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Simulation and investigation of magnetorheological fluid brake

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Wieslaw Lyskawinski; Wojciech Szelag; Cezary Jedryczka
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Abstract:

The paper deals with coupled electromagnetic, hydrodynamic and mechanical motion phenomena in magnetorheological fluid (or simply MRF) brakes. The governing equations of ...Show More

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Abstract:

The paper deals with coupled electromagnetic, hydrodynamic and mechanical motion phenomena in magnetorheological fluid (or simply MRF) brakes. The governing equations of these phenomena are presented. The numerical implementation of the mathematical model is based on the finite element method. Elaborated computer program is used to simulate the operation of MRF brake prototype. In order to verify elaborated algorithm and program, the investigation of the prototype of MR brake is carried out. The dynamic properties as well as mechanical and control characteristics of the brake are determined. The influence of MR fluid properties on functional parameters of the brake is also considered. Chosen results of simulations and measurements are presented.
Published in: 2008 13th International Power Electronics and Motion Control Conference
Date of Conference: 01-03 September 2008
Date Added to IEEE Xplore: 30 September 2008
ISBN Information:
DOI: 10.1109/EPEPEMC.2008.4635624
Conference Location: Poznan, Poland
References is not available for this document.
Contents

I. Introduction

The characteristic feature of MRF is a dependence of their viscosity on magnetic field. A change in viscosity is inseparably connected with a change of yield stress in the fluid. The relationship between the yield stress and the magnetic flux density for MRF-132LD produced by Lord Corporation is shown in Fig. 1. The stress changes during the increase and decrease of magnetic flux density occur in microseconds [3], [6], [15]. The fluids retain their properties in the temperature range from-40°C to 150°C. The B-H characteristic for MRF 132LD is shown in Fig. 2. Relative magnetic permeability of the fluid is small, .

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