纳米表面相互作用及振动测头模型

陈丽娟; 陈晓怀; 刘芳芳; 王景凡

doi:10.7498/aps.65.080603

摘要

如何实现高精度的测量是现代制造业及微电子技术领域的热点问题之一. 基于微纳米测头的三坐标测量机是当前实现高精度测量的重要手段. 随着测量尺寸的减小, 常用的纳米/微纳尺度的测头与待测表面之间形成静态接触, 其表面相互作用成为了影响其测量精度和可靠性的关键因素之一. 本文基于一种触发式振动测头, 研究了其动力学模型, 并通过对测头纳米尺度表面相互作用的理论分析及数值模拟, 确立了测头振动参数与表面相互作用之间的关联. 实验研究表明, 参数优化后的谐振微纳测头能有效抑制表面作用带来的干扰, 提高测量精度.

关键词:

Abstract

The high precision measurement has been a focus in the field of manufacturing and microelectronics in this year. The micro/nano probe for coordinate measuring machine (CMM) acts as a key characteristic because it can measure the high-aspect-ratio components with high precision. Various micro/nano-CMM probes with different principles and different structures have been developed in the last decade. However, most of these studies focused on the sensing principle and measurement methods. There is little research on the behavior of the surface interaction between the probe tip and the workpiece. And the measurement accuracy and reliability of the current probe, especially those of the low stiffness probe, are limited by interaction forces including capillary force, van der Waals force, electrostatic force and Casimir force. Therefore, it becomes a challenge to reduce the effect of the surface interaction forces for the Micro/nano CMM probe. A new trigger probe based on the vibrating principle is analyzed and an optimal method for the appropriate vibrating parameters is presented in this paper. The structure and principle of the probe are briefly described in the first part. In this system, a tungsten stylus with a tip-ball is fixed to the floating plate, which is supported by four L-shape high-elasticity leaf springs. The fiber Bargg grating (FBG) sensors are used in the probe for micro-CMM due to their superiority in t of small size, high sensitivity, large linear measuring range, immunity to electromagnetic interference, and low cost. One end of FBG is attached to a floating plate, and the other end to a retention plate which is connected with the piezoelectric ceramic actuator (PZT). The probe is driven by the PZT vibrating. Assuming that the driving forces can offset the surface interaction forces, then the probe can be described as a forced vibration model of the spring oscillator. Therefore, the equivalent model of the probe is set up. In the second part, a relationship between the vibration parameters of the probe and the surface interaction can be confirmed. Through theoretical analysis and numerical simulation, the appropriate vibrating parameters including resonance amplitude, velocity and frequency of the probe are designed, which can offset the surface interaction forces. In the third part, a probe is designed based on the above theories and an experimental system is set up to verify its rationality. The results show that the resonant micro/nano probe after optimizing its parameters can effectively reduce the influence of surface forces and improve the measurement accuracy.

Keywords:

作者及机构信息

1.
合肥工业大学仪器科学与光电工程学院, 合肥 230009

通信作者: 陈丽娟, shawiu2000@163.com

基金项目: 国家自然科学基金(批准号: 51275148, 51205103)资助的课题.

Authors and contacts

1.
School of Instrument Science and Opto-electronic Engineering, Hefei University of Technology, Hefei 230009, China

Corresponding author: Chen Li-Juan, shawiu2000@163.com

Funds: Project supported by the National Natural Science Foundation of China (Grant Nos. 51275148, 51205103).

参考文献

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施引文献

[1]	Huang Q X, Yu H J, Huang S, Qian J Z 2013 China Mechanical Engineering 24 1264 (in Chinese) [黄强先, 余慧娟, 黄帅, 钱剑钊 2013 中国机械工程 24 1264]
[2]	Zhang X J, Meng Y G, Wen S Z 2004 Acta Phys. Sin. 53 728 (in Chinese) [张向军, 孟勇刚, 温诗铸 2004 物理学报 53 728]
[3]	Richard K L, James C, Claudiu G, Christopher W J, Lakshmi N, Sun W J, Matthew T, Andrew Y 2012 Meas. Sci. Technol. 23 074002
[4]	Bos E J C 2011 Precision Engineering 35 228
[5]	Danzebrink H U, Dai G, Pohlenz F, Dziomba T, Btefisch S, Flgge J, Bosse H 2012 IEEE Instrumentation { Measurement Technology Conference Graz, Austria, May 13-16, 2012 p898
[6]	Michihatam, Takayay, Hayashi T 2008 Annals of the CIRP 57 493
[7]	Guo S, Xiong X M, Xu Z L, Sheng P, Tong P 2014 Chin. Phys. B 23 116802
[8]	Duan F L, Wang G J, Qiu H B 2012 Acta Phys. Sin. 61 046801 (in Chinese) [段芳莉, 王光建, 仇和兵 2012 物理学报 61 046801]
[9]	James D C, Richard K L 2013 Precision Engineering 37 491
[10]	Sergio S, Ibert V, Tewfics, Neil H T, Matteo C 2011 Nanotechnology 22 465705
[11]	Liu S S, Zhang C H, Liu J M 2010 Acta Phys. Sin. 59 6902 (in Chinese) [刘思思, 张朝辉, 刘俊铭 2010 物理学报 59 6902]
[12]	Lambert, Pierre 2007 Capillary Forces in Microassembly (New York: Springer) pp163-174
[13]	Jacob N, Israelachvili 2011 Intermolecularand Surface Forces Third Edition (California: Academic Press) pp107-132
[14]	Sitti M, Hashimoto H 1999 IEEE/ASME International Conference on Advanced Intelligent Mechatronics Atlanta, USA, September 19-23, 1999 p13
[15]	Pril W O 2002 Ph. D. Dissertation (Eindhoven: Eindhoven University of Technology)

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