A Numerical Investigation Into the Heat Transfer Performance and Particle Dynamics of a Compressible, Highly Mass Loaded, High Reynolds Number, Particle Laden Flow

Fluid flow and heat transfer of a gas stream in various ducts have been studied thoroughly before. However, in real applications, a gas stream usually contains dust particles, whose effects were mostly ignored. In this study, the effects of the dust particles on flow and heat transfer characteristics in a parallel-plates duct were numerically investigated in detail. A lattice Boltzmann method combined with a modified immersed boundary approach was employed to calculate the velocity and temperature distribution in duct. The effects of the particles on both the hydrodynamic and thermal boundary layer development in the duct were predicted, respectively. The product of friction factor and Reynolds number (fRe) and local Nusselt number (NuL) along the flow direction were obtained for a particle-laden flow and compared with a pure clear gas flow. The results indicated that for these flow, the "fully-developed" flow was just an approximation. Both the flow and thermal boundary layers were destroyed by the accompanying particles. Particles would form a stable and dense particulate fouling layer at the walls, which could increase the local (fRe) and reduce the NuL in "fully developed" regions. Moreover, duct with super-hydrophobic properties would be less influenced by the particles due to decreased particle deposition because of the anti-dust property of the surface.

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Fluid Flow and Heat Transfer of a Gas Stream Containing Dust Particles in a Parallel-Plates Duct

Pan

Cai

Dong

et al. 2022

Journal of Heat Transfer

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A Numerical Investigation Into the Heat Transfer Performance and Particle Dynamics of a Compressible, Highly Mass Loaded, High Reynolds Number, Particle Laden Flow

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Fluid Flow and Heat Transfer of a Gas Stream Containing Dust Particles in a Parallel-Plates Duct

Fluid Flow and Heat Transfer of a Gas Stream Containing Dust Particles in a Parallel-Plates Duct

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