Optimizing Thermal, Chemical and Environmental Systems treats the evaluation of power or energy limits for processes that arise in various thermal, chemical and environmental engineering systems (heat and mass exchangers, power converters, recovery units, solar collectors, mixture separators, chemical reactors, catalyst regenerators, etc.). The book is an indispensable source for researchers and students, providing the necessary information on what has been achieved to date in the field of process optimization, new research problems, and what kind of further studies should be developed within quite specialized optimizations.…mehr
Optimizing Thermal, Chemical and Environmental Systems treats the evaluation of power or energy limits for processes that arise in various thermal, chemical and environmental engineering systems (heat and mass exchangers, power converters, recovery units, solar collectors, mixture separators, chemical reactors, catalyst regenerators, etc.). The book is an indispensable source for researchers and students, providing the necessary information on what has been achieved to date in the field of process optimization, new research problems, and what kind of further studies should be developed within quite specialized optimizations.
Stanislaw Sieniutycz is a former member of the Committee of Engineering at the Polish Academy of Sciences and also a professor of chemical engineering at the Warsaw University of Technology, Poland. His research focuses on problems of chemical, environmental, ecological, and biomechanical engineering with emphasis on analysis, control, and optimization of these systems. He is a former member of the Editorial Board of Open System and Information Dynamics and an honorary editor of the Journal of Non-Equilibrium Thermodynamics. He has served as an associate editor of Advances in Thermodynamics Series and Energy & Conversion Management. He has published 12 books, 250 articles, and 152 conference papers. He has been a visiting professor at the University of Budapest, University of Bern, University of San Diego, University of Delaware, and University of Chicago.
Inhaltsangabe
1. Outline of Classical Optimization Methods2. Finite Rate Optimization of Steady Thermal Units 3. Neural Networks for Emission Prediction of Dust Pollutants 4. Neural NetworksdA Review of Applications 5. Uncontrolled FluideSolid Systems in Chemistry 6. Maximum Power in Homogeneous Chemical Systems 7. Maximum Conversion in Processes With Chemical Reactions 8. Reactors With Catalyst Decay and Regeneration 9. Fuel Cells and Other Electrochemical Systems 10. Optimizing Circulation Reactor With Deactivating Catalyst 11. Optimizing Reactore-Regenerator System With Catalytic Parallel-Consecutive Reactions 12. Maximum Principle and Other Criteria of Dynamic OptimizationdAn Unconventional Approach
1. Outline of Classical Optimization Methods2. Finite Rate Optimization of Steady Thermal Units 3. Neural Networks for Emission Prediction of Dust Pollutants 4. Neural NetworksdA Review of Applications 5. Uncontrolled FluideSolid Systems in Chemistry 6. Maximum Power in Homogeneous Chemical Systems 7. Maximum Conversion in Processes With Chemical Reactions 8. Reactors With Catalyst Decay and Regeneration 9. Fuel Cells and Other Electrochemical Systems 10. Optimizing Circulation Reactor With Deactivating Catalyst 11. Optimizing Reactore-Regenerator System With Catalytic Parallel-Consecutive Reactions 12. Maximum Principle and Other Criteria of Dynamic OptimizationdAn Unconventional Approach
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