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100   $a20100525d2011      uy             0
101 0 $aeng
135   $aur|n|---|||||
181   $ctxt
182   $cc
183   $acr
200 00$aMembrane process design using residue curve maps$b[electronic resource] /$fMark Peters ... [et al.]
210   $aHoboken, N.J. $cWiley$d2011
215   $a1 online resource (260 p.)
300   $aDescription based upon print version of record.
311   $a0-470-52431-6 
320   $aIncludes bibliographical references and index.
327   $aMEMBRANE PROCESS DESIGN USING RESIDUE CURVE MAPS; CONTENTS; PREFACE; ACKNOWLEDGMENTS; NOTATION; ABOUT THE AUTHORS; 1 INTRODUCTION; 2 PERMEATION MODELING; 2.1 DIFFUSION MEMBRANES; 2.1.1 Gas Separation; 2.1.2 Pervaporation; 2.2 MEMBRANE CLASSIFICATION; 3 INTRODUCTION TO GRAPHICAL TECHNIQUES IN MEMBRANE SEPARATIONS; 3.1 A THOUGHT EXPERIMENT; 3.2 BINARY SEPARATIONS; 3.3 MULTICOMPONENT SYSTEMS; 3.3.1 Mass Balances; 3.3.2 Plotting a Residue Curve Map; 4 PROPERTIES OF MEMBRANE RESIDUE CURVE MAPS; 4.1 STATIONARY POINTS; 4.2 MEMBRANE VECTOR FIELD; 4.3 UNIDISTRIBUTION LINES
327   $a5.3.5 Operating Regions: Selective Membranes5.4 PERMEATION TIME; 5.5 CONTINUOUS MEMBRANE OPERATION; 5.5.1 Nonreflux Equipment; 5.5.2 Reflux Equipment; 5.6 CONCLUSION; 6 COLUMN PROFILES FOR MEMBRANE COLUMN SECTIONS; 6.1 INTRODUCTION TO MEMBRANE COLUMN DEVELOPMENT; 6.1.1 Relevant Works in Membrane Column Research; 6.2 GENERALIZED COLUMN SECTIONS; 6.2.1 The Difference Point Equation; 6.2.2 Infinite Reflux; 6.2.3 Finite Reflux; 6.2.4 CPM Pinch Loci; 6.3 THEORY; 6.3.1 Membrane Column Sections; 6.3.2 The Difference Point Equation for an MCS; 6.3.3 Permeation Modeling; 6.3.4 Properties of the DPE
327   $a6.4 COLUMN SECTION PROFILES: OPERATING CONDITION 16.4.1 Statement; 6.4.2 Mathematics; 6.4.3 Membrane Residue Curve Map; 6.5 COLUMN SECTION PROFILES: OPERATING CONDITION 2; 6.5.1 Statement; 6.5.2 Mathematics; 6.5.3 Column Profile; 6.5.4 Analysis; 6.5.5 Pinch Point Loci; 6.5.6 Further Column Profiles; 6.5.7 Direction of ?T; 6.5.8 Direction of Integration; 6.5.9 Crossing the MBT Boundary; 6.6 COLUMN SECTION PROFILES: OPERATING CONDITIONS 3 AND 4; 6.6.1 Statement; 6.6.2 Mathematics; 6.6.3 Column Profile; 6.6.4 Pinch Point Loci; 6.6.5 Analysis of Column Profile; 6.6.6 Pinch Point
327   $a6.6.7 Further Column Profiles6.6.8 Variations in X? and r?; 6.7 APPLICATIONS AND CONCLUSION; 7 NOVEL GRAPHICAL DESIGN METHODS FOR COMPLEX MEMBRANE CONFIGURATIONS; 7.1 INTRODUCTION; 7.2 COLUMN SECTIONS; 7.2.1 Definition; 7.2.2 The Difference Point Equation; 7.2.3 Vapor-Liquid Equilibrium and Permeation Flux; 7.2.4 Column Profiles; 7.3 COMPLEX MEMBRANE CONFIGURATION DESIGNS: GENERAL; 7.3.1 Overview; 7.3.2 Petlyuk Membrane Arrangement; 7.3.3 Material Balances; 7.4 COMPLEX MEMBRANE CONFIGURATION DESIGNS: OPERATING CONDITION 1; 7.4.1 Statement; 7.4.2 Mathematics; 7.4.3 Column Profiles
327   $a7.4.4 Requirements for Feasibility
330   $aDesign and Synthesis of Membrane Separation Processes provides a novel method of design and synthesis for membrane separation. While the main focus of the book is given to gas separation and pervaporation membranes, the theory has been developed in such a way that it is general and valid for any type of membrane.     The method, which uses a graphical technique, allows one to calculate and visualize the change in composition of the retentate (non-permeate) phase. This graphical approach is based on Membrane Residue Curve Maps. One of the strengths of this approach is tha
606   $aMembrane separation
606   $aDiffusion
606   $aPervaporation
606   $aGas separation membranes
615  0$aMembrane separation.
615  0$aDiffusion.
615  0$aPervaporation.
615  0$aGas separation membranes.
676   $a660/.28424
701   $aPeters$b Mark$f1981-$0965524
801  0$bMiAaPQ
801  1$bMiAaPQ
801  2$bMiAaPQ
906   $aBOOK
912   $a9910139177503321
996   $aMembrane process design using residue curve maps$92190509
997   $aUNINA