Chichester, England : , : Wiley, , 2015

©2015

1-118-67255-0

1-118-67274-7

1-118-67283-6

1 online resource (307 p.)

660/.2832

Membrane reactors

Inglese

Description based upon print version of record.

Includes bibliographical references and index at the end of each chapters.

Inorganic Membrane Reactors: Fundamentals and Applications; Copyright; Contents; Preface; Chapter 1 Fundamentals of Membrane Reactors; 1.1 Introduction; 1.2 Membrane and Membrane Separation; 1.2.1 Membrane Structure; 1.2.2 Membrane Separation; 1.2.3 Membrane Performance; 1.3 Inorganic Membranes; 1.3.1 Types of Inorganic Membranes; 1.3.2 Fabrication of Inorganic Membranes; 1.3.3 Characterization of Inorganic Membranes; 1.3.4 Applications of Inorganic Membranes; 1.4 Inorganic Membrane Reactors; 1.4.1 Basic Principles of Membrane Reactors; 1.4.2 Incorporation of Catalyst in Membrane Reactors

1.4.3 Configuration of Membrane Reactors1.4.4 Classification of Membrane Reactors; References; Chapter 2 Porous Membrane Reactors; 2.1 Introduction; 2.2 Gas Permeation in Porous Membranes; 2.2.1 Types of Porous Membranes; 2.2.2 Transport Mechanisms; 2.2.3 Gas Permeation Flux through Porous Membranes; 2.3 Preparation of Porous Membranes; 2.3.1 Dip-Coating Method; 2.3.2 Sol-Gel Method; 2.3.3 Chemical Vapor Deposition Method; 2.3.4 Phase Inversion Method; 2.3.5 Other Preparation Methods; 2.4 Porous Membranes for Chemical Reactions; 2.4.1 Membrane Materials; 2.4.2 Membrane Functions

2.5 Catalysis in Porous Membrane Reactors2.5.1 Catalyst in Membrane

Reactors; 2.5.2 Catalyst Deposition in Porous Membranes; 2.6 Operation of Porous Membrane Reactors; 2.6.1 Packed Bed Membrane Reactors; 2.6.2 Catalytic Membrane Reactors; 2.6.3 Coupling of Membrane Functions; 2.6.4 Non-uniform Distribution of Membrane Permeability; 2.7 Applications of Porous Membrane Reactors; 2.7.1 Dehydrogenation Reactions; 2.7.2 Reforming Reactions for Hydrogen Production; 2.7.3 Partial Oxidation Reactions; 2.7.4 Gas-Liquid-Solid Multiphase Reactions; 2.7.5 Other Reactions; 2.8 Prospects and Challenges

NotationReferences; Chapter 3 Zeolite Membrane Reactors; 3.1 Introduction; 3.2 Permeation in Zeolite Membranes; 3.2.1 Types of Zeolite Membranes; 3.2.2 Transport Mechanisms; 3.2.3 Permeation Flux in Zeolite Membranes; 3.3 Preparation of Zeolite Membranes; 3.3.1 In-Situ Crystallization Method; 3.3.2 Secondary Growth Method; 3.3.3 Vapor-Phase Transport Method; 3.3.4 Microwave Synthesis Method; 3.4 Configuration of Zeolite Membrane Reactors; 3.4.1 Packed Bed Membrane Reactor; 3.4.2 Catalytic Membrane Reactor; 3.4.3 Pervaporation Membrane Reactor; 3.4.4 Membrane Microreactor

3.5 Applications of Zeolite Membrane Reactors3.5.1 Dehydrogenation Reactions; 3.5.2 Dehydration Reactions; 3.5.3 Oxidative Reactions; 3.5.4 Isomerization Reactions; 3.6 Prospects and Challenges; Notation; References; Chapter 4 Dense Metallic Membrane Reactors; 4.1 Introduction; 4.2 Gas Permeation in Dense Metallic Membranes; 4.2.1 Types of Dense Metallic Membranes; 4.2.2 Hydrogen Permeation Mechanism in Pd-Based Membranes; 4.2.3 Effect of Substrate on H2 Permeation; 4.3 Preparation of Dense Metallic Membranes; 4.3.1 Cold-Rolling and Diffusion Welding Method; 4.3.2 Electroless Plating Method

4.3.3 Electroplating Method

Membrane reactors combine membrane functions such as separation, reactant distribution, and catalyst support with chemical reactions in a single unit. The benefits of this approach include enhanced conversion, increased yield, and selectivity, as well as a more compact and cost-effect design of reactor system. Hence, membrane reactors are an effective route toward chemical process intensification.   This book covers all types of porous membrane reactors, including ceramic, silica, carbon, zeolite, and dense metallic reactors such as Pd or Pd-alloy, oxygen ion-conducting, and proton-conducting