<title>Vibration isolation using a magnetorheological damper in the squeeze-flow mode</title>

This paper presents a dual-mode magnetorheological (MR) fluid mount. Combining the fluid’s flow and squeeze modes of operation gives this MR mount a unique possibility for varying dynamic stiffness and damping. Details on the design of the internal structure of the mount and the magnetic circuit are provided. Simulation and experimental results are presented to show the effectiveness of the magnetic circuit. A mathematical model that combines the behavior of the fluid and the elastomeric parts and takes into account the magnetic activation of the fluid is used to gauge the effect of design parameters on the isolation characteristics of the mount. Experimental results show that in the proposed design, the dynamic stiffness of the mount may be varied over a wide range of frequencies making the mount a unique and versatile vibration isolation device for cases where input excitation occurs over a wide range of frequencies.

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Design Optimization of Squeeze Mode Magnetorheological Damper

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.877.391 ◽

2018 ◽

Vol 877 ◽

pp. 391-396

Author(s):

Jitenkumar D. Patel ◽

Dipal Patel

Keyword(s):

Vibration Isolation ◽

Mr Damper ◽

Magnetorheological Damper ◽

Design Parameters ◽

Flow Mode ◽

Shear Mode ◽

Optimized Design ◽

Engine Mount ◽

Low Amplitude ◽

Femm Software

Mostly, magnetorheological damper research is going on flow mode and shear mode type of damper. Less work is carried out by researcher on squeeze mode type of damper. This will give higher force as compare to flow mode and shear mode type of MRF damper at low excitation. So, this kind of damper can be used as vibration isolation for high impact loading at low amplitude application like engine mount. Aim of this paper is optimized design of Squeeze mode damper for low amplitude application by using design of experiment tool. For design of squeeze mode type of MR damper magnetic field distribution is very important study to improve damping performance. Various parameters like length of coil, diameter of squeeze plate, current passing through coil, number of turns, area of coil and MR fluid gap are considered during optimization and optimization is done by using FEMM software It shows that length of coil, Number of turn and area of coil increases damping performance improves. Other design parameters are check out with mathematical model of MR damper with theoretical calculation like effect of frequency of excitation, diameter of squeeze plate, thick ness of squeeze plate and amplitude of excitation.

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On the Design and Control of a Squeeze-Flow Mode Magnetorheological Fluid Mount

Volume 1: 21st Biennial Conference on Mechanical Vibration and Noise, Parts A, B, and C ◽

10.1115/detc2007-35684 ◽

2007 ◽

Author(s):

Constantin Ciocanel ◽

The Nguyen ◽

Christopher Schroeder ◽

Mohammad Elahinia

Keyword(s):

Vibration Isolation ◽

Hybrid Control ◽

Control Strategies ◽

Dynamic Stiffness ◽

Squeeze Flow ◽

Flow Mode ◽

Force Transmissibility ◽

Displacement Force ◽

Vertical Vibrations ◽

And Control

The paper presents the design and control of a magnetorheological (MR) fluid based mount that combines the squeeze and flow modes in operation. The proposed design yields a high static stiffness and a low dynamic stiffness in the working frequency range of the mount, enhancing the vibration isolation capabilities of the mount compared to existing hydraulic mounts. Vertical vibrations, namely displacement/force transmissibility, can be isolated or significantly reduced, in real time, by controlling the fluid yield stress through an applied electric current. The mount governing equations have been derived and the effect of system parameters on its performance was analyzed. Preliminary results on the implementation of skyhook, groundhook and hybrid control strategies are also presented.

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Influence of response time of magnetorheological valve in Skyhook controlled three-parameter damping system

Advances in Mechanical Engineering ◽

10.1177/1687814018811193 ◽

2018 ◽

Vol 10 (11) ◽

pp. 168781401881119 ◽

Cited By ~ 4

Author(s):

Zbyněk Strecker ◽

Jakub Roupec ◽

Ivan Mazůrek ◽

Ondřej Macháček ◽

Michal Kubík

Keyword(s):

