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Process intensification for sustainable energy conversion / / edited by Fausto Gallucci and Martin van Sint Annaland
| Process intensification for sustainable energy conversion / / edited by Fausto Gallucci and Martin van Sint Annaland |
| Pubbl/distr/stampa | Chichester, England : , : Wiley, , 2015 |
| Descrizione fisica | 1 online resource (408 p.) |
| Disciplina | 660/.28 |
| Soggetto topico |
Chemical processes
Renewable energy sources Green chemistry |
| ISBN |
1-118-44937-1
1-118-44939-8 |
| Formato | Materiale a stampa  |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Cover; Title Page; Copyright; Contents; Preface; List of Contributors; Chapter 1 Introduction; References; Chapter 2 Cryogenic CO2 Capture; 2.1 Introduction-CCS and Cryogenic Systems; 2.1.1 Carbon Capture and Storage; 2.1.2 Cryogenic separation; 2.2 Cryogenic Packed Bed Process Concept; 2.2.1 Capture Step; 2.2.2 CO2 Recovery Step; 2.2.3 H2O Recovery and Cooling Step; 2.3 Detailed Numerical Model; 2.3.1 Model Description; 2.3.2 Simulation Results; 2.3.3 Simplified Model: Sharp Front Approach; 2.3.4 Model Description; 2.3.5 Process Analysis; 2.3.6 Initial Bed Temperature
2.3.7 CO2 Inlet Concentration2.3.8 Inlet Temperature; 2.3.9 Bed Properties; 2.4 Small-Scale Demonstration (Proof of Principle); 2.4.1 Results of the Proof of Principle; 2.5 Experimental Demonstration of the Novel Process Concept in a Pilot-Scale Set-Up; 2.5.1 Experimental Procedure; 2.5.2 Experimental Results; 2.5.3 Simulations for the Proof of Concept; 2.5.4 Radial Temperature Profiles; 2.5.5 Influence of the Wall; 2.6 Techno-Economic Evaluation; 2.6.1 Process Evaluation; 2.6.2 Parametric Study; 2.6.3 Comparison with Absorption and Membrane Technology; 2.7 Conclusions 2.8 Note for the ReaderList of symbols; Greek letters; Subscripts; References; Chapter 3 Novel Pre-Combustion Power Production: Membrane Reactors; 3.1 Introduction; 3.2 The Membrane Reactor Concept; 3.3 Types of Reactors; 3.3.1 Packed Bed Membrane Reactors; 3.3.2 Fluidized Bed Membrane Reactors; 3.3.3 Membrane Micro-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 Fabrication4.4 High-temperature ceramic oxygen separation membrane system on laboratory scale; 4.4.1 Oxygen permeation measurements and sealing dense MIEC ceramic membranes; 4.4.2 BaxSr1-xCo1-xFeyO3-δ and LaxSr1-xCo1-yFeyO3-δ Membranes; 4.4.3 Chemical Stability of Perovskite Membranes Under Flue-Gas Conditions; 4.4.4 CO2-Tolerant MIEC Membranes; 4.5 Integration of High-Temperature O2 Transport Membranes into Oxy-Fuel Process: Real World and Economic Feasibility; 4.5.1 Four-End and Three-End Integration Modes; 4.5.2 Pilot-Scale Membrane Systems 4.5.3 Further Scale-Up of O2 Production SystemsReferences; Chapter 5 Chemical Looping Combustion for Power Production; 5.1 Introduction; 5.2 Oxygen carriers; 5.2.1 Nickel-based OCs; 5.2.2 Iron-based OCs; 5.2.3 Copper-based OCs; 5.2.4 Manganese-based OCs; 5.2.5 Other Oxygen Carriers; 5.2.6 Sulfur Tolerance; 5.3 Reactor Concepts; 5.3.1 Interconnected Fluidized Bed Reactors; 5.3.2 Packed Bed Reactors; 5.3.3 Rotating Reactor; 5.4 The Integration of CLC Reactor in Power Plant; 5.4.1 Natural Gas Power Plant with CLC; 5.4.2 Coal-Based Power Plant with CLC 5.4.3 Comparison between CLC in packed beds and circulated fluidized beds |
| Record Nr. | UNINA-9910140643703321 |
