- Design of power plant processes: Calculation and design of heat transfer and of polytropic processes in turbomachinery
- Design of combustion processes: heat of combution calculations of different fuels, calculation of boiler systems
- Calculation of combined heat and power systems
- Illustration of the key components of a fossil fuel power station using case studies
Module MV-SAM-M137-M-4
Conventional Energy Technology (M, 5.0 LP)
Module Identification
Module Number | Module Name | CP (Effort) |
---|---|---|
MV-SAM-M137-M-4 | Conventional Energy Technology | 5.0 CP (150 h) |
Basedata
CP, Effort | 5.0 CP = 150 h |
---|---|
Position of the semester | 1 Sem. in WiSe |
Level | [4] Bachelor (Specialization) |
Language | [DE] German |
Module Manager | |
Lecturers | |
Area of study | [MV-SAM] Fluid Mechanics and Turbomachinery |
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. | |
---|---|---|---|---|---|---|---|---|---|---|
2V+2U | MV-SAM-86359-K-5 | Conventional Energy Technology
| P | 56 h | 94 h | - | - | PL1 | 5.0 | WiSe |
- About [MV-SAM-86359-K-5]: Title: "Conventional Energy Technology"; Presence-Time: 56 h; Self-Study: 94 h
Examination achievement PL1
- Form of examination: written or oral examination
- Examination Frequency: each semester
- Examination number: 10366
("Conventional Energy Technology")
Written (180 minutes) or oral (30-45 minutes) examination
Evaluation of grades
The grade of the module examination is also the module grade.
Contents
Competencies / intended learning achievements
1. Lecture:
The students are able to
- develop power plant processes and analyse them with regard to the energy flow
- differentiate between power plant processes with regard to ideal and polytropic change of state
- optimise given power plant processes from real examples and propose solutions
- list the advantages of a combined heat and power system, describe them and implement them in a given example.
2. Exercise:
The students are able to
- apply the contents of the lecture to calculation examples in individual and team work
- present their proposed solutions defend them and criticise and evaluate other proposed solutions
Literature
- Baehr, H. D. & Kabelac, S., Thermodynamik - Grundlagen und technische Anwendungen, Springer, 2009
- Strauss, K., Kraftwerkstechnik - zur Nutzung fossiler, nuklearer und regenerativer Energiequellen, Springer,2006
Requirements for attendance (informal)
Modules:
- [MV-LTD-B130-M-4] Energy process and systems engineering (M, 3.0 LP)
- [MV-SAM-B129-M-4] Introduction to Energy Technology (M, 5.0 LP)
- [MV-TD-18-M-4] Thermodynamics I (M, 5.0 LP)
Requirements for attendance (formal)
None
References to Module / Module Number [MV-SAM-M137-M-4]
Course of Study | Section | Choice/Obligation |
---|---|---|
[MV-88.B10-SG] M.Sc. Energy and Process Engineering | Pflichtmodule | [P] Compulsory |
Module-Pool | Name | |
[MV-ALL-MPOOL-6] | Wahlpflichtmodule allgemein | |
[MV-PE-MPOOL-6] | Wahlpflichtmodule Produktentwicklung im Maschinenbau |
Notes on the module handbook of the department Mechanical and Process Engineering
Ausnahmen: