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Evolutionary Methods Based Modeling and Analysis of Solar Thermal SystemsInvestigation of Thermal Performance of Solar Collector Variables Using Fuzzy Logic-Based Expert System

Evolutionary Methods Based Modeling and Analysis of Solar Thermal Systems: Investigation of... [A sand-coated flat plate solar air collector is simulated and optimized using a hybrid SC-TSK-FL technique for the climatic conditions of Bangalore rural, southern part of India. Here SC method is used to cluster the dataset, and TSK-FL is applied to optimize/predict solar air collector characteristics. Different governing features are considered as input parameters, such as air mass flow rate, collector tilt angle, solar radiation, and ambient temperature. Thermal efficiency, temperature rise, and pressure drop are taken as output parameters. Initially, a flat plate solar air collector’s input parameters vary to conduct experiments. Finally, the results reveal that the optimal input setting for sand-coated solar air collector (SCSAC) is 0.0175 kg/s mass flow rate, 674 W/m2 solar radiation, and 31.5 °C inlet temperature and corresponding output parameters are temperature rise of 29 °C, energy efficiency of 16%, and 5.62 Pa pressure drop.] http://www.deepdyve.com/assets/images/DeepDyve-Logo-lg.png

Evolutionary Methods Based Modeling and Analysis of Solar Thermal SystemsInvestigation of Thermal Performance of Solar Collector Variables Using Fuzzy Logic-Based Expert System

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Publisher
Springer International Publishing
Copyright
© The Editor(s) (if applicable) and The Author(s), under exclusive license to Springer Nature Switzerland AG 2023
ISBN
978-3-031-27634-7
Pages
63 –76
DOI
10.1007/978-3-031-27635-4_4
Publisher site
See Chapter on Publisher Site

Abstract

[A sand-coated flat plate solar air collector is simulated and optimized using a hybrid SC-TSK-FL technique for the climatic conditions of Bangalore rural, southern part of India. Here SC method is used to cluster the dataset, and TSK-FL is applied to optimize/predict solar air collector characteristics. Different governing features are considered as input parameters, such as air mass flow rate, collector tilt angle, solar radiation, and ambient temperature. Thermal efficiency, temperature rise, and pressure drop are taken as output parameters. Initially, a flat plate solar air collector’s input parameters vary to conduct experiments. Finally, the results reveal that the optimal input setting for sand-coated solar air collector (SCSAC) is 0.0175 kg/s mass flow rate, 674 W/m2 solar radiation, and 31.5 °C inlet temperature and corresponding output parameters are temperature rise of 29 °C, energy efficiency of 16%, and 5.62 Pa pressure drop.]

Published: Apr 30, 2023

Keywords: Sand coated; SAC; FLES; Energy efficiency; Exergy efficiency

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