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Pinch analysis and process integration [[electronic resource] ] : a user guide on process integration for the efficient use of energy / / by Ian Kemp
| Pinch analysis and process integration [[electronic resource] ] : a user guide on process integration for the efficient use of energy / / by Ian Kemp |
| Autore | Kemp Ian C |
| Edizione | [2nd ed.] |
| Pubbl/distr/stampa | Oxford, : Butterworth-Heinemann, 2007 |
| Descrizione fisica | 1 online resource (415 p.) |
| Disciplina | 660.281 |
| Soggetto topico |
Chemical plants - Energy conservation
Chemical processes Chemical process control |
| Soggetto genere / forma | Electronic books. |
| ISBN |
1-280-74752-8
9786610747528 0-08-046826-8 |
| Formato | Materiale a stampa  |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Front Cover; Pinch Analysis and Process Integration; Copyright page; Contents; Foreword; Foreword to the first edition; Preface; Acknowledgements; Figure acknowledgements; Chapter 1: Introduction; 1.1 What is pinch analysis?; 1.2 History and industrial experience; 1.3 Why does pinch analysis work?; 1.4 The concept of process synthesis; 1.5 The role of thermodynamics in process design; 1.5.1 How can we apply thermodynamics practically?; 1.5.2 Capital and energy costs; 1.6 Learning and applying the techniques; Chapter 2: Key concepts of pinch analysis; 2.1 Heat recovery and heat exchange
2.1.1 Basic concepts of heat exchange 2.1.2 The temperature-enthalpy diagram; 2.1.3 Composite curves; 2.1.4 A targeting procedure: the ""Problem Table""; 2.1.5 The grand composite curve and shifted composite curves; 2.2 The pinch and its significance; 2.3 Heat exchanger network design; 2.3.1 Network grid representation; 2.3.2 A ""commonsense"" network design; 2.3.3 Design for maximum energy recovery; 2.3.4 A word about design strategy; 2.4 Choosing ΔT[sub(min)]: supertargeting; 2.4.1 Further implications of the choice of ΔT[sub(min)]; 2.5 Methodology of pinch analysis 2.5.1 The range of pinch analysis techniques 2.5.2 How to do a pinch study; Exercise; Chapter 3: Data extraction and energy targeting; 3.1 Data extraction; 3.1.1 Heat and mass balance; 3.1.2 Stream data extraction; 3.1.3 Calculating heat loads and heat capacities; 3.1.4 Choosing streams; 3.1.5 Mixing; 3.1.6 Heat losses; 3.1.7 Summary guidelines; 3.2 Case study: organics distillation plant; 3.2.1 Process description; 3.2.2 Heat and mass balance; 3.2.3 Stream data extraction; 3.2.4 Cost data; 3.3 Energy targeting; 3.3.1 ΔT[sub(min)] contributions for individual streams; 3.3.2 Threshold problems 3.4 Multiple utilities 3.4.1 Types of utility; 3.4.2 The Appropriate Placement principle; 3.4.3 Constant-temperature utilities; 3.4.4 Utility pinches; 3.4.5 Variable-temperature utilities; 3.4.6 Balanced composite and grand composite curves; 3.4.7 Choice of multiple utility levels; 3.5 More advanced energy targeting; 3.5.1 Zonal targeting; 3.5.2 Pressure drop targeting; 3.6 Targeting heat exchange units, area and shells; 3.6.1 Targeting for number of units; 3.6.2 Targeting for the minimum number of units; 3.6.3 Area targeting; 3.6.4 Deviations from pure countercurrent flow 3.6.5 Number of shells targeting 3.6.6 Performance of existing systems; 3.6.7 Topology traps; 3.7 Supertargeting: cost targeting for optimal ΔT[sub(min)]; 3.7.1 Trade-offs in choosing ΔT[sub(min)]; 3.7.2 Illustration for two-stream example; 3.7.3 Factors affecting the optimal ΔT[sub(min)]; 3.7.4 Approximate estimation of ideal ΔT[sub(min)]; 3.8 Targeting for organics distillation plant case study; 3.8.1 Energy targeting; 3.8.2 Area targeting; 3.8.3 Cost targeting; 3.8.4 Zonal targeting; 3.8.5 Targeting with utility streams included 3.9 Appendix: Algorithms for Problem Table and composite curves |
| Record Nr. | UNINA-9910457691603321 |
