Please wait a minute...
浙江大学学报(工学版)
J4  2012, Vol. 46 Issue (6): 1067-1073    DOI: 10.3785/j.issn.1008-973X.2012.06.017
    
Static and dynamic optimal design of bridge-type mechanism of
micro/nano-positioning platform
LIN Chao, YU Song-song, TAO Gui-bao, CHENG Kai, TAO You-tao, SU Xin-hong
State Key Laboratory of Mechanical Transmission, Chongqing University, Chongqing 400030, China
Download:   PDF(0KB) HTML
Export: BibTeX | EndNote (RIS)      

Abstract  

In order to solve the restriction between static and dynamic performances, static and dynamic models were set up by using pseudo-rigid-body and the effect of geometric parameters on the static and dynamic performances was analyzed. As a result, the smaller the thickness and the longer the length of flexure hinge are, the better the static performance of the bridge-type mechanism will be, while the dynamic performance goes worse. The dynamic performance is mainly affected by the thickness of flexure hinge, while much less by the length. An optimization model of overall performance of bridge-type mechanism was established, and the thickness, length and other geometric parameters were optimized. In terms of ANSYS, the performances of the mechanism before and after optimization were simulated, and its static and dynamic performances were tested. Experimental results indicated that the stable time after optimization was decreased to 0.032 s, 80% shorter than before optimization, the displacement output decreased by 40.2%, while the overall performance increased to 340.75 mm·Hz, increased by 74.53% than before optimization.

Published: 24 July 2012
CLC:  TH 139  
Service
E-mail this article
Add to my bookshelf
Add to citation manager
E-mail Alert
RSS
Articles by authors
Cite this article:

LIN Chao, YU Song-song, TAO Gui-bao, CHENG Kai, TAO You-tao, SU Xin-hong. Static and dynamic optimal design of bridge-type mechanism of
micro/nano-positioning platform. J4, 2012, 46(6): 1067-1073.

URL:

http://www.zjujournals.com/eng/10.3785/j.issn.1008-973X.2012.06.017     OR     http://www.zjujournals.com/eng/Y2012/V46/I6/1067


微/纳米定位平台的桥式机构静、动态优化设计

为了解决桥式机构静态性能与动态性能相互制约问题,应用伪刚体模型法,建立桥式机构的静、动力学模型,分析表明:柔性板簧厚度越小、长度越长,桥式机构的静态性能越好,但动态性能就越差;动态性能主要受柔性板簧厚度影响,板簧长度对其影响不大.为了优化桥式机构的静、动态性能,建立该机构总性能的优化模型,并对柔性板簧厚度、长度等几何特征参数进行了优化设计.应用ANSYS,对优化前、后的机构进行了仿真分析,并对机构的静、动态性能进行了试验,结果表明:优化后机构的稳态时间减小为0.032 s,比优化前ANSYS仿真缩短了80%,微位移输出减小了40.2%,优化后机构总性能达340.75 mm·Hz,比优化前ANSYS仿真提高了74.53%.

[1] WANG H, ZHANG X M. Input coupling analysis and optimal design of a 3DOF compliant micropositioning stage[J]. Mechanism and Machine Theory, 2008, 43(4): 400-410.
[2] GAO P, SWEI S, YUAN Z. New piezoelectric precision micropositioning stage utilizing flexure hinges[J]. Nanotechnology, 1999, 10 (4): 394-398.
[3] TANG X Y, CHEN I M, LI Q, et al. Design and nonlinear modeling of a largedisplacement XYZ flexure parallel mechanism with decoupled kinematic structure[J]. Scientific Instruments, 2006, 77 (11): 1-11.
[4] DONG W, SUN L N, DU Z J, et al. Stiffness research on a highprecision, largeworkspace parallel mechanism with compliant joints[J]. Precision Engineering, 2008, 32(3): 222-231.
[5] DONG J Y, YAO Q, PLACID M F, et al. Dynamics,control and performance analysis of a novel parallelkinematics mechanism for integrated,multiaxis nanopositioning[J]. Precision Engineering. 2008,32: 20-33.
[6] 魏强,张玉林,宋会英,等.扫描隧道显微镜精密工作台及其控制技术研究[J].中国机械工程, 2007,18(2): 193-196.
WEI Qiang, ZHANG Yulin, SONG Huiying, et al. Research on precision stage and control technology of scanning tunnel ing microscope[J]. China Mechanical Engineering, 2007,18(2): 193-196.
[7] 马立,荣伟彬,孙立宁,等.面向光学精密装配的微操作机器人[J],机械工程学报,2009, 45(2): 280-287.
MA Li, RONG Weibin, SUN Lining, et al. Micro operation robot for optical precise assembly [J]. Journal of Mechanical Engineering,2009, 45(2): 280-287.
[8] YU Y Q, HOWELL L L, LUSK C P, et al. Dynamic modeling of compliant mechanisms based on the pseudorigidbody model[J]. Journal of Mechanical Design, 2005, 127(4): 760-765.
[9] KE Y, GUO T, LI J. A newstyle, slottedcymbal transducer with large displacement and high energy transmission [J]. IEEE Transactions on Ultrasonics Ferroelectrics and Frequency Control, 2004, 51: 1171-1177.

[10] MA H W, YAO S M, WAMG L Q, et al. Analysis of the displacement amplification ratio of bridge type flexure hinge[J]. Sensors and Actuators, 2006, A 132: 730-736.
[11] KIM J H, KIM S H, KWAK Y K, et al. Development and optimization of 3D bridgetype hinge mechanisms [J]. Sensors and Actuators, 2004, A 116: 530-538.
[12] KIM D M, KANG D W, SHIM J Y, et al. Optimal design of a flexure hingebased XYZ atomic force microscopy scanner for minimizing Abbe errors[J]. Review of Scientific Instruments, 2005, 76: 073706.
[13] 于靖军,周强,毕树生,等.基于动力学性能的全柔性机构优化设计[J].机械工程学报,2003, 39(8): 32-36.
YU Jingjun, ZHOU Qiang, BI Shusheng, et al. Optimal design od a fully compliant mechanism based on its dynamic characteristics [J]. China Journal of Mechanical Engineering, 2003, 39(8): 32-36.
[14] 林超,俞松松,程凯,等.大行程5DOF微纳传动平台的设计及特性分析[J].中国机械工程,2010,21(22): 2679-2684.
LIN Chao, YU Songsong, CHENG Kai, et al. Design and analysis of a longdisplacement5DOF nanotransmission platform[J]. China Mechanical Engineering, 2010, 21(22): 2679-2684.
[15] HOWELL L L.柔性机构学[M].北京:高等教育出版社,2007: 98-149.
[1] LIN Chao, TAO You-tao, CHENG Kai, YU Song-song, LIU Lei. Displacement coupling analysis of micro/nano transmission platform[J]. J4, 2013, 47(4): 720-727.
[2] LIN Chao, YU Song-song, CHENG Kai, Cui Xin-hui, TAO You-tao,WANG Jing-chao. Dynamic analysis and testing of micro/nano-positioning platform[J]. J4, 2012, 46(8): 1375-1381.