Statuss(Aktīvs) | Izdruka | Arhīvs(0) | Studiju plāns Vecais plāns | Kursu katalogs | Vēsture |
Course title | Applied Mechanics I |
Course code | Meha2002 |
Credit points (ECTS) | 3 |
Total Hours in Course | 81 |
Number of hours for lectures | 16 |
Number of hours for seminars and practical classes | 16 |
Independent study hours | 49 |
Date of course confirmation | 19/10/2011 |
Responsible Unit | Institute of Mechanics and Design |
Course developers | |
Ph.D., Māris Gailis |
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There is no prerequisite knowledge required for this course | |
Course abstract | |
Students will acquire knowledge on durability, stiffness and stability of materials for calculation of constructions a, develop engineering perception, supporting on the theory they study to put into practice the substantiation of optimal structural design of constructions of machinery. | |
Learning outcomes and their assessment | |
Knowledge - students comprehend the basic principles of engineering calculation on strength, stability and deformation of materials and constructions – quizzes.
Skills - using the methods and modes of the strength of materials students are able to perform practical calculations on strength, stability and deformation of engineering constructions – practical works. Competence - students are able to solve technical problems and perform independent calculation and selection of appropriate machinery for food processing – 3 homeworks. |
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Course Content(Calendar) | |
1.Introduction. Equivalent and balanced systems of forces. Supports and reactions. Interactive test. (Lectures – 2h, practical work – 2h)
2.Geometric parameters of cross section. (Lectures – 1h, practice – 1h) 3.Method of cross section. Diagrams of internal forces. (Lectures – 1h, practical work – 1h) 4.Stresses. Tension, Diagram of stress-strain for plastic and brittle materials. Interactive test. (Lectures – 2h, practical work – 2h) 5.Surface load. Permissible stress. (Lectures – 1h, practical work – 1h) 6.Stresses in tension. 1st quizz. (Lectures – 1h, practical work– 1h) 7.Shearing load. (Lectures – 1h, practical work – 1h) 8.Torsion load. Torsion in round bars. (Lectures – 2h, practical work – 2h) 9.Bending load. Normal stress in bending. Interactive test. (Lectures – 1h, practical work – 1h,) 10.Tangential stress in bending. Calculation of strength. 2nd quizz. (Lectures – 2h, practical work – 2h) 11.Theories of strength. (Lectures – 2h, practical work – 2h) |
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Requirements for awarding credit points | |
Course assessment with a mark is formed follows:
• all homework must be submitted. The homeworks include mechanical load and strength problem solving (40%) • all interactive quizzes must be submitted. The quizzes include multichoice, numerical, interaction via text and figures in the environments of Moodle and Kahoot. Grading in Moodle is automated(20%) • two classroom quizzes must be written (40%). Credit points are assigned if the rate weighted average score is at least grade 4. |
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Description of the organization and tasks of students’ independent work | |
The problems for independent work are similar to the ones given during practice work. The problem starts with statement of initial parameters. To solve the problem, application of the skills obtained during practice is necessary. | |
Criteria for Evaluating Learning Outcomes | |
The grade is formed as the weighted mean of the results of quizzes and homeworks. | |
Compulsory reading | |
1. Meriam J.L., Kraige L.G. Engineering Mechanics. Statics. New York: John Wiley & Sons, 2001. 512 p. 2. Meriam J.L., Kraige L.G. Engineering Mechanics. Dynamics. New York: John Wiley & Sons, 2003. 744 p. | |
Further reading | |
Hibbeler R.C. Statics and mechanics of materials. Singapore: Prentice Hall, 2004. 792 p. | |
Notes | |
Compulsory course for students of the first-level professional higher education study program "Technical Expert" |