Suchergebnis: Katalogdaten im Herbstsemester 2019
Chemie- und Bioingenieurwissenschaften Master | ||||||
Master-Studium (Studienreglement 2018) | ||||||
Kernfächer | ||||||
Prozessentwurf | ||||||
Nummer | Titel | Typ | ECTS | Umfang | Dozierende | |
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529-0643-01L | Process Design and Development IMPORTANT NOTICE for Chemical and Bioengineering students: There are two different version of this course for the two regulations (2005/2018), please make sure to register for the correct version according to the regulations you are enrolled in. Please do not register for this course if you are enrolled in regulations 2005. | W+ | 6 KP | 3G | G. Storti | |
Kurzbeschreibung | The course is focused on the design of Chemical Processes, with emphasis on the preliminary stage of the design approach, where process creation and quick selection among many alternatives are important. The main concepts behind more detailed process design and process simulation are also examined in the last part of the course. | |||||
Lernziel | The course is focused on the design of Chemical Processes, with emphasis on the preliminary stage of the design approach, where process creation and quick selection among many alternatives are important. The main concepts behind more detailed process design and process simulation are also examined in the last part of the course. | |||||
Inhalt | Process creation: decomposition strategies (reduction of differences - vinyl chloride production and hierarchical decomposition - ethanol production). Identification of the "base case design". Heuristics for process synthesis. Preliminary process evaluation: simplified material and energy balances (linear balances), degrees of freedom, short-cut models, flowsheet solution algorithm). Process Integration: sequencing of distillation columns, synthesis of heat exchanger networks. Process economic evaluation: equipment sizing and costing, time value of money, cash flow calculations. Batch Processes: scheduling, sizing and inventories. Detailed Process Design: unit operation models, flash solution algorithms (different iterative methods, inside-out method), sequencing of nonideal distillation columns, networks of chemical reactors. | |||||
Skript | no script | |||||
Literatur | L.T.Biegler et al., Systematic Methods of Chemical Process Design, Prentice Hall, 1997. W.D.Seider et al., Process Design Principles, J. Wiley & Sons, 1998. J.M.Douglas, Conceptual Design of Chemical Processes, McGraw-Hill, 1988. | |||||
Voraussetzungen / Besonderes | Prerequisite: Thermal Unit Operations | |||||
529-0613-01L | Process Simulation and Flowsheeting IMPORTANT NOTICE for Chemical and Bioengineering students: There are two different version of this course for the two regulations (2005/2018), please make sure to register for the correct version according to the regulations you are enrolled in. Please do not register for this course if you are enrolled in regulations 2005. | W+ | 6 KP | 3G | G. Guillén Gosálbez | |
Kurzbeschreibung | This course encompasses the theoretical principles of chemical process simulation, as well as its practical application in process analysis and optimization. The techniques for simulating stationary and dynamic processes are presented, and illustrated with case studies. Commercial software packages are presented as a key engineering tool for solving process flowsheeting and simulation problems. | |||||
Lernziel | This course aims to develop the competency of chemical engineers in process flowsheeting and simulation. Specifically, students will develop the following skills: - Deep understanding of chemical engineering fundamentals: the acquisition of new concepts and the application of previous knowledge in the area of chemical process systems and their mechanisms are crucial to intelligently simulate and evaluate processes. - Modeling of general chemical processes and systems: students have to be able to identify the boundaries of the system to be studied and develop the set of relevant mathematical relations, which describe the process behavior. - Mathematical reasoning and computational skills: the familiarization with mathematical algorithms and computational tools is essential to be capable of achieving rapid and reliable solutions to simulation and optimization problems. Hence, students will learn the mathematical principles necessary for process simulation and optimization, as well as the structure and application of process simulation software. Thus, they will be able develop criteria to correctly use commercial software packages and critically evaluate their results. | |||||
Inhalt | Overview of process simulation and flowsheeting - Definition and fundamentals - Fields of application - Case studies Process simulation - Modeling strategies of process systems - Mass and energy balances and degrees of freedom of process units and process systems Process flowsheeting - Flowsheet partitioning and tearing - Solution methods for process flowsheeting - Simultaneous methods - Sequential methods Process optimization and analysis - Classification of optimization problems - Linear programming - Non-linear programming - Optimization methods in process flowsheeting Commercial software for simulation: Aspen Plus - Thermodynamic property methods - Reaction and reactors - Separation / columns - Convergence, optimisation & debugging | |||||
Literatur | An exemplary literature list is provided below: - Biegler, L.T., Grossmann I.E., Westerberg A.W., 1997, systematic methods of chemical process design. Prentice Hall, Upper Saddle River, US. - Boyadjiev, C., 2010, Theoretical chemical engineering: modeling and simulation. Springer Verlag, Berlin, Germany. - Ingham, J., Dunn, I.J., Heinzle, E., Prenosil, J.E., Snape, J.B., 2007, Chemical engineering dynamics: an introduction to modelling and computer simulation. John Wiley & Sons, United States. - Reklaitis, G.V., 1983, Introduction to material and energy balances. John Wiley & Sons, United States. | |||||
Voraussetzungen / Besonderes | A basic understanding of material and energy balances, thermodynamic property methods and typical unit operations (e.g., reactors, flash separations, distillation/absorption columns etc.) is required. |
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