|
|
Module code: DBMAB-250 |
|
- |
5 |
Academic Year: 2 |
Mandatory course: yes |
Language of instruction:
German |
Assessment:
2 exams consisting of a graded written examination and a graded term paper • Graded exam (Duration 90 min., 100 pts.) The exam will be written in the 3rd semester (Block 3B) according to the examination schedule. • Graded term paper (100 pts.) The topic will be a task related to Machine Elements 2 and 3. It will be handed out on the first working day of the 1st week of Block 4B (4th semester). The term paper is an exam component comprising 30 hours, to be completed within a period of 60 working days (Mon-Fri except public holidays) from the date on which the topic is issued. Prerequisites for receiving credits: The achievement of at least 40 out of 100 points in the module exam. The achievement of at least 40 out of 100 points for the term paper. The module grade is calculated as follows: Exam: 80% Term paper: 20% The grade will be shown as a decimal grade according to the htw saar grading scheme.
[updated 28.04.2023]
|
DBMAB-250 (P720-0013, P720-0014) Mechanical Engineering / Production Technology, Bachelor, ASPO 01.10.2021
, study year 2, mandatory course
DBMAB-250 (P720-0013, P720-0014) Mechanical Engineering / Production Technology, Bachelor, ASPO 01.10.2024
, study year 2, mandatory course
|
The total student study time for this course is 150 hours.
|
Recommended prerequisites (modules):
None.
|
Recommended as prerequisite for:
|
Module coordinator:
Prof. Dr.-Ing. Jan Christoph Gaukler |
Lecturer: Prof. Dr.-Ing. Jan Christoph Gaukler
[updated 11.06.2021]
|
Learning outcomes:
After successfully completing this course, students will expand their knowledge of the basic stresses on "buckling and centric buckling". They will be able to assess the stability of equilibrium positions of compression loaded members and determine the critical load for the buckling of members. In addition, they will be able to apply the strength hypotheses to carry out the stress verification for multi-axial loading and dimension the component by comparing the comparative stress and the material parameters. They will be able to determine the appropriate failure hypothesis (ductile and brittle fracture, fatigue fracture, deformation) and select, calculate and design machine elements of rotary motion (axles, shafts, bolts, journals, plain and roller bearings, couplings and brakes) and gears. Students will be able to work independently and using scientific means on an interdisciplinary task of intermediate complexity (linking technical mechanics, construction and materials technology) for the calculation/dimensioning and design of machine elements.
[updated 28.04.2023]
|
Module content:
Machine elements 2 & 3: • Special strength of materials theory: o Buckling and centric buckling o Superimposed stresses (tension/compression, bending, torsion and buckling) and applying the strength hypotheses o Strength verification regarding failures due to ductile and brittle fractures, due to fatigue fractures and due to deformations o More detailed information on failure due to fatigue fractures Wöhler curve, low cycle fatigue, high cycle fatigue, very high cycle fatigue, load profile, fatigue strength diagram according to Haigh and Smith • Machine elements of rotating motion o Axles, shafts, bolts and pins: types, design and calculation o Plain and rolling bearings: types, design, selection, installation, tolerances, bearing clearance, lubrication, rolling element pairs and Hertzian pressure, dimensioning (static/dynamic), calculation of service life o Clutches (shiftable, non-shiftable) and brakes: types, functionality and selection • Gearboxes: o Gears: geometry, law of gearing, involute gearing o Gear and belt drives
[updated 28.04.2023]
|
Teaching methods/Media:
Lecture: Lecture, demonstrations, question and impulse teaching Exercises: Demonstrations, question and impulse teaching, working on specific problems Term paper: Independent work on a specific problem
[updated 28.04.2023]
|
Recommended or required reading:
• D. Gross, W. Hauger, J. Schröder, W. A. Wall: Technische Mechanik 2 – Elastostatik (Springer) • R. C. Hibbeler: Technische Mechanik 2 – Festigkeitslehre (Pearson) • D. Gross, W. Hauger, P. Wriggers: Technische Mechanik 4 • H. Wittel, D. Jannasch, J. Voßlek, Ch. Spura: Roloff/Matek Maschinenelemente, Springer Vieweg Verlag • K.H. Decker, Maschinenelemente, Carl Hanser Verlag • B. Künne: Köhler/Rögnitz, Maschinenteile 1+2, Springer Vieweg • H. Habenhauer, F. Bodenstein: Maschinenelemente, Springer-Verlag
[updated 28.04.2023]
|