Ankur Gupta scite author profile

In the present study, an innovative stand-alone solar photovoltaic thermal (PVT) dryer has been designed and tested in hot-humid weather conditions of North-East India for drying green chili. The electrical output of the hybrid PVT solar dryer has been utilized to operate the blower for the dryer making the system self-sustained. A comparative analysis of the drying phenomena under the open sun and in the PVT based dryer is performed. Mathematical modeling is also done to investigate the drying kinetics of green chili for both drying conditions. Results indicate that the moisture content of 0.030 (d.b.) in the solar dryer and 0.035 (d.b.) in the open sun has been reduced for a span of 21 and 37 hr, respectively. Hybrid PVT solar dryer has achieved an average thermal efficiency of 31.37% and an average specific moisture extraction rate of 0.228 kg/kWh. The overall energy consumption for drying green chili is calculated to be 4.90 kWh/kg. Also, the overall thermal efficiency of 64.16%, thermal efficiency of 30.15%, and average electrical efficiency of 12.92% are secured. The results demonstrate the improved performance of the present PVT dryer for green chili drying in comparison to some of the conventional direct/indirect solar dryers. Practical ApplicationsThe present PVT solar dryer system can be utilized for drying the products using thermal energy produced by PVT air collector as well as generating electrical power in the decentralized off-grid areas. Solar drying is not adequately popular in the North-Eastern part of India due to the unavailability of solar drying systems for farmers. The agricultural products can be dried in the farming areas by installing this system. This PVT solar dryer provides a solution to the farmers for drying at zero energy cost and can be used as a source of income generation. This PVT solar drying system can be used to increase the storage life and reduce the spoilage and deterioration of agricultural commodities.Energy efficient solar drying process, high-quality products, and faster drying rate compared to traditional drying method can be achieved with the help of using this system. | INTRODUCTIONFood preservation is a significant major challenge to avoid deterioration, spoilage, and increasing the storage life of food products. There are various techniques to avoid food deterioration. The simplest way to preserve food is drying. Solar energy is the most attractive source of energy over the other sources of energy used for drying. The old process used to dry products with some limitation of the system is

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Analysis of the Heat Transfer Coefficient, Thermal Effusivity and Mathematical Modelling of Drying Kinetics of a Partitioned Single Pass Low-Cost Solar Drying of Cocoyam Chips with Economic Assessments

Ndukwu

Ibeh

Ekop

et al. 2022

Energies

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This study examines the heat and mass transfer coefficient, thermal effusivity, and other thermal properties of solar-dried cocoyam chips, as well as the drying kinetics. The research also assessed the economics of the solar dryer. For these reasons, a solar dryer with a partitioned collector was developed that creates a double airflow travel distance to delay the airflow inside the collector. The partitioning of the collector delays the airflow and helps to create more turbulence for the airflow with increased energy. The solar dryer was locally developed at the Michael Okpara University of Agriculture and tested during the humid crop harvesting period of September for the worst-case scenario. The obtained drying curves and kinetics for cocoyam drying are subjected to the vagaries of weather conditions. The drying rate showed declining sinusoidal characteristics and took about 25 h to attain equilibrium. Analysis of the airflow velocity showed gravitation between laminar and turbulent flow, ranging from 171.69 to 5152.77. Specific heat capacity, thermal conductivity, and effusivity declined with moisture content while the thermal diffusivity increased. However, the values of thermal effusivity ranged from 12.2 to 47.94 W.s1/2.m−2.K−1, which is within the range of values for insulators. The heat and mass transfer coefficient varied as a function of the airflow velocity. Fitting the drying curve into semi-empirical models showed that the two-term model was the best-fitted model for the experimental data from drying cocoyam. Using the solar dryer in Nigeria can save $188.63–$1886.13 in running costs with a payback period of 0.059–0.59 years (21.54–215.35 days) at a rate of 10–100% of usage.

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An environmental and economic evaluation of solar photovoltaic thermal dryer

Gupta

Das

Biswas

et al. 2021

Int. J. Environ. Sci. Technol.

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The up-gradation of the conventional indirect mode forced convection solar dryer to Photovoltaic thermal (PVT) based solar dryer is advantageous in terms of energysaving ability, efficiency, self-sufficient design, and ability to work without any additional electrical energy requirement. However, there is a requirement for a comprehensive analysis of the energy, exergy, and environ-economic parameters for developing an efficient and sustainable PVT solar dryer. In this study, a PVT based indirect mode solar dryer has been fabricated and investigated in the environmental conditions of North-East India (Silchar latitude of 24.83°). Experiments were performed to compare the drying characteristics of tomatoes (solanum lycopersicum) under open sun and solar drying conditions. A new mathematical drying model was proposed to predict the drying characteristics of tomato under both the modes of drying. The average PVT dryer efficiency was found to be 34.98%, higher than some of the published works of indirect mode solar dryer conducted under similar experimental conditions. The calculated values of drying effectiveness, collector efficiency factor, coefficient of performance, and heat utilization factor were 1.12-1.58, 0.011-0.029, 0.71, and 0.29, respectively. Furthermore, CO 2 emission, CO 2 mitigation, carbon credit earned parameters were evaluated for 10, 20, and 30 years of system life.

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Experimental study of a solar air heater with modified absorber plate through square obstacles with threaded pin fins

Borah¹,

Pathak²,

Gupta

et al. 2023

Applied Thermal Engineering

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Assessment of Performance and Quality Parameters for Drying Neem Leaves in Novel Photovoltaic-Thermal Solar Dryer

et al. 2022

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Ankur Gupta

Performance analysis of stand‐alone solar photovoltaic thermal dryer for drying of green chili in hot‐humid weather conditions ofNorth‐EastIndia

Analysis of the Heat Transfer Coefficient, Thermal Effusivity and Mathematical Modelling of Drying Kinetics of a Partitioned Single Pass Low-Cost Solar Drying of Cocoyam Chips with Economic Assessments

An environmental and economic evaluation of solar photovoltaic thermal dryer

Experimental study of a solar air heater with modified absorber plate through square obstacles with threaded pin fins

Assessment of Performance and Quality Parameters for Drying Neem Leaves in Novel Photovoltaic-Thermal Solar Dryer

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