Dynamic performance simulation of electrorheological isolator by using bond graph method

Shao Hua Zhang; Juan Wang; Mei Yan Li

Dynamic performance simulation of electrorheological isolator by using bond graph method

Shao Hua Zhang^*, Juan Wang, Mei Yan Li

^*Corresponding author for this work

CAS - Institute of Electronics

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

Abstract

Based on the particular characteristics of the Electrorheological Fluids (ERF) tunable damping, the structure of ER isolator and its working principle are discussed. The two estimative parameters of isolation system-dynamic stiffness and loss angle are determined applying bond graph theory to dynamic simulation and modeling. It is proved that ER isolator will work well in both in the low and high frequency zones. The smart ER fluid can tune its viscosity instantly with controllable electric field and thereby gain ends in active isolation and enlarge the isolation frequency domain efficiently by measuring the system damping.

Original language	English
Pages (from-to)	570-574
Number of pages	5
Journal	Beijing Ligong Daxue Xuebao/Transaction of Beijing Institute of Technology
Volume	25
Issue number	7
Publication status	Published - Jul 2005

Keywords

Bond graph method
Electrorheological effect
Isolation

Cite this

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title = "Dynamic performance simulation of electrorheological isolator by using bond graph method",

abstract = "Based on the particular characteristics of the Electrorheological Fluids (ERF) tunable damping, the structure of ER isolator and its working principle are discussed. The two estimative parameters of isolation system-dynamic stiffness and loss angle are determined applying bond graph theory to dynamic simulation and modeling. It is proved that ER isolator will work well in both in the low and high frequency zones. The smart ER fluid can tune its viscosity instantly with controllable electric field and thereby gain ends in active isolation and enlarge the isolation frequency domain efficiently by measuring the system damping.",

keywords = "Bond graph method, Electrorheological effect, Isolation",

author = "Zhang, {Shao Hua} and Juan Wang and Li, {Mei Yan}",

year = "2005",

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T1 - Dynamic performance simulation of electrorheological isolator by using bond graph method

AU - Zhang, Shao Hua

AU - Wang, Juan

AU - Li, Mei Yan

PY - 2005/7

Y1 - 2005/7

N2 - Based on the particular characteristics of the Electrorheological Fluids (ERF) tunable damping, the structure of ER isolator and its working principle are discussed. The two estimative parameters of isolation system-dynamic stiffness and loss angle are determined applying bond graph theory to dynamic simulation and modeling. It is proved that ER isolator will work well in both in the low and high frequency zones. The smart ER fluid can tune its viscosity instantly with controllable electric field and thereby gain ends in active isolation and enlarge the isolation frequency domain efficiently by measuring the system damping.

AB - Based on the particular characteristics of the Electrorheological Fluids (ERF) tunable damping, the structure of ER isolator and its working principle are discussed. The two estimative parameters of isolation system-dynamic stiffness and loss angle are determined applying bond graph theory to dynamic simulation and modeling. It is proved that ER isolator will work well in both in the low and high frequency zones. The smart ER fluid can tune its viscosity instantly with controllable electric field and thereby gain ends in active isolation and enlarge the isolation frequency domain efficiently by measuring the system damping.

KW - Bond graph method

KW - Electrorheological effect

KW - Isolation

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M3 - Article

AN - SCOPUS:24344441973

SN - 1001-0645

VL - 25

SP - 570

EP - 574

JO - Beijing Ligong Daxue Xuebao/Transaction of Beijing Institute of Technology

JF - Beijing Ligong Daxue Xuebao/Transaction of Beijing Institute of Technology

IS - 7

ER -

Dynamic performance simulation of electrorheological isolator by using bond graph method

Abstract

Keywords

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