Glazed Transitional Space as a Passive Heating System (Case Study: Glazed Loggias in Semi-Arid climate)
الموضوعات :
Yasmina Bouchahm
1
,
Mounira Badeche
2
1 - Department of architecture and urbanism. Laboratory of bioclimatic architecture and environment (A.B.E). University 3. Constantine
2 - Department of architecture and urbanism.
Laboratory of bioclimatic architecture and environment (A.B.E).
University 3. Constantine
الکلمات المفتاحية: Buffer space, Sun space, Passive solar, Overheating,
ملخص المقالة :
The environmental concern, ensuring comfort for occupants, pushed us to search for the impact of glazed loggia on thermal comfort of adjacent space in Cons tantine climate, having s trong climatic cons traints. An experimental s tudy is undertaken and described in this paper. Analysis of the in situ results is also discussed. This work shows that in winter glazed loggia benefit largely from solar gains. In summer, it is a thermal regulating space, delaying diurnal peak of temperature towards the end of the day. Overheating can be avoided with natural ventilation and a good use of the relation glazed loggia-adjacent space. This result leads to the possibility of retrofitting glazed loggias in hard climates, such as in Constantine (Algeria). To define criteria being able to return this addition, favourable and adapted to the winter and the aestival thermal comfort of adjacent space, a simulation is carried. But the only inves tigation is discussed in this paper.
Acfas. (2000). l’architecture des pauvres aux pays des Pharaons. Retrieved from www.acfas.ca/congres/congres68/C2617.HTM.
Deshmukh, M. K., & Deshmukh, S. S. (2008). Modeling of hybrid renewable energy systems. Renewable and Sustainable Energy Reviews, 12(1), 235-249.
ENERTECH. (2005). Etude sur la « basse énergie » appliquée aux bâtiments anciens. Faisabilité technique et économique. Retrieved from http://perso.club-internet.fr/sidler.
Kesik, T., Simpson, M. (2002). Thermal performance of attached sunspaces for Canadian houses. Canadian Conference on Building Energy Simulation, Montreal, Canada, September 11-13, 2002: CD-ROM, Proceedings, Session #3A, Thermal and Air Flow Modelling in Buildings.
Nadine, A. D. R. A. (2001). Proposition d’une procédure de certification énergétique des logements et application au contexte libanais. Doctoral dissertation, École Nationale des Travaux Publics de l’État.
Pasupathy, A., Velraj, R., & Seeniraj, R. V. (2008). Phase change material-based building architecture for thermal management in residential and commercial establishments. Renewable and Sustainable Energy Reviews, 12(1), 39-64.
Saleh, P.H. (2015). Thermal performance of glazed balconies within heavyweight/thermal mass buildings in Beirut, Lebanon’s hot climate. Energy and Buildings, 108, 291–303.
Seifert, R. D. (2009). The attached solar greenhouse. Cooperative Extension Service, University of Alaska Fairbanks.
SOL.A.R. architects engineers. (1988). Thermal design of the habitat. Guide for the area Provence-Alp-coast of azure. Pacca area.
