Design consideration of smart solar dryer for precision drying
Smart solar dryer for precision drying
DOI:
https://doi.org/10.21921/jas.v8i2.7297Keywords:
Evacuated tube, solar dryer, phase change material, load cells, sensorsAbstract
A sensor based solar dryer was designed to control the drying environment for precision drying of agricultural produce. The system entirely used solar energy utilizing both thermal and electrical effect. Paraffin wax (PCM) was used for storage of thermal energy whereas solar battery was used to store the electrical energy. Hot air blower was also provided to supply heat when there is less or no solar radiation. Temperature sensors were provided to control the environment of drying chamber. The exhaust fan started operating depending on the set temperature and thus control the drying environment. Load cells were provided below each tray to measure the dry weight. The drying chamber was made of mild steel with glass wool insulation. The capacity of the designed dryer was 10-15 kg with 6 trays. The designed dryer has target temperature of 55-60oC.
References
Aravindh MA and Sreekumar A. 2015. Solar Drying - A Sustainable Way of Food Processing. Energy Sustainability through Green Energy 26: 27-46.
Dasin DY, Godi NY and Kingsley OC. 2015. Experimental Investigations of the performance of passive solar food dryer tested in Yola Nigeria. International Journal of Energy Engineering 5(1): 9-15.
IS 16648 (Part 5). 2017. Concentrated solar thermal- Part 5 Test Methods.
Jairaj KS, Singh SP and Srikant K. 2009. A review of solar dryers developed for grape drying. Solar Energy 83(9): 1698-1712.
Kant K, Shukla A, Sharma A, Kumar A and Jain A. 2016. Thermal energy storage based solar drying systems: A review. Innovative Food Science and Emerging Technologies 34:86–99.
Mohanraj M and Chandrasekar P. 2008. Drying of copra in forced convection solar drier. Biosystem Engineering 99:604–607.
Musale Y, Patil S, Chougule B and Kalkarni A. 2016. Recent Developments in Solar Refrigeration Technology-A Review. International Journal of Current Engineering and Technology 4: 95-98.
Ogheneruona DE and Yusuf MOL. 2011. Design and fabrication of a direct natural convection solar dryer for Tapioca. Leonardo Electronic Journal of Practices and Technologies 18: 95- 104.
Prakash O. and Kumar A. 2017. Solar Drying Technology Concept, Design, Testing, Modeling, Economics, and Environment. Green Energy and Technology, Springer Nature, Singapore.
Sahay KM and Singh KK. 2004. Unit Operations of Agricultural processing. Vikas Publishing House Private Limited, Delhi, 9-11.
Sansaniwal SK, Kumar M and Rajneesh VK. 2017. Investigation of Indirect Solar Drying of Ginger Rhizomes (Zingiber Officinale): A Comparative Study. Journal of Engineering Science and Technology 12(7): 1956-1971.
Shalaby SM, Bek MA and El-Sebaii AA. 2014. Solar dryers with PCM as energy storage medium: A review. Renewable and Sustainable Energy Reviews 33:110 –116.
Tonui KS, Mutai EB, Mutuli DA, Mbuge DO and Too KV. 2014. Design and evaluation of solar grain dryer with a back-up heater. Research Journal of Applied Sciences, Engineering and Technology 7(15): 3036-3043.