China Mechanical Engineering

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Design and Simulation of Mechanical Decoupling Self-calibration Parallel Six Dimensional Force Sensors

ZHAO Yanzhi1,2;JIAO Leihao1,2;NIU Zhi1,2;LU Chao1,2;ZHAO Tieshi1,2   

  1. 1.Key Laboratory of Parallel Robot and Mechatronic System of Hebei Province,Yanshan University,Qinhuangdao,Hebei,066004
    2.Key Laboratory of Advanced Forging & Stamping Technology and Science of Ministry of Education of China,Yanshan University,Qinhuangdao,Hebei,066004
  • Online:2017-04-10 Published:2017-04-07

机械解耦自标定并联六维力传感器设计及仿真

赵延治1,2;焦雷浩1,2;牛智1,2;鲁超1,2;赵铁石1,2   

  1. 1.燕山大学河北省并联机器人与机电系统实验室,秦皇岛,河北,066004
    2.先进锻压成形技术与科学教育部重点实验室(燕山大学),秦皇岛,河北,066004
  • 基金资助:
    国家自然科学基金资助项目(51105322);河北省自然科学基金资助项目(E2014203176);
    河北省高等学校科学技术研究青年基金资助项目(QN2015040);
    中国博士后科学基金资助项目(2016M590212)

Abstract: To avoide the present situations of the heavy loading calibration of traditional multi-dimensional force sensors, a self-calibration design concept of multi-dimensional force sensors was proposed, the weak coupling full thrust force self-calibration orthogonal parallel six dimensional force sensor structure was design which might realize mechanical decoupling by the rolling of the steel balls. The rolling decoupling principles of the six dimensional force sensors were demonstrated, and then the self-calibration principles of the six dimensional force sensors were demonstrated. An ideal mathematical model of the six dimensional force sensors was established based on the screw theory, and the first order static influence coefficient matrix was obtained. The force analysis and simulation of the six dimensional force sensor were carried out with considering the elastic deformations based on the mechanics solution principles of high-order statically indeterminate structure, and the self-calibration characteristics were proved by combining the numerical examples, which sets the development foundation of the novel six dimensional force sensors.

Key words: six dimensional force sensor, orthogonal parallel, mechanical decoupling, self-calibration

摘要: 针对传统多维力传感器研制后均需繁冗的加载标定这一现状,提出了多维力传感器“自标定”设计理念,通过钢球滚动机械解耦,设计了一种弱耦合全压向力自标定正交并联六维力传感器结构。论证了该六维力传感器的滚动解耦原理,分析了其自标定原理。基于螺旋理论建立了该六维力传感器理想数学模型,计算得到其一阶静力影响系数矩阵。考虑分支弹性变形,基于高次超静定结构力学求解原理,对该六维力传感器进行了受力分析与仿真计算,结合数值算例论证了其自标定特性,从而为该新型六维力传感器的研制奠定基础。

关键词: 六维力传感器, 正交并联, 机械解耦, 自标定

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