Journal of Thermal Engineering and Applications

Using solar cabinet dryer is in many agriculture places, cold industrial places where heated regions require. This setup is useful for high work output and much area cover-up. Usually use simple solar cabinet dryer which is no more sensitive for precision workplace because its performance is low. So, use mixed mode solar cabinet dryer which conclude multi tray adjustable, cover by maximum possible area, using heater and fan which responsible for moisture removal and material of cabinet should high conduction coefficient that all property in setup increases its performance, efficiency and workability also. When use this model then achieve results are (in case of potato) –temperature inside solar cabinet dryer continue six hours are 41.4°C, 55.4°C, 59.8°C, 62.8°C, 68.5°C, 73.4°C, 74.8°C and outside of dryer at same time period are 35.2°C, 38°C, 42.2°C, 41.3°C, 42.6°C, 40.1°C, 37.5°C and percentage of moisture removed in dryer is 12.96%,17.02%, 12.82%, 11.76%, 13.33%, 11.53% and in ambient is 9.25%, 14.28%, 9.52%, 5.26%, 5.55%, 5.88%. Dry rate (gm/sec) of potato in dryer is 1.94×10^-3, 2.2×10^-3, 1.38×10^-3, 1.11×10^-3, 1.11×10^-3, 0.83×10^-3 and in ambient is 1.38×10^-3, 1.94×10^-3, 1.11×10^-3, 0.55×10^-3, 0.55×10^-3, 0.55×10^-3 and so on cotton. In this article, it is discussing about how to increase efficiency of solar cabinet dryer and focused on quality management. Here also discussed about solar selective coating formation on dryer, it absorbs much heat as compare to normal solar cabinet dryer. That means desired improve has done that increases its quality and efficiency and multi-layer coating functioning is applying for improving quality of solar cabinet dryer and solar collector shape is define for this type so that it can absorb maximum possible heat as possible define specific area.

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Bellas D V, Lidorikis E.Design of high-temperature solar-selective coatings for application in solar collectors. 2017 Solar Energy Materials and Solar Cells 170 102–13P. http://dx.doi.org/10.1016/j.solmat.2017.05.056

Weimera D, Rippela D, Hildebrandta T. Astrategy for logistic quality control in micro bulk production. 2014 Procedia Technology 15 323 – 32P. doi: 10.1016/j.protcy.2014.09.086

Marchi B, Zanoni B,Jaber M Y. Economic production quantity model with learning in production, quality, reliability and energy efficiency.2019 Computers & Industrial Engineering https://doi.org/10.1016/j.cie.2019.02.009

Morad M M, El-Shazly M A, Wasfy K I, Thermal analysis and performance evaluation of a solar tunnel greenhouse dryer for drying peppermint plants, 2017 Renewable Energy 101 992e1004. http://dx.doi.org/10.1016/j.renene.2016.09.042

Vallet K, Murali K,Joshi S V, Functional multi-layer nitride coatings for high temperature solar selective applications.2014 Solar EnergyMaterials&SolarCells12114–21. http://dx.doi.org/10.1016/j.solmat.2013.10.024

Cachafeiroa H, Arevaloa L F, Vinuesaa R. Impact of solar selective coating ageing on energy cost, International Conference on Concentrating Solar Power and Chemical Energy Systems. 2015 Solar PACES 2014, Energy Procedia 69 299 – 309P. doi: 10.1016/j.egypro.2015.03.034

Yalin l, Chen Z.Experimental study on thermal performance of solar absorber with CuO nano-structure selective coating. 2019 Energy procedia158 1303-10P. 10.1016/j.egypro.2019.01.323

Cite this Article

Ranjeet Singh Jadaun, Manish Kumar Sagar. Study and Analysis of Solar Cabinet Dryer with used of Solar Selective Material. Journal of Thermal Engineering and Applications. 2019; 6(2): 52–58p.