Kemp Ian C
|
||
| Oxford, : Butterworth-Heinemann, 2007 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Pinch analysis and process integration [[electronic resource] ] : a user guide on process integration for the efficient use of energy / / by Ian Kemp
| Pinch analysis and process integration [[electronic resource] ] : a user guide on process integration for the efficient use of energy / / by Ian Kemp |
| Autore | Kemp Ian C |
| Edizione | [2nd ed.] |
| Pubbl/distr/stampa | Oxford, : Butterworth-Heinemann, 2007 |
| Descrizione fisica | 1 online resource (415 p.) |
| Disciplina | 660.281 |
| Soggetto topico |
Chemical plants - Energy conservation
Chemical processes Chemical process control |
| ISBN |
1-280-74752-8
9786610747528 0-08-046826-8 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Front Cover; Pinch Analysis and Process Integration; Copyright page; Contents; Foreword; Foreword to the first edition; Preface; Acknowledgements; Figure acknowledgements; Chapter 1: Introduction; 1.1 What is pinch analysis?; 1.2 History and industrial experience; 1.3 Why does pinch analysis work?; 1.4 The concept of process synthesis; 1.5 The role of thermodynamics in process design; 1.5.1 How can we apply thermodynamics practically?; 1.5.2 Capital and energy costs; 1.6 Learning and applying the techniques; Chapter 2: Key concepts of pinch analysis; 2.1 Heat recovery and heat exchange
2.1.1 Basic concepts of heat exchange 2.1.2 The temperature-enthalpy diagram; 2.1.3 Composite curves; 2.1.4 A targeting procedure: the ""Problem Table""; 2.1.5 The grand composite curve and shifted composite curves; 2.2 The pinch and its significance; 2.3 Heat exchanger network design; 2.3.1 Network grid representation; 2.3.2 A ""commonsense"" network design; 2.3.3 Design for maximum energy recovery; 2.3.4 A word about design strategy; 2.4 Choosing ΔT[sub(min)]: supertargeting; 2.4.1 Further implications of the choice of ΔT[sub(min)]; 2.5 Methodology of pinch analysis 2.5.1 The range of pinch analysis techniques 2.5.2 How to do a pinch study; Exercise; Chapter 3: Data extraction and energy targeting; 3.1 Data extraction; 3.1.1 Heat and mass balance; 3.1.2 Stream data extraction; 3.1.3 Calculating heat loads and heat capacities; 3.1.4 Choosing streams; 3.1.5 Mixing; 3.1.6 Heat losses; 3.1.7 Summary guidelines; 3.2 Case study: organics distillation plant; 3.2.1 Process description; 3.2.2 Heat and mass balance; 3.2.3 Stream data extraction; 3.2.4 Cost data; 3.3 Energy targeting; 3.3.1 ΔT[sub(min)] contributions for individual streams; 3.3.2 Threshold problems 3.4 Multiple utilities 3.4.1 Types of utility; 3.4.2 The Appropriate Placement principle; 3.4.3 Constant-temperature utilities; 3.4.4 Utility pinches; 3.4.5 Variable-temperature utilities; 3.4.6 Balanced composite and grand composite curves; 3.4.7 Choice of multiple utility levels; 3.5 More advanced energy targeting; 3.5.1 Zonal targeting; 3.5.2 Pressure drop targeting; 3.6 Targeting heat exchange units, area and shells; 3.6.1 Targeting for number of units; 3.6.2 Targeting for the minimum number of units; 3.6.3 Area targeting; 3.6.4 Deviations from pure countercurrent flow 3.6.5 Number of shells targeting 3.6.6 Performance of existing systems; 3.6.7 Topology traps; 3.7 Supertargeting: cost targeting for optimal ΔT[sub(min)]; 3.7.1 Trade-offs in choosing ΔT[sub(min)]; 3.7.2 Illustration for two-stream example; 3.7.3 Factors affecting the optimal ΔT[sub(min)]; 3.7.4 Approximate estimation of ideal ΔT[sub(min)]; 3.8 Targeting for organics distillation plant case study; 3.8.1 Energy targeting; 3.8.2 Area targeting; 3.8.3 Cost targeting; 3.8.4 Zonal targeting; 3.8.5 Targeting with utility streams included 3.9 Appendix: Algorithms for Problem Table and composite curves |
| Record Nr. | UNINA-9910784349003321 |
|
Kemp Ian C
|
||
