Mark William Kennedy scite author profile

In the current study, the morphology including tortuosity, and the permeability of 50-mm thick commercially available 30, 40, 50, and 80 pores per inch (PPI) alumina ceramic foam filters (CFFs) have been investigated. Measurements have been taken of cell (pore), window, and strut sizes, porosity, tortuosity, and liquid permeability. Water velocities from~0.015 to 0.77 m/s have been used to derive both first-order (Darcy) and second-order (Non-Darcy) terms for being used with the Forchheimer equation. Measurements were made using 49-mm ''straight through'' and 101-mm diameter ''expanding flow field'' designs. Results from the two designs are compared with calculations made using COMSOL 4.2a Ò 2D axial symmetric finite element modeling (FEM), as a function of velocity and filter PPI. Permeability results are correlated using directly measurable parameters and compared with the previously published results. Development of improved wall sealing (49 mm) and elimination of wall effects (101 mm) have led to a high level of agreement between experimental, analytic, and FEM methods (±0 to 7 pct on predicted pressure drop) for both types of experiments. Tortuosity has been determined by two inductive methods, one using cold-solidified samples at 60 kHz and the other using liquid metal at 50 Hz, giving comparable results.

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Analysis on Experimental Investigation and Mathematical Modeling of Incompressible Flow Through Ceramic Foam Filters

Akbarnejad

Jonsson

Kennedy

et al. 2016

Metall Mater Trans B

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Empirical Verification of a Short-Coil Correction Factor

Kennedy

Akhtar

Bakken

et al. 2014

IEEE Trans. Ind. Electron.

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An Investigation on Permeability of Ceramic Foam Filters (CFF)

Akbarnejad

Kennedy

Fritzsch

et al. 2015

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Electromagnetically Modified Filtration of Aluminum Melts—Part I: Electromagnetic Theory and 30 PPI Ceramic Foam Filter Experimental Results

Kennedy

Akhtar

Bakken

et al. 2013

Metall Mater Trans B

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