International Journal of Renewable Energy Research-IJRER

It has been proved that the behaviors of both single and multi-pressure types of traditional wind catchers are related to the conditions of lower openings. But still the quantity and the quality of such relation is not recognized. So, this paper aims to indicate the impact of varieties in changing the conditions of such openings and the outdoor wind direction on the velocity of indoor flow in both types of traditional wind catchers. Therefore both types of traditional wind catchers simulated using models in CFD. In this research variations of different border conditions such as lower space without and with opening have been simulated. Also, in case of outdoor wind direction, different angles including 0°, 45°, 90°, 135° and 180° tested. Results of this research showed that in different conditions, the multi-pressure traditional wind catchers show more stable indoor flow, more predictable behavior and finally more efficiency; compared to the single pressure traditional wind catchers. 

Al-Megren, K., 1987. Wind Towers for Passive Ventilated Cooling in Hot- Arid Regions. Dept. of Architecture, University of Michigan, 253, Ph.D. thesis

M. Santamouris, 2002, Natural Ventilation in Buildings A Design Handbook, Cromwell Press, United Kingdom,

Mahmodi, M., 2009, Wind catcher symbol of Iranian architecture, Yazda, Tehran, (in Farsi)

Elmualim A.A., 2006. Effect of damper and heat source on wind catcher natural ventilation performance, Energy and Buildings 38 (939–948)

Bahadori N.M. and yaghobi, M., 2006, Natural ventilation and cooling in traditional buildings, Markaze Nashre Daneshgahi, Tehran, (in Farsi).

Bahadori, M., 1978. Passive cooling system in Iranian architecture, Scientific American, vol. 238, No 2,pp 144-154.

Bahadori, M., 1985. An improved design of wind towers for natural ventilation and passive cooling. Solar Energy 35 (2), 119–129.

Cunningham WA, Thompson TL. 1986. Passive cooling with natural draft cooling towers in combination with solar chimney. In: Proceedings of the passive and low energy architecture. Hungarian Ministry of Industry; p. 23–34.

Givoni, B. 1993. Semi-empirical model of a building with a passive evaporative cool tower, Solar Energy 50 (5), 425–434

Pearlmutter, D., Erell, E., Etzion, Y., Meir, I., Di, H., 1996. Refining the use of evaporation in an experimental down-draft cool tower, Energy and Buildings 23, 191–197

Cook, M., Robinson, D., Lomas, K., Bowman, N., Eppel, H., 2000. Passive down-draft evaporative cooling: airflow modelling. Indoor and Built Environment 9, 325–334.

Francis, E., 2000. The application of passive downdraft evaporative cooling (PDEC) to non-domestic buildings. In: Steemers, K., Yannas, S. (Eds.), 17th PLEA International Conference: Architecture, City, Environment Cambridge, UK.

Ford, B., Diaz, C., 2003. Passive downdraft cooling: hybrid cooling in the Malta Stock Exchange. In: Bustamante, W.G., Collados, B., 20th Plea International Conference: Rethinking Development: Are We Producing a People Oriented Habitat. Santiago, Chile, November 9–12.

A.A. Elmualim, 2006, Dynamic modelling of a wind catcher/tower turret for natural ventilation, Building Services Engineering Research and Technology 27 (3) 165–182

Benjamin MJ, Ray K. 2009. Quantifying the performance of top–down natural ventilation Wind catcher, Building and Environment: 44: 1925–1934

Erell, E., Pearlmutter, D., Etzion, Y., 2007. A multi-stage down-draft evaporative cool tower for semi-enclosed spaces: aerodynamic performance. Solar Energy, doi: 10.1016/ j.solener. 2007.10.010

Pearlmutter, D., Erell, E., Etzion, Y., 2008. A multistage down-draft evaporative cool tower for semi-enclosed spaces: experiments with a water¬ spraying system. Solar Energy 82 430–440.

Montazeri H. 2011. Experimental and numerical study on natural ventilation performance of various multi-opening wind catchers, Building and Environment 46 370-378,

Huges, BR. Calautit, JK. Ghani, SA. 2012. The development of commercial wind towers for natural ventilation: A review. Applied Energy 92 (2012) 606–627.

Abouseba M., 2012, PRACTICAL OPTIMIZING OF TRADITIONAL WIND CATCHERS-MULTI PRESSURE TYPE APPROACH, Master's thesis, Faculty of Engineering, University of Ilam, (in Farsi).