Response Time ◽

Control Algorithm ◽

Vibration Isolation ◽

Suspension System ◽

Magnetorheological Damper ◽

Semiactive Control ◽

Control Loop ◽

Space Industry ◽

Magnetorheological Valve ◽

Suspension Performance

A three-parameter suspension system is often used for vibration isolation of sensitive devices especially in a space industry. This article describes the three-parameter suspension system with magnetorheological valve controlled by Skyhook algorithm. Simulations of such systems showed promising results. They, however, showed that the suspension performance is strongly influenced by magnetorheological valve response time. Results from simulations proved that the semiactive control of such system with response time of magnetorheological damper up to 4 ms outperforms any passive setting. The simulations were verified by an experiment on suspension system with magnetorheological valve with response time between 3.5 and 4.1 ms controlled by a Skyhook algorithm. Although the control algorithm was slightly modified in order to prevent instabilities of control loop caused by signal noise, the results from the experiment showed the same trends like the simulations.

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Magnetorheological damper behaviour in accordance with flow mode

The European Physical Journal Applied Physics ◽

10.1051/epjap/2018180182 ◽

2018 ◽

Vol 84 (2) ◽

pp. 21101

Author(s):

Joanes Berasategui ◽

Ainara Gomez ◽

Manex Martinez-Agirre ◽

Maria Jesus Elejabarrieta ◽

M. Mounir Bou-Ali

Keyword(s):

Rheological Behaviour ◽

Mr Damper ◽

Experimental Tests ◽

Magnetorheological Damper ◽

Flow Mode ◽

Main Design ◽

Mr Dampers ◽

Significant Parameter ◽

Optimal Flow ◽

Theoretical Results

The objective of this article is to determine the optimal flow mode in an MR damper to maximize its performance. Flow mode is one of the main design issues in an MR damper, as it determines the velocity profile and the pressure drop across the gap. In this research, two MR dampers were designed and manufactured with two flow modes: valve and mixed. The response of these two dampers was compared experimentally. Additionally, the experimental tests were correlated by theoretical results that were obtained considering the rheological behaviour of the MR fluid, the shear stress distribution in the gap, and the damper movement. Interestingly, the obtained results suggest that flow mode is not a significant parameter for determining the behaviour of a MR damper.

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Study on Design Method for Magneto-Rheological Fluid Damper Based on Squeeze Mode and Experimental Tests

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.199-200.97 ◽

2011 ◽

Vol 199-200 ◽

pp. 97-101 ◽

Cited By ~ 1

Author(s):

Chang Rong Liao ◽

Li Juan Fu ◽

Ying Yang

Keyword(s):

Analytical Method ◽

Vibration Isolation ◽

Squeeze Flow ◽

Damping Force ◽

Mr Fluid ◽

Isolation System ◽

Technical Requirements ◽

Fluid Damper ◽

Magneto Rheological ◽

Mr Fluid Damper

A Magneto-rheological(MR) fluid damper based on squeeze model is put forward. The squeeze flow differential equation is obtained. Navier slip condition is considered on two boundary surfaces and compatible condition is established. The radial velocity profile and the radial pressure distributions are derived respectively. The mathematical expression of damping force is devloped. In order to verify rationality of analytical method, MR fluid damper based on squeeze mode is designed and fabricated according to technical requirements of engine vibration isolation system. The experimental damping forces from MTS870 Electro-hydraulic Servo with sine wave excitation show that analytical method proposed in this paper is feasible and has the reference value to design MR fluid damper based on squeeze mode.

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Modeling and Verification of an Innovative Active Pneumatic Vibration Isolation System

Journal of Dynamic Systems Measurement and Control ◽

10.1115/1.2807049 ◽

2008 ◽

Vol 130 (3) ◽

Cited By ~ 12

Author(s):

H. Porumamilla ◽

A. G. Kelkar ◽

J. M. Vogel

Keyword(s):

