Your search keyword '"mass-transfer"' showing total 3 results

1. Approximate models of concentration-polarization in Pd-membrane separators. Fast numerical analysis.

Author

Nekhamkina, Olga and Sheintuch, Moshe

Subjects

*OPTICAL polarizers, *MEMBRANE separation, *PALLADIUM, *NUMERICAL analysis, *MASS transfer

Abstract

Several approximate solutions are derived to predict the concentration polarization effect in a shell-and-tube Pd-membrane empty separator with permeate flow either in the tube or in the shell. The first two approximations (Nekhamkina and Sheintuch (2015) [22] ) are governed by ODEs describing the axial profiles of the average variables coupled with algebraic relations that describe the radial profiles of velocity components and species concentrations. The hydrogen membrane flux is approximated by a mass transfer coefficient k=D (∂ c H2 /∂ r ) w /(〈 c H2 〉− c H2 w ) expressed via the Sherwood number Sh = kd/D which is a geometry-dependent parameter ( D is hydrogen diffusivity, c H2 w = p H 2 , w r e t / RT is its membrane wall concentration and d a characteristic length). Here Sh is obtained by 2-D CFD simulations in a wide range of parameters and when plotted vs the separator length, it reaches an asymptotic value that matches the predicted values and is independent of operating conditions. The third approximation reduces the polarization effect to an algebraic equation by approximating the effectiveness factor η =[( p H 2 , w r e t ) 0.5 −( p H 2 p e r ) 0.5 ]/[〈( p H 2 r e t )〉 0.5 −( p H 2 p e r ) 0.5 ] which depends mainly on the ratio of the mass-transfer coefficient to the membrane permeance parameter Γ = Γ ( Sh ). This expression can be used for fast design of separators that avoids or accounts for polarization effects. The three approximations offer a trade-off between accuracy and ease of application. [ABSTRACT FROM AUTHOR]

Published

2016

2. Application of fluidised particles as turbulence promoters in ultrafiltration Improvement of flux and rejection

Subjects

fluidised beds, CONVECTION PROMOTION, fouling, membranes, LAYER, energy consumption, MASS-TRANSFER, mass transfer, PROTEIN SOLUTIONS, BEDS, CROSS-FLOW, MEMBRANE, TRANSPORT

Abstract

To prevent fouling of ultrafiltration membranes during processing of protein solutions, a high degree of turbulence should be introduced in the feed solution, keeping the energy consumption as low as possible. For this purpose, the application of fluidised beds at the upstream side of the membrane can be very attractive. In this study, the effect of fluidised particles is investigated under non-fouling and fouling conditions. In both systems, mass transfer is increased considerably by addition of fluidised particles. The main mechanism of fouling reduction is by an increased diffusion of rejected solutes from the membrane interface back to the bulk solution. Improvement of mass transfer is only a weak function of particle size and density. Therefore, the particles can be chosen as light and small as possible. This greatly reduces the energy consumption in the system and the risk of membrane damage, which may be a problem. Application of fluidised bed systems can be especially attractive in highly viscous systems in which energy consumption can be a problem. (C) 2002 Elsevier Science Ltd. All rights reserved.

Published

2002

3. Can nanofiltration be fully predicted by a model?

Subjects

membrane characterisation, Maxwell-Stefan equations, REJECTION, nanofiltration, MASS-TRANSFER, charged membrane, salt rejections, CROSS-FLOW, MEMBRANE, PERFORMANCE, TRANSPORT, ULTRAFILTRATION

Abstract

There is an increasing need for model-based tools to design membrane processes for new industrial applications or to optimise existing membrane installations. The advantage of such tools is that costs can be saved by reducing the number of experiments. In this study, the requirements for a membrane filtration model, suitable for practical use, are summarised. It is investigated to what extent it is possible to set-up such a model with the current available literature and knowledge. A membrane filtration model has been set-up based on the Maxwell-Stefan transport equations. A Freundlich equation is used to describe the membrane charge by means of adsorption of ions. With the model the permeate flux and rejections of multi-component liquid feeds can be calculated as a function of membrane properties (mean pore size, porosity, thickness, surface charge characteristic) and feed pressure. With two NF-membranes (Desal 5DK and a prototype capillary type 2 membrane) rejection experiments have been carried out with glucose, single salt solutions (NaCl, CaCl2, Na2SO4) and ternary ion mixtures of these salts. With the model the experimental flux-rejection curves can be fitted reasonably well. However, each salt mixture needs its own set of fitted parameters for the membrane charge isotherms. Furthermore, the fitted membrane charges are in contradiction with values from the literature obtained by electrokinetic measurements. Obviously, the membrane charge parameters have lost their physical meaning and are used to compensate for physical phenomena not included in the model. Extending the model with an electrostatic free energy term will be a step forward in development. Further research is needed to fulfil all requirements for the wide scope of industrial applications. (C) 2002 Elsevier Science B.V. All rights reserved.

Published

2002