Design and fabrication of a double- chamber solar dryer

ScienceRise Pub Date : 2022-02-28 DOI:10.21303/2313-8416.2022.002321

Olunloyo Oluwatoyin, Ibiyeye Dare, Ajiboye Opeyemi

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Abstract

Object of research: This paper discusses the design and construction of a modified, cost effective solar dryer for use by the average Nigerian farmer or agri-business entrepreneur. Investigated problem: Local farmers often have a lot of difficulties in properly drying harvested agricultural produce for storage and processing purposes, safely and efficiently due to capital constraints. There was therefore a need for an efficient, low cost solar dryer design to aid in this pursuit. Methodology: The designed dryer is a passive dryer that makes use of heat energy tapped through glass collectors placed over the drying and air inlet chambers respectively. The dryer was designed and constructed with carefully selected, inexpensive materials with dimensions of 40cm x 40cm x 60cm for the drying chamber and dimensions of 10cm x 80cm x 40cm for the heating chamber. The glass collectors (4mm thick) were inclined at an angle of incidence of 17.26°. Okra slices were used to test the performance of the dryer. Results / Area of practical use: The study yielded a low cost (€145.60) modified solar dryer capable of drying agricultural produce in a safe and clean way. During eight (8) hours of drying under a temperature range of 39 °C – 45 °C, the initial weight of the okra slices reduced from 150g to 9g, 9g, 10g and 9g on each of the four trays of the drying chamber respectively. Local farmers and agripreneurs will be encouraged to make use of this clean alternative of drying food produce without the drawbacks from regular sun drying. Conclusion: There is need for more work to be done in terms of installation of solar panels to enhance dryer performance. More work should also be carried out on tests during the dry season for increased dryer efficiency.

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双室太阳能干燥机的设计与制造

研究对象：本文讨论了一种改良的、成本效益高的太阳能烘干机的设计和建造，供尼日利亚普通农民或农业企业企业家使用。调查问题：由于资金限制，当地农民在安全有效地干燥收获的农产品以进行储存和加工方面经常遇到很多困难。因此，需要一种高效、低成本的太阳能干燥器设计来帮助实现这一目标。方法：设计的烘干机是一种被动式烘干机，它利用通过分别放置在烘干室和进气室上的玻璃收集器获得的热能。干燥机采用精心挑选的廉价材料设计和制造，干燥室尺寸为40cm x 40cm x 60cm，加热室尺寸为10cm x 80cm x 40厘米。玻璃收集器（4mm厚）以17.26°的入射角倾斜。用秋葵切片测试干燥机的性能。结果/实际使用领域：该研究产生了一种低成本（145.60欧元）的改良太阳能烘干机，能够以安全清洁的方式烘干农产品。在39°C–45°C的温度范围内干燥八（8）小时，干燥室四个托盘上的秋葵片的初始重量分别从150克降至9克、9克、10克和9克。将鼓励当地农民和农业企业家使用这种清洁的替代品来干燥食品，而不会有定期阳光干燥的缺点。结论：在安装太阳能电池板以提高干燥机性能方面，还需要做更多的工作。为了提高烘干机的效率，还应在旱季进行更多的测试工作。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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ScienceRise

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3 weeks