Dynamic modeling and analysis of junction surfaces of robotic modules

2013 IEEE International Conference on Robotics and Biomimetics (ROBIO) Pub Date : 2013-12-01 DOI:10.1109/ROBIO.2013.6739774

Huaizhu Li, Y. Guan, Shizhong Chen, Pinhong Wu, Wenqiang Wu, Xin Chen, Hong Zhang

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Abstract

Junction surface plays an important role in the performance of a modular robot in terms of positioning error and system stiffness. In this paper, junction surfaces of robotic modules are modeled and analyzed based on virtual medium. The asperity of a junction surface is first made equivalent to an isotropic virtual medium layer, and the thick surface contact fractal theory is combined with the contact mechanics theory. The analytical dynamic model is thus established, by which the coupling relationship between the asperities of junction surface is successfully simulated. The fractal dimension and the scale coefficient of the equivalent junction surfaces are obtained by surface profilometer and power spectrum analysis, and the dynamic characteristic parameters of the virtual medium are calculated. Comparison result shows that the theoretical and measured modal shapes basically match, and the relative errors between the theory natural frequency and the test natural frequency of every order are less than 7.3%, which verifies the effectiveness of the dynamic model of the module junction surface.

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机器人模块连接面的动力学建模与分析

接合面对模块化机器人的定位误差和系统刚度起着重要的作用。本文基于虚拟介质对机器人模块的连接面进行了建模和分析。首先将结点表面的粗糙度等效为各向同性的虚拟介质层，并将厚面接触分形理论与接触力学理论相结合。建立了解析动力学模型，成功地模拟了结面凹凸度之间的耦合关系。通过表面轮廓仪和功率谱分析，得到了等效结面的分形维数和尺度系数，并计算了虚拟介质的动态特性参数。对比结果表明，理论模态振型与实测模态振型基本吻合，各阶理论固有频率与试验固有频率的相对误差均小于7.3%，验证了模型的有效性。

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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2013 IEEE International Conference on Robotics and Biomimetics (ROBIO)

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