Processing of membranes for oxygenation using the Bellhouse-effect

Neußer, Christine; Bach, Christophe; Doeringer, J.; Jockenhoevel, Stefan

doi:10.1515/cdbme-2015-0028

Cited by 2 publications

(1 citation statement)

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“…Neusser and coworkers recently attempted to transfer the concept of furrowed flow channels to new biohybrid membranes. They developed a setup to transfer a flat sheet oxygenation membrane into a membrane having furrows and seeded them with endothelial cells [22,23].…”

Section: Mass Transport In Furrowed Channelsmentioning

confidence: 99%

Sinusoidal shaped hollow fibers for enhanced mass transfer

Luelf,

Tepper,

Breisig

et al. 2018

Preprint

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Inducing secondary flows and vortices is known to enhance mass transport. They can be imposed by structured flow channels for instance. In particular, these vortices reduce fouling and concentration polarization. In this work we present a new method of producing hollow fiber membranes with a sinusoidal change in diameter over the fiber length. We engineered a pulsation module that imposes a sinusoidally fluctuating bore liquid flow rate. Harmonic bore flow conditions can be varied over a wide range. The fluctuating bore liquid flow rate translates into axial membrane properties varying with respect to inner bore diameter and wall thickness. The resulting narrowing and widening of the membrane lumen channel are hypothesized to induce secondary vortices to the liquid inside the membrane lumen known as the Bellhouse effect. Improved oxygen transport from shell-to-lumen side prove superiority over straight hollow fiber membranes in G/L absorption process. We anticipate the dynamic flow module to be easily integrated into currently existing hollow fiber membrane spinning processes.

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Section: Mass Transport In Furrowed Channelsmentioning

confidence: 99%