期刊文献+

超磁致伸缩执行器全耦合非线性动态有限元模型 被引量:6

Coupling Nonlinear Dynamic Finite Element Model of Giant Magnetostrictive Actuator
下载PDF
导出
摘要 超磁致伸缩执行器在高频率下工作时,能量损失不仅包括磁滞损失、Terfenol-D棒涡流损失,还包括执行器导磁回路的附加涡流损失,同时执行器上存在磁场、电场、温度场及机械应力场四场之间的耦合。本文考虑超磁致伸缩执行器Terfenol-D棒质量、预压应力、偏置磁场、磁滞和涡流损失,从电场、磁场和机械应力场三场耦合角度,建立超磁致伸缩执行器三维非线性动态有限元模型。超磁致伸缩材料磁滞特性由Berqvist和Engdahl磁滞模型来描述。应用FEMLAB建模分析并与实验结果对比,发现模型与实验结果吻合较好,验证了所建立三维动态FEM模型的正确性。 The giant magnetostrictive actuator works at high frequency, and then the loss of giant magnetostrictive actuator includes magnetic hysteresis loss, eddy currency loss, and excess eddy current loss of actuator loop. The coupling between four fields (i. e., magnetic field, electric field, thermal field and mechanical stress field) is occurred at the actuator. Considering the mass of Terfenol-D rod, pre-stress, biased field, the loss of magnetic hysteresis and eddy current, a 3-D nonlinear dynamic model of GMA was established based on the coupled relationship of the three fields (magnetic field, electric field and mechanical stress field). The magnetic behavior was described by the Berqvist and Engdahl stress dependent magnetic hysteresis model for ferromagnetic hysteresis. The simulation results with commercial software FEMLAB were in agreement well with the experimental data. Therefore, the model constructed is valid, and it can help to optimize design of the GMA.
出处 《农业机械学报》 EI CAS CSCD 北大核心 2008年第3期123-126,共4页 Transactions of the Chinese Society for Agricultural Machinery
基金 国家自然科学基金资助项目(项目编号:50575205) 国家“863”高技术研究发展计划资助项目(项目编号:2006AA04Z233) 浙江省自然科学基金资助项目(项目编号:Y104243、Y105686) 浙江省科技攻关项目(项目编号:2006C11234)
关键词 超磁致伸缩执行器 涡流 磁滞损失 动态有限元模型 耦合 Giant magnetostrictive actuator, Eddy current, Loss of magnetic hysteresis, Dynamic finite element model, Coupling
  • 相关文献

参考文献11

  • 1Venkataraman R. Modeling and adaptive control of magnetostrictive actuators[D]. Maryland, USA, 1999.
  • 2Jiles D C. Modeling the effects of eddy current losses on frequency dependent hysteresis in electrically conducting media[J]. IEEE Trans. Magn., 1994, 30(6) :4 326-4 328.
  • 3黄文美,王博文,曹淑瑛,孙英,翁玲.计及涡流效应和应力变化的超磁致伸缩换能器的动态模型[J].中国电机工程学报,2005,25(16):132-136. 被引量:19
  • 4Delince F, Genon A, Gillard J M, et al. A numerical computation of the magnetostrictive effect in ferromagnetic materials [J]. Japanese J. Appl. Phys., 1991,69(8): 5 794-5 796.
  • 5Benbouzid M E H, Reyne G, Meunier G. Variational formulation for nonlinear FE modeling of terfenol-D rods using surface splines for material in data [ J ]. Elsevier Studies in Appl. Electromag. in Mat., 1993, 4 : 185 - 191.
  • 6Kanna K S, Dasgupta A A. A nonlinear Galerkin finite-element theory for modeling magnetostrictive smart structures[ J ]. Smart Mater. Struct,, 1997(6) : 341 - 350.
  • 7Jos'E L, P' erez-aparici0, Sosa horacio. A continuum three-dimensional, fully coupled, dynamic, non-linear finite element formulation for magnetostrictive materials[J]. Smart Mater. Struet., 2004(13);493-502.
  • 8Benatar J G, Flatau A B. FEM implementation of a magnetostrictive transducer[J ]. Smart Structures and Materials, Proc. of SPIE, 2005, 5764 : 482- 493.
  • 9Bergqvist A, Engdahl G. A model for magnetomechanical hysteresis and losses in magnetostrictive materials[J]. Japanese J. Appl. Phys., 1996,79(8): 6 476 - 6 479.
  • 10Bergqvist A, Engdahl G. A phenomenologieal magnetomechanical hysteresis model[ J ]. Japanese J. Appl. Phys., 1994, 75(10): 5 496-5 498.

二级参考文献15

  • 1黄文美,王博文,闫荣格,曹淑瑛.超磁致伸缩换能器有限元动态模型的研究[J].河北工业大学学报,2004,33(5):1-4. 被引量:4
  • 2曹淑瑛,王博文,郑加驹,闫荣格,黄文美.应用混合遗传算法的超磁致伸缩致动器磁滞模型的参数辨识[J].中国电机工程学报,2004,24(10):127-132. 被引量:21
  • 3黄文美,王博文,曹淑瑛,闫荣格,王绍亮.超磁致伸缩超声换能器的结构与谐振频率分析[J].微特电机,2004,32(9):5-8. 被引量:4
  • 4Duenas T A, Hsu L, CarmanG P. Magnetostrictive composite material systems analytical/experimental[C]. Boston : Advanced Smart Materials Fundamentals and Applications, 1996.
  • 5Adly A A, Mayergoyz I D. Magnetostriction simulation using anisotropic vector Preisach-type models[J]. IEEE Trans. Magn, 1996,32(5): 4473-4475.
  • 6Smith R C. Modeling techniques for magnetostrictive actuators [C]. San Diego: Proceedings of SPIE Symposium on Smart Structures and Materials, 1997.
  • 7Basso V, Bertotti G. Hysteresis models for the description of domain wall motion[J]. IEEETrans. Magn., 1996, 32(5): 4210-4212.
  • 8FaidleyLE, LundBJ, FlatauABetal. Tefernol-Delasto-magnetic properties under varied operating conditions using hysteresis loop analysis[C]. California: SPIE Symposium on Smart Structures, 1998.
  • 9Calkins F T, Smith R C, Flatau A B. Energy-based hysteresis model for magnetostrictive transducers[J]. IEEE Trans. on Magn, 2000,36(2): 429-439.
  • 10Jiles D C. Modelling the effects of eddy current losses on frequencu dependent hysteresis in electrically conducting media[J]. IEEE Trans.on Magn, 1994, 30(6): 4326-4328.

共引文献18

同被引文献78

引证文献6

二级引证文献24

相关作者

内容加载中请稍等...

相关机构

内容加载中请稍等...

相关主题

内容加载中请稍等...

浏览历史

内容加载中请稍等...
;
使用帮助 返回顶部