Experimental Air Impingement Crossflow Comparison and Theoretical Application to Photovoltaic Efficiency Improvement

Pablo Martínez-Filgueira,Unai Fernandez-Gamiz,Ekaitz Zulueta,Gustavo García,Josu Soriano,Ander Sánchez-Chica

doi:10.3390/su12145577

Pablo Martínez-Filgueira, Unai Fernandez-Gamiz + Show 4 more

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https://doi.org/10.3390/su12145577

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Journal: Sustainability	Publication Date: Jul 10, 2020
Citations: 4	License type: CC BY 4.0

Affiliation: University of the Basque Country

Abstract

The photovoltaic cell temperature is a key factor in solar energy harvesting. Solar radiation raises temperature on the cell, lowering its peak efficiency. Air jet impingement is a high heat transfer rate system and has been previously used to cool the back surface of photovoltaic modules and cells. In this work, an experimental comparison of the cooling performance of two different air jet impingement crossflow schemes was performed. Crossflow is defined as the air mass interacting with a certain jet modifying its movement. This leads to a change in its heat exchange capabilities and is related with the inlet-outlet arrangement of the fluid. In this work, zero and minimum crossflow schemes were compared. The main contribution of this work considered the consumption of the flow supplying devices to determine the most suitable system. The best configuration increased the net power output of the cell by 6.60%. These results show that air impingement cooling can play a role in increasing photovoltaic profitability. In terms of uniformity, on small impingement plates with a low number of nozzles, the advantages expected from the zero crossflow configuration did not stand out.

Highlights

Solar photovoltaic PV energy is a renewable energy source with great projection [1] and a wide adoption of this technology could lead to an abundant and inexpensive power source
The efficiency of a photovoltaic system is defined as the fraction of usable electrical energy that has been converted from the incident energy
The thermal distribution of each panel is analyzed by thermography and the results show that the output power increases as the temperature decreases

Summary

Introduction

Solar photovoltaic PV energy is a renewable energy source with great projection [1] and a wide adoption of this technology could lead to an abundant and inexpensive power source. Efficiency is influenced by several factors, such as cell material [4], manufacturing process [5], or environmental conditions [6] This last factor is of great importance, since the irradiance, environmental temperature, weather conditions, or presence of dust or dirt can influence the temperature of the cell, leading to variations in its efficiency. This led to researchers like Ali et al [7] to develop models that determine the parameters that define a PV cell efficiency in real time

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