Finite element analysis of a membrane-type piezoelectric tactile sensor with four sensing elements

IEEE Sensors, 2005. Pub Date : 2005-10-31 DOI:10.1109/ICSENS.2005.1597709

A. Mirbagheri, J. Dargahi, Farhad Aghili, K. Parsa

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引用次数: 3

Abstract

This paper focuses on the finite element modeling of a membrane-type piezoelectric tactile sensor with four sensing elements; the membrane is made of polyvinylidene fluoride (PVDF). This tactile sensor, capable of measuring magnitude and position of an applied normal force along with an estimation of the shape of the contacting objects, is an improved version of its already-tested three-element predecessor. It overcomes the problems of crosstalk, complexity, and fragility, which are associated with an array of sensing elements arranged in a matrix form. Difficulties of attaining a closed-form solution are briefly discussed and the results of finite element analysis are presented. Triangulation method is combined with membrane stresses to determine the position and the magnitude of forces. If the force is applied on the membrane by pressing an object on it, then through triangulation an estimation of the shape of the object can be found as well. With this approach the entire area of the tactile sensor becomes active. The sensor is linear, highly sensitive and exhibits high dynamic range. This tactile sensor can potentially be used in robotic and medical applications

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具有四个传感元件的薄膜式压电触觉传感器的有限元分析

本文重点研究了具有四个传感元件的薄膜式压电触觉传感器的有限元建模;该膜由聚偏氟乙烯(PVDF)制成。这种触觉传感器，能够测量施加的法向力的大小和位置，以及对接触物体形状的估计，是其已经测试过的三元素前身的改进版本。它克服了串扰、复杂性和脆弱性等问题，这些问题与以矩阵形式排列的传感元件阵列有关。简要讨论了获得封闭解的困难，并给出了有限元分析的结果。三角剖分法结合膜应力来确定力的位置和大小。如果力是通过将物体压在膜上而施加在膜上，那么通过三角测量也可以找到对物体形状的估计。通过这种方法，触觉传感器的整个区域变得活跃。该传感器是线性的，高灵敏度和高动态范围。这种触觉传感器可以潜在地用于机器人和医疗应用

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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IEEE Sensors, 2005.

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