Jimeng Shi scite author profile

In order to improve performance of photovoltaic/thermal (or PV/T for simplicity) collectors, this paper firstly validated a previous computational thermal model and then introduced an improved computational thermal model to investigate the effects of the major control parameters on the thermal performance of PV/T collectors, including solar cell temperature, back surface temperature, and outlet water temperature. Besides, a computational electrical model of PV/T system was also introduced to elaborate the relationship of voltage, current and power of a PV module (MSX60 poly-crystalline solar cell) used in an experiment in the literature. Simulation results agree with the experimental data very well. The effects of the time-steps from 1 hour to minute, which is closed to the real time, were also reported. At last, several suggestions to improve the efficiency of PV/T system were illustrated.

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Physic-Informed Neural Network Approach Coupled with Boundary Conditions for Solving 1D Steady Shallow Water Equations for Riverine System

Yin

Bian

et al. 2023

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Computational Simulation and Analysis of Major Control Parameters of Time-Dependent Photovoltaic/Thermal Collectors

Shi

Lin

2021

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In order to improve the transient performance of photovoltaic/thermal (or PV/T for simplicity) collectors, this paper firstly developed and validated a computational thermal model to investigate the effects of the major control parameters on the thermal performance of PV/T collectors, including inlet water temperature and inlet water flow rate. Secondly, a computational electrical model of PV/T system, coupled with the thermal model, was also introduced to elaborate the relationship of voltage, current and power of a PV module (MSX60 poly-crystalline solar cell) used in an experiment in the literature. The thermal and electrical models were solved simultaneously to predict the transient energy conversion efficiencies of the PV/T system. Simulation results were found to agree with the experimental data very well. The effects of the time-steps from 1 hour to 1 minute, which is closed to the real time, were also reported at various conditions. It was found that both thermal and electrical efficiencies are fluctuating with time. There is an optimal water flow rate at which the efficiencies are at the maximum. At last, several suggestions to improve the efficiency of PV/T system were discussed.

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Computational Simulation and Analysis of Major Control Parameters of Time-Dependent PV/T Collectors

Shi

Lin

2021

Preprint

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Jimeng Shi

Time Series Forecasting (TSF) Using Various Deep Learning Models

Computational Simulation and Analysis of Major Control Parameters of Time-Dependent PV/T Collectors

Physic-Informed Neural Network Approach Coupled with Boundary Conditions for Solving 1D Steady Shallow Water Equations for Riverine System

Computational Simulation and Analysis of Major Control Parameters of Time-Dependent Photovoltaic/Thermal Collectors

Computational Simulation and Analysis of Major Control Parameters of Time-Dependent PV/T Collectors

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