| Chichester, England : , : Wiley, , 2015 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Process intensification for sustainable energy conversion / / edited by Fausto Gallucci and Martin van Sint Annaland
| Process intensification for sustainable energy conversion / / edited by Fausto Gallucci and Martin van Sint Annaland |
| Pubbl/distr/stampa | Chichester, England : , : Wiley, , 2015 |
| Descrizione fisica | 1 online resource (408 p.) |
| Disciplina | 660/.28 |
| Soggetto topico |
Chemical processes
Renewable energy sources Green chemistry |
| ISBN |
1-118-44937-1
1-118-44939-8 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Cover; Title Page; Copyright; Contents; Preface; List of Contributors; Chapter 1 Introduction; References; Chapter 2 Cryogenic CO2 Capture; 2.1 Introduction-CCS and Cryogenic Systems; 2.1.1 Carbon Capture and Storage; 2.1.2 Cryogenic separation; 2.2 Cryogenic Packed Bed Process Concept; 2.2.1 Capture Step; 2.2.2 CO2 Recovery Step; 2.2.3 H2O Recovery and Cooling Step; 2.3 Detailed Numerical Model; 2.3.1 Model Description; 2.3.2 Simulation Results; 2.3.3 Simplified Model: Sharp Front Approach; 2.3.4 Model Description; 2.3.5 Process Analysis; 2.3.6 Initial Bed Temperature
2.3.7 CO2 Inlet Concentration2.3.8 Inlet Temperature; 2.3.9 Bed Properties; 2.4 Small-Scale Demonstration (Proof of Principle); 2.4.1 Results of the Proof of Principle; 2.5 Experimental Demonstration of the Novel Process Concept in a Pilot-Scale Set-Up; 2.5.1 Experimental Procedure; 2.5.2 Experimental Results; 2.5.3 Simulations for the Proof of Concept; 2.5.4 Radial Temperature Profiles; 2.5.5 Influence of the Wall; 2.6 Techno-Economic Evaluation; 2.6.1 Process Evaluation; 2.6.2 Parametric Study; 2.6.3 Comparison with Absorption and Membrane Technology; 2.7 Conclusions 2.8 Note for the ReaderList of symbols; Greek letters; Subscripts; References; Chapter 3 Novel Pre-Combustion Power Production: Membrane Reactors; 3.1 Introduction; 3.2 The Membrane Reactor Concept; 3.3 Types of Reactors; 3.3.1 Packed Bed Membrane Reactors; 3.3.2 Fluidized Bed Membrane Reactors; 3.3.3 Membrane Micro-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 Fabrication4.4 High-temperature ceramic oxygen separation membrane system on laboratory scale; 4.4.1 Oxygen permeation measurements and sealing dense MIEC ceramic membranes; 4.4.2 BaxSr1-xCo1-xFeyO3-δ and LaxSr1-xCo1-yFeyO3-δ Membranes; 4.4.3 Chemical Stability of Perovskite Membranes Under Flue-Gas Conditions; 4.4.4 CO2-Tolerant MIEC Membranes; 4.5 Integration of High-Temperature O2 Transport Membranes into Oxy-Fuel Process: Real World and Economic Feasibility; 4.5.1 Four-End and Three-End Integration Modes; 4.5.2 Pilot-Scale Membrane Systems 4.5.3 Further Scale-Up of O2 Production SystemsReferences; Chapter 5 Chemical Looping Combustion for Power Production; 5.1 Introduction; 5.2 Oxygen carriers; 5.2.1 Nickel-based OCs; 5.2.2 Iron-based OCs; 5.2.3 Copper-based OCs; 5.2.4 Manganese-based OCs; 5.2.5 Other Oxygen Carriers; 5.2.6 Sulfur Tolerance; 5.3 Reactor Concepts; 5.3.1 Interconnected Fluidized Bed Reactors; 5.3.2 Packed Bed Reactors; 5.3.3 Rotating Reactor; 5.4 The Integration of CLC Reactor in Power Plant; 5.4.1 Natural Gas Power Plant with CLC; 5.4.2 Coal-Based Power Plant with CLC 5.4.3 Comparison between CLC in packed beds and circulated fluidized beds |
| Record Nr. | UNINA-9910808632903321 |
| Chichester, England : , : Wiley, , 2015 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||