Magnetorheological damper 3-D simulation with finite element method

Jun Qiang Li; Xi Zhe Zang; Jie Zhao

Magnetorheological damper 3-D simulation with finite element method

Jun Qiang Li^*
, Xi Zhe Zang
, Jie Zhao

^*Corresponding author for this work

School of Mechatronics Engineering

Harbin Institute of Technology

Research output: Contribution to journal › Article › peer-review

3 Scopus citations

Abstract

Depending on the characteristics of the magnetorheological damper, the 1/16 3-D model of the damper was built with the ANSYS APDL. Based on different nonlinear magnetization characteristics of magnetorheological fluid and magnetic core material, the finite element model of the damper was built with the edge-based Solid117 element, and 3-D static nonlinear magnetic analysis was performed. In the general post processor, with the magnetic flux density average and magnetic field intensity average of the work area, based on above results, the magnetorheological damper's properties: yield torque vs current and coefficient of magnetic dispersion were calculated.

Original language	English
Pages (from-to)	5594-5596+5601
Journal	Xitong Fangzhen Xuebao / Journal of System Simulation
Volume	21
Issue number	17
State	Published - 5 Sep 2009

Keywords

3-D static nonlinear electromagnetic analysis
Finite element method
Magnetorheological damper
Parameter design

Cite this

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title = "Magnetorheological damper 3-D simulation with finite element method",

abstract = "Depending on the characteristics of the magnetorheological damper, the 1/16 3-D model of the damper was built with the ANSYS APDL. Based on different nonlinear magnetization characteristics of magnetorheological fluid and magnetic core material, the finite element model of the damper was built with the edge-based Solid117 element, and 3-D static nonlinear magnetic analysis was performed. In the general post processor, with the magnetic flux density average and magnetic field intensity average of the work area, based on above results, the magnetorheological damper's properties: yield torque vs current and coefficient of magnetic dispersion were calculated.",

keywords = "3-D static nonlinear electromagnetic analysis, Finite element method, Magnetorheological damper, Parameter design",

author = "Li, \{Jun Qiang\} and Zang, \{Xi Zhe\} and Jie Zhao",

year = "2009",

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language = "英语",

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TY - JOUR

T1 - Magnetorheological damper 3-D simulation with finite element method

AU - Li, Jun Qiang

AU - Zang, Xi Zhe

AU - Zhao, Jie

PY - 2009/9/5

Y1 - 2009/9/5

N2 - Depending on the characteristics of the magnetorheological damper, the 1/16 3-D model of the damper was built with the ANSYS APDL. Based on different nonlinear magnetization characteristics of magnetorheological fluid and magnetic core material, the finite element model of the damper was built with the edge-based Solid117 element, and 3-D static nonlinear magnetic analysis was performed. In the general post processor, with the magnetic flux density average and magnetic field intensity average of the work area, based on above results, the magnetorheological damper's properties: yield torque vs current and coefficient of magnetic dispersion were calculated.

AB - Depending on the characteristics of the magnetorheological damper, the 1/16 3-D model of the damper was built with the ANSYS APDL. Based on different nonlinear magnetization characteristics of magnetorheological fluid and magnetic core material, the finite element model of the damper was built with the edge-based Solid117 element, and 3-D static nonlinear magnetic analysis was performed. In the general post processor, with the magnetic flux density average and magnetic field intensity average of the work area, based on above results, the magnetorheological damper's properties: yield torque vs current and coefficient of magnetic dispersion were calculated.

KW - 3-D static nonlinear electromagnetic analysis

KW - Finite element method

KW - Magnetorheological damper

KW - Parameter design

UR - https://www.scopus.com/pages/publications/70349393862

M3 - 文章

AN - SCOPUS:70349393862

SN - 1004-731X

VL - 21

SP - 5594-5596+5601

JO - Xitong Fangzhen Xuebao / Journal of System Simulation

JF - Xitong Fangzhen Xuebao / Journal of System Simulation

IS - 17

ER -

Magnetorheological damper 3-D simulation with finite element method

Abstract

Keywords

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