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Life cycle assessment and economic valuation of a natural convection solar greenhouse dryer in Western Maharashtra, India

Treść / Zawartość
Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
The current study focuses on the life cycle assessment and an economic valuation of a natural convection solar greenhouse dryer in Western Maharashtra, India. The Solar Greenhouse Dryer is an active device that gains solar radiation incident on to the surface of the dryer and along with wind energy, it removes moisture from agricultural yield. The combination of solar Energy and wind energy removes moisture from agricultural yield. The Solar Greenhouse Dryer is primarily used in rural settings; hence, it is very important to analyse the environmental and economic aspects associated with the dryer to obtain the maximum benefit from the dryer with less investment possible. The experiment involving a natural convection solar dryer was conducted at Bahe, Borgaon, Tal-Walwa, Dist- Sangli, Maharashtra, India located at 17.115° N and 74.33° E. The environmental parameters taken into considerations during the analysis covered energy, Energy payback time and CO2 emissions, mitigation and carbon credits earned by the dryer. The economic analysis of the solar dryer consists of the annual cost of the dryer, the salvage value, the annual saving obtained and the payback period respectively. The embodied energy of the solar greenhouse dryer considering all the components of the dryer is 238.317 kWh, the energy payback time is 0.588 years and CO2 emissions are 24.327 kg per year, the carbon dioxide mitigation is 2.042 kg per kWh and the carbon credits earned by the dryer are nearly 28, 600. The annual cost of the dryer is Rs. 21, 600, the salvage value of the dryer is Rs. 7, 160, the annual savings obtained from the dryer are Rs. 1,62, 574 and the payback period is around 2 years respectively. The Solar Greenhouse Dryer is a cost-effective and environmentally friendly solution that can effectively be used in rural settings by farmers to prevent various post-harvest losses associated with the agricultural yield and to gain extra additional income from the dried products.
Rocznik
Strony
99--105
Opis fizyczny
Bibliogr. 12 poz., rys., tab.
Twórcy
  • Department of Technology, Shivaji University, Kolhapur, Maharashtra State, India
  • Department of Technology, Shivaji University, Kolhapur, Maharashtra State, India
  • Department of Technology, Shivaji University, Kolhapur, Maharashtra State, India
Bibliografia
  • 1. Vijayan S, Arjunan T. V., Anil Kumar. Fundamentals of Drying. Solar Drying Technology - Concept, Design, Testing and Modeling, Economics and Environment 2017; 3-38.
  • 2. Labuza TP, McNally L, Gallagher D, Hawkes J, Hurtado F. Stability of intermediate moisture foods. 1. Lipid oxidation. Journal of Food Science 1972; 37(1):154–159.
  • 3. Prakash O, Kumar A. Annual performance of modified greenhouse dryer under passive mode in no-load conditions. International Journal of Green Energy 2015;12:1091–1099.
  • 4. Akshay Vijay, Bagi Jaydeep, Prabhu Pravin. Design of a Solar Modified Greenhouse Prototype. Journal of Science and Technology; 2021; 06(01); 118-125.
  • 4. Pushpendra Singh, M. K. Gaur. Environmental and economic analysis of solar greenhouse dryer: A Review. International Journal of Energy Technology 2020; 2(1): 55-69.
  • 5. Mohamed A. Eltawila, Mostafa M. Azama, Abdulrahman O. Alghannamb. Energy analysis of hybrid solar tunel dryer with PV system and solar collector for drying mint. Journal of Cleaner Production 2018; 1-32.
  • 6. Saravanan Dhanushkodi, Vincent Wilson, Kumarasamy Sudhakar. Life Cycle Cost of Solar Biomass Hybrid Dryer Systems for Cashew Drying of Nuts in India. Environmental and Climate Technologies 2015; 22-33.
  • 7. Aymen ELkhadraoui, Sami Kooli, Ilhem Hamdi, Abdelhamid Farhat. Experimental investigation and economic evaluation of a new mixed mode solar greenhouse dryer for drying of red pepper and grape. Renewable Energy 2015; 1-8.
  • 8. Ketki Deshmane S, Yadav AA, Ingawale SM. Winddata Estimation of Kolhapur district using Improved Hybrid Optimization by Genetic Algorithms (iHOGA) and NASA Prediction of Worldwide Energy Resources (NASA Power). International Research Journal of Engineering and Technology 2020;2530–2538.
  • 9. Yadav AA, Prabhu PA, Bagi JS. Numerical simulation and experimental validation of solar greenhouse dryer using finite element analysis for different roof shapes. Journal of Mechanical and Energy Engineering 2021; 5(1): 69-80.
  • 10. Yadav AA, Prabhu PA, Bagi JS. Response Surface Modelling and performance evaluation of solar dryer for drying of grapes. Journal of Mechanical and Energy Engineering 2021; 5(2): 157-168.
  • 11. Yadav AA, Prabhu PA, Bagi JS. Experimental Performance and Response Surface Modelling of Solar dryer for drying of bitter gourd in western Maharashtra, India. Journal of Post-Harvest Technology. 2021; 9(3): 1-16.
Uwagi
PL
Błędna numeracja w Bibliografii.
PL
Opracowanie rekordu ze środków MEiN, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2022-2023).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-e3653358-e818-43c0-a7a6-fa2c13c27195
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