磁控形状记忆合金多场耦合仿真分析与模型预测

doi:10.16731/j.cnki.1671-3133.2018.12.004

现代制造工程 ›› 2018, Vol. 459 ›› Issue (12): 17-23.doi: 10.16731/j.cnki.1671-3133.2018.12.004

磁控形状记忆合金多场耦合仿真分析与模型预测

涂福泉, 李根, 沈林鹏, 胡升谋, 李恒, 刘谋泽

武汉科技大学机械自动化学院,武汉 430081

收稿日期:2017-11-20 发布日期:2019-01-07
作者简介:涂福泉,教授,博士,主要从事智能材料研究。E-mail:tfqhb@163.com
基金资助:
国家自然科学基金项目(51274155);湖北省自然科学基金项目(2015CFA114)

Simulation analysis and model prediction of MSMA multi field coupling

Tu Fuquan, Li Gen, Shen Linpeng, Hu Shengmou, Li Heng, Liu Mouze

College of Machinery and Automation,Wuhan University of Science and Technology,Wuhan 430081,China

Received:2017-11-20 Published:2019-01-07

摘要/Abstract

摘要： 磁控形状记忆合金(MSMA)固有的磁滞非线性特性严重影响了MSMA驱动器定位精度,以Ni₂MnGa 磁控形状记忆合金为研究对象,利用MSMA多场耦合系统进行实验,控制实验温度和磁场强度,记录外加应力、温度、磁场强度及MSMA应变等实验数据。在Ansys Maxwell软件中进行MSMA驱动装置模型磁路的电磁场仿真,得到最佳的耦合磁场强度。结合实验数据,运用能量守恒定律和热力学理论,构建MSMA多场耦合模型,预测了多场耦合变量曲线,得到MSMA驱动器工作的最佳耦合条件,为MSMA驱动器高精度定位提供了理论依据。

关键词: 磁控形状记忆合金, 多场耦合模型, 实验与仿真, 驱动器, 精度定位

Abstract: The inherent hysteresis nonlinearity of MSMA influences MSMA drive positioning accuracy to Ni₂MnGa magnetic shape memory alloy as the research object,multi field coupling system using MSMA control experiment,experimental temperature and magnetic field strength,stress,temperature,and record the magnetic field and the experimental data of MSMA strain.The electromagnetic field simulation of the MSMA drive device model magnetic circuit is carried out at Ansys Maxwell,and the optimum coupling magnetic field strength is obtained.According to the experimental data,using the law of conservation of energy and the thermodynamics theory,construct multi field coupling model MSMA,prediction of multi field coupling variable curve,the best coupling conditions of MSMA actuator,and provides a theoretical basis for the high precision positioning MSMA drive.

Key words: Magnetically Controlled Shape Memory Alloy(MSMA), multi field coupling model, experiment and simulation, drive, precision positioning

中图分类号:

TH142.2

涂福泉, 李根, 沈林鹏, 胡升谋, 李恒, 刘谋泽. 磁控形状记忆合金多场耦合仿真分析与模型预测[J]. 现代制造工程, 2018, 459(12): 17-23.

Tu Fuquan, Li Gen, Shen Linpeng, Hu Shengmou, Li Heng, Liu Mouze. Simulation analysis and model prediction of MSMA multi field coupling[J]. Modern Manufacturing Engineering, 2018, 459(12): 17-23.

参考文献

[1] SCHLÜTER K,HOLZ B,RAATZ A.Principle design of actuators driven by magnetic shape memory alloys[J].Advanced Engineering Materials,2012,14(8):682-686.
[2] SADEGHZADEH A,ASUA E,FEUCHTWANGER J,et al.Ferromagnetic shape memory alloy actuator enabled for nanometric position control using hysteresis compensation[J].Sensors & Actuators A Physical,2012,182(15):122-129.
[3] NESPOLI A,RIGAMONTI D,VILLA E,et al.Design,characterization and perspectives of shape memory alloy elements in miniature sensor proof of concept[J].Sensors & Actuators A Physical,2014,218(1):142-153.
[4] 涂福泉,毛阳,胡良智,等.基于磁控形状记忆合金的伺服阀驱动器[J].机床与液压,2014,42(3):115-117.
[5] SOZINOV A,LIKHACHEV A A,ULLAKKO I.Crystal structures and magnetic anisotropy properties of Ni-Mn-Ga martensitic phases with giant magnetic-field-induced strain[J].IEEE Tram Magnetics,2002,38(5):2814.
[6] LIKHACHEV A A,ULLAKKO K.Magnetic-field-controlled twin boundaries motion and giant magneto-mechanical effects in Ni-Mn-Ga shape memory alloy[J].Physics Letters A,2000,275(1):142-151.
[7] TU Fuquan,HU Shengmou,ZHUANG Yuhang,et al.Hysteresis Curve Fitting Optimization of Magnetic Controlled Shape Memory Alloy Actuator[J].Actuators,2016,5(4):25.
[8] LIN J H,CHIANG M H.Hysteresis analysis and positioning control for a magnetic shape memory actuator[J].Sensors,2015,15(4):8054-8071.
[9] SUDARSANA Rao H,GHORPADE V G,Mukherjee A.A genetic algorithm based back propagation network for simulation of stress-strain response of ceramic-matrix-composites[J].Computers & Structures,2006,84(5):330-339.
[10] SADEGHZADEH A,ASUA E,FEUCHTWANGER J,et al.Ferromagnetic shape memory alloy actuator enabled for nanometric position control using hysteresis compensation[J].Sensors & Actuators A Physical,2012,182(15):122-129.
[11] GAO W,KIM S W,BOSSE H,et al.Measurement technologies for precision positioning[J].CIRP Annals Manufacturing Technology,2015,64(2):773-796.
[12] KARACA H E,KARAMAN I,BASARAN B,et al.Magnetic field and stress induced martensite reorientation in NiMnGa ferromagnetic shape memory alloy single crystals[J].Acta Materialia,2006,54(54):233-245.
[13] HALDAR K,LAGOUDAS D C,KARAMAN I.Magnetic field-induced martensitic phase transformation in magnetic shape memory alloys:Modeling and experiments[J].Journal of the Mechanics & Physics of Solids,2014,69(9):33-66.
[14] 倽国迎.压电陶瓷驱动微位移平台的磁滞补偿控制理论和方法研究[J].金属加工:冷加工,2014(12):167.
[15] KARACA H E,IBRAHIM K,BURAK B,et al.Magnetic Field-Induced Phase Transformation in NiMnCoIn Magnetic Shape-Memory Alloys——A New Actuation Mechanism with Large Work Output[J].Advanced Functional Materials,2009,19(7):983-998.
[16] LINDQUIST P G,MÜLLNER P.Working Ni-Mn-Ga Single Crystals in a Magnetic Field Against a Spring Load[J].Shape Memory and Superelasticity,2015,1(1):69-77.
[17] YAMAMOTO T,TAYA M,SUTOU Y,et al.Magnetic field-induced reversible variant rearrangement in Fe-Pd single crystals[J].Acta Materialia,2004,52(17):5083-5091.

磁控形状记忆合金多场耦合仿真分析与模型预测

Simulation analysis and model prediction of MSMA multi field coupling

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