Bachelor Maschinenbau mit Praxissemester

knows the various basic architectures for digital computer architectures
can identify and classify the individual architecture elements
can analyze application scenarios and select suitable architecture features
knows the entire range from the structure level (RTL) to the instruction set level (ISA) and can apply these
can understand and apply architecture manuals and instruction set manuals of current computer architectures
Optimization options for computer architectures (e.g. caching, jump prediction) are understood and can be assessed
knows paradigms such as parallel processing and special areas such as architectures for embedded systems through exemplary insights
can assess and select microcontrollers with regard to their area of application and program them close to the hardware in assembler and C
can use a development environment (using the Keil uVision environment as an example)
can analyze current computer architectures and evaluate and discuss them against the background of their knowledge

Structure and function of the Turing machine as an introductory example of a very rudimentary computer architecture => identification of the basic components arithmetic unit/control unit/memory/instruction set
Structure and function of the integer Java virtual machine according to Tanenbaum
Instruction set (ISA) and microcode, optimization of microcode, explanation of the specifics of ISA in Java byte code, CISC, RISC
Analysis and optimization of the processing pipeline, instruction fetch unit, jump prediction, speculative execution, out-of-order execution
Analysis of memory architecture, caching, memory types (SDRAM, graphics DRAM, SRAM, flash) and architectures
Comparative analysis of Intel Core and Intel Netburst architecture with regard to the above-mentioned topics
Parallel computer architectures, including cache coherence (especially MESI), VLIW
Examples of special computers (mobile processors, data flow computers)
Architectures for embedded systems (including ARM, introduction of DMA and interrupt units)
Atmel AVR as an example for microcontrollers, architecture, ISA, assembler and C programming

Teaching methods

Lecture in interaction with the students, with blackboard writing and projection
Solving practical exercises in individual or team work
Processing programming tasks on the computer in individual or team work

Participation requirements

See the respective valid examination regulations (BPO/MPO) of the study program.

Forms of examination

written exam paper

Requirements for the awarding of credit points

passed written exam

Applicability of the module (in other degree programs)

Bachelor of Medical Informatics
Bachelor of Computer Science
Bachelor of Computer Science
Bachelor of Medical Informatics Dual
Bachelor of Computer Science

Literature

Tanenbaum, A.: Computerarchitektur, 5. Auflage, Pearson, 2006
Yiu, J.: The Definitive Guide to the ARM Cortex M0, Newnes, Elsevier, 2011
Martin, T.: The Designer's Guide to the Cortex-M Processor Family, Newnes, Elsevier, 2013
Brinkschulte, U.; Ungerer, T.: Mikrocontroller und Mikroprozessoren, 3. Auflage, Springer, 2010

Mathematik
PF

6 SWS

8 ECTS

Number
53400
Duration (semester)
1

Statik
PF

4 SWS

5 ECTS

Number
53500
Duration (semester)
1

2. Semester of study

Fertigungstechnik
PF

3 SWS

4 ECTS

Number
53700
Language(s)
de
Duration (semester)
1

Festigkeitslehre
PF

4 SWS

6 ECTS

Number
54100
Duration (semester)
1

Konstruktionselemente I
PF

3 SWS

4 ECTS

Number
54200
Language(s)
de
Duration (semester)
1
Contact time
2 V / 30h; 2 Ü / 30 h
Self-study
90 h

Learning outcomes/competences

The students ...

have knowledge of basic design techniques as well as the use and design of the most common machine elements
can design simple components and demonstrate their durability under static load.
know the essential connection techniques for fixed connections of components and can design and calculate preloaded screw connections and shaft-hub connections in particular.
are able to develop simple designs according to Business Studies and technically feasible criteria
are able to identify and select the necessary information (characteristic values, geometric data, etc.) and compare it with the current state of the art
know the basic procedure for dimensioning machine elements and can apply it to previously unknown machine elements

Basics of component calculation
- Types of stress and calculation of stresses in components
- Material and component strength, strength verifications
Basic rules of design and design guidelines
Bolt connections
Axles, shafts, pivots
Shaft/hub connections
Basics of rolling bearings

Teaching methods

Lecture
Exercise

The lectures convey the theoretical content. Practical problems are dealt with promptly in the corresponding exercises using typical tasks. The solutions are developed and presented individually and in teams.

Participation requirements

Formal:

In order to be admitted to the final module examination, at least 35 ECTS from the first two semesters must have been earned at the time of registration for the examination.

Content:

Knowledge from the modules Statics and Mathematics I and Technical Drawing is strongly recommended

Forms of examination

The module concludes with a written exam.

Duration: 90

Assistance permitted:

Roloff / Matek (textbook and table book)
Non-programmable pocket calculator

In addition, bonus points (up to 1/6 of the total score) can be earned in the four online tests offered. The bonus points are credited to a written exam passed with at least a sufficient grade (4.0). The bonus points can therefore significantly improve the module grade, but are not mandatory for passing the module. They offer an additional opportunity to increase your own performance and improve your grade.
Students will receive precise details on how to complete the module during the first course. Details and dates are described in detail in the corresponding ILIAS course.

Requirements for the awarding of credit points

The module examination must be completed with a minimum grade of sufficient (4.0).

Applicability of the module (in other degree programs)

optional

Importance of the grade for the final grade

2.45 % (see StgPO)

Literature

Spura; Fleischer; et al.: Roloff/Matek Maschinenelemente: Normung, Berechnung, Gestaltung – Lehrbuch und Tabellenbuch. Wiesbaden: Springer Vieweg
Hoischen (Begründer): Technisches Zeichnen: Grundlagen, Normen, Beispiele, Darstellende Geome- trie. Berlin: Cornelsen Scriptor
Decker; et al.: Maschinenelemente Funktion, Gestaltung und Berechnung. München: Hanser Verlag
Haberhauer Maschinenelemente Gestaltung, Berechnung, Anwendung. Springer Vieweg
Sauer: Konstruktionselemente des Maschinenbaus1 Grundlagen der Berechnung und Gestaltung von Maschinenelementen, Springer Vieweg Verlag, Berlin
Schlecht, Bertold: Maschinenelemente 1, Festigkeit, Wellen, Verbindungen, Federn, Kupplungen. München: Pearson
Schlecht, Bertold: Maschinenelemente 2, Getriebe, Verzahnungen, Lagerungen. München; Pearson

Managementmethoden
PF

3 SWS

4 ECTS

Number
53900
Language(s)
de
Duration (semester)
1

Mathematik II
PF

4 SWS

5 ECTS

Number
54000
Duration (semester)
1

Physik
PF

3 SWS

6 ECTS

Number
53300
Duration (semester)
1

Thermodynamik
PF

5 SWS

5 ECTS

Number
53800
Duration (semester)
1
Contact time
-
Self-study
BA-Arbeit: 360 h, Kolloquium: 90 h

Learning outcomes/competences

The thesis demonstrates that students are able to solve a practice-oriented engineering task from their field of specialization within a specified period of 12 weeks using scientific and practical methods.

Bachelor thesis:

The Bachelor's thesis consists of the independent processing of an engineering task (theoretical, constructive, experimental) from the subject area of the Bachelor's degree program. The thesis can be carried out in the laboratories of the faculty, in an industrial company or, in suitable cases, as a written term paper (literature work). The thesis must be submitted in written form to present the applied engineering methods and results.

The Bachelor's thesis typically consists of an analysis, in which the requirements are determined, and the concept, which discusses the alternative solutions and maps the requirements to the existing framework conditions. In addition, there is usually an implementation of particularly important aspects of the concept. The implementation alone does not provide sufficient opportunities to apply methods and findings specific to the profession and is therefore not sufficient for a Bachelor's thesis. The Bachelor's thesis includes a work plan, which students draw up and agree with their supervisors. Such a plan offers opportunities to apply the project management skills acquired in the project and is an important prerequisite for successfully completing the required work in the specified time.

Colloquium:

At the beginning of the colloquium, the student presents the results of their Bachelor's thesis in the form of a presentation. This is followed by an examination discussion.

Teaching methods

Independent, practice-oriented project work. Supervision is provided by a professor and, in the case of industrial work, in cooperation with the project manager in the company.

Participation requirements

Formal:

In order to participate in the Bachelor's thesis and colloquium, at least 180 ECTS credit points must be earned. For further admission requirements, see §29 of the StgPO Mechanical Engineering (2021).

In terms of content: none

Forms of examination

Module examination in the form of a project-related written elaboration, 30 to 45 minutes colloquium including an examination discussion.

Requirements for the awarding of credit points

The Bachelor's examination is passed if all prescribed module examinations, the thesis and the colloquium have each been graded at least "sufficient" (4.0) or "passed".

Applicability of the module (in other degree programs)

none

Importance of the grade for the final grade

15 % thesis; 5 % colloquium

Literature

Basisliteratur:

Lindenlauf, Frank: Wissenschaftliche Arbeiten in den Ingenieur- und Naturwissenschaften: Ein praxisorientierter Leitfaden für Semester- und Abschlussarbeiten. Wiesbaden: Springer Fachmedien, 2022
Hirsch-Weber, Andreas; Scherer, Stefan: Wissenschaftliches Schreiben und Abschlussarbeit in Natur- und Ingenieurwissenschaften: Grundlagen – Praxisbeispiele – Übungen. Stuttgart: Utb Verlag, 2016

Weitere Literatur:

In Abhängigkeit des zu vergebenden Themas wird ein erster Literaturhinweis gegeben. Grundsätzlich gehört zur Bachelor-Thesis eine eigenständige Literaturrecherche.

3. Semester of study

CAD
PF

3 SWS

3 ECTS

Number
54600
Language(s)
de
Duration (semester)
1

Dynamik
PF

4 SWS

5 ECTS

Number
54700
Duration (semester)
1

Elektrotechnik
PF

5 SWS

5 ECTS

Number
54400
Duration (semester)
1

Konstruktionselemente II
PF

5 SWS

7 ECTS

Number
54800
Duration (semester)
1
Contact time
-
Self-study
BA-Arbeit: 360 h, Kolloquium: 90 h

Learning outcomes/competences

Teaching methods

Independent, practice-oriented project work. Supervision is provided by a professor and, in the case of industrial work, in cooperation with the project manager in the company.

Participation requirements

Forms of examination

Module examination in the form of a project-related written elaboration, 30 to 45 minutes colloquium including an examination discussion.

