Development of a Small Scale Concentrating Parabolic trough Solar Collector for Drying Purposes

Authors

  • Muhammad Aamir Khan The University of Agriculture, Peshawar
  • M. Rahman The University of Agriculture, Peshawar
  • M. Hanif The University of Agriculture, Peshawar
  • Muhammad Aamir Israr The University of Agriculture, Peshawar
  • S. Fahad Shah The University of Agriculture, Peshawar

DOI:

https://doi.org/10.18034/ei.v1i1.213

Keywords:

Solar Energy, Solar Collector, Solar Drier and Collector Efficiency

Abstract

A high performance solar collector was developed to modify agricultural building environment such as dairy, poultry farm buildings and greenhouses. Moreover it should be efficiently utilized as a solar dryer for drying various agricultural products and by products. The materials used include steel sheet with high performance of reflecting light, absorber tube, and angle iron and fully insulated drying chamber. A CPTSC was a tilted at 340south (Equivalent to the latitude of Peshawar) Pakistan. A CPTSC a total reflecting surface area was 2.9 m2 respectively. The absorber tube having a surface of 0.376 m2 was fixed in front of the reflector at the distance equal to the focal length. The total volume of drying chamber was 0.3135 m3. An experiment was conducted to enhance the efficiency of the CPTSC and two air mass flow rate treatments were tested with normal and convective mass air flow rate, 0.6 kg. Min-1 and 1.72 kg. Min-1 under the average temperature of the month (January, February and March, 2012). Moreover, the process was replicated three times under the completely randomized design. The result showed that both air mass flow rate and average temperature of the month significantly effected the efficiency of a concentrating parabolic trough solar collector. The new model of a CPTSC increased the efficiency from 8 to 25 % with increase in both air mass flow rates and average temperature of the months. Therefore it is concluded that the solar collector efficiency increased with increasing air mass flow rate.

Downloads

Download data is not yet available.

Author Biographies

  • Muhammad Aamir Khan, The University of Agriculture, Peshawar

    Department of Agricultural Mechanization, Faculty of Crop Production Sciences, The University of Agriculture, Peshawar, Pakistan

  • M. Rahman, The University of Agriculture, Peshawar

    Department of Agricultural Mechanization, Faculty of Crop Production Sciences, The University of Agriculture, Peshawar, Pakistan

  • M. Hanif, The University of Agriculture, Peshawar

    Department of Agricultural Mechanization, Faculty of Crop Production Sciences, The University of Agriculture, Peshawar, Pakistan

  • Muhammad Aamir Israr, The University of Agriculture, Peshawar

    Department of Rural Development, Institute of Development Sciences, The University of Agriculture, Peshawar, Pakistan

  • S. Fahad Shah, The University of Agriculture, Peshawar

    Department of Rural Development, Institute of Development Sciences, The University of Agriculture, Peshawar, Pakistan

References

Ahmed A. G. 2011. Design and Construction of a Solar Drying System, a Cylindrical Section and Analysis of the Performance of the Thermal Drying System. Afr. Jr. Agri-Resh vol. 6(2);PP343-351,18.

Aswathanarayana. U., T.Harikrishnan and K.M.T Sahini. 2010. Green Energy. CRC. Press. Taylor and Francise. Balked Books Publishers. India

Balbir Singh M. S and F.Sulaiman. 2009. Electrical and Electronics Engineering, University Teknologi PETRONAS, Bandar Seri Iskandar, 31750 Tronoh, Perak, Malaysia.

Belessiotis.V., and Delyannis.E. 2010. Solar drying. Laboratory of Solar & other Energy Systems, NSRC “DEMOKRITOS”, P.O. box 60228. 153-10. Aghia Paraskevi, Greece.

Christian. N., J. B. Natowitze.. Our Energy Future. A Johan Wiley and Son. INC. Pub. Press.

Dikbasan. T., 2007. Determination of Effective Parameters for Drying of Apples. M.S. Thesis. The Graduate School of Engi. and Sci. Izmir Inst. Tech. Turkey.

Ehiem.J.C., S.V.Irtwange and S.E. Obetta. 2009. Design and Development of an Industrial Fruit and Vegetable Dryer. Dept. Agri. Engi, Uni.Agri. Umudike, Makurdi, Nigeria.

Fuller, R.J., T. Lhendup and L. Aye. 2005. International Technalogies Centre(IDTC). Deptt. Civil and Envi. Engi.Uni. Melbourne Australia.

Henderson and Perry. 1976. Food Processing Engineering. AVI pub. Press. INC.

Matthew G. Green and D.Schwarz. 2001. Solar Drying Technology for Food Preservation. Gate information Service gtz, PO Box 5180, 65726 Eschborn, Germany

Radu D. R. 2010. New Trends in Designing Parabolic trough Solar Concentrators and Heat Storage Concrete Systems in Solar Power Plants. J. Solar Energy. 12(3). 277-287.

Shuang Y., L. Xiao, and Y. R. Li. 2011.Effiect of aperture Position and size on natural convection heat loss of a solar heat- Pipe receiver. Laboratory of low-grade Energy Utilization Technologies and System, Changqing Uni. Ministry of Edu. Changqing 400044, China.

Yadav. S. N. 2011. Agricultural Engineering Fundamentals and Application. Bio Tech Book Publishers, Delhi. India.

--0--

Downloads

Published

2013-06-16

Issue

Section

Peer Reviewed Articles

How to Cite

Development of a Small Scale Concentrating Parabolic trough Solar Collector for Drying Purposes. (2013). Engineering International, 1(1), 9-17. https://doi.org/10.18034/ei.v1i1.213