An innovative Fast-Converging speed MPPT approach without oscillation for temperature varying in photovoltaic systems applications
Abdеlkhalеk Chеllakhi, Said Еl Bеid, Younes Abouelmahjoub
Abstract
This paper offers an innovative maximum power point tracking (MPPT) approach for photovoltaic system under temperature varying. Basically, the innovative approach is introduced to improve tracking performance under difficult scenarios of temperature change. By far, it can be used to avoid the main shortcomings of the conventional MPPT strategies, e.g., ripple around the MPP at steady-state regime, sluggishness velocity converging, and loss of tracking direction under fast change of temperature. Also, it can be used to improve the tracking performance under low irradiance level and rapid load change. With respect to its direct control strategy based on the photovoltaic current control, it provides a quick tracking of the real MPP without steady-state fluctuations. To show the advantages and accuracy of the innovative MPPT approach, a comparison with other traditional strategies, e.g., P&O and INC techniques is investigated using simulation in MATLAB/Simulink® software under different scenarios of temperature, load, and insolation levels. In the light of the results collected, the innovative MPPT approach minimized the convergence time by five times, reduced the steady-state fluctuations to zero and improved the average tracking efficiency by 8.51% and 9.04% compared to the P&O and INC MPPT schemes, respectively.