Experiencia en el uso de la Lógica Difusa para el Control del Seguimiento del Punto de Máxima Potencia en Convertidores para Módulos Fotovoltaicos

Farfán, Roberto F.; Cadena, Carlos A.; Villa, Luis T.

doi:10.1016/j.riai.2015.03.004

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Resumen

En el siguiente trabajo se presenta un sistema experto de control difuso (FLC), desarrollado para la búsqueda del punto de máxima potencia en módulos fotovoltaicos. Los FLC se utilizan ampliamente en diferentes sistemas de control, debido a que un diseño adecuado permite combinar velocidad y precisión en el control. En el trabajo se realiza un análisis a través del cual se definen las variables de entrada y el conjunto de reglas que utilizará el FLC. Tal análisis consiste en validar un modelo de módulo fotovoltaico-convertidor DC- DC y plantear simulaciones, en donde se observe la variación de potencia fotovoltaica a medida que el convertidor cambia el punto de trabajo. La respuesta del FLC desarrollado se observa en simulaciones en donde se modela los módulos fotovoltaicos y el transitorio que impone el convertidor DC-DC. Estas últimas ponen de manifiesto que el control propuesto es adecuado y superior al que ofrecen un sistema convencional de búsqueda. En el trabajo se presentan medidas que indican que la respuesta del FLC desarrollado es adecuada bajo diferentes condiciones de irradiancia y temperatura, verificando su correcto funcionamiento. La implementación física final del FLC propuesto, se realiza por medio de un microcontrolador PIC de 32 bits.

Palabras clave:

Lógica Difusa

FLC

Boost

Fotovoltaico.

Abstract

In this paper a fuzzy control expert system (FLC) is presented. Such system is developed for finding the maximum power point in photovoltaic modules. FLCs are widely used in various control systems, due to a suitable design which combines speed and accuracy in control. In the paper the input variables as well as the set of rules to be used in the control are defined. In such sense a photovoltaic module model - dcdc converter was validated in order to perform different simulations, to observe photovoltaic power variations in different operating points. The simulations show that the proposed control is suitable and better than a conventional system. Experimental measures indicate that the response of FLC developed under different conditions for irradiance and temperature are correct. The final physical implementation of FLC proposed is performed through a 32-bit PIC microcontroller.

Keywords:

Fuzzy Logic

FLC

Boost

Photovoltaic.

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Referencias no citadas

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