Wake structure of laminar flow past a sphere under the influence of a transverse magnetic field

Pan, Jun-Hua; Zhang, Nian-Mei; Ni, Ming-Jiu

doi:10.1017/jfm.2019.423

Cited by 8 publications

(2 citation statements)

References 29 publications

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“…Moreover, this numerical solver has already been proven to be accurate in simulating the MHD flow past a rigid sphere with body-fitted grids, as presented by Pan et al. (2018) and Pan, Zhang & Ni (2019). Herein, we just replace the rigid sphere by an (two) oblate bubble(s) through imposing the free-slip boundary condition at the bubble interface.…”

Section: Problem Statement and The Numerical Methodsmentioning

confidence: 93%

A numerical study of a bubble pair rising side by side in external magnetic fields

Zhang

2021

J. Fluid Mech.

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The motion of a pair of bubbles rising side by side under the influence of external magnetic fields is numerically examined. Through solving the fully three-dimensional Navier–Stokes equations, the results reveal that the bubble interactions are rather sensitive to the field direction and strength. At first, we identify that, in a hydrodynamic flow, whether the two bubbles will bounce or coalesce depends on the developments of the counter-rotating streamwise vortices during the collision. In particular, for an originally bouncing bubble pair, a streamwise magnetic field tends to promote their coalescence by weakening the strengths of the standing streamwise vortices, and such a weakening effect is caused by the asymmetric distribution of the Lorentz force in the presence of another bubble such that a torque is induced to offset the original streamwise vortices. Under a horizontal magnetic field, on the other hand, the influences are highly dependent on the angle between the bubble centroid line and the field: a transverse field or a moderate spanwise field always leads the bubble pair to coalescence while a strong spanwise field has the opposite effect. This anisotropic effect comes from the Lorentz force induced flow diffusion along the magnetic field, which not only produces two pairs of streamwise vortices at the bubble rear, but also homogenizes the pressure along the magnetic lines. As the competition between the two mechanisms varies with the magnetic direction and strength, the interaction between the bubble pair also changes. We show that the external magnetic fields control the bubble interaction through reconstructing the vortex structures, and hence the core mechanisms are identified.

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Section: Problem Statement and The Numerical Methodsmentioning

confidence: 93%

A numerical study of a bubble pair rising side by side in external magnetic fields

Zhang

2021

J. Fluid Mech.

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“…Tamoor et al [21] investigated that the Newtonian MHD Casson fluid heating features are addressed by stretched cylinders moving at a linear velocity. Pan et al [22][23][24] numerically investigated the effects of instability and transition of a vertical ascent or drop in a free field affected by a vertical magnetic field. Furthermore, they examined that the magnetic field can be used to destabilise the fluid solid system Chen et al [25] numerically studied the effects of turbulent shear flow in the cylindrical container of an electrically conducting fluid.…”

Section: Introductionmentioning

confidence: 99%

Numerical Computation of MHD Thermal Flow of Cross Model over an Elliptic Cylinder: Reduction of Forces via Thickness Ratio

Majeed

Rasheed

Abbasi

et al. 2021

Mathematical Problems in Engineering

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The present work is concerned with a comprehensive analysis of hydrodynamic forces, under MHD and forced convection thermal flow over a heated cylinder in presence of insulated plates installed at walls. The magnetic field is imposed in the transverse direction of flow. The Galerkin finite element (GFE) scheme has been used to discretize the two-dimensional system of nonlinear partial different equations. The study is executed for the varying range of flow behavior index n from 0.4 to 1.6, Hartmann number Ha from 0 to 100, Reynolds number Re from 10 to 50, Grashof number Gr from 1 to 10, thickness ratio e from 0.5 to 1.0, and Prandtl number Pr from 1 to 10, respectively. A coarse hybrid computational grid is developed, and further refinement is carried out for obtaining the highly accurate solution. The optimum case selection is based on flow patterns, drag and lift coefficients, and pressure drop reduction against cylinder thickness ratios and average Nusselt numbers. Drag coefficient increases with an increase in thickness ratio e . The drag force reduction for e = 0.5 and e = 0.75 is also observed for a range of the power law index as compared with e = 1.0 cylinder. Maximum pressure drop over the back and front points of cylinder is reported at Ha = 100 .

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Electromagnetic interaction between a permanent magnet and a sphere moving in liquid metal

2021

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Wake structure of laminar flow past a sphere under the influence of a transverse magnetic field

Cited by 8 publications

References 29 publications

A numerical study of a bubble pair rising side by side in external magnetic fields

A numerical study of a bubble pair rising side by side in external magnetic fields

Numerical Computation of MHD Thermal Flow of Cross Model over an Elliptic Cylinder: Reduction of Forces via Thickness Ratio

Electromagnetic interaction between a permanent magnet and a sphere moving in liquid metal

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