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Direct Kinetostatic Analysis of a Gripper with Curved Flexures

Alessandro Cammarata, Pietro Davide Maddío, Rosario Sinatra, Nicola Pio Belfiore

2022Micromachines22 citationsDOIOpen Access PDF

Abstract

Micro-electro-mechanical-systems (MEMS) extensively employed planar mechanisms with elastic curved beams. However, using a curved circular beam as a flexure hinge, in most cases, needs a more sophisticated kinetostatic model than the conventional planar flexures. An elastic curved beam generally allows its outer sections to experience full plane mobility with three degrees of freedom, making complex non-linear models necessary to predict their behavior. This paper describes the direct kinetostatic analysis of a planar gripper with an elastic curved beam is described and then solved by calculating the tangent stiffness matrix in closed form. Two simplified models and different contributions to derive their tangent stiffness matrices are considered. Then, the Newton-Raphson iterative method solves the non-linear direct kinetostatic problem. The technique, which appears particularly useful for real-time applications, is finally applied to a case study consisting of a four-bar linkage gripper with elastic curved beam joints that can be used in real-time grasping operations at the microscale.

Topics & Concepts

HingePlanarStiffnessCompliant mechanismMicroscale chemistryBeam (structure)TangentStiffness matrixTangent stiffness matrixDegrees of freedom (physics and chemistry)Matrix (chemical analysis)Structural engineeringEngineeringFinite element methodComputer sciencePhysicsGeometryMathematicsMaterials scienceComputer graphics (images)Composite materialMathematics educationQuantum mechanicsPiezoelectric Actuators and ControlForce Microscopy Techniques and ApplicationsAdvanced MEMS and NEMS Technologies
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