Performance of a Solar Drying System Driven by a Hybrid Power System

Hao Zhong; Zhi Min Li; Tong Wu; Ming Jiu Yu; Run Sheng Tang

doi:10.4028/www.scientific.net/AMR.455-456.139

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HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 455-456Performance of a Solar Drying System Driven by a...

Performance of a Solar Drying System Driven by a Hybrid Power System

Abstract:

To increase the production and improve the quality of dried agricultural products, a new drying system with a hybrid driving power system was developed and tested. The system with total collector area of 100m2 is consisted of 10 drying units and each of them is consisted of 5 identical air collectors and a greenhouse-like drying chamber. Each of collectors in the system is equipped with a DC fan, powered by either 120W solar modules or a 300W wind turbine, and an AC fan, directly powered by the electricity from grid. Such drying system can operate in all time of any day and avoid any possible spoilage of dried products as found in conventional solar dryers due to the formation of mould on the surface of dried materials in the events of consecutive rainy days. Field test for the drying of 9 fruits was conducted from November to December in 2005. The results indicated that the system was very effective for the drying of fruits and the solar drying time for most of the materials to be investigated was only one third of that required in the natural sun drying. Test results also showed that the nocturnal ventilation of drying chambers at the early stage of drying exercise was necessary for materials with high initial moisture content in order to further shorten the solar drying time.

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Periodical:

Advanced Materials Research (Volumes 455-456)

Pages:

139-146

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.455-456.139

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Online since:

January 2012

Authors:

Hao Zhong, Zhi Min Li, Tong Wu, Ming Jiu Yu, Run Sheng Tang

Keywords:

Field Test, Hybrid Power System, Nocturnal Ventilation, Solar Drying System

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References

[1] V. K. Sharma, A. Colangelo and G. Spagna, Experimental investigation of different solar dryers suitable for fruit and vegetable, Renewable Energy 6, pp.413-424, (1995).

DOI: 10.1016/0960-1481(94)00075-h

Google Scholar

[2] J. C. Hollick, Commercial scale solar drying, Renewable Energy 16, pp.714-719, (1999).

DOI: 10.1016/s0960-1481(98)00258-4

Google Scholar

[3] B. K. Bala, M. R. A. Mondol, B. K. Biswas, D. B. L. Chowdury and S. Janjai, Solar drying of pineapple using solar tunnel drier, Renewable Energy 28, pp.183-190, (2003).

DOI: 10.1016/s0960-1481(02)00034-4

Google Scholar

[4] A. Esper and W. Muhalbauer, Solar drying: an effective means of food preservation, Renewable Energy 15, pp.95-100, (1998).

DOI: 10.1016/s0960-1481(98)00143-8

Google Scholar

[5] B. K. Bale, M. R. A. Mondol, Experimental investigation on solar drying of fish using solar tunnel drier, Drying Technology 19, pp.1-19, (2001).

DOI: 10.1081/drt-100102915

Google Scholar

[6] A. Esper, W. Muhlbauer, PV-driven solar tunnel drier, In: Agricultural Engineering Conference, Bangkok, December 6-9, (1994).

Google Scholar

[7] P. Schirmer, S. Janjai, A. Esper, R. W. Smitabhindu, Muhlbauer, Experimental investigation of the performance of the solar tunnel dryer for dying bananas, Renewable Energy 7, pp.119-129, (1996).

DOI: 10.1016/0960-1481(95)00138-7

Google Scholar

[8] A. A. El-Sebaii, S. Aboul-Enein, M. R. I. Ramadan and H. G. El-Gohary, Experimental investigation of an indirect type natural convection solar dryer,. Energy Conversion and Management 43, pp.2251-2266, (2002).

DOI: 10.1016/s0196-8904(01)00152-2

Google Scholar

[9] V. K. Sharma, A. Colangelo and G. Spagna, Experimental investigation of different solar dryers suitable for fruit and vegetable, Renewable Energy 6, pp.413-424, (1995).

DOI: 10.1016/0960-1481(94)00075-h

Google Scholar

[10] Z.M. Li, H. Zhong, R.S. Tang, T. Liu, W.F. Gao, Y. Zhang, Experimental investigation on solar drying of salted greengages, Renewable Energy 31, pp.837-847, (2006).

DOI: 10.1016/j.renene.2005.05.008

Google Scholar