ConFluReM

Key Info

Basic Information

Coordinator:
Portrait: Prof. Dr. Matthias Wessling © Copyright: Stefan Hense
Prof. Dr. Matthias Wessling
Faculty:
Mathematics, Computer Science and Natural Sciences
Organizational Unit:
Chair of Chemical Process Engineering
Pillar:
Excellent Science
Project duration:
01.09.2016 to 31.08.2021
EU contribution:
2.500.000 euros
 

Title

Controlling Fluid Resistances at Membranes

Concept

Today’s materials research in the field of synthetic membranes gives access to highly permeable and extremely selective membranes. However, their potential will remain ineffective as high and selective transport rates always go along with resistances emerging at the membrane fluid interface in the form diffusion limitations in the laminary boundary layers. In order to make full use of the very many new materials, also new means to control and minimize such fluid based resistances need to be developed. Yet another phenomena disturbs the full potential use of membranes: retained solutes, colloids and biological matter accumulates at the membrane interface and causes irreversible fouling and scaling.

The proposed research aims to develop a rigorous translational methodology to control and improve mass transport through the fluid/membrane interface. ConFluReM will establish Strategic Tools and New Instruments to:

(1) comprehend and quantify the prevalent mass transport resistances in representative membrane separation processes,
(2) synthesize and fabricate new nano-, micro- and mesoscale material and device systems as instruments to control and overcome the limitations of concentration polarization and fouling,

Strategic Tools are experimental and simulation methods to quantify and engineer the mass transport and hydrodynamical properties of the new membrane systems. These encompass flow imaging (flowMRI, microPIV and microfluidic transport studies) as well as computational fluidic dynamics (CFD and CFDEM). New Instruments are synthetic and fabrication means as well as process condition means to improve mixing at the membrane/fluid interface. These encompass (a) lateral patterning of chemical topology of the membrane surface by printing and stamping, (b) shaping the 3D geometry of channels using additive manufacturing techniques and (c) imposing dynamical gradients to destablize fluid side resistances.

Additional information

This grant is hosted at DWI - Lebniz Institute for Interactive Materials.