State of the art of techno-economics of nanofluid-laden flat-plate solar collectors for sustainable accomplishment

Shamshirgaran, S.R. and Al-Kayiem, H.H. and Sharma, K.V. and Ghasemi, M. (2020) State of the art of techno-economics of nanofluid-laden flat-plate solar collectors for sustainable accomplishment. Sustainability (Switzerland), 12 (21). pp. 1-42.

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Abstract

Emerging nanotechnology with solar collector technology has attracted the attention of researchers to enhance the performance of solar systems in order to develop efficient solar thermal systems for future sustainability. This paper chronologically reviews the various research works carried out on the performance enhancement of nanofluid-filled flat-plate solar collectors (FPCs). Gaps in the radiation exergy models and maximum exergy of FPCs, the importance of pressure drops in collector manifolds in exergy analysis, and the economics of nanofluid-laden FPCs have been addressed. The necessity of replacing currently used chemically derived glycol products with a renewable-based glycol has not been reported in the current literature thoroughly, but it is pondered in the current paper. Moreover, the thermophysical properties of all common metal and metal oxide nanoparticles utilized in various studies are collected in this paper for the first time and can be referred to quickly as a data source for future studies. The different classical empirical correlations for the estimation of specific heat, density, conductivity, and viscosity of reported nanofluids and base liquids, i.e., water and its mixture with glycols, are also tabulated as a quick reference. Brief insights on different performance criteria and the utilized models of heat transfer, energy efficiency, exergy efficiency, and economic calculation of nanofluid-based FPCs are extracted. Most importantly, a summary of the current progress in the field of nanofluid-charged FPCs is presented appropriately within two tables. The tables contain the status of the main parameters in different research works. Finally, gaps in the literature are addressed and mitigation approaches are suggested for the future sustainability of nanofluid-laden FPCs. © 2020 by the authors. Licensee MDPI, Basel, Switzerland.

Item Type: Article
Impact Factor: cited By 2
Uncontrolled Keywords: economic analysis; exergy; heating; nanoparticle; nanotechnology; photovoltaic system; solar power; sustainability; thermochemistry; viscosity
Depositing User: Ms Sharifah Fahimah Saiyed Yeop
Date Deposited: 25 Mar 2022 02:56
Last Modified: 25 Mar 2022 02:56
URI: http://scholars.utp.edu.my/id/eprint/29805

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