| Oxford, : Butterworth-Heinemann, 2007 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Pinch analysis and process integration : a user guide on process integration for the efficient use of energy / / by Ian Kemp
| Pinch analysis and process integration : a user guide on process integration for the efficient use of energy / / by Ian Kemp |
| Autore | Kemp Ian C |
| Edizione | [2nd ed.] |
| Pubbl/distr/stampa | Oxford, : Butterworth-Heinemann, 2007 |
| Descrizione fisica | 1 online resource (415 p.) |
| Disciplina | 660.281 |
| Soggetto topico |
Chemical plants - Energy conservation
Chemical processes Chemical process control |
| ISBN |
1-280-74752-8
9786610747528 0-08-046826-8 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Front Cover; Pinch Analysis and Process Integration; Copyright page; Contents; Foreword; Foreword to the first edition; Preface; Acknowledgements; Figure acknowledgements; Chapter 1: Introduction; 1.1 What is pinch analysis?; 1.2 History and industrial experience; 1.3 Why does pinch analysis work?; 1.4 The concept of process synthesis; 1.5 The role of thermodynamics in process design; 1.5.1 How can we apply thermodynamics practically?; 1.5.2 Capital and energy costs; 1.6 Learning and applying the techniques; Chapter 2: Key concepts of pinch analysis; 2.1 Heat recovery and heat exchange
2.1.1 Basic concepts of heat exchange 2.1.2 The temperature-enthalpy diagram; 2.1.3 Composite curves; 2.1.4 A targeting procedure: the ""Problem Table""; 2.1.5 The grand composite curve and shifted composite curves; 2.2 The pinch and its significance; 2.3 Heat exchanger network design; 2.3.1 Network grid representation; 2.3.2 A ""commonsense"" network design; 2.3.3 Design for maximum energy recovery; 2.3.4 A word about design strategy; 2.4 Choosing ΔT[sub(min)]: supertargeting; 2.4.1 Further implications of the choice of ΔT[sub(min)]; 2.5 Methodology of pinch analysis 2.5.1 The range of pinch analysis techniques 2.5.2 How to do a pinch study; Exercise; Chapter 3: Data extraction and energy targeting; 3.1 Data extraction; 3.1.1 Heat and mass balance; 3.1.2 Stream data extraction; 3.1.3 Calculating heat loads and heat capacities; 3.1.4 Choosing streams; 3.1.5 Mixing; 3.1.6 Heat losses; 3.1.7 Summary guidelines; 3.2 Case study: organics distillation plant; 3.2.1 Process description; 3.2.2 Heat and mass balance; 3.2.3 Stream data extraction; 3.2.4 Cost data; 3.3 Energy targeting; 3.3.1 ΔT[sub(min)] contributions for individual streams; 3.3.2 Threshold problems 3.4 Multiple utilities 3.4.1 Types of utility; 3.4.2 The Appropriate Placement principle; 3.4.3 Constant-temperature utilities; 3.4.4 Utility pinches; 3.4.5 Variable-temperature utilities; 3.4.6 Balanced composite and grand composite curves; 3.4.7 Choice of multiple utility levels; 3.5 More advanced energy targeting; 3.5.1 Zonal targeting; 3.5.2 Pressure drop targeting; 3.6 Targeting heat exchange units, area and shells; 3.6.1 Targeting for number of units; 3.6.2 Targeting for the minimum number of units; 3.6.3 Area targeting; 3.6.4 Deviations from pure countercurrent flow 3.6.5 Number of shells targeting 3.6.6 Performance of existing systems; 3.6.7 Topology traps; 3.7 Supertargeting: cost targeting for optimal ΔT[sub(min)]; 3.7.1 Trade-offs in choosing ΔT[sub(min)]; 3.7.2 Illustration for two-stream example; 3.7.3 Factors affecting the optimal ΔT[sub(min)]; 3.7.4 Approximate estimation of ideal ΔT[sub(min)]; 3.8 Targeting for organics distillation plant case study; 3.8.1 Energy targeting; 3.8.2 Area targeting; 3.8.3 Cost targeting; 3.8.4 Zonal targeting; 3.8.5 Targeting with utility streams included 3.9 Appendix: Algorithms for Problem Table and composite curves |
| Record Nr. | UNINA-9910828005303321 |
|
Kemp Ian C
|
||
| Oxford, : Butterworth-Heinemann, 2007 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
