Performance analysis of evacuated tube type solar air heater with parabolic trough type collector

Pandey, Saurabh; Mishra, Shubham; Sharma, Aniket; Verma, Ashutosh Kumar; Yadav, Laxmikant

doi:10.1007/s42108-021-00158-w

Cited by 14 publications

(3 citation statements)

References 25 publications

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“…Mehla & Yadav 27) explored PCM scientifically and demonstrated that the apparatus performs best at night. A mathematical simulation of an ETSAH with a parabolic trough collector was created by Pandey et al 28) . They discovered that a flowing fluid receives the maximum radiation from the sun.…”

Section: Introductionmentioning

confidence: 99%

Enhancing the Thermal Efficiency and Optimum Temperature of a Modified Evacuated Tube Solar Air Collector by using the Reflector

Zaphar,

Verma

2023

Evergreen

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The experimental investigation of the thermal efficiency of a retrofitted evacuated tube solar collector employing air as the working fluid, with and without a rectangular aluminum sheet reflector during the winter, considering both sunny day and hazed day climatic conditions occurred at Glocal University in Saharanpur, India, between 30 17' (latitude) North and 77 38' (longitude) East. The solar collector comprises vacuum tubes with directed inner tubes that are 22 mm in diameter and are put in a single-ended steel cuboid-shaped manifold. The inner steel tubes supply the input air into the vacuum tube. The heated air is generated in vacuum tubes, collected in the central header cylindrical manifold, and expelled through the exit pipe. With an aluminum sheet reflector fixed, the flow velocity, mass flow rate, and irradiance affect thermal efficiency and exit air temperature. In the case of a stainless-steel tube with a 22 mm diameter and a length of 1.27 meters, the maximum temperature difference between the outside air and the input air is 71.9 C, and the maximum temperature recorded is 96.9 C. A higher efficiency of 36.69% is attained with a suitable aluminum sheet reflector at an increased flow rate of 20.14 kg/h. In ETSCs that have been updated, there is an average rise in exit air temperature of 37.5%.

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Section: Introductionmentioning

confidence: 99%

Enhancing the Thermal Efficiency and Optimum Temperature of a Modified Evacuated Tube Solar Air Collector by using the Reflector

Zaphar,

Verma

2023

Evergreen

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“…Researchers have attempted to integrate parabolic trough collectors with ETSCs to enhance the overall performance of evacuated tube solar collectors. Saurabh Pandey et al [15] carried out an experimental study in order to boost the effectiveness of an evacuated U-tube solar collector incorporated with a parabolic trough solar collector used for air heating. By employing various mass flow rates, the authors found that a mass flow rate of 0.0082 Kg/s yielded the highest average thermal effectiveness (21.3%).…”

Section: Introductionmentioning

confidence: 99%

New Evacuated Tube Solar Collector with Parabolic Trough Collector and Helical Coil Heat Exchanger for Usage in Domestic Water Heating

et al. 2023

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Buildings represent approximately two-thirds of the overall energy needs, mainly due to the growing energy consumption of air conditioning and water heating loads. Hence, it is necessary to minimize energy usage in buildings. Numerous research studies have been carried out on evacuated tube solar collectors, but to our knowledge, no previous study has mentioned the combination of an evacuated tube solar collector with a parabolic trough collector and a helical coil heat exchanger. The objective of this paper is to evaluate the thermal behavior of an innovative evacuated tube solar collector (ETSC) incorporated with a helical coil heat exchanger and equipped with a parabolic trough collector (PTC) used as a domestic water heater. To design the parabolic solar collector, the Parabola Calculator 2.0 software was used, and the Soltrace software was used to determine the optical behavior of a PTC. Moreover, an analytical model was created in order to enhance the performance of the new model of an ETSC by studying the impact of geometric design and functional parameters on the collector’s effectiveness. An assessment of the thermal behavior of the new ETSC was performed. Thus, the proposed analytical model gives the possibility of optimizing ETSCs used as domestic water heaters with lower computational costs. Furthermore, the optimum operational and geometrical parameters of the new ETSC base-helical tube heat exchanger include a higher thermal efficiency of 72%. This finding highlights the potential of the heat exchanger as an excellent component that can be incorporated into ETSCs.

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“…Pandey et al . [38] have utilized the solar PTC to heat air at a variable mass flow rate. At a lesser mass flow rate, they found elevated exit temperatures.…”

Section: Introductionmentioning

confidence: 99%

Solar energy assisted thermal treatment model to decontaminate airborne viruses in hospital

Soni¹,

Sharma²,

Nimesh³

et al. 2022

Thermal Science and Engineering Progress

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Performance analysis of evacuated tube type solar air heater with parabolic trough type collector

Cited by 14 publications

References 25 publications

Enhancing the Thermal Efficiency and Optimum Temperature of a Modified Evacuated Tube Solar Air Collector by using the Reflector

Enhancing the Thermal Efficiency and Optimum Temperature of a Modified Evacuated Tube Solar Air Collector by using the Reflector

New Evacuated Tube Solar Collector with Parabolic Trough Collector and Helical Coil Heat Exchanger for Usage in Domestic Water Heating

Solar energy assisted thermal treatment model to decontaminate airborne viruses in hospital

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