Diseño, construcción y evaluación de un sistema de refrigeración para el panel fotovoltaico sp150p

With the need to reduce dependence on fossil fuels, photovoltaic solar panel technology has been widely developed, with affordable prices on the market. Colombia has great solar potential to generate electrical energy through solar panels. Inherent in its operation is the drawback of raising its tem...

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Autores:
Gallo Miranda, Guillermo
Salamanca Cárdenas, Jefferson
Batista Rodríguez, Carlos
Hernández Moreno, Saúl
Tipo de recurso:
Fecha de publicación:
2020
Institución:
Universidad Santo Tomás
Repositorio:
Universidad Santo Tomás
Idioma:
spa
OAI Identifier:
oai:repository.usta.edu.co:11634/32687
Acceso en línea:
http://revistas.ustatunja.edu.co/index.php/ingeniomagno/article/view/2055
http://hdl.handle.net/11634/32687
Palabra clave:
Photovoltaic panel
cooling system
heat transfer
solar radiation
Panel fotovoltaico
sistema refrigeración
transferencia calor
radiación solar
Painel fotovoltaico
sistema de refrigeração
transferência de calor
radiação solar
Rights
License
Derechos de autor 2020 Ingenio Magno
Description
Summary:With the need to reduce dependence on fossil fuels, photovoltaic solar panel technology has been widely developed, with affordable prices on the market. Colombia has great solar potential to generate electrical energy through solar panels. Inherent in its operation is the drawback of raising its temperature, which affects its functionality. The objective of this work was: to evaluate a refrigeration system for a photovoltaic panel SP150P, installed on the roof of the Antonio Nariño University, in Tunja at the latitude of 5,553 degrees N and longitude W of 77,367 degrees. A statistical analysis of the temperatures initially recorded and stored was performed with the use of thermocouples placed at different points on the panel. The previous results allowed the sizing of the refrigeration system. Other variables, such as height, wind speed and geographic location of the panel, were also taken into account in the design. The flow regime was calculated using the Reynolds number and the heat transfer processes by conduction, convention and radiation from the panel to the heat exchanger, which allowed determining the necessary parameters of the solenoid valve that would control the flow by gravity from a tank placed at a height above the panel. These results demonstrate the feasibility of reducing the temperature of the solar panels and improving their efficiency, making it feasible to implement them at industrial levels or in other potential applications.

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