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Comprehensive numerical modeling of intermittent flow cooling with enhanced photovoltaic efficiency in PVT/NPCM systems

Hui Chen, Jianfeng Zhang, Ming Shen, Hui Fang, Yiren Ma

2024Case Studies in Thermal Engineering24 citationsDOIOpen Access PDF

Abstract

The photoelectric conversion efficiency of photovoltaic thermal (PVT) systems is a key concern in solar energy research. The widespread use of continuous nanofluid cooling in PVT/NPCM (Nano-Enhanced Phase Change Material) systems leads to heightened energy consumption. In order to improve efficiency of the PVT/NPCM systems, a two-dimensional transient heat transfer numerical model is established to analyze the PVT/NPCM system with intermittent flow cooling. Corresponding govern equations with boundary conditions are proposed, and numerically solved by using the finite element method. Simulation results are compared with experimental data, showing a deviation of less than 7%. The findings indicate that the intermittent cooling reduces the flow energy consumption required to drive 2220 liters of nanofluid compared to continuous cooling over a 7-hour period. Furthermore, under intermittent cooling conditions, the average electrical efficiency stands at approximately 19.7%. Notably, the electrical efficiency of PVT/NPCM systems employing intermittent flow cooling closely aligns with those employing continuous flow cooling, exhibiting a maximum deviation of merely 0.0348%. Additionally, intermittent flow cooling emerges as a favorable choice under solar radiation intensities surpasses 1000W/m2, enabling a significant reduction in overall energy consumption while maintaining commendable cooling performance.

Topics & Concepts

Photovoltaic systemMaterials scienceWater coolingMechanicsThermodynamicsNuclear engineeringHeat transferPhase-change materialNanofluidEnvironmental scienceThermalPhysicsElectrical engineeringEngineeringSolar Thermal and Photovoltaic SystemsPhase Change Materials ResearchHeat Transfer Mechanisms