Evaluation and comparing of natural and forced solar dryer for mint drying in Khuzestan province

Habibi Asl, J.; Behbahani, L.; Azizi, A.

doi:10.22067/jam.v7i1.48370

Document Type : Research Article

Authors

Agricultural Engineering Research Department, Khuzestan Agricultural and Natural Resources Research and Education Centre, AREEO, Ahvaz, Iran

https://doi.org/10.22067/jam.v7i1.48370

Abstract

Introduction
Many vegetables such as mint are highly seasonal in nature. They are available in plenty at a particular period of time in specific regions that many times result in market glut. Due to perishable nature, huge quantity of vegetables is spoiled within a short period. The post-harvest loss in vegetables has been estimated to be about 30-40% due to inadequate post-harvest handling, lack of infrastructure, processing, marketing and storage facilities. Therefore, the food processing sector can play a vital role in reducing the post-harvest losses and value addition of vegetables which will ensure better remuneration to the growers. Drying is a common technique for preservation of food and other products; including fruits and vegetables. The major advantage of drying food products is the reduction of moisture content to a safe level that allows extending the shelf life of dried products. The removal of water from foods provides microbiological stability and reduces deteriorate chemical reactions. Also, the process allows a substantial reduction in terms of mass, volume, packaging requirement, storage and transportation costs with more convenience. Sun drying is a well known traditional method of drying agricultural products immediately after harvest. However, it is plagued with in-built problems, since the product is unprotected from rain, storm, windborne dirt, dust, and infestation by insects, rodents, and other animals. It may result in physical and structural changes in the product such as shrinkage, case hardening, loss of volatiles and nutrient components and lower water reabsorption during rehydration. Therefore, the quality of sun dried product is degraded and sometimes become not suitable for human consumption. For these reasons, to utilize renewable energy sources, reduce vegetable losses and increase farmers income, the current project has been conducted in the Agricultural Engineering Department of Khuzestan Agricultural Research Center during the years 2011-2013.
Materials and Methods
In this research an indirect cabinet solar dryer with three trays and grooved collector was constructed. To improve air convection, a chimney was mounted above the dryer. The dryer performance was evaluated by drying mint leaves in three levels of mass density of 2, 3, and 4 kg m^-2 at two drying manners of natural and forced convection and compared with drying mint leaves in shade as the traditional method.
Results and Discussion
The results showed that total drying time required in different solar drier treatments was 3.5 to 15 h, while it was about 5 days in traditional method. Drying time in upper trays was more as the air flow decreased due to increase in mass density. Mean required drying time in forced convection was 29.7% less than that of natural convection. Maximum essences with 0.80% and 0.76% were belonged to "natural convection and 3kg m^-2 mass density" and "forced convection and 4 kg m^-2 mass density" treatments respectively, while minimum one with 0.30% was for "forced convection and 2 kg m^-2 mass density" treatment. Also, the highest and lowest chlorophyll content with 8.51 and 4.18 mg ml^-1 were measured in "natural convection and 3 kg m^-2 mass density" and "forced convection and 4 kg m^-2 mass density" treatments respectively. According to obtained results, 3 and 4 kg m^-2 mass density can be suggested for natural and forced convection solar drying of mint leaves in Khuzestan condition respectively.
Conclusion
In order to reduce vegetable losses and increase Khuzestan vegetable producers income, indirect cabinet solar dryer for drying mint leaves in winter season, could be an appropriate option. For natural and forced convection drying methods, mass density of 3 and 4 kg m^-2 is recommended respectively.

Keywords

20.1001.1.22286829.1396.7.1.10.5

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Journal of Agricultural Machinery

Evaluation and comparing of natural and forced solar dryer for mint drying in Khuzestan province

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Volume 7, Issue 1 - Serial Number 13
Spring and Summer
2017
Pages 114-125

Evaluation and comparing of natural and forced solar dryer for mint drying in Khuzestan province

References

References

Send comment about this article

Volume 7, Issue 1 - Serial Number 13Spring and Summer 2017Pages 114-125

Volume 7, Issue 1 - Serial Number 13
Spring and Summer
2017
Pages 114-125