A SPH solver for simulating paramagnetic solid fluid interaction in the presence of an external magnetic field

•SPH was developed for simulating magnetorheological fluids at micro-scale.•Magnetic flux continuity was directly imposed modifying the force calculation.•Benchmarks solved involving magneto-hydrodynamic interaction of solid bodies.•Stress responses of a sheared suspended magnetic chain was investig...

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Published in:Applied mathematical modelling 2016-04, Vol.40 (7-8), p.4341-4369
Main Authors: Hashemi, M.R., Manzari, M.T., Fatehi, R.
Format: Article
Language:English
Subjects:
Chains
Computational fluid dynamics
Computer simulation
Fluid flow
Fluids
Magnetic fields
Magnetorheology
Magnetostatics
Mathematical analysis
Mathematical models
Particulate flow
Smoothed particle hydrodynamics (SPH)
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cited_by cdi_FETCH-LOGICAL-c373t-ad302725421b83a42816f4544d1ab56fcc86c3845821b78a8122cfc2033be1d33
cites cdi_FETCH-LOGICAL-c373t-ad302725421b83a42816f4544d1ab56fcc86c3845821b78a8122cfc2033be1d33
container_end_page 4369
container_issue 7-8
container_start_page 4341
container_title Applied mathematical modelling
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creator Hashemi, M.R.
Manzari, M.T.
Fatehi, R.
description •SPH was developed for simulating magnetorheological fluids at micro-scale.•Magnetic flux continuity was directly imposed modifying the force calculation.•Benchmarks solved involving magneto-hydrodynamic interaction of solid bodies.•Stress responses of a sheared suspended magnetic chain was investigated. The Smoothed Particle Hydrodynamics (SPH) method is extended to solve magnetostatic problems involving magnetically interacting solid bodies. In order to deal with the jump in the magnetic permeability at a fluid-solid interface, a consistent SPH scheme is utilized and a modified formulation is proposed to calculate the magnetic force density along the interface. The results of the magnetostatic solver are verified against those of the finite element method. The governing fluid flow equations are discretized using the same SPH scheme, developing an efficient method for simulating the motion of paramagnetic solid bodies in a fluid flow. The proposed algorithm is applied to a benchmark problem including a suspended paramagnetic solid body moving under the influence of a non-uniform magnetic field and the result is validated against literature. The proposed method is further verified by simulating the magneto-hydrodynamic interaction of two suspended circular cylinders. As a more complex test-case, the evolution of a suspended magnetic chain under the influence of a rotating magnetic field is also simulated. The deformation of a chain formed by a number of paramagnetic solid bodies in a shear flow is simulated. Steady state and dynamic responses of the magnetic chain are investigated under steady and oscillatory shear flows. The effects of Reynolds number, solid volume fraction, strength of the external magnetic field and the number of solid bodies forming the chain, are discussed.
doi_str_mv 10.1016/j.apm.2015.11.020
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The Smoothed Particle Hydrodynamics (SPH) method is extended to solve magnetostatic problems involving magnetically interacting solid bodies. In order to deal with the jump in the magnetic permeability at a fluid-solid interface, a consistent SPH scheme is utilized and a modified formulation is proposed to calculate the magnetic force density along the interface. The results of the magnetostatic solver are verified against those of the finite element method. The governing fluid flow equations are discretized using the same SPH scheme, developing an efficient method for simulating the motion of paramagnetic solid bodies in a fluid flow. The proposed algorithm is applied to a benchmark problem including a suspended paramagnetic solid body moving under the influence of a non-uniform magnetic field and the result is validated against literature. The proposed method is further verified by simulating the magneto-hydrodynamic interaction of two suspended circular cylinders. 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The Smoothed Particle Hydrodynamics (SPH) method is extended to solve magnetostatic problems involving magnetically interacting solid bodies. In order to deal with the jump in the magnetic permeability at a fluid-solid interface, a consistent SPH scheme is utilized and a modified formulation is proposed to calculate the magnetic force density along the interface. The results of the magnetostatic solver are verified against those of the finite element method. The governing fluid flow equations are discretized using the same SPH scheme, developing an efficient method for simulating the motion of paramagnetic solid bodies in a fluid flow. The proposed algorithm is applied to a benchmark problem including a suspended paramagnetic solid body moving under the influence of a non-uniform magnetic field and the result is validated against literature. The proposed method is further verified by simulating the magneto-hydrodynamic interaction of two suspended circular cylinders. 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subjects Chains
Computational fluid dynamics
Computer simulation
Fluid flow
Fluids
Magnetic fields
Magnetorheology
Magnetostatics
Mathematical analysis
Mathematical models
Particulate flow
Smoothed particle hydrodynamics (SPH)
title A SPH solver for simulating paramagnetic solid fluid interaction in the presence of an external magnetic field
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