Energy Optimization in Process Systems and Fuel Cells
Autor Stanislaw Sieniutycz, Jacek Jezowskien Limba Engleză Paperback – 16 mai 2018
This third edition contains substantial revisions and modifications, with new material on catalytic reactors, sorption systems, sorbent or catalyst regenerators, dryers, and more.
- Presents a unified approach to the optimization and integration of energy systems
- Includes a large number of examples treating dynamical systems
- Provides exposition showing the power of thermodynamics
- Contains a large number of maximum power analyses and their extensions
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Specificații
ISBN-13: 9780081025574
ISBN-10: 0081025572
Pagini: 812
Dimensiuni: 152 x 229 mm
Greutate: 1.07 kg
Ediția:3
Editura: ELSEVIER SCIENCE
ISBN-10: 0081025572
Pagini: 812
Dimensiuni: 152 x 229 mm
Greutate: 1.07 kg
Ediția:3
Editura: ELSEVIER SCIENCE
Public țintă
Graduate students and researchers in chemical, mechanical, materials and environmental engineering, as well as those engaged in system theory, operation research, chemistry, applied physics, applied mathematicsCuprins
1. Brief review of static optimization methods
2. Dynamic optimization problems
3. Energy limits for thermal engines and heat pumps at steady states
4. Hamiltonian optimization of imperfect cascades
5. Maximum power from solar energy
6. Hamilton-Jacobi-Bellman theory of energy systems
7. Numerical optimization in allocation, storage and recovery of thermal energy and resources
8. Optimal control of separation processes
9. Optimal decisions for chemical reactors
10. Fuel cells and limiting performance of electro-chemo-biological system
11. Systems theory in thermal and chemical engineering. Heat integration within process integration
12. Maximum heat recovery and its consequences for process system design
13. Targeting and supertargeting in heat exchanger network (HEN) design
14. Minimum utility cost (MUC) target by optimization approaches
15. Minimum number of units (MNU) and minimum total surface area (MTA) targets
16. Simultaneous HEN targeting for total annual cost
17. Heat exchanger network synthesis
18. Heat exchanger network retrofit
19. Approaches to water network design
2. Dynamic optimization problems
3. Energy limits for thermal engines and heat pumps at steady states
4. Hamiltonian optimization of imperfect cascades
5. Maximum power from solar energy
6. Hamilton-Jacobi-Bellman theory of energy systems
7. Numerical optimization in allocation, storage and recovery of thermal energy and resources
8. Optimal control of separation processes
9. Optimal decisions for chemical reactors
10. Fuel cells and limiting performance of electro-chemo-biological system
11. Systems theory in thermal and chemical engineering. Heat integration within process integration
12. Maximum heat recovery and its consequences for process system design
13. Targeting and supertargeting in heat exchanger network (HEN) design
14. Minimum utility cost (MUC) target by optimization approaches
15. Minimum number of units (MNU) and minimum total surface area (MTA) targets
16. Simultaneous HEN targeting for total annual cost
17. Heat exchanger network synthesis
18. Heat exchanger network retrofit
19. Approaches to water network design