Natural Frequency ◽

Vibration Isolation ◽

Computational Study ◽

Hydraulic Cylinder ◽

Magnetorheological Damper ◽

Isolation System ◽

Vibration Isolation System ◽

Seat Suspension ◽

Active Vibration ◽

Novel Concept

This paper presents a novel concept in active pneumatic vibration isolation. The novelty in the concept is in utilizing an air-spring-orifice-accumulator combination to vary the natural frequency as well as inject damping into the system per requirement, thereby eliminating the need for a hydraulic cylinder or a magnetorheological damper. This continuously variable natural frequency and damping (CVNFD) technology is aimed at achieving active vibration isolation. For analysis purposes, a particular application in the form of pneumatic seat suspension for off-road vehicles is chosen. A mathematical model representing the system is derived rigorously from inertial dynamics and first principles in thermodynamics. Empirical corelations are also used to include nonlinearities such as friction that cannot be accounted for in the thermodynamic equations. An exhaustive computational study is undertaken to help understand the physics of the system. The computational study clearly depicts the CVNFD capability of the vibration isolation system. An experimental test rig is built to experimentally validate analytical and simulation modeling of the system. Experimental verification corroborated the variable natural frequency and damping characteristic of the system observed through computational simulations.

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Experimental Verification of Controllability of a Mixed Mode MR Fluid Mount

ASME 2011 Conference on Smart Materials, Adaptive Structures and Intelligent Systems, Volume 1 ◽

10.1115/smasis2011-4947 ◽

2011 ◽

Author(s):

Shuo Wang ◽

Mohammad Elahinia ◽

The Nguyen

Keyword(s):

Mixed Mode ◽

Alternative Energy ◽

Vibration Isolation ◽

Dynamic Stiffness ◽

Hybrid Vehicles ◽

Flow Mode ◽

Shear Mode ◽

Mr Fluid ◽

Set Up ◽

Different Levels

With the advent of alternative energy and hybrid vehicles come new vibration problems and challenges that require nontraditional solutions. Semi-active vibration isolation devices are preferred to address the problem due to their effectiveness and affordability. A magnetorheological (MR) fluid mount can provide effective vibration isolation for applications such as hybrid vehicles. The MR fluid can produce different levels of damping when exposed to different levels of magnetic field. The fluid can be working in three modes which are the flow mode, shear mode and squeeze mode. A mixed mode MR fluid mount was designed to operate in a combination of the flow mode and the squeeze mode. Each of the working modes and the combined working mode has been studied. The mount’s performance has been verified in simulation and experiments. Based on the simulation and experimental results, it can be seen that the mount can provide a large range of dynamic stiffness. Given this range of dynamic stiffness, a controller has been designed to achieve certain dynamic stiffness at certain frequencies. The experiments are set up to realize the hardware-in-the-loop tests. Results from the experiments show that the mixed mode MR fluid mount is able to achieve desired dynamic stiffness which is directly related to vibration transmissibility.

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A novel inverse dynamic model for a magnetorheological damper based on network inversion

Journal of Vibration and Control ◽

10.1177/1077546317705991 ◽

2017 ◽

Vol 24 (15) ◽

pp. 3434-3453 ◽

Cited By ~ 6

Author(s):

MJL Boada ◽

BL Boada ◽

V Diaz

Keyword(s):

Dynamic Model ◽

Vibration Isolation ◽

Mr Damper ◽

Inverse Model ◽

Magnetorheological Damper ◽

Hysteretic Behavior ◽

Inverse Dynamic ◽

Inverse Dynamic Model ◽

Mr Dampers ◽

Highly Nonlinear

Semi-active suspensions based on magnetorheological (MR) dampers are receiving significant attention, especially for control of vibration isolation systems. The nonlinear hysteretic behavior of MR dampers can cause serious problems in controlled systems, such as instability and loss of robustness. Most of the developed controllers determine the desired damping forces which should be produced by the MR damper. Nevertheless, the MR damper behavior can only be controlled in terms of the applied current (or voltage). In addition to this, it is necessary to develop an adequate inverse dynamic model in order to calculate the command current (or voltage) for the MR damper to generate the desired forces as close as possible to the optimal ones. Due to MR dampers being highly nonlinear devices, the inverse dynamics model is difficult to obtain. In this paper, a novel inverse MR damper model based on a network inversion is presented to estimate the necessary current (or voltage) such that the desired force is exerted by the MR damper. The proposed inverse model is validated by carrying out experimental tests. In addition, a comparison of simulated tests with other damper controllers is also presented. Results show the effectiveness of the network inversion for inverse modeling of an MR damper. Thus, the proposed inverse model can act as a damper controller to generate the command current (or voltage) to track the desired damping force.

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