Part I: Preliminaries

Chapter 1. Introduction to modular process intensification

Chapter 2. Computer-aided modular process intensification: design, synthesis, and operability

Part II: Methodologies

Chapter 3. Phenomena-based synthesis representation for modular process intensification

Chapter 4. Process synthesis, optimization, and intensification

Chapter 5. Enhanced GMF for process synthesis, intensification, and heat integration

Chapter 6. Steady-state flexibility analysis

Chapter 7. Inherent safety analysis

Chapter 8. Multi-parametric model predictive control

Chapter 9. Synthesis of operable process intensification systems

Part III: Case Studies

Chapter 10. Envelope of design solutions for intensified reaction/separation systems

Chapter 11. Process intensification synthesis of extractive separation systems with material selection

Chapter 12. Process intensification synthesis of dividing wall column systems

Chapter 13. Operability and control analysis in modular process intensification systems

Chapter 14. A framework for synthesis of operable and intensified reactive separation systems

Chapter 15. A software prototype for synthesis of operable process intensification systems

Selected References

• Tian, Y., Meduri, V., Bindlish, R., & Pistikopoulos, E. N. (2022). A Process Intensification synthesis framework for the design of dividing wall column systems. Computers & Chemical Engineering, 160, 107679.

• Georgiadis, M. C., Pistikopoulos, E. N. (2006). Energy and Process Integration; Thermal and Fluid Physics and Engineering. Begell House, Inc.

• Papalexandri, K. P., & Pistikopoulos, E. N. (1996). Generalized modular representation framework for process synthesis. AIChE Journal, 42(4), 1010-1032.

Selected References

• Pistikopoulos, E. N., Diangelakis, N. A., Oberdieck, R., Papathanasiou, M. M., Nascu, I., & Sun, M. (2015). PAROC - An integrated framework and software platform for the optimisation and advanced model-based control of process systems. Chemical Engineering Science, 136, 115-138.

• Pistikopoulos, E. N., Diangelakis, N. A., Oberdieck, R. (2020). Multi-parametric Optimization and Control. John Wiley & Sons.

• Burnak, B., Diangelakis, N. A., Pistikopoulos, E. N. (2020) Integrated process design and operational optimization via multi-parametric programming. Morgan & Claypool Publishers.

Selected References

• Tian, Y., & Pistikopoulos, E. N. (2018). Synthesis of operable process intensification systems - Steady-state design with safety and operability considerations. Industrial & Engineering Chemistry Research, 58(15), 6049-6068.

• Pistikopoulos, E. N., Tian, Y., & Bindlish, R. (2021). Operability and control in process intensification and modular design: Challenges and opportunities. AIChE Journal, 67(5), e17204.

• Dimitriadis, V. D., & Pistikopoulos, E. N. (1995). Flexibility analysis of dynamic systems. Industrial & Engineering Chemistry Research, 34(12), 4451-4462.

A number of representative modular and intensified processes are covered, including reactive separation for olefin metathesis and methyl tert-butyl ether production, BTX ternary separation, heterogeneous separation for industrial methyl methacrylate purification, extractive separation using ionic liquid solvents, etc.