Requirements for the awarding of credit points

The Bachelor's examination is passed if all prescribed module examinations, the thesis and the colloquium have each been graded at least "sufficient" (4.0) or "passed".

Applicability of the module (in other degree programs)

none

Importance of the grade for the final grade

15 % thesis; 5 % colloquium

Literature

Basisliteratur:

Lindenlauf, Frank: Wissenschaftliche Arbeiten in den Ingenieur- und Naturwissenschaften: Ein praxisorientierter Leitfaden für Semester- und Abschlussarbeiten. Wiesbaden: Springer Fachmedien, 2022
Hirsch-Weber, Andreas; Scherer, Stefan: Wissenschaftliches Schreiben und Abschlussarbeit in Natur- und Ingenieurwissenschaften: Grundlagen – Praxisbeispiele – Übungen. Stuttgart: Utb Verlag, 2016

Weitere Literatur:

In Abhängigkeit des zu vergebenden Themas wird ein erster Literaturhinweis gegeben. Grundsätzlich gehört zur Bachelor-Thesis eine eigenständige Literaturrecherche.

Sprache und Rhetorik
PF

4 SWS

5 ECTS

Number
54500
Duration (semester)
1

Strömungsmechanik
PF

5 SWS

5 ECTS

Number
54300
Duration (semester)
1

4. Semester of study

Automatisierungstechnik
PF

5 SWS

6 ECTS

Number
54900
Duration (semester)
1

Betriebswirtschaft
PF

4 SWS

4 ECTS

Number
55000
Duration (semester)
1

Additive Fertigung
WP

4 SWS

5 ECTS

Number
57460
Language(s)
de
Duration (semester)
1

Aerodynamik
WP

4 SWS

5 ECTS

Number
54310
Duration (semester)
1

Aktuelle Themen aus dem Maschinenbau
WP

0 SWS

5 ECTS

Number
57400
Language(s)
de
Duration (semester)
1
Contact time
2 V / 30 h; 2 Ü / 30 h
Self-study
90 h

Learning outcomes/competences

In this course, students gain an overview of current topics in mechanical engineering and new technologies. Students will be able to prepare qualified presentations and convey the selected content and information in a structured and confident manner.

Changing content depending on the events on offer

Teaching methods

Lecture
Exercises

The lectures convey the theoretical content. Practical problems are dealt with promptly in exercises/practicals using typical tasks.

Participation requirements

Formal: none

In terms of content: none

Forms of examination

Module examination Written exam Current topics in mechanical engineering

Requirements for the awarding of credit points

The module examination must be passed with a minimum grade of 4.0.

Applicability of the module (in other degree programs)

optional

Importance of the grade for the final grade

3.48 % (see BPO)

Aktuelle Themen der Vertriebsausbildung
WP

0 SWS

5 ECTS

Number
58070
Language(s)
de
Duration (semester)
1

Automatisierungstechnik
WP

4 SWS

5 ECTS

Number
57480
Language(s)
de
Duration (semester)
1
Contact time
2 V / 30 h; 2 Ü / 30 h
Self-study
90 h

Learning outcomes/competences

Changing content depending on the events on offer

Teaching methods

Lecture
Exercises

The lectures convey the theoretical content. Practical problems are dealt with promptly in exercises/practicals using typical tasks.

Participation requirements

Formal: none

In terms of content: none

Forms of examination

Module examination Written exam Current topics in mechanical engineering

Requirements for the awarding of credit points

The module examination must be passed with a minimum grade of 4.0.

Applicability of the module (in other degree programs)

optional

Importance of the grade for the final grade

3.48 % (see BPO)

Betriebswirtschaftslehre und -organisation II
WP

0 SWS

5 ECTS

Number
58230
Language(s)
de
Duration (semester)
1
Contact time
60 h
Self-study
90 h

Learning outcomes/competences

Technical and methodological competence:

After completing the course, students will be able to

Understand the principles, protocols and architecture of the internet
Use elementary commands of the Linux and Windows operating systems for network configuration and network testing
Perform and interpret protocol and network analyses with analysis tools
Analyze existing wired and wireless networks
Design and implement wired and wireless networks
Configure network components (router, switch) including VLAN and NAT

Reference models (ISO/OSI, TCP/IP)
Bit transmission layer, transmission media
Ethernet, network components: Hub, switch, router; virtual LANs (VLAN)
IP protocols, addressing, routing
Network Address Translation (NAT)
Protocols of the transport layer
IPv6, IPSec, SSL/TLS
Wireless communication

Teaching methods

Lecture in interaction with the students, with blackboard writing and projection
Exercise accompanying the lecture
Processing programming tasks on the computer in individual or team work

Participation requirements

See the respective valid examination regulations (BPO/MPO) of the study program.

