Solar energy systems – Potential of nanofluids

Global warming escalation has extended average temperature of earth beyond its safe limit. To avert this environmental-threat, solar energy has acquired substantial attention of remarkable researchers in this century. To effectively utilize solar energy by transforming into thermal and electrical en...

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Bibliographic Details
Published in:Journal of molecular liquids 2019-09, Vol.289, p.111049, Article 111049
Main Authors: Wahab, Abdul, Hassan, Ali, Qasim, Muhammad Arslan, Ali, Hafiz Muhammad, Babar, Hamza, Sajid, Muhammad Usman
Format: Article
Language:English
Subjects:
Efficiency improvement
Heat transfer enhancement
Nanofluid applications
Solar collectors
Solar energy
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Summary:Global warming escalation has extended average temperature of earth beyond its safe limit. To avert this environmental-threat, solar energy has acquired substantial attention of remarkable researchers in this century. To effectively utilize solar energy by transforming into thermal and electrical energy, the involvement of nanofluids having intensified thermal, optical and magnetic properties, has become very popular. The foremost objective of this article is to provide a comprehensive review on the applications of nanofluids in solar energy systems like solar collectors, photovoltaic cells, solar stills, and thermal energy storage, which are thoroughly discussed in this paper. The effect of various critical parameters including flow rate of nanofluid, concentration of nanoparticles in base fluid, size, and type of nanoparticles on the efficiency of solar systems is thoroughly analyzed by graphical means. Comparison is made between the performance of nanofluid and base fluid in terms of electrical and thermal efficiency enhancements for all solar energy systems. Effect of nanoparticles on outlet temperature of working fluid, area reduction of solar system, optical efficiency, pumping power and friction factor of working fluid is also analyzed. In addition, the stats of the entire work considering leading investigators, organizations, countries, and journals have also been discussed briefly. Results suggest that nanofluid have a massive impact on heat transfer and system overall efficiency compared to base fluid in solar energy systems. Moreover, various challenges including stability, cost-effectiveness, higher pumping power with the use of nanofluids have also been briefly discussed in this study. [Display omitted] •Discussion on the effect of various critical parameters on performance of solar systems.•Challenges that hinders the applications of nanofluids in solar systems.•Summarized the studies in tables and briefly discussed the stats of the entire work.•Productivity of solar still can be maximized by lowering water depth.•In solar collectors, maximum efficiency is achieved at lower concentration of nanoparticles in base fluid.
ISSN:0167-7322
1873-3166
DOI:10.1016/j.molliq.2019.111049