Numerical study of magnetic circuit response in magneto-rheological damper

Khan, Sadak Ali; Suresh, A.; Ramaiah, N. Seetha

doi:10.1108/jedt-05-2013-0034

Cited by 4 publications

(1 citation statement)

References 9 publications

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“…This figure is useful to drive the pressure drops proportional to rotational speed and pressure drop proportional to input current. The pressure drop due to the viscosity of MR fluid and the pressure drop due to the yield stress of MR fluid is given by Equations (1) and (2) [19,20].…”

Section: Configuration and Modelingmentioning

confidence: 99%

A New Rotary Magnetorheological Damper for a Semi-Active Suspension System of low-Floor Vehicles

Park,

Kang,

Choi

2024

Preprint

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This study explores the significance of active suspension systems for vehicles with lower chassis compared to conventional ones, aiming at the development of future automobiles. Conventional linear MR (Magneto-Rheological) dampers were found inadequate in ensuring sufficient vibration control because the vehicle's chassis becomes lowered in the unmanned vehicles or purposed based vehicles. As an alternative, a rotary type of MR damper is proposed in this work. The proposed damper is designed based on pre-specified design parameters through mathematical modeling and magnetic field analyses. Subsequently, a prototype of the rotary MR damper identical to the design is fabricated, and effectiveness is shown through experimental investigations. In configuring the experiments, a proportional-integral (PI) controller is employed for current control to reduce the response time of the damper. The results presented in this work provides useful guidelines to develop a new type of MR damper applicable to various types of future vehicles’ suspension systems with low distance from the tire to the body floor.

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Section: Configuration and Modelingmentioning

confidence: 99%

A New Rotary Magnetorheological Damper for a Semi-Active Suspension System of low-Floor Vehicles

Park,

Kang,

Choi

2024

Preprint

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Research on Fluid Viscous Damper Parameters of Cable-Stayed Bridge in Northwest China

He¹,

Yang²,

Xiao³

et al. 2017

Shock and Vibration

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To optimize the aseismic performance of nonlinear fluid viscous dampers (FVD) of cable-stayed bridge in the highly seismic zone, Xigu Yellow River Bridge in northwest China is taken as an example. Nonlinear time-history analysis method is used to research on the relation among the internal forces, displacements, and damping parameters of the 650 tonnage FVD. The method of getting the minimum of binary functions is used to obtain the optimal parameters of FVD. Also, the 1 : 1 full-scale FVD model is made and used in the constitutive relation test. Then the test result of the damping parameters can be got by normal equation method. The optimized method to obtain the damping parameters is further verified. The results indicate that seismic response in key positions of the cable-stayed bridge can be reduced by installing longitudinal nonlinear FVD between the towers and girders if choosing reasonable damping parameters and . The optimal damping parameters can be calculated accurately by the proposed method of optimizing damping parameters of nonlinear FVD, and the constitutive relation test verifies the correctness of the optimization analysis method. Conclusions concerned can be applied to the design of nonlinear FVD for cable-stayed bridges.

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Characteristics, Optimal Design, and Performance Analyses of MRF Damper

De-kui

Nie

et al. 2018

Shock and Vibration

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Magnetorheological fluid (MRF) damper is one of the most promising semiactive devices for vibration control. In this paper, a shear-valve mode MRF damper for pipeline vibration control is proposed. The dynamic model and the state equation of the pipeline are established and the linear quadratic regulator (LQR) is used to generate the optimal damping force of MRF damper. The design concept considering the structure and the electromagnetic properties simultaneously is discussed in detail. A mathematical model of the relation between shear stress and control current based on interpolation method is established. Finite element analysis (FEA) software COMSOL is selected to simulate the magnetic field and electromagnetism-thermal field of the MRF damper. A computational method based on the simulation model is established to calculate the shear stress. In order to reduce the magnetic leakage, a method of adding magnetism-insulators at both ends of the piston head is presented. The influence of control current, displacement, and velocity on mechanical performance of the proposed MRF damper is experimentally investigated. The test results show that the performance of the MRF damper is basically identical with the theoretical prospective and the simulation conclusions, which proves the correctness and feasibility of this design concept.

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Numerical study of magnetic circuit response in magneto-rheological damper

Cited by 4 publications

References 9 publications

A New Rotary Magnetorheological Damper for a Semi-Active Suspension System of low-Floor Vehicles

A New Rotary Magnetorheological Damper for a Semi-Active Suspension System of low-Floor Vehicles

Research on Fluid Viscous Damper Parameters of Cable-Stayed Bridge in Northwest China

Characteristics, Optimal Design, and Performance Analyses of MRF Damper

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