Design and Implementation of Extremum-Seeking Control Based on MPPT for Dual-Axis Solar Tracker

Author:

Solís-Cervantes Cesar Ulises1ORCID,Palomino-Resendiz Sergio Isai2ORCID,Flores-Hernández Diego Alonso3ORCID,Peñaloza-López Marco Antonio3ORCID,Montelongo-Vazquez Carlos Manuel2ORCID

Affiliation:

1. Automatic Control Department, CINVESTAV-IPN, Av. Instituto Politecnico Nacional 2508, Col. San Pedro Zacatenco, Mexico City C.P. 07360, Mexico

2. Automation and Control Engineering Department, ESIME-IPN, Unidad Profesional Adolfo López Mateos, Zacatenco, Av. Luis Enrique Erro s/n, Mexico City C.P. 07738, Mexico

3. Instituto Politécnico Nacional UPIITA, Mexico City C.P. 07340, Mexico

Abstract

The increase in the production efficiency of photovoltaic technology depends on its alignment in relation to the solar position. Solar tracking systems perform the tracking action by implementing control algorithms that help the reduction of tracking errors. However, conventional algorithms can reduce the life of actuators and mechanisms due to control action, significantly reducing operation times and profitability. In this article, an unconventional control scheme is developed to address the mentioned challenges, presenting the design and implementation of an extremum-seeking control to perform maximum power point tracking for a two-axis solar tracker instrumented with a solar module. The proposed controller is governed by the dynamics of a classic proportional-integral scheme and assisted by sensorless feedback. Also, it has an anti-wind-up-type configuration for the integral component and counts with a variable amplitude for the dither signal. The proposal is validated experimentally by comparison between a fixed system and a two-axis system in azimuth-elevation configuration. In addition, two performance indices are defined and analyzed, system energy production and tracking error. The results show that the proposal allows producing up to 27.75% more than a fixed system, considering the tracker energy consumption due to the tracking action and a pointing accuracy with ±1.8° deviation. Finally, an analysis and discussion are provided based on the results, concluding that the proposed algorithm is a viable alternative to increase the performance of tracked photovoltaic systems.

Funder

CONAHCYT

SIP-IPN

Publisher

MDPI AG

Reference64 articles.

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3. Iqbal, M. (2012). An Introduction to Solar Radiation, Elsevier.

4. Abou Jieb, Y., Hossain, E., and Hossain, E. (2022). Photovoltaic Systems: Fundamentals and Applications, Springer.

5. Prinsloo, G., and Dobson, R. (2015). Sun Tracking and Solar Renewable Energy Harvesting: Solar Energy Harvesting, Trough, Pinpointing and Heliostat Solar Collecting Systems, Solar Books.

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