Drag force on a sphere moving towards a corrugated wall

Masséi, Nicolas; Anthore, R.; Cichocki, B.; Szymczak, Piotr; Feuillebois, François

doi:10.1017/s0022112004009942

Cited by 57 publications

(63 citation statements)

References 25 publications

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“…sistent with early results obtained for a far field situation [19][20][21], but does not support recent AFM data [15]. However, as shown by the simulation data, Eq.…”

contrasting

confidence: 99%

Random-Roughness Hydrodynamic Boundary Conditions

2010

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We report results of lattice Boltzmann simulations of a high-speed drainage of liquid films squeezed between a smooth sphere and a randomly rough plane. A significant decrease in the hydrodynamic resistance force as compared with that predicted for two smooth surfaces is observed. However, this force reduction does not represent slippage. The computed force is exactly the same as that between equivalent smooth surfaces obeying no-slip boundary conditions, but located at an intermediate position between peaks and valleys of asperities. The shift in hydrodynamic thickness is shown to depend on the height and density of roughness elements. Our results do not support some previous experimental conclusions on very large and shear-dependent boundary slip for similar systems.

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“…sistent with early results obtained for a far field situation [19][20][21], but does not support recent AFM data [15]. However, as shown by the simulation data, Eq.…”

contrasting

confidence: 99%

Random-Roughness Hydrodynamic Boundary Conditions

2010

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“…These concern the settling of particles in a quiescent fluid in a gravity field (see, e.g., [8,9]) and particles moving near a vertical wall [10,11]. To the best of the authors' knowledge, the interaction between a particle and a boundary on which a shear stress is imposed in a recirculating flow has not been treated.…”

Section: Introductionmentioning

confidence: 99%

Particle–boundary interaction in a shear-driven cavity flow

Romanò

Kuhlmann

2017

Theor. Comput. Fluid Dyn.

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The motion of a heavy finite-size tracer is numerically calculated in a two-dimensional shear-driven cavity. The particle motion is computed using a discontinuous Galerkin-finite-element method combined with a smoothed profile method resolving all scales, including the flow in the lubrication gap between the particle and the boundary. The centrifugation of heavy particles in the recirculating flow is counteracted by a repulsion from the shear-stress surface. The resulting limit cycle for the particle motion represents an attractor for particles in dilute suspensions. The limit cycles obtained by fully resolved simulations as a function of the particle size and density are compared with those obtained by one-way coupling using the Maxey-Riley equation and an inelastic collision model for the particle-boundary interaction, solely characterized by an interaction-length parameter. It is shown that the one-way coupling approach can faithfully approximate the true limit cycle if the interaction length is selected depending on the particle size and its relative density.

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“…Almost all the experimental studies indicate that there is a critical Stokes number, St c ≈ 10, below which no rebound occurs. [44][45][46][47] In the current study, the Stokes number is quite smaller than St c ≈ 10. Therefore, the restitution coefficient is not considered.…”

Section: Particle-wall Collision and Rebounding Processesmentioning

confidence: 47%

Modeling of conductive particle motion in viscous medium affected by an electric field considering particle-electrode interactions and microdischarge phenomenon

2016

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Up and down motion of a spherical conductive particle in dielectric viscous fluid driven by a DC electric field between two parallel electrodes was investigated. A nonlinear differential equation, governing the particle dynamics, was derived, based on Newton's second law of mechanics, and solved numerically. All the pertaining dimensionless groups were extracted. In contrast to similar previous works, hydrodynamic interaction between the particle and the electrodes, as well as image electric forces, has been taken into account. Furthermore, the influence of the microdischarge produced between the electrodes and the approaching particle on the particle dynamics has been included in the model. The model results were compared with experimental data available in the literature, as well as with some additional experimental data obtained through the present study showing very good agreement. The results indicate that the wall hydrodynamic effect and the dielectric liquid ionic conductivity are very dominant factors determining the particle trajectory. A lower bound is derived for the charge transferred to the particle while rebounding from an electrode. It is found that the time and length scales of the post-microdischarge motion of the particle can be as small as microsecond and micrometer, respectively. The model is able to predict the so called settling/dwelling time phenomenon for the first time. Published by AIP Publishing. [http://dx

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Drag force on a sphere moving towards a corrugated wall

Cited by 57 publications

References 25 publications

Random-Roughness Hydrodynamic Boundary Conditions

Random-Roughness Hydrodynamic Boundary Conditions

Particle–boundary interaction in a shear-driven cavity flow

Modeling of conductive particle motion in viscous medium affected by an electric field considering particle-electrode interactions and microdischarge phenomenon

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