Spring-balanced 3-DoF serial planar manipulators for constant forces in arbitrary directions

Juang, Chia-Wei; Jhuang, Chi-Shiun; Chen, Dar‐Zen

doi:10.1017/s0263574723000279

Cited by 2 publications

(1 citation statement)

References 32 publications

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“…Different balancing mechanisms were developed by researchers two decades back. Examples are counterweight [1, 2], pneumatic or hydraulic cylinders [3], mechanical balancing like gear train [4], helical/torsional spring [5, 6], and cam mechanism [7]. Most of the above-mentioned balancing mechanisms were used for planar mechanisms.…”

Section: Introductionmentioning

confidence: 99%

Design, static analysis, and dynamic system modeling of 3-PPRS parallel manipulator with load-balancing UPS leg

Prasad

Ganesh

2023

Robotica

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As a heavy load is applied to the parallel manipulators, it causes inaccuracies while positioning the end-effector or unbalanced dynamic forces in the legs. Various load-balancing techniques overcome this. However, the disadvantage of most load-balancing mechanisms is that they add inertia to the assembly and decrease the speed of motion. This article studies a new load-balancing method (a passive damper mechanism). The passive balancing mechanism is proposed to negate the inertia effects while countering the static inaccuracies in the parallel mechanism. This is verified by the structural analysis of the mechanism. The impact of the damper element on the dynamics of the mechanism is unknown. Hence, a complete mathematical model for the balancing mechanism has been developed to study its impact on the dynamics of the entire structure. Laplace transformations characterize the system response. The inclusion of a passive damper in a 3-prismatic-prismatic-revolute-spherical system was examined and found to be stable and critically damped. Such a passive damper was envisaged to facilitate additional force transmission for the actuators, and the DC gain from the system response validates the torque support for the actuators.

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Section: Introductionmentioning

confidence: 99%

Design, static analysis, and dynamic system modeling of 3-PPRS parallel manipulator with load-balancing UPS leg

Prasad

Ganesh

2023

Robotica

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A resistance torque compensation algorithm based on Luenberger observer for minimally invasive surgical robot

Sang,

Huang,

et al. 2024

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Purpose The patient-side manipulator (PSM) achieves high torque capability by combining harmonic servo system with high reduction ratio and low torque motor. However, high reduction ratio can increase inertia and decrease compliance of the manipulator. To enhance the backdrivability of the minimally invasive surgical robot, this paper aims to propose a resistance torque compensation algorithm. Design/methodology/approach A resistance torque compensation algorithm based on dynamics and Luenberger observer is proposed. The dynamics are established, considering joint flexibility and an improved Stribeck friction model. The dynamic parameters are experimentally identified by using the least squares method. With the advantages of clear structure, simple implementation and fast solution speed, the Luenberger observer is selected to estimate the unmeasured dynamic information of PSM and realize the resistance torque compensation. Findings For low-speed surgical robots, the centrifugal force term in the dynamic model can be simplified to reduce computational complexity. Joint flexibility and an improved Stribeck friction model can be considered to improve the accuracy of the dynamic model. Experiment results show that parameter identification and estimated results of the Luenberger observer are accurate. The backdrivability of the PSM is enhanced in ease and smoothness. Originality/value This algorithm provides potential application prospects for surgical robots to maintain high torque while remaining compliant. Meanwhile, the enhanced backdrivability of the manipulator helps to improve the safety of the preoperative manual adjustment.

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Spring-balanced 3-DoF serial planar manipulators for constant forces in arbitrary directions

Cited by 2 publications

References 32 publications

Design, static analysis, and dynamic system modeling of 3-PPRS parallel manipulator with load-balancing UPS leg

Design, static analysis, and dynamic system modeling of 3-PPRS parallel manipulator with load-balancing UPS leg

A resistance torque compensation algorithm based on Luenberger observer for minimally invasive surgical robot

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