Resumen

En el presente trabajo se hace uso de los arreglos ortogonales propuestos por Taguchi para maximizar el rendimiento térmico de un colector solar de aire de placa plana. En el proceso de optimización son considerados cinco factores controlables, los cuales son: longitud del colector, material de la placa absorbedora, material de la cubierta, altura del canal de flujo de aire, ancho del colector; y tres factores no controlables, los cuales son: velocidad del aire, irradiación solar y temperatura ambiente. Para llevar a cabo los diferentes experimentos establecidos por el arreglo ortogonal, se desarrolló una metodología de diseño térmico para colectores solares de aire de placa plana. La metodología se aplica al diseño térmico de un colector solar de aire evaluado de forma experimental. Los resultados muestran que el material de la placa absorbedora, el material de la cubierta y la altura del canal de flujo de aire son estadísticamente significativos para determinar el rendimiento térmico del colector, mientras que la longitud y ancho del colector no son significativos estadísticamente. Se obtiene un aumento del 7.5% en el rendimiento térmico del colector entre el diseño óptimo y el diseño del colector evaluado de forma experimental.

Palabras Clave: ANOVA, arreglos ortogonales de Taguchi, colector solar de aire de placa plana, optimización.

Abstract

This work makes use of orthogonal arrays proposed by Taguchi to maximize the thermal performance of a flat plate air solar collector. On the process optimization are taken into account five control factors, which are: collector length, material type of the absorber plate, material type of the cover, height of the air flow channel and width of the collector; and three non-controllable factors, which are: wind velocity, solar irradiation and room temperature. In order to carry out the different experiments established by the orthogonal arrangement, a thermal design methodology was developed for flat plate air solar collectors. The methodology is applied to the thermal design of an experimentally evaluated solar collector. The results show that the material type of the absorber plate, the material type of the cover and the height of the air flow channel are statistically significant to calculate the thermal efficiency of the collector, while the length and width of the collector are not statistically significant. An increase of 7.5% in the thermal performance of the collector is obtained between the optimal design and the design of the collector evaluated experimentally.

Keywords: ANOVA, Taguchi´s orthogonal arrays, flat plate air solar collector, optimization.

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