A new physics-based solar reconfigured model to enhance efficiency under partial shading conditions: Experimental feasibility

Abstract

ABSTRACT Maximum power generation from solar modules is adversely affected by partial shading conditions. To strengthen and obtain feasible output under any complex shadings, a new double diode model with deterioration factor (DDM-DF) is proposed for the optimal selection of shading patterns. It is used to validate the effectiveness of the novel heuristic approach called time-distance-constrained topology (D-CT). The novel D-CT is compared with conventional techniques (bridge link (BL), series-parallel (S-P), total cross-tied (TCT)), conventional puzzles (sudoku (SDK), magic-square (M-SP)), and recently reconfigured techniques (permutation-combination (PCR), knight-tour (KTR)). In this paper, the experimental study validates the outcomes obtained by MATLAB/SIMULINK results under various realistic shadings. Experimental results prove that the novel proposed D-CT enhances the efficiency by 5.45%, 3.57%, and 3.54% over TCT, PCR, and KTR under inverted-L shading. Further, the minimum and maximum mismatch loss reduced by the proposed D-CT is up to 1.90% and 97.61% under top shading against SDK and S-P respectively. The real-time validation for the proposed novel 4×4 D-CT under pi and diagonal shading exhibits greater performance parameter enhancement of a solar array subjected to shadings in correlation with other models.