Forms of examination

written written examination
study achievements during the semester (bonus points)

Requirements for the awarding of credit points

passed written exam

Applicability of the module (in other degree programs)

Bachelor of Business Informatics
Bachelor of Software and Systems Engineering (dual)
Bachelor of Computer Science
Bachelor of Computer Science
Bachelor's degree in Medical Informatics
Bachelor of Medical Informatics Dual
Bachelor of Computer Science Dual
Bachelor of Computer Science Dual

Literature

Andrew S. Tanenbaum, David J. Wetherall; Computernetzwerke; Pearson Studium; 5. Auflage; 2012
Douglas E. Comer, Ralph Droms; Computernetzwerke und Internets; Pearson Studium; 3. Auflage; 2001

Bewegungs- und Kraftübertragung
WP

6 SWS

5 ECTS

Number
58120
Duration (semester)
1

CAD -Produktvisualisierung
WP

4 SWS

5 ECTS

Number
58200
Duration (semester)
1

CAD/CAM-Anwendungen
WP

4 SWS

5 ECTS

Number
57340
Duration (semester)
1
Contact time
60 h
Self-study
90 h

Learning outcomes/competences

Technical and methodological competence:

Students master basic mathematical concepts of computer science and their methods such as set theory, relations, propositional logic, complex numbers as well as groups and solids.
Students who have completed the module have mastered basic and advanced concepts and methods from linear algebra and are able to apply these methods with reference to their practical applications to solve typical tasks in computer science.
The graduates demonstrate a confident handling of the concepts and methods of vector and matrix calculus and their geometric interpretation, setting up and solving linear systems of equations as well as dealing with straight lines and planes.

Interdisciplinary methodological skills and self-competence:

Graduates of the module are able to solve computer science problems by setting up and calculating the corresponding mathematical models (for example by setting up and solving linear systems of equations). They demonstrate confidence in the appropriate selection of problem-specific solution methods and their application.

Social skills:

The participants understand the relevance of the content taught to their field of study and are able to communicate this relevance adequately.

The event includes the following topics:

Basics of mathematics for computer scientists: Introduction to set theory, cardinality of sets, relations, basics of propositional logic, complex numbers, groups and solids.
Vectors and vector calculus: notation and interpretation, operations on vectors and their properties (addition, scalar multiplication, scalar product, cross product), vector spaces, length of vectors, collinearity, linear dependence and independence, concepts of dimension and basis, angles between vectors.
Lines and planes: Representation in linear algebra, applications, positional relationships between points / straight line / planes
Matrices: Notation and interpretation, operations on matrices and their properties (transposing matrices, addition, scalar multiplication, matrix multiplication), Gaussian algorithm, determinants, inverse matrices and their calculation
Linear systems of equations: motivation and applications, matrix-vector form of linear systems of equations, Gaussian algorithm for solving linear systems of equations, homogeneous and inhomogeneous linear systems of equations and their relationships, rank of a matrix and relation to the solution set of linear systems of equations
Eigenvalues and basic transformations

Teaching methods

Lecture in interaction with the students, with blackboard writing and projection
Solving practical exercises in individual or team work

Participation requirements

See the respective valid examination regulations (BPO/MPO) of the study program.

Forms of examination

written exam paper

Requirements for the awarding of credit points

passed written exam

Applicability of the module (in other degree programs)

Bachelor of Computer Science
Bachelor's degree in Medical Informatics
Bachelor of Medical Informatics Dual
Bachelor of Computer Science Dual

Literature

Skript zur Vorlesung,
G. Teschl und S. Teschl, Mathematik für Informatiker 1, 3. Auflage, Springer Verlag (2008) - im Intranet der FH elektronisch verfügbar.
G. Teschl und S. Teschl, Mathematik für Informatiker 2, 2. Auflage, Springer Verlag (2007) - im Intranet der FH elektronisch verfügbar.
G. Fischer, Lineare Algebra, Vieweg, Braunschweig/Wiesbaden, 12. Auflage (2000).
Preuß, W., Wenisch, G., Lehr- und Übungsbuch Mathematik für Informatiker.

CAE
WP

0 SWS

5 ECTS

Number
57510
Language(s)
de
Duration (semester)
1

Elektrische Maschinen im Maschinenbau
WP

4 SWS

5 ECTS

Number
57860
Duration (semester)
1

Elektronik
WP

0 SWS

5 ECTS

Number
57350
Language(s)
de
Duration (semester)
1

Energietechnik I
WP

6 SWS

5 ECTS

Number
57380
Duration (semester)
1

Energietechnik II
WP

4 SWS

5 ECTS

Number
57820
Duration (semester)
1

Fahrzeugdynamik
WP

0 SWS

5 ECTS

Number
58180
Language(s)
de
Duration (semester)
1
Contact time
60 h
Self-study
90 h

Learning outcomes/competences

Subject and methodological competencies:

Develop EER models and transfer them to relational databases
Discuss the limitations of the relational database model using examples.
Apply methods of object-relational mapping.
Explain the 5-level model of a database management system.
Explain concepts of storage and access management.
Use examples to apply the methods of access optimization and transaction management.

Social skills:

Developing, creating, communicating and presenting learning content in teams

Implementation concepts

Memory management
Logical and physical access optimization
Transaction management
Distributed databases
Performance optimization and SQL tuning

Database models

Data modeling (EER model)
Limitations of the relational model
Object-relational mapping frameworks

Teaching methods

seminar-style teaching with flipchart, smartboard or projection
Solving practical exercises in individual or team work
Internship to accompany the lecture
working on programming tasks on the computer in individual or team work
active, self-directed learning through Internet-supported tasks, sample solutions and accompanying materials
exercises or projects based on practical examples
The lecture is offered as a video
Inverted teaching (inverted classroom)

Participation requirements

See the respective valid examination regulations (BPO/MPO) of the study program.

