Comparative study of the efficiency of rectangular and triangular flat plate solar collectors through finite element method

Main Article Content

Isaac Simbaña
https://orcid.org/0000-0002-3324-3071
William Quitiaquez
Patricio Cabezas
Patricio Quitiaquez

Abstract

This investigation compared the efficiency of a flat-plate solar collector with triangular and square geometry, by using the finite element method (FEM). The design of the geometries and the utilized parameters for the simulation were obtained from previous publications. SolidWorks was used to model the two collectors, meanwhile, the Fluent module of the ANSYS software was used for the simulation by the FEM. Collectors integrated a pipe of 7 mm internal diameter with a plate thickness of 11 mm; the defined material was aluminum. An ambient temperature of 20 °C was considered, with solar radiation of 1000 W·m-2 and heat transfer surfaces of 61 250 and 122 500 mm2 for the triangular and square collectors, respectively. The quality of the mesh was excellent, obtaining a skewness of 0.2486, with which efficiencies of 62 and 39 % and maximum temperatures of 27 and 25.5 °C were obtained for the triangular and square collectors, respectively. Due to the geometries performing as fins, the temperatures are higher in the corners and, therefore, achieving higher efficiency is impossible.

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How to Cite
Simbaña, I., Quitiaquez, W., Cabezas, P., & Quitiaquez, P. (2024). Comparative study of the efficiency of rectangular and triangular flat plate solar collectors through finite element method. Revista Técnica "energía", 20(2), PP. 81–89. https://doi.org/10.37116/revistaenergia.v20.n2.2024.593
Section
EFICIENCIA ENERGÉTICA

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