A type of symmetrical differential lever displacement amplification mechanism

Wei Fan; Huaxue Jin; Yuchen Fu; Yuyang Lin

doi:10.1051/meca/2021003

All issues

Volume 22 (2021)

Mechanics & Industry, 22 (2021) 5

References

Open Access

Issue		Mechanics & Industry Volume 22, 2021


Article Number		5
Number of page(s)		8
DOI		https://doi.org/10.1051/meca/2021003
Published online		08 March 2021

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Y.M. Li, H. Tang, Q.S. XU et al., Development trend of micro-manipulation robot technology forbiomedical applications, Journal of Mechanical Engineering 47 , 1–13 (2011) [Google Scholar]
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L.Y. Zheng, J.Y. Shen, P.F. Wang et al., Research on flexure hinge amplification mechanism for piezoelectric actuator displacement amplification, Scientific and Technological Innovation and Application 24, 21–22 (2018) [Google Scholar]
L.J. Lai, Z.N. Zhu, Design, modeling and testing of a novel flexure-based displacement amplification mechanism, Sensors and Actuators A: Physical 266 , 122–129 (2017) [Google Scholar]
M. Li, X.F. Chen, Q. Lu, Simulation design of flexible mechanism of piezoelectric laminated actuation system, Mechanical design and manufacturing engineering 47 , 25–29 (2018) [Google Scholar]
Q. Lu, W.Q. Huang, M.X. Sun, Parametric design of flexible amplification mechanism based on flexure hinge, Vibration, Test and Diagnosis 36 , 935–941 (2016) [Google Scholar]
Q.S. Xu, Y.M. Li, Analytical modeling, optimization and testing of a compound bridge-type compliant displacement amplifier, Mechanism and Machine Theory 46, 183–200 (2011) [Google Scholar]
G. Tang, P.J. ZOU, G.Y. Xie et al., Amplification mechanism of flexure hinge based on triangle and lever principle, Mechanical Design and Research 34 , 46–49 (2018) [Google Scholar]
Z. Yang, T.L. Song, Design and analysis of flexible hinge amplification mechanism, Coal Mine Machinery 39 , 12–14 (2018) [Google Scholar]
T. Liu, X.M. Zhang, Design of two-dimensional micro displacement platform based on flexure hinge lever amplification mechanism, Mechanical Engineer, 165–168 (2014) [Google Scholar]
S.B. Choi et al., A magnification device for precision mechanisms featuring piezoactuators and flexure hinges: design and experimental validation, Mechanism and Machine Theory 42, 1184–1198 (2007) [Google Scholar]
W. Dong, F.X. Chen, F.T. Gao et al., Development and analysis of a bridge-lever-type displacement amplifier based on hybrid flexure hinges, Precision Engineering 54 , 171–181 (2018) [Google Scholar]
J.G. Wan, L.W. Zhong, Research and Analysis on the amplification ratio characteristics of bridge type micro-displacement amplifier, China Water Transport 18 , 117–119 (2018) [Google Scholar]
J.J. Li, G.M. Chen, Optimal design of flexible two-stage differential micro-displacement amplification mechanism, Journal of Mechanical Engineering 55 , 21–28 (2019) [Google Scholar]
K.J. Liu, Optimization design of lever type flexure hinge micro-displacement amplification mechanism. Chinese Society of Mechanics, Shanghai Jiaotong University, Chinese mechanical congress-2015 abstracts, 2015, p. 256 [Google Scholar]
J.Y. Shen, H.J. Zhang, Y. Zhan, A calculation method of magnification of lever type flexure hinge mechanism with piezoelectric ceramic actuator, Journal of agricultural machinery 44 , 267–271 (2013) [Google Scholar]
X. Wei, K. Tim, Flexure hinges for piezoactuator displacement amplifiers: flexibility, accuracy, and stress considerations, Precision Engineering 19 , 4–10 (1996) [Google Scholar]
Y.M. Yu, J.S. Leng, Design and dynamic performance simulation of flexible micro displacement amplification mechanism, Mechanical Design and Research 27 , 48–51, 55 (2011) [Google Scholar]
C.T. Wang, Y.Q. Wang, X.F. Yang et al., Analysis of stiffness characteristics of three kinds of four-bar flexure hinge mechanisms based on ANSYS, Mechanical Transmission 41 , 59–63, 76 (2017) [Google Scholar]
X.Y. Jiang, D.F. Chen, Performance analysis of differential displacement amplifier based on ANSYS, Journal of Hubei University of Technology 25 , 77–79 (2010) [Google Scholar]
G.M. Chen, Y.K. Ma, J.J. Li, A tensural displacement amplifier employing elliptic-arc flexurehinges, Sensors and Actuators A: Physical 247 , 307–315 (2016) [Google Scholar]

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[1] P.R. Ouyang, W.J. Zhang, M.M. Gupta et al., Overview of the development of a visual-based automated bio-micro-manipulation system, Mechatronics 17 , 578–588 (2007) [Google Scholar]