Forms of examination

written examination paper
work during the semester (bonus points)
examinations during the semester

Requirements for the awarding of credit points

passed written exam

Applicability of the module (in other degree programs)

Bachelor of Business Informatics
Bachelor of Software and Systems Engineering (dual)
Bachelor's degree in Software and Systems Engineering (dual)
Bachelor of Computer Science
Bachelor of Computer Science
Bachelor's degree in Medical Informatics
Bachelor of Medical Informatics Dual
Bachelor of Computer Science Dual

Literature

R. Elmasri, S. Navathe, Grundlagen von Datenbanksystemen, 2009
A. Kemper, A. Eickler, Datenbanksysteme (Eine Einführung), 2015
G. Saake, K.-U. Sattler, A. Heuer, Datenbanken Implementierungstechniken, 2011
R. Niemiec, Oracle database 12c release 2 performance tuning tips & techniques, 2017
R. Panther, SQL-Anfragen optimieren, 2014

Fahrzeugkonstruktion
WP

0 SWS

5 ECTS

Number
58170
Language(s)
de
Duration (semester)
1

Fertigungsverfahren und -technik
WP

0 SWS

5 ECTS

Number
57470
Language(s)
de
Duration (semester)
1

Finite Elemente Methoden
WP

4 SWS

5 ECTS

Number
57390
Duration (semester)
1

Fördertechnik I
WP

0 SWS

5 ECTS

Number
57720
Language(s)
de
Duration (semester)
1
Contact time
2 V / 30h; 2 Ü / 30 h
Self-study
90 h

Learning outcomes/competences

The students ...

have knowledge of basic design techniques as well as the use and design of the most common machine elements
can design simple components and demonstrate their durability under static load.
know the essential connection techniques for fixed connections of components and can design and calculate preloaded screw connections and shaft-hub connections in particular.
are able to develop simple designs according to Business Studies and technically feasible criteria
are able to identify and select the necessary information (characteristic values, geometric data, etc.) and compare it with the current state of the art
know the basic procedure for dimensioning machine elements and can apply it to previously unknown machine elements

Basics of component calculation
- Types of stress and calculation of stresses in components
- Material and component strength, strength verifications
Basic rules of design and design guidelines
Bolt connections
Axles, shafts, pivots
Shaft/hub connections
Basics of rolling bearings

Teaching methods

Lecture
Exercise

Participation requirements

Forms of examination

The module concludes with a written exam.

Duration: 90

Assistance permitted:

Roloff / Matek (textbook and table book)
Non-programmable pocket calculator

Requirements for the awarding of credit points

The module examination must be completed with a minimum grade of sufficient (4.0).

Applicability of the module (in other degree programs)

optional

Importance of the grade for the final grade

2.45 % (see StgPO)

Literature

Spura; Fleischer; et al.: Roloff/Matek Maschinenelemente: Normung, Berechnung, Gestaltung – Lehrbuch und Tabellenbuch. Wiesbaden: Springer Vieweg
Hoischen (Begründer): Technisches Zeichnen: Grundlagen, Normen, Beispiele, Darstellende Geome- trie. Berlin: Cornelsen Scriptor
Decker; et al.: Maschinenelemente Funktion, Gestaltung und Berechnung. München: Hanser Verlag
Haberhauer Maschinenelemente Gestaltung, Berechnung, Anwendung. Springer Vieweg
Sauer: Konstruktionselemente des Maschinenbaus1 Grundlagen der Berechnung und Gestaltung von Maschinenelementen, Springer Vieweg Verlag, Berlin
Schlecht, Bertold: Maschinenelemente 1, Festigkeit, Wellen, Verbindungen, Federn, Kupplungen. München: Pearson
Schlecht, Bertold: Maschinenelemente 2, Getriebe, Verzahnungen, Lagerungen. München; Pearson

Fördertechnik II
WP

0 SWS

5 ECTS

Number
57730
Language(s)
de
Duration (semester)
1

Füge- und Beschichtungstechnik
WP

0 SWS

5 ECTS

Number
58300
Language(s)
de
Duration (semester)
1
Contact time
2 V / 30 h; 2 Ü / 30 h
Self-study
90 h

Learning outcomes/competences

Changing content depending on the events on offer

Teaching methods

Lecture
Exercises

The lectures convey the theoretical content. Practical problems are dealt with promptly in exercises/practicals using typical tasks.

Participation requirements

Formal: none

In terms of content: none

Forms of examination

Module examination Written exam Current topics in mechanical engineering

Requirements for the awarding of credit points

The module examination must be passed with a minimum grade of 4.0.

