Abstract To address the problems of insufficient adaptability of photovoltaic (PV) cleaning robots in mountainous environments, where it is challenging to balance cleaning repeatability and cleaning integrity, this paper proposes a three-legged compound mobile mechanism and conducts optimization of its key parameters. First, the topological structure of the mechanism is designed based on the locomotion mode of inchworms. Combined with the requirements of PV panel cleaning tasks and the characteristics of cleaning methods, a compound motion mode integrating linear cleaning and rotational cleaning is adopted to determine the final structural configuration of the mechanism. Second, considering the relationship between the key parameters of the mechanism and the robot’s cleaning repeatability as well as cleaning integrity, a comprehensive performance index is constructed. The genetic algorithm is introduced for parameter optimization. Simulation results show that the optimal solution occurs at the larger step length and the maximum unilateral width of the cleaning mechanism within the valid interval. Finally, a prototype was fabricated for experiments. The results demonstrate that the robot can maintain stable adsorption on inclined and undulating PV panels, and the actual cleaning path is consistent with the theoretical trajectory, verifying the effectiveness of the design and the accuracy of the theoretical analysis in this paper.
Zhang et al. (Wed,) studied this question.