Impact of computational domain on the prediction of buoyancy-driven ventilation cooling
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[1] Mats Sandberg,et al. Flow and heat transfer in the air gap behind photovoltaic panels , 1998 .
[2] R. Ben‐Mansour,et al. Turbulent natural convection in vertical parallel-plate channels , 2006 .
[3] Guohui Gan,et al. Numerical determination of adequate air gaps for building-integrated photovoltaics , 2009 .
[4] M. Dupont,et al. Wall temperature experimental investigation in a thermally driven channel , 2000 .
[5] P. Heiselberg,et al. An Experimental Investigation of a Solar Chimney model with Uniform Wall Heat Flux , 2003 .
[6] S. Orszag,et al. Renormalization group analysis of turbulence. I. Basic theory , 1986 .
[7] O. Manca,et al. Optimum plate separation in vertical parallelplate channels for natural convective flows: incorporation of large spaces at the channel extremes , 1997 .
[8] A. Lahellec,et al. Modelling natural convection in a heated vertical channel for room ventilation , 2000 .
[9] R. Bennacer,et al. Numerical Simulation of a Vertical Solar Collector Integrated in a Building Frame: Radiation and Turbulent Natural Convection Coupling , 2006 .
[10] Ammar Bouchair. Solar chimney for promoting cooling ventilation in southern Algeria , 1994 .
[11] Guohui Gan. Simulation of buoyancy-induced flow in open cavities for natural ventilation , 2006 .
[12] Andrei G. Fedorov,et al. Turbulent natural convection heat transfer in an asymmetrically heated, vertical parallel-plate channel , 1997 .