Process intensification for sustainable energy conversion /

This book addresses the application of process intensification to sustainable energy production, combining two very topical subject areas. Due to the increasing process of petroleum, sustainable energy production technologies must be developed, for example bioenergy, blue energy, chemical looping co...

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Detalles Bibliográficos
Clasificación:Libro Electrónico
Otros Autores: Gallucci, Fausto, Sint Annaland, Martin van
Formato: Electrónico eBook
Idioma:Inglés
Publicado: Chichester, West Sussex, United Kingdom : Wiley, 2015.
Temas:
Chemical processes.
Renewable energy sources.
Green chemistry.
Renewable Energy
Procédés chimiques.
Énergies renouvelables.
Chimie verte.
SCIENCE > Chemistry > Industrial & Technical.
TECHNOLOGY & ENGINEERING > Chemical & Biochemical.
Chemical processes
Green chemistry
Renewable energy sources
Acceso en línea:Texto completo
Tabla de Contenidos:
  • Title Page; Copyright; Table of Contents; Preface; List of Contributors; Chapter 1: Introduction; References; Chapter 2: Cryogenic CO2 Capture; 2.1 Introduction
  • CCS and Cryogenic Systems; 2.2 Cryogenic Packed Bed Process Concept; 2.3 Detailed Numerical Model; 2.4 Small-Scale Demonstration (Proof of Principle); 2.5 Experimental Demonstration of the Novel Process Concept in a Pilot-Scale Set-Up; 2.6 Techno-Economic Evaluation; 2.7 Conclusions; 2.8 Note for the Reader; References; Chapter 3: Novel Pre-Combustion Power Production: Membrane Reactors; 3.1 Introduction.
  • 3.2 The Membrane Reactor Concept3.3 Types of Reactors; 3.4 Conclusions; 3.5 Note for the reader; References; Chapter 4: Oxy Fuel Combustion Power Production Using High Temperature O2 Membranes; 4.1 Introduction; 4.2 MIEC Perovskites as Oxygen Separation Membrane Materials for the Oxy-fuel Combustion Power Production; 4.3 MIEC Membrane Fabrication; 4.4 High-temperature ceramic oxygen separation membrane system on laboratory scale; 4.5 Integration of High-Temperature O2 Transport Membranes into Oxy-Fuel Process: Real World and Economic Feasibility; References.
  • Chapter 5: Chemical Looping Combustion for Power Production5.1 Introduction; 5.2 Oxygen carriers; 5.3 Reactor Concepts; 5.4 The Integration of CLC Reactor in Power Plant; 5.5 Conclusions; References; Chapter 6: Sorption-Enhanced Fuel Conversion; 6.1 Introduction; 6.2 Development in Sorption-Enhanced Processes; 6.3 Sorbent Development; 6.4 Process Descriptions; 6.5 Sorption-Enhanced Reaction Processes in Power Plant for CO2 Capture; 6.6 Conclusions; References; Chapter 7: Pd-Based Membranes in Hydrogen Production for Fuel cells; 7.1 Introduction.
  • 7.2 Characteristics of Fuel Cells and Applications7.3 Centralized and Distributed Hydrogen Production for Energy Applications; 7.4 Pd-Based Membranes; 7.5 Hydrogen Production Using Pd-Based Membranes; 7.6 Process Intensification by Microstructured Membrane Reactors; 7.7 Integration of Pd-Based Membranes and Fuel Cells; 7.8 Final Remarks; Acknowledgements; References; Chapter 8: From Biomass to SNG; 8.1 Introduction; 8.2 Current Status of Bio-SNG Production and Facilities in Europe; 8.3 Bio-SNG Process Configuration; 8.4 Catalytic Systems; 8.5 The Case Study; 8.6 Chemical Efficiency.
  • 8.7 ConclusionsReferences; Chapter 9: Blue Energy: Salinity Gradient for Energy Conversion; 9.1 Introduction; 9.2 Fundamentals of Salinity Gradient Exploitation; 9.3 Pressure Retarded Osmosis Technology; 9.4 The Reverse Electrodialysis Technology; 9.5 Other Salinity Gradient Technologies; 9.6 Osmotic Power Plants Potential; 9.7 Conclusions; References; Chapter 10: Solar Process Heat and Process Intensification; 10.1 Solar Process Heat
  • A Short Technology Review; 10.2 Potential of Solar Process Heat in Industry; 10.3 Bottlenecks for Integration of Solar Process Heat in Industry.
  • 10.4 PI
  • A Promising Approach to Increase the Solar Process Heat Potential?

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