Cargando…
Handbook of process integration. minimisation of energy and water use, waste and emissions / Klemes, Waste and emissions :
Since its first development in the 1970s, Process Integration (PI) has become an important methodology in achieving more energy efficient processes. This pioneering handbook brings together the leading scientists and researchers currently contributing to PI development, pooling their expertise and s...
| Clasificación: | Libro Electrónico |
|---|---|
| Formato: | Electrónico eBook |
| Idioma: | Inglés |
| Publicado: |
Oxford, UK :
Woodhead Publishing,
2013.
|
| Colección: | Woodhead Publishing in energy ;
no. 61. |
| Temas: | |
| Acceso en línea: | Texto completo |
Tabla de Contenidos:
- Cover; Handbook of Process Integration (PI): Minimisation of Energy and Water Use, Waste and Emissions; Copyright; Contents; Contributor contact details; Woodhead Publishing Series in Energy; Foreword; Part I Overview of Process Integration and Analysis; 1 Process Integration (PI): An Introduction; 1.1 Introduction; 1.2 A Short History of Process Integration (PI); 1.3 Current Centres of Expertise in PI; 1.4 Sources of Further Information; 1.5 References; 2 Basic Process Integration Terminology; 2.1 Introduction; 2.2 Process Integration Terms: The Importance of Context.
- 2.3 Fundamental Process Integration Terms2.4 Conventions: Symbols for Heaters and Coolers; 2.5 References; 2.6 Appendix: Nomenclature; 3 Process Design, Integration and Optimisation: Advantages, Challenges and Drivers; 3.1 Introduction; 3.2 Grassroots Design versus Retrofit Design; 3.3 Process Integration; 3.4 Integration versus Intensification; 3.5 Process Integration Techniques; 3.6 Optimisation of Integrated Processes; 3.7 Controllability of Integrated Processes; 3.8 Process Integration under Disturbances; 3.9 References; Part II Heat Integration.
- 4 Heat Integration: Targets and Heat Exchanger Network Design4.1 Introduction; 4.2 Stages in the Design of Heat Recovery Systems; 4.3 Data Extraction; 4.4 Performance Targets; 4.5 Process Modifications; 4.6 Network Design; 4.7 Design Evolution; 4.8 Conclusion; 4.9 Sources of Further Information; 4.10 References; 5 Application of Process Integration to the Synthesis of Heat and Power UtilitySystems Including Combined Heat and Power (CHP) and Industrial Heat Pumps; 5.1 Introduction; 5.2 Targeting Utility Loads and Temperature Levels.
- 5.3 Integration of Advanced Energy Conversion Cycles as Process Utilities: Basic Concepts5.4 Process Integration of Heat Engines; 5.5 Process Integration of Heat Pumps; 5.6 Sources of Further Information and Advice; 5.7 References; 6 Total Site Methodology; 6.1 Introduction; 6.2 Data Extraction for Total Sites; 6.3 Total Site Profiles and Total Site Composite Curves; 6.4 Site Utility Grand Composite Curve (SUGCC); 6.5 Conclusion; 6.6 Sources of Further Information; 6.7 References; 7 Extending Total Site Methodology to Address Varying Energy Supply and Demand; 7.1 Introduction.
- 7.2 Characteristics of Energy Supply and Demand7.3 Thermal Energy Storage and Integrated Architecture; 7.4 Terminology for Process Streams and Utilities; 7.5 Identification of Time Slices; 7.6 Heat Cascades for the Evaluation of Total Site Targets When There Is Variation in Supply and Demand; 7.7 Case Study: Integration of Solar Thermal Energy into a Locally Integrated Energy Sector (LIES); 7.8 Conclusion; 7.9 Sources of Further Information; 7.10 References; 7.11 Appendix: Nomenclature; 8Analysis and Design of Heat Recovery Systems for Grassroots and Retrofit Situations; 8.1 Introduction.