Applicability of the module (in other degree programs)

optional

Importance of the grade for the final grade

3.48 % (see BPO)

Fügetechnik
WP

4 SWS

5 ECTS

Number
58330
Duration (semester)
1

Getriebetechnik
WP

0 SWS

5 ECTS

Number
57560
Language(s)
de
Duration (semester)
1

High-Tech-Metalle
WP

0 SWS

5 ECTS

Number
57740
Language(s)
de
Duration (semester)
1

Hydraulik und Pneumatik
WP

0 SWS

5 ECTS

Number
57410
Language(s)
de
Duration (semester)
1

Informationssysteme
WP

0 SWS

5 ECTS

Number
57500
Language(s)
de
Duration (semester)
1

Instandhaltungsmanagement
WP

0 SWS

5 ECTS

Number
57440
Language(s)
de
Duration (semester)
1

Investitionsrechnung
WP

0 SWS

5 ECTS

Number
58020
Language(s)
de
Duration (semester)
1

KFZ Kraftübertragung
WP

0 SWS

5 ECTS

Number
58220
Language(s)
de
Duration (semester)
1

Klimatechnik
WP

0 SWS

5 ECTS

Number
57790
Language(s)
de
Duration (semester)
1

Kolbenmaschinen
WP

4 SWS

5 ECTS

Number
57330
Duration (semester)
1

Konstruktionselemente III
WP

0 SWS

5 ECTS

Number
57310
Language(s)
de
Duration (semester)
1

Konstruktionsmethoden
WP

0 SWS

5 ECTS

Number
57450
Language(s)
de
Duration (semester)
1

Krane und Kranbahnen
WP

0 SWS

5 ECTS

Number
58110
Language(s)
de
Duration (semester)
1

Kunststofftechnik im Fahrzeugbau
WP

0 SWS

5 ECTS

Number
57590
Language(s)
de
Duration (semester)
1

Kältetechnik
WP

0 SWS

5 ECTS

Number
57780
Language(s)
de
Duration (semester)
1

Logistik
WP

4 SWS

5 ECTS

Number
57490
Duration (semester)
1

Managementkompetenzen
WP

0 SWS

5 ECTS

Number
58290
Language(s)
de
Duration (semester)
1

Mechanismentechnik
WP

0 SWS

5 ECTS

Number
58160
Language(s)
de
Duration (semester)
1

Oberflächentechnik
WP

0 SWS

5 ECTS

Number
58190
Language(s)
de
Duration (semester)
1

Product Lifecycle Management
WP

0 SWS

5 ECTS

Number
57360
Language(s)
de
Duration (semester)
1

Produkt- und Prozessoptimierung
WP

0 SWS

5 ECTS

Number
57530
Language(s)
de
Duration (semester)
1

Qualitätssicherung
WP

0 SWS

5 ECTS

Number
57540
Language(s)
de
Duration (semester)
1

Robotik I
WP

4 SWS

5 ECTS

Number
58100
Duration (semester)
1

Robotik II
WP

0 SWS

5 ECTS

Number
57920
Language(s)
de
Duration (semester)
1

SixSigma
WP

0 SWS

5 ECTS

Number
58210
Language(s)
de
Duration (semester)
1

Sondergebiete der Konstruktions- und Fertigungstechnik
WP

0 SWS

5 ECTS

Number
57870
Language(s)
de
Duration (semester)
1

Sondergebiete der Maschinen-, Energie- und Umwelttechnik
WP

4 SWS

5 ECTS

Number
57880
Duration (semester)
1

Sondergebiete der Werkstofftechnik
WP

0 SWS

5 ECTS

Number
57520
Language(s)
de
Duration (semester)
1

Sondergebiete der Zerspanung
WP

0 SWS

5 ECTS

Number
58130
Language(s)
de
Duration (semester)
1

Sondergebiete des Vertriebsmanagements
WP

0 SWS

5 ECTS

Number
58250
Language(s)
de
Duration (semester)
1

Stahlbau I
WP

0 SWS

5 ECTS

Number
57900
Language(s)
de
Duration (semester)
1

Stahlbau II
WP

0 SWS

5 ECTS

Number
57930
Language(s)
de
Duration (semester)
1

Technical English for Engineers
WP

0 SWS

5 ECTS

Number
57420
Language(s)
de
Duration (semester)
1

Technical communications
WP

0 SWS

5 ECTS

Number
58240
Language(s)
de
Duration (semester)
1

Turbomaschinen
WP

4 SWS

5 ECTS

Number
57760
Duration (semester)
1

Umformtechnik
WP

0 SWS

5 ECTS

Number
58310
Language(s)
de
Duration (semester)
1

Umwelttechnik
WP

6 SWS

5 ECTS

Number
57770
Duration (semester)
1

Unternehmensberatung und Auftragsabwicklung
WP

0 SWS

5 ECTS

Number
58060
Language(s)
de
Duration (semester)
1

Unternehmensberatung und Beratungsmarketing
WP

0 SWS

5 ECTS

Number
58050
Language(s)
de
Duration (semester)
1

Verbrennungskraftmaschinen
WP

0 SWS

5 ECTS

Number
57750
Language(s)
de
Duration (semester)
1

Verfahrenstechnik
WP

4 SWS

5 ECTS

Number
58080
Duration (semester)
1

Vertragsrecht
WP

0 SWS

5 ECTS

Number
58010
Language(s)
de
Duration (semester)
1

Vertriebsqualitätsmanagement für technische Investitionsgüter und Serienprodukte
WP

