Abstract

This study aims to reduce energy consumption and optimize indoor air quality in thermally conditioned buildings through a numerical analysis of air quality in a rectangular chamber ventilated by air displacement. The lattice Boltzmann multiple relaxation time (LBM-MRT) method was employed to simulate the physical behavior of a rectangular room with heating applied to its left vertical wall. A porous partition was introduced at the center of the floor. The extended Darcy–Brinkman–Forchheimer model was applied to model the porous medium. Computational simulations were conducted over a range of characteristic numbers. The results indicate that optimal thermal dissipation conditions in a ventilated cavity with a porous separator are achieved at moderate Reynolds numbers (250) and high Rayleigh numbers (106). Thermal comfort is realized when natural convection dominates the flow dynamics. Moreover, in a porous medium with low permeability (106), natural convection leads to a pollutant displacement efficiency twice that of forced convection, irrespective of the buoyancy ratio. These findings underscore the significance of integrating ventilation systems with porous materials to achieve energy-efficient indoor environments.

Issue Section:
Porous Media
Keywords:
indoor air quality, pollutant removal efficiency, heat removal efficiency, LB-MRT method, porous separation, ventilated cavity
Topics:
Air pollution, Boundary-value problems, Cavities, Flow (Dynamics), Heat, Lattice Boltzmann methods, Pollution, Relaxation (Physics), Simulation, Temperature, Reynolds number, Porous materials, Permeability, Buoyancy, Fluids, Natural convection, Rayleigh number, Numerical analysis

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