Module Handbook

  • 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, bzw. am 13.01.2021 verabschiedet.

Ausnahmen:

Module MV-MEMT-5-M-6

Grundlagen der Energietechnik (M, 8.0 LP)

Module Identification

Module Number Module Name CP (Effort)
MV-MEMT-5-M-6 Grundlagen der Energietechnik 8.0 CP (240 h)

Basedata

CP, Effort 8.0 CP = 240 h
Position of the semester 2 Sem. from WiSe
Level [6] Master (General)
Language [DE] German
Module Manager
Lecturers
Reference course of study [MV-66.108-SG] M.Ed. LaBBS Metals Technology
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-TD-86050-K-4
Thermodynamics I
P 56 h 94 h - - PL1 5.0 WiSe
2V MV-LAF-86308-K-7
Vehicle Propulsion Systems
P 28 h 62 h - - PL2 3.0 SuSe
  • About [MV-TD-86050-K-4]: Title: "Thermodynamics I"; Presence-Time: 56 h; Self-Study: 94 h
  • About [MV-LAF-86308-K-7]: Title: "Vehicle Propulsion Systems"; Presence-Time: 28 h; Self-Study: 62 h

Examination achievement PL1

  • Form of examination: written exam (Klausur) (90 Min.)
  • Examination Frequency: each semester
  • Examination number: 10050 ("Thermodynamics I")
    Prüfungsdauer soll im Rahmen einer PO-Änderung auf 90-120 Min. angepasst werden.

Examination achievement PL2

  • Form of examination: written exam (Klausur) (90 Min.)
  • Examination Frequency: each semester
  • Examination number: 10308 ("Powertrain Engineering")

Evaluation of grades

All partial module examinations have to be passed. The module grade is the weighted average of the partial examination grades according to the following weights:

Gewichtung nach Leistungspunkten

Contents

Die Studierenden verstehen die wesentlichen Grundlagen der Thermodynamik der Verbrennungsmotoren und deren Anwendung in der Technik, insbesondere in den für berufsbildende Schulen wichtigen Gebieten, und beherrschen deren grundlegende Methodik.
  • Thermodynamic system, open and closed, temperature, heat, work
  • 1st law of thermodynamics, energy enthalpy
  • Simple thermal and caloric equations of state of pure fluids: ideal gas, fluid with constant density
  • Properties of pure substances: p,T-diagram, p,v-diagram, p,h-diagram
  • Thermodynamics of fluid process components and machines (turbines, compressors, pumps, nozzles, throttles)
  • Cyclic processes
  • Heat engines, refrigeration engines, heat pumps, efficiency, coefficient of performance.
  • 2nd law of thermodynamics
  • Reversibe and ireversible processes
  • Entropy
  • T,s-diagram und h,s-diagramm
1. Introduction
  • motorcar history
  • definitions and notations
  • automotive mobility
  • forecasts and future development of mobility

2. Basics of Longitudinal Dynamics

  • driving resistances
  • driving dynamics
  • powertrain
  • driving performance

3. Conventional Powertrains

  • internal combustion engines,
  • emissions and environmental impact,
  • fuels and energy sources
  • potentials of conventional powertrains

4. Alternative Propulsion Systems

  • conventional engines operating on alternative fuels
  • hybrid powertrains
  • pure electric powertrains

5. Powertrain Components

  • clutches and torque converters
  • gearboxes
  • drive shafts
  • differential gears
  • exhaust system
  • energy storage
  • vehicle electrics & electronics

Competencies / intended learning achievements

1. Lectures

The students are able to describe and discuss the:

  • basic concepts of thermodynamics
  • methods of thermodynamics
  • laws of thermodynamics
  • thermodynamic properties of pure substances

2. Excercises

The students are able to apply the learning outcomes of the lecture to solve thermodynamic problems

For Bachelor's teaching profession for vocational schools in metal technology:.