0 SWS

5 ECTS

Number
58040
Language(s)
de
Duration (semester)
1

Webtechnologien
WP

0 SWS

5 ECTS

Number
57660
Language(s)
de
Duration (semester)
1

Werkstoff- und Fertigungstechnik
WP

0 SWS

5 ECTS

Number
57300
Language(s)
de
Duration (semester)
1

5. Semester of study

Studienarbeit
PF

4 SWS

5 ECTS

Number
55300
Language(s)
de
Duration (semester)
1

Numerische Verfahren
WP

4 SWS

5 ECTS

Number
58280
Duration (semester)
1

Technische Akustik
WP

0 SWS

5 ECTS

Number
57580
Language(s)
de
Duration (semester)
1

Vertriebsmanagement
WP

0 SWS

5 ECTS

Number
58000
Language(s)
de
Duration (semester)
1

Werkstoff- und Fertigungstechnik in Kraftwerken
WP

0 SWS

5 ECTS

Number
58140
Language(s)
de
Duration (semester)
1

6. Semester of study

Praxissemester
PF

0 SWS

25 ECTS

Number
55400
Duration (semester)
1
Contact time
30 h
Self-study
45 h

Learning outcomes/competences

After successful completion of the module students will be able to:

Knowledge and understanding

name and explain key technical vocabulary from IT and technology .
describe technical objects, systems and processes precisely in Englishhe describe.

Use, application and generation of knowledge

structure technical content appropriately for the target group(introduction - main part - conclusion) and transfer it into an understandable presentation .
Suitable visualizations (e.g. diagrams/tables) to support technical statements statements use.
Concisely summarize technical information (e.g. Abstract/Handout/Slide-Text) and them into presentation materials integrate.

Communication and cooperation

present technical content correctly and comprehensibly in English .
an English-language technical discussion lead by asking questions, arguing and giving feedback.

Scientific self-image / Professionalism

Fundamental principles of scientific work in English apply by citing and citing sources correctly.
the own linguistic and technical presentation reflect and further develop this with the help of feedback develop.

Basics of technical English: Technical vocabulary, typical formulations, description of technical facts.
Presentation techniques: Structure/outline, linguistic means, presentation phrases, use of visual aids. visual aids
Scientific work: Source work, citation techniques, precise summaries of technical content. content.
Discussion techniques: Questions/answers, argumentation, feedback, role plays/exercises on IT topics.
Practical application: Presentations on technical IT topics during the semester

Teaching methods

Seminar-style teaching in English language with activating phases.
Oral and written exercises on technical description and technical description and terminology.
Presentation workshops (preparation, implementation, feedback).
Discussions/role-playing games on current IT topics.
Independent research and development of presentation content. presentation content.

Participation requirements

See the respective valid examination regulations (BPO/MPO) of the study program.

Forms of examination

R (presentation / presentation), ungraded (pass / fail)

Competence-oriented Description of the examination:
With the presentation, students demonstrate that they can present technical content in a technically correct, structured and target group-oriented manner in English and can answer questions in a short technical discussion.

Duration: 10-15 minutes presentation + subsequent Q&A session
Evaluation criteria (pass/fail) passed): Professionalism, comprehensibility, linguistic accuracy, presentation technique accuracy, presentation technique

Requirements for the awarding of credit points

Participation in the placement test before the semester.
Passed Semester-long presentation (10-15 minutes) with Q&A session.
Minimum attendance: At least 80 % of the appointments (usually corresponds to max. 20 % missing appointments); required, as learning objectives can only be achieved through continuous practice, presentation and discussion. If the minimum attendance is not met without excuse, the preliminary examination work is deemed not to have been completed. As a result, the module will be graded as "failed" (NB).

Applicability of the module (in other degree programs)

Bachelor of Business Informatics
Bachelor of Software and Systems Engineering (dual)
Bachelor of Computer Science
Bachelor's degree in Medical Informatics
Bachelor of Medical Informatics Dual
Bachelor of Computer Science Dual

Literature

Williams, E., Kleinschroth, R., Courtney, B. (2025). "Matters Technik - IT Matters 3rd Edition - Revised: B1-C1 - Englisch für technische Ausbildungsberufe". Cornelsen Verlag. ISBN-13: 978-3-06-452538-2

Sondergebiete des Maschinenbaus - Blended Learning
WP

0 SWS

5 ECTS

Number
58320
Language(s)
de
Duration (semester)
1

Web-Kinematik
WP

0 SWS

5 ECTS

Number
58270
Language(s)
de
Duration (semester)
1
Contact time
2 V / 30 h; 2 Ü / 30 h
Self-study
90 h

7. Semester of study

Ingenieurmäßiges Arbeiten
PF

6 SWS

10 ECTS

Number
55500
Duration (semester)
1

Thesis und Kolloquium
PF

0 SWS

15 ECTS

Number
58020
Language(s)
de
Duration (semester)
1
Contact time
-
Self-study
BA-Arbeit: 360 h, Kolloquium: 90 h

Learning outcomes/competences

Teaching methods

Independent, practice-oriented project work. Supervision is provided by a professor and, in the case of industrial work, in cooperation with the project manager in the company.

Participation requirements

Forms of examination

Module examination in the form of a project-related written elaboration, 30 to 45 minutes colloquium including an examination discussion.

Requirements for the awarding of credit points

The Bachelor's examination is passed if all prescribed module examinations, the thesis and the colloquium have each been graded at least "sufficient" (4.0) or "passed".

