- Conceptual process design
- Process flow diagram
- Process simulation
- Distillation fundamentals and practice
- Distillation lines
- Residue curves
- ∞/∞-analysis
- Design of column sequences
- Synthesis and analysis of industrial chemical processes
- Energetic process optimization
- Reactive distillation
Module MV-TD-135-M-7
Process Thermodynamics (M, 4.0 LP)
Module Identification
Module Number | Module Name | CP (Effort) |
---|---|---|
MV-TD-135-M-7 | Process Thermodynamics | 4.0 CP (120 h) |
Basedata
CP, Effort | 4.0 CP = 120 h |
---|---|
Position of the semester | 1 Sem. in SuSe |
Level | [7] Master (Advanced) |
Language | [DE] German |
Module Manager | |
Lecturers | |
Area of study | [MV-LTD] Engineering Thermodynamics |
Reference course of study | [MV-88.B10-SG] M.Sc. Energy and Process Engineering |
Livecycle-State | [NORM] Active |
Courses
Type/SWS | Course Number | Title | Choice in Module-Part | Presence-Time / Self-Study | SL | SL is required for exa. | PL | CP | Sem. | |
---|---|---|---|---|---|---|---|---|---|---|
3V+1U | MV-TD-86054-K-7 | Process Thermodynamics
| P | 56 h | 64 h | - | - | PL1 | 4.0 | SuSe |
- About [MV-TD-86054-K-7]: Title: "Process Thermodynamics"; Presence-Time: 56 h; Self-Study: 64 h
Examination achievement PL1
- Form of examination: oral examination with written preparation (50-65 Min.)
- Examination Frequency: each semester
- Examination number: 10067 ("Process Thermodynamics")
Evaluation of grades
The grade of the module examination is also the module grade.
Contents
Competencies / intended learning achievements
1. Lectures
The students are able to describe and discuss the methods of
- conceptual process design
- distillation process design
- energetic process optimization
2. Excercises
The students are able to apply the learning outcomes of the lecture to process design problems, they are professional in using process simulators, they know how to work in teams and present their results.
Literature
- E. Blaß, Entwicklung verfahrenstechnischer Prozesse: Methoden, Zielsuche, Lösungssuche, Lösungsauswahl. 2., vollst. überarb. Aufl. – Berlin: Springer (1997)
- M.F. Doherty, M.F. Malone, Conceptual design of distillation systems. – Boston: McGraw-Hill (2001)
- H.G. Hirschberg, Handbuch Verfahrenstechnik und Anlagenbau: Chemie, Technik, Wirtschaftlichkeit. – Berlin: Springer (1999)
- K. Sattler, Thermische Trennverfahren: Grundlagen, Auslegung, Apparate. 3. Aufl. – Weinheim: VCH (2001)
- H. Schuler, Prozeßsimulation. – Weinheim: VCH (1995)
Requirements for attendance (informal)
Modules:
- [MV-TD-19-M-4] Thermodynamics II (M, 4.0 LP)
- [MV-TD-56-M-4] Thermodynamics of Mixtures (M, 5.0 LP)
- [MV-TVT-59-M-4] Thermal Separation Processes I (M, 6.0 LP)
Requirements for attendance (formal)
None
References to Module / Module Number [MV-TD-135-M-7]
Course of Study | Section | Choice/Obligation |
---|---|---|
[MV-88.B10-SG] M.Sc. Energy and Process Engineering | Pflichtmodule | [P] Compulsory |
[MV-88.A29-SG] M.Sc. Biological and Chemical Engineering | Studienschwerpunkt II | [P] Compulsory |
Module-Pool | Name | |
[MV-ALL-MPOOL-6] | Wahlpflichtmodule allgemein | |
[MV-BioVT-MPOOL-6] | Wahlpflichtmodule Bioverfahrenstechnik | |
[MV-CE-MPOOL-6] | Wahlpflichtmodule Computational Engineering |
Notes on the module handbook of the department Mechanical and Process Engineering
Ausnahmen: