SylabUZ
| Course name | Strength of Materials II |
| Course ID | 06.1-WM-ER-MiBM-10_18 |
| Faculty | Faculty of Engineering and Technical Sciences |
| Field of study | WM - oferta ERASMUS |
| Education profile | - |
| Level of studies | Erasmus programme |
| Beginning semester | winter term 2019/2020 |
| Semester | 2 |
| ECTS credits to win | 5 |
| Course type | obligatory |
| Teaching language | english |
| Author of syllabus |
|
| The class form | Hours per semester (full-time) | Hours per week (full-time) | Hours per semester (part-time) | Hours per week (part-time) | Form of assignment |
| Lecture | 30 | 2 | - | - | Exam |
| Laboratory | 15 | 1 | - | - | Credit with grade |
The aim of the course is to introduce students to problem-solving methodology and analysis of the strength found in mechanical engineering
Strength of Materials I, Technical Mechanics I, Mathematics.
LECTURE
Determination of beam bending deformations. Analytical method for determining of a bending line of beams. The Clebsch method. Stability of the compressed rods. Elastic buckling of straight bars. Euler's formula. Tetmajer and Johnson- Ostenfeld formulas. Slender rods compression and bending. Beams on elastic fundation. Strongly curved rods bending. Issues a static indeterminable bending. Single and multi-span beams. The equation of three moments. Statically indeterminable frame. Energy methods. Clapeyron system. Calculation of deformations using the Castigliano theorem. Menabrea’s theorem. Calculation of statically indeterminable beams and frames using the Menabrea’s theorem. Bending of plates. Cylindrical bending of plates. Two mutually perpendicular pure bending of plates. Differential equation of a circularly symmetric plate. Bending of rectangular plates. Spherical, cylindrical and conical tank. The stresses in thick-walled tanks. The Lamé task.
LABORATORY
Laboratory topics:
Measurement of the Young modulus by extensometric method,
Measurement of the Young modulus by method of retaining extensometry
Diagonal bending,
Examination of the compressed rod buckling
Examination of a circular ring strain
Correction exercises, tests.
Lectures with audiovisual aids. Solving classes. Working with the book. Group work in laboratory classes
| Outcome description | Outcome symbols | Methods of verification | The class form |
Lecture
positive evaluation of the test
Laboratory
received positive ratings of reports carried out laboratory
Evaluation of the course is getting positive ratings from all forms: Lecture, Laboratory
1. Walicka A, Walicki E, Michalski D, Jurczak P, Falicki J., Wytrzymałość materiałów / T. 1: Podręcznik akademicki. Teoria, wzory i tablice do ćwiczeń laboratoryjnych. - Zielona Góra : Oficyna Wydawnicza Uniwersytetu Zielonogórskiego, 2008
2. Walicka A, Walicki E, Michalski D, Jurczak P, Falicki J., Wytrzymałość materiałów T. 2: Ćwiczenia laboratoryjne – Materiały pomocnicze. - Zielona Góra : Oficyna Wydawnicza Uniwersytetu Zielonogórskiego, 2008.
3. Case J., Chilver A.Ch., Ross C.T.F., Strength of Materials and Structures, Arnold, the Hodder Headline Group, 1999.
4. da Silva V.D., Mechanics and Strength of Materials, Springer-Verlag, Berlin, Heidelberg, 2006.
5. Kobayashi T., Strength and Toughness of Materials, Springer-Verlag Tokyo, 2004,
6. Niezgodziński M. E., Niezgodziński T., Wytrzymałość materiałów, 1979 PWN wyd. XI,
1. Rżysko J., Statyka i wytrzymałość materiałów , 1979 PWN,
2. Jakubowicz A., Orłoś Z., Wytrzymałość materiałów, 1984 WNT,
3. Gubrynowiczowa J., Wytrzymałość materiałów, 1968 PWN.
4. Banasiak M., Grossman K., Trombski M., Zbiór zadań z wytrzymałości materiałów, 1998, PWN.
Modified by dr inż. Paweł Jurczak (last modification: 09-05-2019 10:01)
