Preload characteristics identification of the piezoelectric-actuated 1-DOF compliant nanopositioning platform

Ruizhou WANG; Xianmin ZHANG

doi:10.1007/s11465-015-0328-z

PDF(3669 KB)

Front. Mech. Eng. ›› 2015, Vol. 10 ›› Issue (1) : 20-36. DOI: 10.1007/s11465-015-0328-z

RESEARCH ARTICLE

Preload characteristics identification of the piezoelectric-actuated 1-DOF compliant nanopositioning platform

Author information +

History +

Abstract

Packaged piezoelectric ceramic actuators (PPCAs) and compliant mechanisms are attractive for nanopositioning and nanomanipulation due to their ultra-high precision. The way to create and keep a proper and steady connection between both ends of the PPCA and the compliant mechanism is an essential step to achieve such a high accuracy. The connection status affects the initial position of the terminal moving plate, the positioning accuracy and the dynamic performance of the nanopositioning platform, especially during a long-time or high-frequency positioning procedure. This paper presents a novel external preload mechanism and tests it in a 1-degree of freedom (1-DOF) compliant nanopositioning platform. The 1-DOF platform utilizes a parallelogram guiding mechanism and a parallelogram load mechanism to provide a more accurate actual input displacement and output displacement. The simulation results verify the proposed stiffness model and dynamic model of the platform. The values of the preload displacement, actual input displacement and output displacement can be measured by three capacitive sensors during the whole positioning procedure. The test results show the preload characteristics vary with different types or control modes of the PPCA. Some fitting formulas are derived to describe the preload displacement, actual input displacement and output displacement using the nominal elongation signal of the PPCA. With the identification of the preload characteristics, the actual and comprehensive output characteristics of the PPCA can be obtained by the strain gauge sensor (SGS) embedded in the PPCA.

Keywords

nanopositioning / preload characteristic / packaged piezoelectric ceramic actuator / compliant mechanism

Cite this article

EndNote

Ris (Procite)

Bibtex

Download citation ▾

Ruizhou WANG, Xianmin ZHANG. Preload characteristics identiﬁcation of the piezoelectric-actuated 1-DOF compliant nanopositioning platform. Front. Mech. Eng., 2015, 10(1): 20‒36 https://doi.org/10.1007/s11465-015-0328-z

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Zhang Y L, Zhang Y, Ru C, et al. A load-lock-compatible nanomanipulation system for scanning electron microscope. IEEE/ASME Transactions on Mechatronics, 2013, 18(1): 230–237 CrossRef Google scholar

[2]	Tang H, Li Y. Design, analysis, and test of a novel 2-DOF nanopositioning system driven by dual mode. IEEE Transactions on Robotics, 2013, 29(3): 650–620 CrossRef Google scholar

[3]	Yong Y K, Moheimani S O R, Kenton B J, et al. Invited review article: High-speed flexure-guided nanopositioning: Mechanical design and control issues. Review of Scientific Instruments, 2012, 83(12): 121101–121122 CrossRef Google scholar

[4]	Espinosa H D, Zhu Y, Moldovan N. Design and operation of a mems-based material testing system for nanomechanical characteri-zation. Journal of Microelectromechanical Systems, 2007, 16(5): 1219–1231 CrossRef Google scholar

[5]	Fukuda T, Nakajima M, Liu P, et al. Nanofabrication, nanoinstrumentation and nanoassembly by nanorobotic manipulation. International Journal of Robotics Research, 2009, 28(4): 537–547 CrossRef Google scholar

[6]	Wang H, Zhang X. Input coupling analysis and optimal design of a 3-DOF compliant micro-positioning stage. Mechanism and Machine Theory, 2008, 43(4): 400–410 CrossRef Google scholar

[7]	Kim H, Gweon D G. Development of a compact and long range xyθ_z nanopositioningstage. Review of Scientific Instruments, 2012, 83(8): 085102–085108 CrossRef Google scholar

[8]	Culpepper M L, Anderson G. Design of a low-cost nano-manipulator which utilizes a monolithic, spatial compliant mechanism. Precision Engineering, 2004, 28(4): 469–482 CrossRef Google scholar

[9]	Li Y, Xu Q. A totally decoupled piezo-driven XYZ flexure parallel micropositioning stage for micro/nanomanipulation. IEEE Transactions on Automation Science and Engineering, 2011, 8(2): 265– 279 CrossRef Google scholar

[10]	Wang R, Zhang X. Design & test of a novel planar 3-DOF precision positioning platform with a large magnification. In: Proceedings of 2014 International Conference on Manipulation, Manufacturing and Measurement on the Nanoscale (3M-NANO). Taipei: IEEE, 2014, 288–295

[11]	Howell L L. Compliant Mechanisms. New York: Wiley-InterScience, 2001

[12]	Lobontiu N. Compliant Mechanisms: Design of Flexure Hinges. Boca Raton: CRC Press, 2003

[13]	Yong Y K, Lu T F, Handley D C. Review of circular flexure hinge design equations and derivation of empirical formulations. Precision Engineering, 2008, 32(2): 63–70 CrossRef Google scholar

[14]	Lin R, Zhang X, Long X, et al. Hybrid flexure hinges. Review of Scientific Instruments, 2013, 84(8): 085004–085014 CrossRef Google scholar

[15]	Adriaens H J M T S, de Koning W, Banning R. Modeling piezoelectric actuators. IEEE/ASME Transactions on Mechatronics, 2000, 5(4): 331–341 CrossRef Google scholar

[16]	Ge P, Jouaneh M. Tracking control of a piezoceramic actuator. IEEE Transactions on Control Systems Technology, 1996, 4(3): 209–216 CrossRef Google scholar

[17]	Baxter L K. Capacitive Sensors: Design and Applications. Piscataway: IEEE Press, 1997

[18]	Fleming A J. A review of nanometer resolution position sensors: Operation and performance. Sensors and Actuators A: Physical, 2013, 190: 106–126 CrossRef Google scholar

[19]	Tian Y, Shirinzadeh B, Zhang D. Design and dynamics of a 3-DOF flexure-based parallel mechanism for micro/nano manipulation. Microelectronic Engineering, 2010, 87(2): 230–241 CrossRef Google scholar

[20]	Yong Y K, Aphale S S, Moheimani S O R. Design, identification, and control of a flexure-based XY stage for fast nanoscale positioning. IEEE Transactions on Nanotechnology, 2009, 8(1): 46–54 CrossRef Google scholar

[21]	Leang K K, Fleming A J. High-speed serial-kinematic SPM scanner: Design and drive considerations. Asian Journal of Control, 2009, 11(2): 144–153 CrossRef Google scholar

[22]	Zhang X, Wang R. China Patent, 2014103010471, 2014-<month>06</month>-<day>27</day>

[23]	Bathe K J, Wilson E L. Numerical Methods in Finite Element Analysis. Englewood Cliffs: Prentice-Hall, 1976

Acknowledgements

This research was supported by the National Natural Science Foundation of China (Grant No. 91223201), the Natural Science Foundation of Guangdong Province (Grant No. S2013030013355), Project GDUPS (2010) and the Fundamental Research Funds for the Central Universities (Grant No. 2012ZP0004). These supports are greatly acknowledged.