Numerical investigation of the effects of the nano-enhanced phase change materials on the thermal and electrical performance of hybrid PV/thermal systems

•Developed and validated two dimensional numerical model using Finite Difference Method.•Effect of the nanoPCM thickness, atm temp, solar conc and flow rate on PV/T performance.•Performance enhanced using PCM and is dependent on the nanoparticles loading.•NanoPCM is effective at high ambient tempera...

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Veröffentlicht in:	Energy conversion and management 2020-02, Vol.205, p.112449, Article 112449
Hauptverfasser:	Abdelrazik, A.S., Al-Sulaiman, F.A., Saidur, R.
Format:	Artikel
Sprache:	eng
Schlagworte:	Computer simulation Cooling Cooling effects Efficiency Graphene Hybrid systems Mathematical models Nano-enhanced PCM Nanoparticles Paraffin Paraffin wax Phase change materials Photovoltaic cells PV/PCM PW-based nanoPCM Solar energy Temperature distribution Thermal regulation Thermodynamic efficiency Thermodynamic properties Weather
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creator	Abdelrazik, A.S. Al-Sulaiman, F.A. Saidur, R.
description	•Developed and validated two dimensional numerical model using Finite Difference Method.•Effect of the nanoPCM thickness, atm temp, solar conc and flow rate on PV/T performance.•Performance enhanced using PCM and is dependent on the nanoparticles loading.•NanoPCM is effective at high ambient temperature, solar conc. and layer thickness.•In mid-July, PV/T/nanoPCM (10 wt%) has higher electrical efficiency than PV by 22% Hybrid PV/phase change material (PV/PCM) module and PV/thermal (PV/T) system are reported as showing low heat rejection and non-uniform PV temperature distribution respectively. Combining both systems and inclusion of nanoparticles in the PCM at different loadings, which enhances the thermal behavior of PCMs, is employed in this study, as a potential solution. Using numerically-validated model, the influence of a layer of nano-enhanced phase change material (nanoPCM), located below the PV panel, on the thermal and electrical performance of a hybrid PV/thermal is evaluated. The effect of different weather and operating conditions is also evaluated. The numerical simulation results illustrate that the hybrid PV/thermal system with PCM (PV/T/PCM) has a better performance as compared to the standalone PV system. Inclusion of different loadings from the Graphene nanoplatelets (GNP) in the Paraffin wax (PW) PCM enhances the cooling of the PV panel and shows higher electrical efficiency. As nanoparticles loading-percentage is increased, PV panel temperature is lowered and the electrical efficiency is increased. The effect of the nanoparticles on the heat absorption by the cooling fluid and the thermal efficiency variation depends on the weather conditions. However, in most cases, low loadings of nanoparticles leads to higher thermal gains. For two days in mid-January (winter) and mid-July (summer) in Dhahran (Saudi Arabia), the hybrid PV/T/nanoPCM system with 10% of nanoparticles shows higher electrical efficiency (6.9 and 22%, respectively) compared to the standalone PV system.
doi_str_mv	10.1016/j.enconman.2019.112449
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Combining both systems and inclusion of nanoparticles in the PCM at different loadings, which enhances the thermal behavior of PCMs, is employed in this study, as a potential solution. Using numerically-validated model, the influence of a layer of nano-enhanced phase change material (nanoPCM), located below the PV panel, on the thermal and electrical performance of a hybrid PV/thermal is evaluated. The effect of different weather and operating conditions is also evaluated. The numerical simulation results illustrate that the hybrid PV/thermal system with PCM (PV/T/PCM) has a better performance as compared to the standalone PV system. Inclusion of different loadings from the Graphene nanoplatelets (GNP) in the Paraffin wax (PW) PCM enhances the cooling of the PV panel and shows higher electrical efficiency. As nanoparticles loading-percentage is increased, PV panel temperature is lowered and the electrical efficiency is increased. The effect of the nanoparticles on the heat absorption by the cooling fluid and the thermal efficiency variation depends on the weather conditions. However, in most cases, low loadings of nanoparticles leads to higher thermal gains. For two days in mid-January (winter) and mid-July (summer) in Dhahran (Saudi Arabia), the hybrid PV/T/nanoPCM system with 10% of nanoparticles shows higher electrical efficiency (6.9 and 22%, respectively) compared to the standalone PV system.</description><identifier>ISSN: 0196-8904</identifier><identifier>EISSN: 1879-2227</identifier><identifier>DOI: 10.1016/j.enconman.2019.112449</identifier><language>eng</language><publisher>Oxford: Elsevier Ltd</publisher><subject>Computer simulation ; Cooling ; Cooling effects ; Efficiency ; Graphene ; Hybrid systems ; Mathematical models ; Nano-enhanced PCM ; Nanoparticles ; Paraffin ; Paraffin wax ; Phase change materials ; Photovoltaic cells ; PV/PCM ; PW-based nanoPCM ; Solar energy ; Temperature distribution ; Thermal regulation ; Thermodynamic efficiency ; Thermodynamic properties ; Weather</subject><ispartof>Energy conversion and management, 2020-02, Vol.205, p.112449, Article 112449</ispartof><rights>2019 Elsevier Ltd</rights><rights>Copyright Elsevier Science Ltd. 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Combining both systems and inclusion of nanoparticles in the PCM at different loadings, which enhances the thermal behavior of PCMs, is employed in this study, as a potential solution. Using numerically-validated model, the influence of a layer of nano-enhanced phase change material (nanoPCM), located below the PV panel, on the thermal and electrical performance of a hybrid PV/thermal is evaluated. The effect of different weather and operating conditions is also evaluated. The numerical simulation results illustrate that the hybrid PV/thermal system with PCM (PV/T/PCM) has a better performance as compared to the standalone PV system. Inclusion of different loadings from the Graphene nanoplatelets (GNP) in the Paraffin wax (PW) PCM enhances the cooling of the PV panel and shows higher electrical efficiency. As nanoparticles loading-percentage is increased, PV panel temperature is lowered and the electrical efficiency is increased. The effect of the nanoparticles on the heat absorption by the cooling fluid and the thermal efficiency variation depends on the weather conditions. However, in most cases, low loadings of nanoparticles leads to higher thermal gains. 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subjects	Computer simulation Cooling Cooling effects Efficiency Graphene Hybrid systems Mathematical models Nano-enhanced PCM Nanoparticles Paraffin Paraffin wax Phase change materials Photovoltaic cells PV/PCM PW-based nanoPCM Solar energy Temperature distribution Thermal regulation Thermodynamic efficiency Thermodynamic properties Weather
title	Numerical investigation of the effects of the nano-enhanced phase change materials on the thermal and electrical performance of hybrid PV/thermal systems
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