FUZZY LOGIC CONTROL TO PROCESS CHANGE IRRADIATION AND TEMPERATURE IN THE SOLAR CELL BY CONTROLLING FOR MAXIMUM POWER POINT

Authors

  • Raghad Hameed Ahmed Middle Technical University, Technical Instructors Training Institute, Baghdad, Iraq Author
  • suhad hasan Rhaif Middle Technical University, Technical Instructors Training Institute, Baghdad, Iraq Author
  • Seham Ahmed Hashem Middle Technical University, Technical Instructors Training Institute, Baghdad, Iraq Author

DOI:

https://doi.org/10.31272/jeasd.27.1.3

Keywords:

Fuzzy logic, direct current to direct current (DC-DC) converter, photovoltaic systems, Matlab/Simulink, efficiency

Abstract

This paper presents intelligent control methods to get the maximum power point (MPPT) to be a photovoltaic system that operates with high efficiency when weather conditions change as well as fluctuations in temperatures resulting from sunlight. The proposed method of controlling by fuzzy control techniques is applied with a Direct current to Direct current (DC-DC) converter device. The important steps of the control unit for integrated design. The photovoltaic system, which was designed by Matlab / Simulink, was implemented with simulations of autonomous water pumping techniques. Comparison of results with simulations without MPPT control. We have noticed that the system in the case of using the MPPT that was used in the fuzzy logic unit gave high efficiency for the energy production from the solar cell the crucial control unit steps for integrated design. Simulated autonomous water pumping methods were used to implement the Matlab/Simulink-designed photovoltaic system. Results comparison with simulations lacking MPPT control. We have observed that the system provided great efficiency for the energy generation from the solar cell in the event of using the MPPT that was used in the fuzzy logic unit.

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Key Dates

Published

2023-01-01

How to Cite

FUZZY LOGIC CONTROL TO PROCESS CHANGE IRRADIATION AND TEMPERATURE IN THE SOLAR CELL BY CONTROLLING FOR MAXIMUM POWER POINT . (2023). Journal of Engineering and Sustainable Development, 27(1), 28-36. https://doi.org/10.31272/jeasd.27.1.3

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