Micro-gripper for Precision Meso-scale Assembly

doi:10.3969/j.issn.1000-1093.2014.12.021

Abstract

Abstract: Meso-scale parts are widely used in the complex miniature weapon systems. On account of a large dimension range, a variety of shapes and vulnerable structures of the meso-scale parts, the weapon systems are mainly assembled by hand, bringing poor efficiency and reliability. A challenging issue in the precision assembly of miniature weapon systems is how to safely and reliably grip the meso-scale parts in the automatic handling and assembly. A micro-gripper for gripping the sub-millimeter and millimeter scale shafts and parts is developed, including a pair of rigid and flexible gripping jaws and a precision linear motion stage. A Wheatstone bridge, which consists of strain gauges stuck on the flexible gripping jaw, is used to detect a clamping force on a part in real time. The structural parameters of flexible gripping jaw are designed optimally, and an optimal design model of gripping jaws is proposed. A simulation analysis is carried out to determine the best sticking positions of the gauges. A strain-force model for the special shape of flexible gripping jaw is derived. Grip-release experiments indicate that the micro-gripper is capable to grip the meso-scale parts stably and nondestructively.

Key words: apparatus and intruments technology, meso-scale, micro-gripper, optimization model, micro-force sensing

CLC Number:

TP241

SUN Yuan， JIN Xin, YE Xin， ZHANG Zhi-jing， ZHANG Xiao-feng. Micro-gripper for Precision Meso-scale Assembly[J]. Acta Armamentarii, 2014, 35(12): 2078-2086.

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