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Prediction of polymeric membrane separation and purification performances = a combined mechanical, chemical and thermodynamic model for organic systems /

Record Type:	Language materials, printed : Monograph/item
Title/Author:	Prediction of polymeric membrane separation and purification performances/ by Alexander Anim-Mensah, Rakesh Govind.
Reminder of title:	a combined mechanical, chemical and thermodynamic model for organic systems /
Author:	Anim-Mensah, Alexander.
other author:	Govind, Rakesh.
Published:	Cham :Springer International Publishing : : 2015.,
Description:	xviii, 51 p. :ill., digital ; : 24 cm.;
Contained By:	Springer eBooks
Subject:	Membrane separation. -
Online resource:	http://dx.doi.org/10.1007/978-3-319-12409-4
ISBN:	9783319124094 (electronic bk.)

Prediction of polymeric membrane separation and purification performances = a combined mechanical, chemical and thermodynamic model for organic systems /
Anim-Mensah, Alexander.

Prediction of polymeric membrane separation and purification performancesa combined mechanical, chemical and thermodynamic model for organic systems /[electronic resource] :by Alexander Anim-Mensah, Rakesh Govind. - Cham :Springer International Publishing :2015. - xviii, 51 p. :ill., digital ;24 cm. - SpringerBriefs in molecular science,2191-5407. - SpringerBriefs in molecular science..

Introduction -- Background -- Model Development and Effects of the Various Model Parameters -- Developed Model Application to Aqueous- Organic and Purely Organic Separation and Purification System -- Conclusions -- Future Direction.

This brief describes the development of a new model for realistically characterizing solution-diffusion transport mechanisms in polymeric membranes that are used for separation and purification of organic solvents. Polymeric membranes used in these environments, if not selected appropriately, undergo excessive swelling and compaction resulting in lowered performance or membrane destruction in the long-term. This brief describes the relationship between key parameters from a chemical, mechanical and thermodynamic perspective. Moreover, the authors show how this new model points membrane manufacturers, scientists, and engineers towards an understanding of how these key parameters are considered in (1) designing and manufacturing membranes for the right application, (2) designing the right test experiments to determine the long-term membrane behavior in a short time, (3) minimizing the number of experiments to determine a reliable membrane for an application and (4) selecting the right membrane with higher level of certainty. The overall benefits of the model includes saving money and time. A simplified version of the model is included to assist the reader.

ISBN: 9783319124094 (electronic bk.)

Standard No.: 10.1007/978-3-319-12409-4doiSubjects--Topical Terms:

677819
Membrane separation.

LC Class. No.: TP248.25.M46

Dewey Class. No.: 660.2842

Prediction of polymeric membrane separation and purification performances = a combined mechanical, chemical and thermodynamic model for organic systems /
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245 1 0 $a Prediction of polymeric membrane separation and purification performances $h [electronic resource] : $b a combined mechanical, chemical and thermodynamic model for organic systems / $c by Alexander Anim-Mensah, Rakesh Govind.
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505 0 $a Introduction -- Background -- Model Development and Effects of the Various Model Parameters -- Developed Model Application to Aqueous- Organic and Purely Organic Separation and Purification System -- Conclusions -- Future Direction.
520 $a This brief describes the development of a new model for realistically characterizing solution-diffusion transport mechanisms in polymeric membranes that are used for separation and purification of organic solvents. Polymeric membranes used in these environments, if not selected appropriately, undergo excessive swelling and compaction resulting in lowered performance or membrane destruction in the long-term. This brief describes the relationship between key parameters from a chemical, mechanical and thermodynamic perspective. Moreover, the authors show how this new model points membrane manufacturers, scientists, and engineers towards an understanding of how these key parameters are considered in (1) designing and manufacturing membranes for the right application, (2) designing the right test experiments to determine the long-term membrane behavior in a short time, (3) minimizing the number of experiments to determine a reliable membrane for an application and (4) selecting the right membrane with higher level of certainty. The overall benefits of the model includes saving money and time. A simplified version of the model is included to assist the reader.
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