Interception efficiency in two-dimensional flow past confined porous cylinders

Shahsavari, Setareh; Wardle, Brian L.; McKinley, Gareth H.

doi:10.1016/j.ces.2014.05.054

Cited by 13 publications

(3 citation statements)

References 29 publications

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“…Examples include coal particles in power stations, suspended sediment in coastal waters, and catalyst clusters in fluidized bed reactors. The permeability of the particle can affect the flow pattern as well as particle-fluid interactions to various extents (Chen & Cai 1999;Bhattacharyya, Dhinakaran & Khalili 2006;Shahsavari, Wardle & McKinley 2014). Nonetheless, there have been no investigations about the rotation of porous particles in fluid flow, apart from a very recent theoretical analysis by Masoud, Stone & Shelley (2013) on the rotation of porous ellipsoids in an unbounded simple shear flow.…”

Section: Introductionmentioning

confidence: 99%

On the rotation of a circular porous particle in 2D simple shear flow with fluid inertia

Liu

2016

J. Fluid Mech.

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We investigate numerically the rotational behaviour of a circular porous particle suspended in a two-dimensional (2D) simple shear flow with fluid inertia at particle shear Reynolds number up to 108. We use the volume-averaged macroscopic momentum equation to formulate the flow field inside and outside the moving porous particle, which is solved by a modified single relaxation time lattice Boltzmann method. The effects of fluid inertia, confinement of the bounding walls, and permeability of the particle are studied. Our two-dimensional simulation results confirm that the permeability has little effect on the rotation of a porous particle in unbounded shear flow without fluid inertia (Masoud, Stone & Shelley, J. Fluid Mech., vol. 733, 2013, R6), but also suggest that the role of permeability cannot be neglected when the confinement effect is significant, or the fluid inertia is not negligible. The fluid inertia and the confined walls have similar effects on the rotation of a porous particle as that on a solid impermeable particle. The angular velocity decays with an increase in fluid inertia, and the confinement effect suppresses the angular velocity to a shear rate ratio below 0.5. A simple scaling argument based on the balance of torque exerted by fluid flows adjacent to the two bounding walls and that due to the flow recirculation can explain our results.

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Section: Introductionmentioning

confidence: 99%

On the rotation of a circular porous particle in 2D simple shear flow with fluid inertia

Liu

2016

J. Fluid Mech.

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“…While flow around solid objects is a popular problem in aerodynamics, flow around porous objects has only recently begun to be investigated within in the past few decades, using either high fidelity numerical simulation or experiments [78][79][80][81][82]. Here, we present an example of flow past a porous cylinder using the LBM.…”

Section: Flow Past a Porous Cylinder (Via Lattice Boltzmann)mentioning

confidence: 99%

Suite-CFD: An Array of Fluid Solvers Written in MATLAB and Python

Battista¹

2020

Fluids

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Computational Fluid Dynamics (CFD) models are being rapidly integrated into applications across all sciences and engineering. CFD harnesses the power of computers to solve the equations of fluid dynamics, which otherwise cannot be solved analytically except for very particular cases. Numerical solutions can be interpreted through traditional quantitative techniques as well as visually through qualitative snapshots of the flow data. As pictures are worth a thousand words, in many cases such visualizations are invaluable for understanding the fluid system. Unfortunately, vast mathematical knowledge is required to develop one’s own CFD software and commercial software options are expensive and thereby may be inaccessible to many potential practitioners. To that extent, CFD materials specifically designed for undergraduate education are limited. Here we provide an open-source repository, which contains numerous popular fluid solvers in 2 D (projection, spectral, and Lattice Boltzmann), with full implementations in both MATLAB and Python3. All output data is saved in the . v t k format, which can be visualized (and analyzed) with open-source visualization tools, such as VisIt or ParaView. Beyond the code, we also provide teaching resources, such as tutorials, flow snapshots, measurements, videos, and slides to streamline use of the software.

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“…Modeling has suggested that changing the CNT elements' geometry to optimize the flow interception at a given pressure drop and fluid volumetric flow rate enhances polymer and bioparticle interception with the CNT surfaces 67 . The recorded intensity via confocal imaging is likely to be conservative and may underestimate the count because of several factors: (1) Fabrication of the microfluidic devices requires inverted imaging, i.e., through the PDMS because of the opacity of silicon.…”

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confidence: 99%

Layer-by-layer functionalized nanotube arrays: A versatile microfluidic platform for biodetection

et al. 2015

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We demonstrate the layer-by-layer (LbL) assembly of polyelectrolyte multilayers (PEM) on three-dimensional nanofiber scaffolds. High porosity (99%) aligned carbon nanotube (CNT) arrays are photolithographically patterned into elements that act as textured scaffolds for the creation of functionally coated (nano)porous materials. Nanometer-scale bilayers of poly(allylamine hydrochloride)/poly(styrene sulfonate) (PAH/SPS) are formed conformally on the individual nanotubes by repeated deposition from aqueous solution in microfluidic channels. Computational and experimental results show that the LbL deposition is dominated by the diffusive transport of the polymeric constituents, and we use this understanding to demonstrate spatial tailoring on the patterned nanoporous elements. A proof-of-principle application, microfluidic bioparticle capture using N-hydroxysuccinimide-biotin binding for the isolation of prostate-specific antigen (PSA), is demonstrated.

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Interception efficiency in two-dimensional flow past confined porous cylinders

Cited by 13 publications

References 29 publications

On the rotation of a circular porous particle in 2D simple shear flow with fluid inertia

On the rotation of a circular porous particle in 2D simple shear flow with fluid inertia

Suite-CFD: An Array of Fluid Solvers Written in MATLAB and Python

Layer-by-layer functionalized nanotube arrays: A versatile microfluidic platform for biodetection

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