Modeling and Analysis of Leaf Spring Based Double Parallel-Guiding Mechanism Considering Thermal Effect

Volume 5A: 43rd Mechanisms and Robotics Conference Pub Date : 2019-11-25 DOI:10.1115/detc2019-97690

Shuaishuai Lu, P. Yan

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Abstract

In the present paper, we take the leaf spring based double parallel-guiding mechanism (DPGM) as a particular case study to investigate a parametric model by considering the stress stiffening effect of the temperature variation based on the beam constraint model (BCM). In particular, a model with the temperature variation term of the DPGM is derived by incorporating the elastic stretch induced by the thermal effect of the leaf spring flexure into the BCM. Different from the traditional BCM, the compliance calculated by the established model is no longer only affected by the external loads, but the thermal deformation generated by the temperature variation. Therefore the derived model can describe both the load-nonlinearity and the thermal-nonlinearity. Based on the analysis results of a basic parallelogram module (BPM), we obtain a model of the DPGM, and the finite element analysis (FEA) method is adopted to verify the proposed model. The proposed model is a general parametric method to characterize the mechanical property of the DPGM, which can be further explored to support the optimization and control of motion systems composed of leaf spring based compliant mechanisms.

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考虑热效应的叶弹簧双并联导向机构建模与分析

本文以基于板簧的双平行导向机构(DPGM)为例，研究了基于梁约束模型(BCM)的考虑温度变化应力加劲效应的参数化模型。在此基础上，将叶片弹簧挠曲的热效应引起的弹性拉伸引入到BCM中，建立了带温度变化项的DPGM模型。与传统的BCM不同，所建立的模型计算的柔度不再只受外部载荷的影响，而是受温度变化产生的热变形的影响。因此，所建立的模型既可以描述载荷非线性，也可以描述热非线性。基于基本平行四边形模块(BPM)的分析结果，建立了DPGM的模型，并采用有限元分析(FEA)方法对该模型进行了验证。该模型是表征叶片弹簧柔性机构力学性能的通用参数化方法，可为基于叶片弹簧的柔性机构组成的运动系统的优化和控制提供进一步的支持。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Volume 5A: 43rd Mechanisms and Robotics Conference

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