Abstract

In this work, a multi-objective optimization framework is developed for optimizing low Reynolds number () hovering flight. This framework is then applied to compare the efficiency of rigid revolving and flapping wings with rectangular shape under varying and Rossby number (, or aspect ratio). The proposed framework is capable of generating sets of optimal solutions and Pareto fronts for maximizing the lift coefficient and minimizing the power coefficient in dimensionless space, explicitly revealing the trade-off between lift generation and power consumption. The results indicate that revolving wings are more efficient when the required average lift coefficient is low (<1 for and <1.6 for ), while flapping wings are more efficient in achieving higher . With the dimensionless power loading as the single-objective performance measure to be maximized, rotary flight is more efficient than flapping wings for regardless of the amount of energy storage assumed in the flapping wing actuation mechanism, while flapping flight is more efficient for . It is observed that wings with low perform better when higher is needed, whereas higher cases are more efficient at regions. However, for the selected geometry and , the efficiency is weakly dependent on when the dimensionless power loading is maximized.

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