Abstract
Load capacity is an important index to reflect the practicability of legged robots. Existing research into quadruped robots has not analyzed their load performance in terms of their structural design and control method from a systematic point of view. This paper proposes a structural design method and crawling pattern generator for a planar quadruped robot that can realize high-payload locomotion. First, the functions required to evaluate the leg’s load capacity are established, and quantitative comparative analyses of the candidates are performed to select the leg structure with the best load capacity. We also propose a highly integrated design method for a driver module to improve the robot’s load capacity. Second, in order to realize stable load locomotion, a novel crawling pattern generator based on trunk swaying is proposed which can realize lateral center of mass (CoM) movement by adjusting the leg lengths on both sides to change the CoM projection in the trunk width direction. Finally, loaded crawling simulations and experiments performed with our self-developed quadruped robot show that stable crawling with load ratios exceeding 66% can be realized, thus verifying the effectiveness and superiority of the proposed method.
Highlights
The design of bionic robots has benefited from the introduction of robust and energy-saving movements based on those of animals
Lateral center of mass (CoM) movement is realized by adjusting the leg lengths on both sides, which can change the CoM projection to track the zero moment point (ZMP) in the trunk width direction; a feedforward and feedback control method based on trunk position compliance (TPC) is proposed to provide further stability improvements
It can be concluded that the crawling pattern generator with trunk swaying and feedforward and feedback compensation control (FFC) proposed in this paper shows an obvious improvement in stability during crawling motion at different speeds, and the experiments performed with different loads show that the planar quadruped robot with traditional parallel (TP) legs can crawl stably under a load of at least 20 kg
Summary
The design of bionic robots has benefited from the introduction of robust and energy-saving movements based on those of animals. To overcome the deficiencies described above, a structural design method and crawling pattern generator for a planar quadruped robot with a high payload is proposed in this paper This robot is composed of four parallel legs, which have the advantages of a superior load capacity and good structural stability. To realize stable high-payload locomotion for a quadruped robot with the fewest DoFs, a novel crawling pattern generation method based on trunk swaying is proposed Using this method, lateral CoM movement is realized by adjusting the leg lengths on both sides, which can change the CoM projection to track the ZMP in the trunk width direction; a feedforward and feedback control method based on trunk position compliance (TPC) is proposed to provide further stability improvements.
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