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Magnetostrictive and Kinematic Model Considering the Dynamic Hysteresis and Energy Loss for GMA

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Abstract

Due to the influence of magnetic hysteresis and energy loss inherent in giant magnetostrictive materials (GMM), output displacement accuracy of giant magnetostrictive actuator (GMA) can not meet the precision and ultra precision machining. Using a GMM rod as the core driving element, a GMA which may be used in the field of precision and ultra precision drive engineering is designed through modular design method. Based on the Armstrong theory and elastic Gibbs free energy theory, a nonlinear magnetostriction model which considers magnetic hysteresis and energy loss characteristics is established. Moreover, the mechanical system differential equation model for GMA is established by utilizing D’Alembert’s principle. Experimental results show that the model can preferably predict magnetization property, magnetic potential orientation, energy loss for GMM. It is also able to describe magnetostrictive elongation and output displacement of GMA. Research results will provide a theoretical basis for solving the dynamic magnetic hysteresis, energy loss and working precision for GMA fundamentally.

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References

  1. ZHENG Jigui, HUANG Yuping, WU Hongxing, et al. Design of a transverse-flux permanent-magnet linear generator and controller for use with a free-piston stirling engine[J]. Chinese Journal of Mechanical Engineering, 2016, 29(4): 832–842.

  2. ZHANG Zhonghua, KAN Junwu, WANG Shuyun, et al. Effects of driving mode on the performance of multiple-chamber piezoelectric pumps with multiple actuators[J]. Chinese Journal of Mechanical Engineering, 2015, 28(5): 954–963.

  3. NAKANO H. Angstrom positioning system using a giant magnetostriction actuator for high power applications[C]//Proceedings of the Power Conversion, Osaka, Japan, April 25, 2002: 1102–1107.

  4. TONG D, VELDHUIS S C. ELBESTAWI M A. Control of a dual stage magnetostrictive actuator and linear motor feed drive system [J]. International Journal of Advanced Manufacturing Technology, 2007, 33(3–4): 379–388.

  5. LV Fuzai, XIANG Zhaiqin, QI Zongjun, et al. The mechanical design of micro displacement actuator for precision noncircular cutting[J]. Mechanical Science and Technology, 2000, 19(5): 767– 769. (in Chinese)

  6. KIM J, DOO J. Magnetostrictive self-moving cell linear motor[J]. Mechatronics, 2003, 13 (7): 739–753.

  7. LUO Y H, HUTAPEA P. Stress-strain behavior of a smart magnetostrictive actuator for a bone transport device[J]. Journal of Medical Device, 2008, 2(4): 041002-1.

  8. LIU H F, WANG S J, MA C, et al. Study on an actuator with giant magnetostrictive aterials for driving galvanometer in selective laser intering precisely[J]. International Journal of Mechatronics and Manufacturing Systems, 2015, 9(3/4): 116–133.

  9. XING Haiyan, DANG Yongbin, WANG Ben, et al. Quantitative metal magnetic memory reliability modeling for welded joints[J]. Chinese Journal of Mechanical Engineering, 2016, 29(2): 372–377.

  10. LIU Changhai, JIANG Hongzhou. Influence of magnetic reluctances of magnetic elements on servo valve torque motors[J]. Chinese Journal of Mechanical Engineering, 2016, 29(1): 136–144.

  11. ZHANG Peng, LEE Kwang-Hee, LEE Chul-Hee. Friction behavior of magnetorheological fluids with different material types and magnetic field strength[J]. Chinese Journal of Mechanical Engineering, 2016, 29(1): 84–90.

  12. DAVINO D, GIUSTINIANI A, VISONE C. Compensation of magnetostrictive Hysteresis by Arduino: Floating versus fixed-point performances[J]. IEEE Transactions on Magnetics, 2014, 50, 11, Article number: 6971449.

  13. LINNEMANN K, KLINKEL S, WAGNER W. A constitutive model for magnetostrictive and piezoelectric materials[J]. International Journal of Solids and Structures, 2009, 46 (5): 1149–1166.

  14. LI Y S, ZHU Y C, WU H T. Modeling and inverse compensation for giant magnetostrictive transducer applied in smart material electrohydrostatic actuator[J]. Journal of Intelligent Material Systems and Structures, 2014, 25 (3): 378–388.

  15. ZHU Yu-Chuan, XU Hong-Xiang, CHEN Long, et al. Dynamic preisach model in giant magnetostrictive actuator based on hyperbolic tangent function hysteresis operators[J]. Journal of Mechanical Engineering, 2014, 50(6): 165–170. (in Chinese)

  16. MOSES A J, ANDERSON P I, SOMKUN S. Modeling 2-d magnetostriction in nonoriented electrical steels using a simple magnetic domain model[J]. IEEE Transactions on Magnetics, 2015, 51(5): 7036108.

  17. ZHANG L X, WANG X S, CAO J. Measurement and compensation of pitch error based on GMA with elimination of its hysteresis[J]. Journal of Mechanical Science and Technology, 2014, 28(5): 1855–1866.

  18. BERGQVIST A, ENGDAHL G. A stress-dependent magnetic preisach hysteresis model[J]. IEEE Transactions on Magnetics, 1991, 27 (6): 4796–4798.

  19. TAN X B, BARASA J S. Modeling and control of hysteresis in magnetostrictive actuators[J]. Automatica, 2004, 40(9): 1469–1480.

  20. HU C C, SHI Y G, CHEN Z Y. Synthesis, magnetic properties and magnetostriction of Pr0.5Nd0.5(Fe1-xCox)(1.9) cubic Laves alloys [J]. Journal of Alloys and Compounds, 2014, 613: 153–156.

  21. LIU Huifang, JIA ZhenYuan, WANG Fuji, et al. Parameter indentification of displacement model for giant magnetostrictive actuator[J]. Journal of Mechanical Engineering, 2010, 46(15), 148–153. (in Chinese)

  22. ZENG Jiewei, SU Lanhai, XU Liping, et al. Research on the stress measurement of steel plate based on inverse magnetostrictive effect [J]. Journal of Mechanical Engineering, 2014, 50(8): 17–22. (in Chinese)

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Authors and Affiliations

  1. School of Mechanical Engineering, Shenyang University of Technology, Shenyang, 110870, China

    Huifang LIU, Xingwei SUN, Yifei GAO, Hanyu WANG & Zijin GAO

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  1. Huifang LIU
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  2. Xingwei SUN
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  3. Yifei GAO
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  4. Hanyu WANG
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  5. Zijin GAO
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Corresponding author

Correspondence to Xingwei SUN.

Additional information

Supported by National Natural Science Foundation of China (Grant No. 51305277), Doctoral Program of Higher Education China (Grant No. 20132102120007), Shenyang Science and Technology Plan Project (Grant No.F15-199-1-14), and China Postdoctoral Science Foundation (Grant No.2014T70261).

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LIU, H., SUN, X., GAO, Y. et al. Magnetostrictive and Kinematic Model Considering the Dynamic Hysteresis and Energy Loss for GMA. Chin. J. Mech. Eng. 30, 241–255 (2017). https://doi.org/10.1007/s10033-017-0074-8

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  • DOI: https://doi.org/10.1007/s10033-017-0074-8

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