DRYING OF SQUASH USING SOLAR TUNNEL DRYER WITH PHOTOVOLTAIC | ||||
| Misr Journal of Agricultural Engineering | ||||
| Article 21, Volume 26, Issue 2, April 2009, Page 922-934 PDF (287.19 K) | ||||
| Document Type: Original Article | ||||
| DOI: 10.21608/mjae.2009.109759 | ||||
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| Authors | ||||
| A. Derbala1; N.A. Udroiu2; A. Mitroi2; C. Iacomi2 | ||||
| 1Agricultural engineering dept., faculty of agriculture, Tanta University, Egypt. | ||||
| 2Agricultural engineering dept., University of agricultural sciences and veterinary medicine, Bucharest, Romania. | ||||
| Abstract | ||||
| Experimental solar tunnel dryer (type Hohenheim 2x18 m) with photovoltaic-module and integrated air heat collector has been installed at the department of agricultural engineering, university of agronomic sciences and veterinary medicine, Bucharest, Romania to study and evaluate the squash drying process. The obtained results indicated that, there is an inversely relation between the air relative humidity and both the air temperature and the intensity of solar radiation. The maximum difference between the drying air temperature and ambient temperature was 30 ºC afternoon (14.20 h) at two different thicknesses of squash slices (0.5 and 1 cm). The higher rate of moisture removal was 80 kg/h in case of 1 cm thick of squash slices at the first two hours. On the other hand, it was 45 kg/h in case of 0.5 cm thick of squash slices at the first three hours. The potassium and phosphor ratios increased in the dried squash as compared with the fresh squash. Whilst, the nitrogen ratio decreased in thicknesses of slices and the minimum value was found with 0.5 cm thick. The solar tunnel dryer can be used to enhance the quality of agricultural dried crops. The production of dried crops is a promising alternative method to sale as compared with the fresh produce. | ||||
| Keywords | ||||
| drying; dried vegetables; solar dryer; PV- Module | ||||
| References | ||||
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