International Journal of Renewable Energy Research-IJRER

This paper summarizes a numerical study of natural convection in a solar chimney. The Transported fluid is the air (Pr=0.702), it is considered as a Newtonian and incompressible fluid, by using the Boussinesq approximation, the governing equations are taken to be in the vorticity-stream function formulation in hyperbolic coordinates. For heating conditions we suppose an isothermal walls of the collector (T_h for the ground and T_c for the roof, with T_h>T_c). Solution of the defined equations has been done with numerical control volume method. We examined the effect of the system geometry on the natural convection phenomenon in the solar chimney. Finally, the simulation results have been given as airflows and temperature patterns.

Solar chimney; Natural convection; Renewable energy; Vorticity-Stream function formulation

J. Schlaich, The Solar Chimney: Electricity from the Sun, Edition Axel Menges, Stuttgart, Germany, 1995.

W. Haaf, K. Friedrich, G. Mayer, J. Schlaich, Solar chimneys, Part I: principle and construction of the pilot plant in Manzanares, International Journal of Solar Energy 2 (1983) 3–20.

MA. Bernardes, S. dos, RM. Valle, MFB.Cortez, Numerical analysis of natural laminar convection in a radial solar heater, International Journal of Thermal Science 38 (1999) 42-50.

TW. Von Backström, TP. Fluri, Maximum fluid power condition in solar chimney power plants-an analytical approach, Solar Energy 80 (2006) 1417-1423.

T.W. Von Backstrom, A.J. Cannon, Compressible flow through solar power plant chimneys, Journal of Solar Energy Engineering 122 (2000) 138–145.

JP. Pretorius, DG. Kröger, Critical evaluation of solar chimney power plant performance, Solar Energy 80 (2006) 535–544.

TZ. Ming, W. Liu, GL. Xu, AW. Fan, A study of the solar chimney power plant systems. Journal of Engineering Thermodynamics. 3 (2006) 505-517.

CB. Maia, AG. Ferreira, RM. Valle, MFB. Cortez, Theoretical evaluation of the influence of geometric parameters and materials on the behavior of the air flow in a solar chimney, Computers and Fluids. 38 (2009) 625-36.

H. Pastohr, O. Kornadt, K. Gurlebeck, Numerical and analytical calculations of the temperature and flow field in the upwind power plant, International Journal of Energy Research. 28 (2004) 495-510.

X. Zhou, J. Yang, B. Xiao, G. Hou, Experimental study of temperature field in a solar chimney power setup, Applied Thermal Engineering. 27 (2007) 2044-50.

Touï¬k Chergui, Salah Larbi, Amor Bouhdjar. Thermo-hydrodynamic aspect analysis of flows in solar chimney power plants—A case study Renewable and Sustainable Energy Reviews 14 (2010) 1410–1418.

S.V. Patankar, Numerical heat transfer and fluid flow, Hemisphere, Washington, D.C, 1980.

A. Bouhdjar, A. Harhad, A. Benkhelifa, Numerical simulation of transient mixed convection in a cylindrical cavity, Numerical Heat Transfer 31 (1996) 305–324.

W. Aung, L.S. Fletcher, V. Sernas, Development of laminar free convection between vertical flat plates with asymmetric heating, Int. J. Heat Mass Trans. 15 (1972) 2293-2308