Numerical simulation of a brick wall containing solar heated water channels in cold regions
Abstract
Maintenance of indoor comfort temperatures in cold regions especially during winters requires huge energy requirements. However, solar energy can be utilized to reduce this power requirement. The present paper deals with an explicit transient numerical solution of a north facing brick wall in an extremely cold region of Leh (India) containing rectangular sectioned PVC channels along the length of wall filled with water raised to 20 ºC with solar water heater for a typical day in the month of December and another day in the month of May on 24 hours based variable ambient conditions. As compared to a similar brick wall without water channels, average rate of heat transfer from within the simulated indoor environment to the inside surface of wall was calculated to be reduced by 44.6% in December and 29.6% in May so as to maintain a uniform and steady comfort indoor temperature of 26 ºC.
Full Text:
PDFReferences
U.S. Department of Energy. Energy Information Administration, International Energy Outlook 2016.
European Commission, Directorate General for Energy and Transport. European Energy and Transport, Trends to 2030 ˗ Update 2007; 2008.
H.M. Taleb, “Using passive cooling strategies to improve thermal performance and reduce energy consumption of rresidential buildings in U.A.E buildings,” Frontiers of Architectural Research, vol. 3(2), pp. 154-165, June 2014.
L. Pires, Pedro D. Silva, and J.P. Castro Gomes, “Experimental study of an innovative element for passive cooling of buidings,” Sustainable Energy Technologies and Assessments, vol. 4, pp. 29-35, 2013.
M. Lain, and J.L.M. Hensen, “Passive and low energy cooling techniques in buildings,” Proceedings of the 17th Int. Air-conditioning and Ventilation Conference, pp. 1-7, May 2006.
V. Costanzo, G. Evola, A. Gagliano, L. Marletta, and F. Nocera, “Study on the application of cool paintings for the passive cooling of existing buildings in mediterranean climates,” Advances in Mechaniical Engineering, vol. 5, pp. 1-10, 2013.
L. Pires, P.D. Silva, and J.P.C Gomes, “Performance of textile and building materials for a particular evaporative cooling purpose,” Experimental Thermal and Fluid Science, vol. 35(4), pp. 670-675, May 2011.
W. Chen, and W. Liu, “Thermal analysis on the cooling performance of a porous evaporative plate for building,” Heat Trans. Asian Res., vol. 39, pp.-127-140, 2010.
H. Bencheikh, “Full scale experimental studies of a passive cooling roof in hot arid areas,” International Journal of Renewable Energy Technology Research, vol. 2(6), pp. 170-180, June 2013.
www.engineeringtoolbox.com/
http:/mnre.gov.in/solar-energy/ch4.pdf
http://simulationresearch.lbl.gov/modelica/releases/v.2.1.0/help/Buildings_HeatTransfer_Data_Solids.html