Analysis and Optimization of Motion Coupling for the Coordinated Operation of Flexible Multi-Arm Space Robots

Pan, Guangtang; Jia, Qingxuan; Chen, Gang; Wang, Yifan; Sun, Fei

doi:10.3390/act12050198

Actuators

2023

DOI: 10.3390/act12050198

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Analysis and Optimization of Motion Coupling for the Coordinated Operation of Flexible Multi-Arm Space Robots

Guangtang Pan

Qingxuan Jia

Gang Chen

et al.

Abstract: This paper presents a novel approach for analyzing and optimizing motion coupling in the coordinated operation tasks of flexible space multi-arm robots (FMSRs). The method integrates motion coupling between multiple arms and system stiffness to improve the motion and force accuracy of FMSRs by optimizing the configuration. First, a comprehensive model of an FMSR is established using the hypothetical modal method. Then, the motion coupling relationship among multiple arms is analyzed, and a motion coupling degr… Show more

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Design and Experimental Evaluation of a Minimal-Damage Cotton Topping Device

Xu,

Han,

Qiu

et al. 2024

Agriculture

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Cotton topping is a crucial aspect of cotton production, inhibiting apical dominance in cotton plants. Existing cotton topping machinery often results in over-topping. To address this challenge, the characteristics of manual topping operations were emulated by incorporating bionic principles to analyze the motions involved. Studying the artificial topping action and the trajectory of hand movements led to the design of a bionic topping manipulator and a trajectory-generating mechanism, serving as the core component of the cotton topping device. A flat-bottomed follower disc cam mechanism was used to facilitate the automatic opening and closing of the manipulator. The cam’s working area was divided, its contour curve selected, and the manipulator’s pulling spring’s action point and length determined. Subsequently, parametric equations for the motion trajectory of the bionic topping manipulator were established. Building on the topping mechanism’s working principle, a mechanical model was developed to analyze the swing of cotton plants. The model demonstrates that the displacement at the free end of the stalk was primarily influenced by its length. A lifter was then designed to reduce plant swing amplitude and orderly distribute its top position. The designed prototype of a single-row cotton bionic topping device was tested and verified through orthogonal tests, using operating speed, rotational speed, and topping depth as test factors. The topping rate and over-topping rate served as the indices for testing. The results indicated an average topping rate of 78.67% and an over-topping rate of 8%. This was achieved at a 0.3 m/s operating speed, a 40 r/min rotational speed, and a 110 mm topping depth. Cotton topping devices demonstrated greater effectiveness in minimizing damage to cotton plants, and future research should focus on enhancing topping rates even further. This study provides a theoretical foundation and test data to support the design of cotton topping machinery, guiding future mechanical improvements and agricultural practices.

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Design and Experimental Evaluation of a Minimal-Damage Cotton Topping Device

Xu,

Han,

Qiu

et al. 2024

Agriculture

View full text Add to dashboard Cite

show abstract

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Analysis and Optimization of Motion Coupling for the Coordinated Operation of Flexible Multi-Arm Space Robots

Cited by 1 publication

References 19 publications

Design and Experimental Evaluation of a Minimal-Damage Cotton Topping Device

Design and Experimental Evaluation of a Minimal-Damage Cotton Topping Device

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