Performance Analysis of a Novel Photovoltaic Thermal PVT Double Pass Solar Air Heater with Cylindrical PCM Capsules using CFD

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Abstract

Photovoltaic thermal double pass solar air heater (PVT-DPSAH) with PCM capsules in the bottom channel is a promising design for enhancing the system performance. The PVT-DPSAH comprises a glass cover, absorber plate (PV), PCM capsules, and back plate. The current study uses COMSOL Multiphysics software to perform a computational fluid dynamics (CFD) analysis of a novel PVT-DPSAH with vertical cylindrical PCM capsules in the second channel. To solve the differential equations in the 3D computational domain, the finite element method (FEM) is employed. This study uses the high Reynolds (Re) number and ?-? turbulent flow model with enhanced wall functions. The impact of varying solar irradiance levels (500- 800 W/m2) on the performance of PVT-DPSAH, with mass flow rates ranging from 0.011 kg/s to 0.065 kg/s, is investigated. The optimum mass flow rate (?) was found to be 0.037 kg/s at solar irradiances ranging from 500 W/m2 to 800 W/m2, with average thermal efficiencies, electrical efficiencies, and fluid output temperatures of 60.7% to 63.4%, 11.25% to 11.02% and 42.96 oC to 49.54 oC, respectively. PVT collector's maximum combined efficiency was 84.12% at solar irradiance of 800 W/m2 with the ? of 0.065 kg/s. This study identified RT-47 paraffin-wax-PCM as the best option for the PVT-DPSAH based on the PCM's thermal distribution and melting temperature.
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基于CFD的新型圆柱形PCM胶囊光伏热PVT双通道太阳能空气加热器性能分析
光电双通式太阳能空气加热器(ppt - dpah)是一种很有前途的提高系统性能的设计方案。pvt - dpah包括玻璃罩、吸收板(PV)、PCM胶囊和背板。目前的研究使用COMSOL Multiphysics软件对一种新型ppt - dpah进行了计算流体动力学(CFD)分析,该ppt - dpah在第二通道中安装了垂直圆柱形PCM胶囊。为了在三维计算域中求解微分方程,采用了有限元法。本研究采用高雷诺数和?-?具有增强壁面功能的湍流模型。在质量流量为0.011 kg/s ~ 0.065 kg/s的情况下,研究了不同太阳辐照强度(500 ~ 800 W/m2)对ppt - dpah性能的影响。在500 W/m2 ~ 800 W/m2的太阳辐照度范围内,最佳质量流量为0.037 kg/s,平均热效率、电效率和流体输出温度分别为60.7% ~ 63.4%、11.25% ~ 11.02%和42.96 oC ~ 49.54 oC。当太阳辐照度为800 W/m2时,PVT集热器的最大组合效率为84.12%。0.065 kg/s。根据PCM的热分布和熔融温度,本研究确定RT-47石蜡-PCM是pvt - dpah的最佳选择。
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来源期刊
International Journal of Renewable Energy Research
International Journal of Renewable Energy Research Energy-Energy Engineering and Power Technology
CiteScore
2.80
自引率
10.00%
发文量
58
期刊介绍: The International Journal of Renewable Energy Research (IJRER) is not a for profit organisation. IJRER is a quarterly published, open source journal and operates an online submission with the peer review system allowing authors to submit articles online and track their progress via its web interface. IJRER seeks to promote and disseminate knowledge of the various topics and technologies of renewable (green) energy resources. The journal aims to present to the international community important results of work in the fields of renewable energy research, development, application or design. The journal also aims to help researchers, scientists, manufacturers, institutions, world agencies, societies, etc. to keep up with new developments in theory and applications and to provide alternative energy solutions to current issues such as the greenhouse effect, sustainable and clean energy issues.
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