotential Lattice Boltzmann model to trace the solidliquid interface for the natural convection melting in a square cavity [16]. Bourada et al (2020) analyzed a problem of mixed convection numerically in a liddriven square cavity, in which the upper wall is movable and kept at constant cold temperature. In contrast, the cavity contains a porous obstacle placed on the bottom wall with a constant hot temperature [17].…”

“…Bourada et al (2020) analyzed a problem of mixed convection numerically in a liddriven square cavity, in which the upper wall is movable and kept at constant cold temperature. In contrast, the cavity contains a porous obstacle placed on the bottom wall with a constant hot temperature [17].…”

Lid-Driven Cavity For Mantle Convection Modelling Using Lattice Boltzmann Method

“…Boltzmann model combined with the pseudopotential Lattice Boltzmann model to trace the solidliquid interface for the natural convection melting in a square cavity [16]. Bourada et al (2020) analyzed a problem of mixed convection numerically in a liddriven square cavity, in which the upper wall is movable and kept at constant cold temperature. In contrast, the cavity contains a porous obstacle placed on the bottom wall with a constant hot temperature [17].…”

“…Bourada et al (2020) analyzed a problem of mixed convection numerically in a liddriven square cavity, in which the upper wall is movable and kept at constant cold temperature. In contrast, the cavity contains a porous obstacle placed on the bottom wall with a constant hot temperature [17].…”

Lid-Driven Cavity For Mantle Convection Modelling Using Lattice Boltzmann Method