[2] G. Velasco-Herrera, Parallel micro-manipulator system with applications in micro-assembles and micro-machine-making, WSEAS Transactions on System 4 , 980–987 (2005) [Google Scholar]

[3] Y.M. Li, H. Tang, Q.S. XU et al., Development trend of micro-manipulation robot technology forbiomedical applications, Journal of Mechanical Engineering 47 , 1–13 (2011) [Google Scholar]

[4] N. Dechev, L. Ren, W. Liu et al., Development of a 6 degree of freedom robotic micro manipulatorfor use in 3D MEMS micro-assembly, IEEE International Conference on Robotics and Automation, ICRA, Orlando, 2006, pp. 281–288 [Google Scholar]

[5] L.Y. Zheng, J.Y. Shen, P.F. Wang et al., Research on flexure hinge amplification mechanism for piezoelectric actuator displacement amplification, Scientific and Technological Innovation and Application 24, 21–22 (2018) [Google Scholar]

[6] L.J. Lai, Z.N. Zhu, Design, modeling and testing of a novel flexure-based displacement amplification mechanism, Sensors and Actuators A: Physical 266 , 122–129 (2017) [Google Scholar]

[7] M. Li, X.F. Chen, Q. Lu, Simulation design of flexible mechanism of piezoelectric laminated actuation system, Mechanical design and manufacturing engineering 47 , 25–29 (2018) [Google Scholar]

[8] Q. Lu, W.Q. Huang, M.X. Sun, Parametric design of flexible amplification mechanism based on flexure hinge, Vibration, Test and Diagnosis 36 , 935–941 (2016) [Google Scholar]

[9] Q.S. Xu, Y.M. Li, Analytical modeling, optimization and testing of a compound bridge-type compliant displacement amplifier, Mechanism and Machine Theory 46, 183–200 (2011) [Google Scholar]

[10] G. Tang, P.J. ZOU, G.Y. Xie et al., Amplification mechanism of flexure hinge based on triangle and lever principle, Mechanical Design and Research 34 , 46–49 (2018) [Google Scholar]

[11] Z. Yang, T.L. Song, Design and analysis of flexible hinge amplification mechanism, Coal Mine Machinery 39 , 12–14 (2018) [Google Scholar]

[12] T. Liu, X.M. Zhang, Design of two-dimensional micro displacement platform based on flexure hinge lever amplification mechanism, Mechanical Engineer, 165–168 (2014) [Google Scholar]

[13] S.B. Choi et al., A magnification device for precision mechanisms featuring piezoactuators and flexure hinges: design and experimental validation, Mechanism and Machine Theory 42, 1184–1198 (2007) [Google Scholar]

[14] W. Dong, F.X. Chen, F.T. Gao et al., Development and analysis of a bridge-lever-type displacement amplifier based on hybrid flexure hinges, Precision Engineering 54 , 171–181 (2018) [Google Scholar]

[15] J.G. Wan, L.W. Zhong, Research and Analysis on the amplification ratio characteristics of bridge type micro-displacement amplifier, China Water Transport 18 , 117–119 (2018) [Google Scholar]

[16] J.J. Li, G.M. Chen, Optimal design of flexible two-stage differential micro-displacement amplification mechanism, Journal of Mechanical Engineering 55 , 21–28 (2019) [Google Scholar]

[17] K.J. Liu, Optimization design of lever type flexure hinge micro-displacement amplification mechanism. Chinese Society of Mechanics, Shanghai Jiaotong University, Chinese mechanical congress-2015 abstracts, 2015, p. 256 [Google Scholar]

[18] J.Y. Shen, H.J. Zhang, Y. Zhan, A calculation method of magnification of lever type flexure hinge mechanism with piezoelectric ceramic actuator, Journal of agricultural machinery 44 , 267–271 (2013) [Google Scholar]

[19] X. Wei, K. Tim, Flexure hinges for piezoactuator displacement amplifiers: flexibility, accuracy, and stress considerations, Precision Engineering 19 , 4–10 (1996) [Google Scholar]

[20] Y.M. Yu, J.S. Leng, Design and dynamic performance simulation of flexible micro displacement amplification mechanism, Mechanical Design and Research 27 , 48–51, 55 (2011) [Google Scholar]

[21] C.T. Wang, Y.Q. Wang, X.F. Yang et al., Analysis of stiffness characteristics of three kinds of four-bar flexure hinge mechanisms based on ANSYS, Mechanical Transmission 41 , 59–63, 76 (2017) [Google Scholar]

[22] X.Y. Jiang, D.F. Chen, Performance analysis of differential displacement amplifier based on ANSYS, Journal of Hubei University of Technology 25 , 77–79 (2010) [Google Scholar]

[23] G.M. Chen, Y.K. Ma, J.J. Li, A tensural displacement amplifier employing elliptic-arc flexurehinges, Sensors and Actuators A: Physical 247 , 307–315 (2016) [Google Scholar]