Dynamischer Default-Fachbereich geändert auf MV

Notes on the module handbook of the department Mechanical and Process Engineering

Die hier dargestellten veröffentlichten Studiengang-, Modul- und Kursdaten des Fachbereichs Maschinenbau und Verfahrenstechnik ersetzen die Modulbeschreibungen im KIS und wuden mit Ausnahme folgender Studiengänge am 28.10.2020 verabschiedet.

Ausnahmen:

BSc. Bio- und Chemieingenieurwissenschaften (Stand WS 20/21): https://www.mv.uni-kl.de/fileadmin/mv/Studium_Lehre/Modulhandbuecher/MH_BSc_BCI.pdf
BEd. Lehramt Metalltechnik (Stand WS 19/20): https://www.mv.uni-kl.de/fileadmin/mv/Studium_Lehre/Modulhandbuecher/MHB_Bachelor_Lehramt_Metalltechnik.pdf
MSc. Bio- und Chemieingenieurwissenschaften (Stand WS 20/21): https://www.mv.uni-kl.de/fileadmin/mv/Studium_Lehre/Modulhandbuecher/MH_Msc_BCI.pdf
MEd. Lehramt Metalltechnik Werkstoffe und Fertigung (Stand WS 19/20): https://www.mv.uni-kl.de/fileadmin/mv/Studium_Lehre/Modulhandbuecher/MHB_Master_Lehramt_Metalltechnik_-_Werkstoffe_und_Fertigung.pdf
MEd. Lehramt Metalltechnik Maschinen- und Fahrzeugtechnik (Stand WS 19/20): https://www.mv.uni-kl.de/fileadmin/mv/Studium_Lehre/Modulhandbuecher/MHB_Master_Lehramt_Metalltechnik_-_Fahrzeugtechnik.pdf
MEd. Lehramt Metalltechnik Verfahrenstechnik (Stand WS 19/20): https://www.mv.uni-kl.de/fileadmin/mv/Studium_Lehre/Modulhandbuecher/MHB_Master_Lehramt_Metalltechnik_-_Verfahrenstechnik.pdf

Course MV-SAM-86356-K-4

Turbomachinery I (2V+2U, 4.0 LP)

Course Type

SWS	Type	Course Form	CP (Effort)	Presence-Time / Self-Study
-	K	Lecture with exercise classes (V/U)	4.0 CP		64 h
2	V	Lecture		28 h
2	U	Lecture hall exercise class		28 h
(2V+2U)			4.0 CP	56 h	64 h

Basedata

SWS	2V+2U
CP, Effort	4.0 CP = 120 h
Position of the semester	1 Sem. in WiSe
Level	[4] Bachelor (Specialization)
Language	[DE] German
Lecturers	Roclawski, Harald, Dr.-Ing. (WMA \| DEPT: MV)
Area of study	[MV-SAM] Fluid Mechanics and Turbomachinery
Additional informations
Livecycle-State	[NORM] Active

Introduction to design and work principle of axial, diagonal and radial turbomachinery
Euler equation of turbomachinery
Power and work machines
Thermal and hydraulic turbomachinery
Application of the conservation principles of thermodynamics on turbomachinery
Application examples of turbomachinery in thermodynamic cycles
1-D theory of turbomachinery
Characteristic numbers and maps
Affinity laws
Euler differential equation of relative flow

Competencies / intended learning achievements

1. Lecture

The students will be able:

to describe the design and work principles of turbomachinery
to explain the principle of energy conversion in turbomachinery
to apply the 1D theory of turbomachinery to different machine types
to work with characteristic numbers and maps
to analyze flows in turbomachinery

2. Tutorial

The students will be able:

to calculate the energy conversion in turbomachinery
to apply the conservation equations of thermodynamics to turbomachinery
to sketch and calculate the velocity components for turbomachinery
to calculate the characteristic numbers and maps of turbomachinery

Literature

C. Pfleiderer, H. Petermann: Strömungsmaschinen, Springer Verlag, Berlin, 1991
P. Hill, C. Peterson: Mechanics and Thermodynamics Propusion, Addison-Wesley Publishing Company, New York, 1992

Materials

Blackboard, projector. For further information and course materials please consider the corresponding OLAT-course.

Requirements for attendance (informal)

Modules:

Requirements for attendance (formal)

None

References to Course [MV-SAM-86356-K-4]

Module	Name	Context
[MV-SAM-31-M-4]	Turbomachinery I	P: Obligatory	2V+2U, 4.0 LP

Module Handbook