Applicability of the module (in other degree programs)

none

Importance of the grade for the final grade

15 % thesis; 5 % colloquium

Literature

Basisliteratur:

Lindenlauf, Frank: Wissenschaftliche Arbeiten in den Ingenieur- und Naturwissenschaften: Ein praxisorientierter Leitfaden für Semester- und Abschlussarbeiten. Wiesbaden: Springer Fachmedien, 2022
Hirsch-Weber, Andreas; Scherer, Stefan: Wissenschaftliches Schreiben und Abschlussarbeit in Natur- und Ingenieurwissenschaften: Grundlagen – Praxisbeispiele – Übungen. Stuttgart: Utb Verlag, 2016

Weitere Literatur:

In Abhängigkeit des zu vergebenden Themas wird ein erster Literaturhinweis gegeben. Grundsätzlich gehört zur Bachelor-Thesis eine eigenständige Literaturrecherche.

1. Semester	2. Semester	3. Semester	4. Semester	5. Semester	6. Semester	7. Semester
Ingenieurinformatik PF 3SWS 3ECTS	Fertigungstechnik PF 3SWS 4ECTS	CAD PF 3SWS 3ECTS	Automatisierungstechnik PF 5SWS 6ECTS	Studienarbeit PF 4SWS 5ECTS	Praxissemester PF 0SWS 25ECTS	Ingenieurmäßiges Arbeiten PF 6SWS 10ECTS
Ingenieurmethodik PF 5SWS 2ECTS	Festigkeitslehre PF 4SWS 6ECTS	Dynamik PF 4SWS 5ECTS	Betriebswirtschaft PF 4SWS 4ECTS	Compulsory elective modules (4)	Compulsory elective modules (2)	Thesis und Kolloquium PF 0SWS 15ECTS
Ingenieurwissenschaftliche Grundlagen PF 6SWS 8ECTS	Konstruktionselemente I PF 3SWS 4ECTS	Elektrotechnik PF 5SWS 5ECTS	Compulsory elective modules (66)
Mathematik PF 6SWS 8ECTS	Managementmethoden PF 3SWS 4ECTS	Konstruktionselemente II PF 5SWS 7ECTS
Statik PF 4SWS 5ECTS	Mathematik II PF 4SWS 5ECTS	Sprache und Rhetorik PF 4SWS 5ECTS
	Physik PF 3SWS 6ECTS	Strömungsmechanik PF 5SWS 5ECTS
	Thermodynamik PF 5SWS 5ECTS

Study plan

Ingenieurinformatik

Fertigungstechnik

CAD

Automatisierungstechnik

Studienarbeit

Praxissemester

Ingenieurmäßiges Arbeiten

Ingenieurmethodik

Festigkeitslehre

Dynamik

Betriebswirtschaft

Compulsory elective modules (4)

Compulsory elective modules (2)

Thesis und Kolloquium

Ingenieurwissenschaftliche Grundlagen

Konstruktionselemente I

Elektrotechnik

Compulsory elective modules (66)

Mathematik

Managementmethoden

Konstruktionselemente II

Statik

Mathematik II

Sprache und Rhetorik

Physik

Strömungsmechanik

Thermodynamik

Compulsory elective modules 1. Semester

Compulsory elective modules 2. Semester

Compulsory elective modules 3. Semester

Compulsory elective modules 4. Semester

Additive Fertigung

Aerodynamik

Aktuelle Themen aus dem Maschinenbau

Aktuelle Themen der Vertriebsausbildung

Automatisierungstechnik

Betriebswirtschaftslehre und -organisation II

Bewegungs- und Kraftübertragung

CAD -Produktvisualisierung

CAD/CAM-Anwendungen

CAE

Elektrische Maschinen im Maschinenbau

Elektronik

Energietechnik I

Energietechnik II

Fahrzeugdynamik

Fahrzeugkonstruktion

Fertigungsverfahren und -technik

Finite Elemente Methoden

Fördertechnik I

Fördertechnik II

Füge- und Beschichtungstechnik

Fügetechnik

Getriebetechnik

High-Tech-Metalle

Hydraulik und Pneumatik

Informationssysteme

Instandhaltungsmanagement

Investitionsrechnung

KFZ Kraftübertragung

Klimatechnik

Kolbenmaschinen

Konstruktionselemente III

Konstruktionsmethoden

Krane und Kranbahnen

Kunststofftechnik im Fahrzeugbau

Kältetechnik

Logistik

Managementkompetenzen

Mechanismentechnik

Oberflächentechnik

Product Lifecycle Management

Produkt- und Prozessoptimierung

Qualitätssicherung

Robotik I

Robotik II

SixSigma

Sondergebiete der Konstruktions- und Fertigungstechnik

Sondergebiete der Maschinen-, Energie- und Umwelttechnik

Ingenieurinformatik
PF

3 SWS

3 ECTS

Ingenieurmethodik
PF

5 SWS

2 ECTS

Ingenieurwissenschaftliche Grundlagen
PF

6 SWS

8 ECTS

Mathematik
PF

6 SWS

8 ECTS

Statik
PF

4 SWS

5 ECTS

Fertigungstechnik
PF

3 SWS

4 ECTS

Festigkeitslehre
PF

4 SWS

6 ECTS

Konstruktionselemente I
PF

3 SWS

4 ECTS

Managementmethoden
PF

3 SWS

4 ECTS

Mathematik II
PF

4 SWS

5 ECTS

Physik
PF

3 SWS

6 ECTS

Thermodynamik
PF

5 SWS

5 ECTS