Experimental study of using both ZnO/ water nanofluid and phase change material (PCM) in photovoltaic thermal systems

Sardarabadi, Mohammad; Passandideh-Fard, Mohammad; Maghrebi, Mohammad Javad; Ghazikhani, Mohsen

doi:10.1016/j.solmat.2016.11.032

Cited by 254 publications

(46 citation statements)

References 17 publications

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“…PCM not only decreases the surface temperature and but also maintains the stable surface temperature without any major jumps. Sardarabadi 28 and Sidik 14 reported the similar behavior for ZnO and CuO.…”

Section: Surface Temperaturementioning

confidence: 64%

Comparative study to use nanofluid ZnO and CuO with phase change material in photovoltaic thermal system

Manigandan

Kumar

2019

Int J Energy Res

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Summary In this study, the simultaneous use of nanofluid and phase changing material as a coolant for photovoltaic fluid collector system and its effects are investigated experimentally. Two types of nanofluid are taken for the consideration, that is, ZnO and CuO, which are water‐based fluid. The experiments are performed in five different types of photovoltaic thermal system conventional: PT, PVT (ZnO), PVT (CuO), PCM medium (PVT/PCM/ZnO), and PCM medium (PVT/PCM/CuO). The results are obtained for surface temperature, energy, and thermal efficiency, and it is compared with each other. Further, the effect of the nanofluid as the effective alternative for pure deionized water is measured. From the results, it is evident that the PVT/PCM/CuO system minted 15% high electric output compared with convention module. Furthermore, the addition of the CuO nanofluid increases the thermal output significantly up to 8% for PVT and 12% for PCM without energy consumption. It also found that the nanofluid increases the overall energy efficiency of the system compared with convention PV.

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Section: Surface Temperaturementioning

confidence: 64%

Comparative study to use nanofluid ZnO and CuO with phase change material in photovoltaic thermal system

Manigandan

Kumar

2019

Int J Energy Res

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“…The electrical, thermal and overall efficiencies are observed to be 12.75%, 85% and 97.75%, respectively. Sardarabadi et al (2017) compare the performances of HPV/T collectors with ZnO-water nanofluid and Phase Change Material (PCM). The system as well as the several performance results are given in Fig.…”

Section: Performance Enhancement Techniques For Hpv/t Collectorsmentioning

confidence: 99%

Hybrid Photovoltaic/Thermal (HPV/T) Systems: From Theory to Applications

Cüce¹,

Oztekin²,

Cuce³

2018

Energy Research Journal

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Hybrid photovoltaic/ thermal systems are very promising clean energy harvesting devices where they can be used either standalone system or can be incorporated with other systems. In this study, historical developments leading to current Hybrid Photovoltaic/Thermal (HPV/T) systems as it is used today and global findings to enhance the performance of HPV/T system through state-of-the-art analyses are presented in a thematic way. The findings from initial studies on the HPV/T systems is revealed in an historical way and rest of sections are formed based on selected criteria. The paper covers basic and advanced type collectors, working fluids, analyzing methods to assess performance, thermodynamic approaches, optimization of design parameters and mass flow rates, techniques to enhance performance and comparative studies. Especially, various parametric studies to optimize performance of the HPV/T with respect to selected parameters including different types of absorbers, packing factor, cooling schemes, working fluid types, modifications at different sections of the system are comprehensively investigated. Based on the conclusions, the variation in electrical and thermal efficiencies are mainly in the scope of this study. It is observed from the literature that solar HPV/T system has a great potential to be one of the up and coming clean energy technology.

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“…They noted that the panel temperature was reduced by 53% while the electrical efficiency increased from 10.66% to 12.6% . Sardarabadi et al employed ZnO/water nanofluid as a cooling fluid for PVT system, and they achieved an average improvement of 5% in thermal efficiency . Su et al studied an energy analysis to maximize the power output that can be obtained from a PCM fiber .…”

Section: Introductionmentioning

confidence: 99%

Energy, exergy, and economical analyses of a photovoltaic thermal system integrated with the natural zeolites for heat management

Kandilli

2019

Int J Energy Res

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Summary In this study, the first time in the literature, natural zeolite has been employed for photovoltaic thermal (PVT) and experimentally tested as a thermal energy storage material. The main aim of the paper is to introduce natural zeolite as a heat storage material for PVT systems. The PVT systems integrated with phase change materials and natural zeolite were designed, the components of the system were explained, the thermodynamical modelling including the first and second laws was presented, the system performances were evaluated, performance parameters were investigated, energy and exergy efficiencies were determined, and economical analyses of each system were performed. Besides, all results were compared with a conventional PVT system. The average overall energy efficiency values for PVT experiments were 33% for paraffin, 37% for stearic acid, 40% for zeolite, and 32% for conventional PVT systems. The payback period of the PVT system with paraffin, zeolite, stearic acid, and conventional PVT was calculated as 10, 8, 9, and 9 years, respectively. The results show that the natural zeolite is a material with significant potential to be used for heat management in PVT for any meteorological condition.

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Experimental study of using both ZnO/ water nanofluid and phase change material (PCM) in photovoltaic thermal systems

Cited by 254 publications

References 17 publications

Comparative study to use nanofluid ZnO and CuO with phase change material in photovoltaic thermal system

Comparative study to use nanofluid ZnO and CuO with phase change material in photovoltaic thermal system

Hybrid Photovoltaic/Thermal (HPV/T) Systems: From Theory to Applications

Energy, exergy, and economical analyses of a photovoltaic thermal system integrated with the natural zeolites for heat management

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