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Design and optimization of a decoupled serial constant force microgripper for force sensitive objects manipulation

Shan Ye, Bingxiao Ding, Jianhua Zhong, Yangmin Li

2023Robotica13 citationsDOIOpen Access PDF

Abstract

Abstract To address coupling motion issues and realize large constant force range of microgrippers, we present a serial two-degree-of-freedom compliant constant force microgripper (CCFMG) in this paper. To realize a large output displacement in a compact structure, Scott–Russell displacement amplification mechanisms, bridge-type displacement amplification mechanisms, and lever amplification mechanisms are combined to compensate stroke of piezoelectric actuators. In addition, constant force modules are utilized to achieve a constant force output. We investigated CCFMG’s performances by means of pseudo-rigid body models and finite element analysis. Simulation results show that the proposed CCFMG has a stroke of 781.34 ${\unicode[Times]{x03BC}}\mathrm{m}$ in the X-direction and a stroke of 258.05 ${\unicode[Times]{x03BC}}\mathrm{m}$ in the Y-direction, and the decoupling rates in two directions are 1.1% and 0.9%, respectively. The average output constant force of the clamp is 37.49 N. The amplification ratios of the bridge-type amplifier and the Scott–Russell amplifier are 7.02 and 3, respectively. Through finite element analysis-based optimization, the constant force stroke of CCFMG is increased from the initial 1.6 to 3 mm.

Topics & Concepts

Decoupling (probability)AmplifierDisplacement (psychology)Constant (computer programming)ActuatorPhysicsControl theory (sociology)Finite element methodLeverComputer scienceEngineeringElectrical engineeringControl engineeringOptoelectronicsControl (management)PsychotherapistProgramming languageThermodynamicsArtificial intelligenceQuantum mechanicsPsychologyCMOSPiezoelectric Actuators and ControlAdvanced MEMS and NEMS TechnologiesForce Microscopy Techniques and Applications