Experimental and Theoretical Investigation of Performance of a Solar Chimney Model, Part I: Experimental Investigation

Essaied    Shuia; Bashir   Arebi; Ibrahim   Abuashe

doi:10.51646/jsesd.v3i1.88

Authors

Essaied M. Shuia Faculty of engineering, Zawia University, Zawia - Libya
Bashir H. Arebi Faculty of engineering, Tripoli University - Libya
Ibrahim A. abuashe Faculty of engineering, Zawia University, Zawia - Libya

DOI:

https://doi.org/10.51646/jsesd.v3i1.88

Keywords:

Solar energy, solar chimney, Buoyancy effect, Draf tower, Renewable energy

Abstract

This paper presents the experimental data that was collected from a small pilot solar chimney. The experimental data together with ambient conditions are used to evaluate the performance and study the behavior of the solar chimney; this data will be used for comparison with theoretical models in another paper (part II). T e solar chimney prototype was designed and constructed at the Subrata Faculty of Engineering-Libya. The data were collected over several days of June 2011. T e solar chimney system contains two
main components; the solar collector and the solar chimney. T e solar collector roof has a circular area of 126 m2, the solar chimney is a PVC tube with an internal diameter of 0.2 m and the total height of the chimney is 9.8 m. T e measurements include the intensity of solar radiation inside/outside the collector, temperature and velocity of air at the entrance of the chimney, temperature and speed of wind outside the collector, temperature of the ground inside collector, and temperature measurements of air at specif c points at different levels throughout the collector. Solar irradiance was found to affect the chimney temperature and subsequently affect the chimney air velocity. T e experimental results showed that temperature differences of (30 – 45°C) were recorded between the ambient temperature and that of air inside the chimney in the middle of the day, where the highest air temperature of 73.4°C
was recorded at the entrance of the solar chimney. The maximum air velocity of 3.6 m/s was recorded inside the solar chimney at noon on 9 June. Wind speed outside the collector had a small effect on the speed of the air inside the chimney and tends to change slightly, hence, can neglect influence of wind speed on the performance of the system. Also, the experimental results indicate that such type of system can trap a suffi cient amount of solar radiation, which elevates the air temperature to a sufficient value able to generate enough air f ow to operate a wind turbine to produce electricity; this means the solar chimney system for electricity
production can work in the north-western part of Libya in the summer time at least.

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References

. Schlaich, J., “ e Solar Chimney: Electricity from the Sun”, Edition Axel Menges, Stuttgart, 1995.

. Pasumarthi, N., Sherif, S. A., “Experimental and theoretical performance of a demonstration solar chimney model - Part I: Mathematical model development”, International Journal of Energy Research, 22, 277-288, 1998a.

. Pasumarthi, N., Sherif, S. A., “Experimental and theoretical performance of a demonstration solar chimney model - Part II: Experimental and theoretical results and economic analysis”, International Journal of Energy Research, 22, 443-461, 1998b.

. Zhou, X., et al., “Experimental study of temperature eld in a solar chimney power

setup”, Applied Thermal Engineering, 27, 2044-2050, 2007.

. Hamdan, M. O., Rabbata, O., “Experimental solar chimney data with analytical model prediction”, World Renewable Energy Forum

Denver, CO May 13-17, 2012.

. Straube, J. F., “Heat ow basics”, UW Building Science, 2000-2003.

. Munson, B. R., Young, D. F., Okiishi, T. H., Huebsch, W. W., “Fundamentals of Fluid Mechanics”, Sixth Edition, ISBN 978-0470-

-9, USA.