A parametric assessing and intelligent forecasting of the energy and exergy performances of a dish concentrating photovoltaic/thermal collector considering six different nanofluids and applying two meticulous soft computing paradigms

In the present study, the application of six engine oil-based Nano fluids (NFs) in a solar concentrating photovoltaic thermal (CPVT) collector is investigated. The calculations were performed for different values of nanoparticle volume concentration, receiver tube diameter, concentrator surface area, receiver length, receiver actual to the maximum number of channels ratio, beam radiation, and a constant volumetric flow rate. Besides, two novel soft computing paradigms namely, the cascaded forward neural network (CFNN) and Multi-gene genetic programming (MGGP) were adopted to predict the first law efficiency (eta(I)) and second law efficiency (eta(II)) of the system based on the influential parameters, as the input features. It was found that the increase of nanoparticle concentration leads to an increase in eta(I) and a decrease in eta(II). Moreover, the rise of both the concentrator surface area (from 5 m(2) to 20 m(2)) and beam irradiance (from 150 W/m(2) to 1000 W/m(2)) entails an increase in both the eta(I) (by 39% and 261%) and eta(II) (by 55% and 438%). Furthermore, it was reported that the pattern of changes in both eta(I) and eta(II) with serpentine tube diameter, receiver plate length, and absorber tube length is increasing-decreasing. The results of modeling demonstrated that the CFNN had superior performance than the MGGP model. (C) 2022 Elsevier Ltd. All rights reserved.

Automated summary

This study investigates the application of six engine oil-based Nano fluids in a solar concentrating photovoltaic thermal collector. The increase of nanoparticle concentration, concentrator surface area, and beam irradiance were found to improve the system's efficiency.