Students understand the essentials of thermodynamics and its application in technology, especially in areas important for vocational schools and master its basic methodology.

Students will be able to
  • name and determine the driving resistances of vehicles,
  • distinguish between different drive concepts in terms of layout and characteristics,
  • derive the driving performances from characteristic maps of demand and supply,
  • identify the essential properties and characteristics of conventional powertrains and carry out calculations, e.g. of characteristic values,
  • explain the correlations between pollutant formation, emission and immission as well as possibilities for their mitigation ( engine-internal, engine-external),
  • assess the basic properties and characteristics of conventional and alternative fuels,
  • distinguish between various types of alternative drives - internal combustion engines operated on alternative fuels, hybrid drives, battery-electric drives and fuel cell-electric drives - and to assess their properties and potential,
  • describe the design and properties of various vehicle transmissions, clutches and converters,
  • name the most important properties of other powertrain components such as cardan shafts, differentials, etc.

Literature

  • P. Stephan, K. Schaber, K. Stephan, F. Mayinger: Thermodynamik, Band 1 Einstoffsysteme; 16. Auflage, Springer, Berlin, 2006.
  • M. M. Abbott, H. C. van Ness: Thermodynamik, Theorie und Anwendungen; McGraw-Hill, Hamburg, 1987.
  • H. D. Baehr, S. Kabelac: Thermodynamik; 13. Auflage, Springer, Berlin, 2006.
  • Haken, Karl-Ludwig:„Grundlagen der Kraftfahrzeugtechnik“, Hanser Verlag, München, 1. Auflage, 2008
  • Braess, Hans-Hermann, Seiffert, Ulrich: „Vieweg Handbuch Kraftfahrzeugtechnik“, Vieweg Verlag, Wiesbaden, 5. Auflage, 2007
  • Fischer, Richard, u.a.: „Fachkunde Kraftfahrzeugtechnik“, Europa-Lehrmittel Verlag, Haan-Gruiten, 29. Auflage, 2009
  • Drexl, H.-J.: „Kraftfahrzeugkupplungen“, Verlag Moderne Industrie, Landsberg/Lech, 1997
  • Robert Bosch GmbH: „Kraftfahrtechnisches Taschenbuch“, Plochingen, 26. Auflage, 2007
  • Naunheimer, Harald, Bertsche, Bernd, Lechner, Gisbert: „Fahrzeuggetriebe“, Springer Verlag, Berlin/Heidelberg/New York, 2. Auflage, 2007
  • Steinhilper, Waldemar, Sauer, Bernd: „Konstruktionselemente des Maschinenbaus 2“, Springer Verlag, Berlin/Heidelberg/New York, 6. Auflage, 2008
  • Looman, Johannes: „Zahnradgetriebe“, Springer Verlag, Berlin/Heidelberg/New York, 3.Auflage, 1996, Nachdruck in veränderter Ausstattung 2009
  • Mollenhauer, K., Tschöke, H.: „Handbuch Dieselmotoren“, Springer Verlag, Berlin/New York/ Heidelberg, 3. Auflage, 2007
  • van Basshuysen, R., Schäfer, F.: „Handbuch Verbrennungsmotor“, Vieweg & Teubner Verlag, Wiesbaden, 5. Auflage, 2010
  • Todsen, Uwe: „Verbrennungsmotoren“, Hanser Verlag, München, 1. Auflage, 2012
  • Trzesniowski, Michael: „Rennwagentechnik“, Springer Vieweg Verlag, Wiesbaden, 3. Auflage, 2012

Requirements for attendance of the module (informal)

None

Requirements for attendance of the module (formal)

None

References to Module / Module Number [MV-MEMT-5-M-6]

Course of Study Section Choice/Obligation
[MV-66.108-SG] M.Ed. LaBBS Metals Technology [Core Modules (non specialised)] Maschinen- und Fahrzeugtechnik [P] Compulsory