Digitale Lehre
The event will be held in SoSe 2020 as a Digital Teaching. The Digital Teaching will probably start in week 17 (from 20.04.2020).
The technical access to the Digital Teaching will provided via Moodle. In Moodle you can download the lecture (video/slides)
Literatur
[list]
[*]M. Oechsner: Umdruck zur Vorlesung (Foliensätze und Skript).
[*]H. J. Bargel; Schulze: Werkstoffkunde, VDI-Verlag, 2012.
[*]E. Hornbogen: Werkstoffe, Springer-Verlag, 2012.
[*]Hornbogen et al.: Werkstoffe, Fragen und Antworten, Springer-Verlag, 2012.
[*]H. Ilschner: Werkstoffwissenschaften, Springer-Verlag, 2010.
[*]H. Blumenauer: Werkstoffprüfung, Dt. Verlag für Kunststoffindustrie, Stuttgart, 2012.
[*]D. Askeland: Materialwissenschaften, Spektrum Lehrbuch, 1996
[/list]
Voraussetzungen
Successful conclusion of course "Material Science & Engineering I" is recommended.
Requirement for the exam is the successful Recitation Lab attendanc. Without the Recitation Lab you cannot write the exam "Material Science & Engineering II"
Erwartete Teilnehmerzahl
300
Official Course Description
[b]Syllabus[/b]
Basics of mechanics of materials, extended damage mechanisms and damage description: Basics of design philosophies, stress states, strength theories, equilibrium stresses, notches, fatigue behavior, causes for failure, non-destructive testing and metallography, fracture mechanics, corrosion, tribology
[b]Learning Outcomes[/b]
After completing this course the student will be able to:
1. Characterize and distinguish different stress states.
2. Describe, use, and evaluate strength hypothesis based on the loading scheme and material behavior.
3. Analyse the specifics and influencing factors of notches and transfer those to real component and material applications.
4. Evaluate influence factors on fatigue strength in order to select and apply a suitable method of characterization.
5. Describe methods to characterize the material state by means of non-destructive tests and metallographic investigations.
6. Apply Fracture Mechanics concepts and distinguish those by their validity limits.
7. Assess the different aspects of further damage mechanisms like corrosion and tribology.
The event will be held in SoSe 2020 as a Digital Teaching. The Digital Teaching will probably start in week 17 (from 20.04.2020).
The technical access to the Digital Teaching will provided via Moodle. In Moodle you can download the lecture (video/slides)
Literatur
[list]
[*]M. Oechsner: Umdruck zur Vorlesung (Foliensätze und Skript).
[*]H. J. Bargel; Schulze: Werkstoffkunde, VDI-Verlag, 2012.
[*]E. Hornbogen: Werkstoffe, Springer-Verlag, 2012.
[*]Hornbogen et al.: Werkstoffe, Fragen und Antworten, Springer-Verlag, 2012.
[*]H. Ilschner: Werkstoffwissenschaften, Springer-Verlag, 2010.
[*]H. Blumenauer: Werkstoffprüfung, Dt. Verlag für Kunststoffindustrie, Stuttgart, 2012.
[*]D. Askeland: Materialwissenschaften, Spektrum Lehrbuch, 1996
[/list]
Voraussetzungen
Successful conclusion of course "Material Science & Engineering I" is recommended.
Requirement for the exam is the successful Recitation Lab attendanc. Without the Recitation Lab you cannot write the exam "Material Science & Engineering II"
Erwartete Teilnehmerzahl
300
Official Course Description
[b]Syllabus[/b]
Basics of mechanics of materials, extended damage mechanisms and damage description: Basics of design philosophies, stress states, strength theories, equilibrium stresses, notches, fatigue behavior, causes for failure, non-destructive testing and metallography, fracture mechanics, corrosion, tribology
[b]Learning Outcomes[/b]
After completing this course the student will be able to:
1. Characterize and distinguish different stress states.
2. Describe, use, and evaluate strength hypothesis based on the loading scheme and material behavior.
3. Analyse the specifics and influencing factors of notches and transfer those to real component and material applications.
4. Evaluate influence factors on fatigue strength in order to select and apply a suitable method of characterization.
5. Describe methods to characterize the material state by means of non-destructive tests and metallographic investigations.
6. Apply Fracture Mechanics concepts and distinguish those by their validity limits.
7. Assess the different aspects of further damage mechanisms like corrosion and tribology.
- Lehrende: Matthias Oechsner
Semester: ST 2020