The variation effects of parabolic mirrors surface on energy and exergy efficiencies in a double-exposure solar cooker

Zamani, Hossein; Moghiman, Mohammad; Kianifar, Ali

doi:10.22101/JRIFST.2014.06.15.313

The variation effects of parabolic mirrors surface on energy and exergy efficiencies in a double-exposure solar cooker

Document Type : Original Paper

Authors

¹ PhD. Student, Department of Mechanic, Engineering College, Ferdowsi University of Mashhad, Iran

² Professor, Department of Mechanic, Engineering College, Ferdowsi University of Mashhad, Iran

³ Associated Professor, Department of Mechanic, Engineering College, Ferdowsi University of Mashhad, Iran

10.22101/JRIFST.2014.06.15.313

Abstract

The energy and exergy efficiencies for a double exposure solar cooker are determined. In order to observe the variation effects of a parabolic mirrors surface on energy and exergy efficiencies two identical systems were designed, constructed and tested under the same climatic conditions; the parabolic mirrors in one of the systems have been fully exposed to the sun and mirrors of the one were movable to see the variation effects on the energy and exergy efficiencies. The results show that using a double exposure solar cooker is recommended when high temperature is needed for cooking purpose. For other applications, such as food heating and pasteurization it is better that solar box-type cooker is employed. In such case, the system would be simpler, less costly and easier for transportation. This research is designed to develop a suitable double-exposure solar cooker performance and the tests were carried out in the Research Institute of Food Science and Technology, located at 36 latitude and 54 longitudes in Mashhad, Iran.

Keywords

References

Al-Soud, M. S., Abdallah, E., Akayleh, A., Abdallah, S., & Hrayshat, E. S. 2010. A parabolic solar cooker with automatic two axes sun tracking system. Applied Energy, 87: 463–470.

Amer, E.H. 2003. Theoretical and experimental assessment of a double exposure solar cooker. Energy Conversion and Management, 44: 2651-2663.

Funk, P.A., & Larson, D.L. 1998. Parametric model of solar cooker performance. Solar Energy, 62: 63–68.

Harmim, A., Belhamel, M., Boukar, M., & Amar, M. 2010.Experimental investigation of a box-type solar cooker with a finned absorber plate. Energy. 35: 3799–3802.

Harmim, A., Boukar, M., & Amar, M. 2008. Experimental study of a double exposure solar cooker with finned cooking vessel. Solar Energy, 82: 287–289.

Harmim, A., Merzouk, M., Boukar, M., & Amar, M. 2012. Mathematical modeling of a box-type solar cooker employing an asymmetric compound parabolic concentrator. Solar Energy, 86: 1673-1682.

Harmim, A., Merzouk, M., Boukar, M., & Amar, M. 2012. Performance study of a box-type solar cooker employing an asymmetric compound parabolic concentrator. Energy, 47: 471-480.

Harmim, A., Merzouk, M., Boukar, M., & Amar, M. 2013. Design and experimental testing of an innovative building-integrated box type solar cooker, Solar Energy, 98: 422-433.

Kumar. N., Tilak, C., & Mistry, H.N., 2010. A truncated pyramid non-tracking type multipurpose domestic solar cooker/hot water system. Applied Energy, 87: 471–477.

Kumar. N., Vishwanath, G., & Anurag, G. 2012. An exergy based unified test protocol for solar cookers of different geometries. Renewable Energy, 44: 457-462.

Muthusivagami, R.M., Velraj, R., & Sethumadhavan, R. 2010. Solar cookers with and without thermal storage: a review. Renewable and Sustainable Energy Reviews, 14: 691–701.

Nahar, N. M., & Gupta, P. 1991. Energy conservation potential for solar cookers in arid zones of India. Energy, 16: 965-969.

Narasimha Rao, A.V., & Subramanyam S. 2005. Solar cookers, part-II, cooking vessel with central annular cavity. Solar Energy, 78: 19–22.

Panwara, N.L., Kaushika, S.C., Kotharib, S. 2012. State of the art of solar cooking: an overview. Renewable and Sustainable Energy Reviews 16: 3776– 3785.

Panwara, N.L., Kaushikb, S.C., & Kotharia, S. 2011. Role of renewable energy sources in environmental protection: a review. Renewable and Sustainable Energy Reviews, 15: 1513–1524.

Riyad A.M., Salah A., & Muslih I.M., 2011, Design, Construction and Operation of Spherical Solar Cooker with Automatic, Sun Tracking System. Energy Conversion and Management, 52: 615–620.

Schwarzera, K., & Vieira da Silva, M. E. 2003. Solar cooking system with or without heat storage for families and institutions. Solar Energy, 75: 35–41.

Valmiki, M.M., Li, P., Heyer, J., Morgan, M., Albinali, A., Alhamidi, & Jeremy Wagoner, K. 2011. A novel application of a Fresnel lens for a solar stove and solar heating. Renewable Energy, 36: 1614-1620.