Determination of optimal magnetorheological fluid particle loading and size for shear mode monotube damper

Magnetorheological (MR) fluids belong to a class of controllable fluids, and the composition and concentration of its components govern its magnetorheological properties. In this study, an optimum particle loading (or mass fraction) and size of iron particles in MR fluid for use in a shear mode mono...

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Bibliographic Details
Published in:Journal of the Brazilian Society of Mechanical Sciences and Engineering 2019-10, Vol.41 (10), p.1-15, Article 392
Main Authors: Acharya, Subash, Saini, Tak Radhe Shyam, Kumar, Hemantha
Format: Article
Language:English
Subjects:
Accumulators
Carbonyls
Computational fluid dynamics
Damping
Engineering
Field strength
Fluids
Genetic algorithms
Iron
Magnetic fields
Magnetic properties
Magnetorheological fluids
Mechanical Engineering
Multiple objective analysis
Optimization
Optimization techniques
Shear
Synthesis
Technical Paper
Variance analysis
Viscosity
Yield strength
Yield stress
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Summary:Magnetorheological (MR) fluids belong to a class of controllable fluids, and the composition and concentration of its components govern its magnetorheological properties. In this study, an optimum particle loading (or mass fraction) and size of iron particles in MR fluid for use in a shear mode monotube MR damper were determined based on the damping force and off-state viscosity of synthesized MR fluid samples. Initially, the morphological and magnetic properties of carbonyl iron particles were characterized. Six MR fluid samples were prepared composed of combination of three different particle loadings and two sizes of iron particles. Magnetorheological tests were conducted on these samples to determine the flow curves at off-state and on-state magnetic field conditions. Herschel–Bulkley model was used for mathematical representation of flow curves at different magnetic fields and to determine their dynamic yield stress. Further, a shear mode monotube MR damper with accumulator was designed by using optimization technique for desired dynamic range and damping force. Magnetostatic analysis was performed to determine the magnetic field strength generated in the shear gap at different currents. The damping force was calculated for synthesized MR fluids based on their dynamic yield stress corresponding to the magnetic field strength in the shear gap. Analysis of variance was performed to analyse the significance of independent factors on the damping force and off-state viscosity of MRF. The optimal particle loading and size which yielded maximum damping force with minimum off-state viscosity were determined using a multi-objective genetic algorithm.
ISSN:1678-5878
1806-3691
DOI:10.1007/s40430-019-1895-4