Abstract
The module temperature is the most important parameter influencing the output power of solar photovoltaic (PV) systems, aside from solar irradiance. In this paper, we focus on the interdisciplinary research that combines the correlation analysis, mutual information (MI) and heat transfer theory, which aims to figure out the correlative relations between different meteorological impact factors (MIFs) and PV module temperature from both quality and quantitative aspects. The identification and confirmation of primary MIFs of PV module temperature are investigated as the first step of this research from the perspective of physical meaning and mathematical analysis about electrical performance and thermal characteristic of PV modules based on PV effect and heat transfer theory. Furthermore, the quantitative description of the MIFs influence on PV module temperature is mathematically formulated as several indexes using correlation-based feature selection (CFS) and MI theory to explore the specific impact degrees under four different typical weather statuses named general weather classes (GWCs). Case studies for the proposed methods were conducted using actual measurement data of a 500 kW grid-connected solar PV plant in China. The results not only verified the knowledge about the main MIFs of PV module temperatures, more importantly, but also provide the specific ratio of quantitative impact degrees of these three MIFs respectively through CFS and MI based measures under four different GWCs.
Highlights
Given the increasingly serious problems of fossil energy shortage and greenhouse gas emissions, the need for sustainable and low-carbon energy technologies is on the rise [1]
Plants, the changes of PV module temperature mainly rely on three meteorological impact factors (MIFs): ambient temperature, solar irradiance and wind speed
Quantitative methods based on correlation-based feature selection (CFS) and mutual information (MI) theory to describe the degree of influence of MIFs on PV module temperature are proposed after the interdisciplinary theory analysis using correlation analysis, PV material and heat transfer theory
Summary
Given the increasingly serious problems of fossil energy shortage and greenhouse gas emissions, the need for sustainable and low-carbon energy technologies is on the rise [1]. Roof-top PV, building integrated photovoltaic (BIPV) and other small-scale PV systems can be equivalent to negative electricity demand during the daytime with solar irradiance, which significantly reshape the traditional load curves by providing electricity directly to the load behind the meter This effect will result in difficulties in load forecasting under different weather conditions, on which the dispatch operation depends [9]. To analyze meteorological impact factors (MIFs) and material or system-dependent properties for PV module temperature, reference [22] summarized a number of formulas of physical expression of Tm. Considering exchange of PV module temperature, apart from the heat transfer and energy balance, power conversion efficiency of PV module affecting by PV effect must take into account.
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