Lecturer(s)


Růžička Milan, prof. Ing. CSc.

Course content

1. Revision PP I. 2. Crooked rods (thin / thick), statically determinate, statically indeterminate and frames. 3. Thickwalled cylindrical vessel, a balance, differential equations, tension, stress and strain conditions. 4. Shrink thickwalled vessels, carrying capacity, overshoot and control of the unloaded condition. 5. rotating thin discs, balance equations, stress. Thin circular plates, balance element and differential equations. 6. Thin circular axisymmetric plate deformation and complex cases boards. 7. Spatial stress, augmented Hooke's law and the mathematical theory of elasticity. 8. Energy Methods in flexibility and their application to the calculation of buckling. 9. Combination strut with bending, solution of differential equations and approximate methods of calculation. 10. Plasticity  concepts, plasticity during uniaxial tension, torsion and bending, the principle of minimum and the formation of plastic mechanism. 11. plasticity in multiaxial stress state conditions plasticity and problem solving. 12. Numerical methods in elasticity and strength and fundamentals of fracture mechanics. 13. Experimental methods in elasticity.

Learning activities and teaching methods

Monologic (reading, lecture, briefing), Work with text (with textbook, with book), Elearning
 Class attendance
 20 hours per semester
 Preparation for classes
 150 hours per semester
 Semestral paper
 70 hours per semester
 Preparation for credit
 5 hours per semester
 Preparation for exam
 30 hours per semester

Learning outcomes

The course emphasis on the theoretical basis of the discussed concepts and derivation of basic relations and relations between concepts. In addition, students gain advanced knowledge in certain topics focusing on the use of related courses in the theoretical basis of studies and master's degree. Students will gain advanced knowledge of the following topics of: curved beams and frames, thickwalled cylindrical vessel, rotating discs, circular plate, approximate methods of solving strut, bending and buckling combination, analysis of spatial stress and reshaping, and the mathematical theory of elasticity and basics of plasticity theory. In lectures is emphasized the relations and mutual relationships between quantities. Emphasis is placed on engineering approach to solve issues and corresponds to the basic course Strength of Materials I, including the derivation of all basic relations.
The aim is to extend students' knowledge gained in the previous basic course. The course puts more emphasis on the theoretical basis of the concepts discussed and on the derivation of basic relationships and connections between concepts. In addition, students will gain advanced knowledge in some thematic areas: crooked bars and frames, thickwalled cylindrical vessels, rotating discs, circular plates, approximate methods of buckling, combination of bending and buckling, analysis of spatial stress and strain and mathematical theory of elasticity and fundamentals of plasticity theory. In the course the relations and relations between the variables are emphasized. Emphasis is placed on the engineering approach to solving problems corresponding to the basic subject of Elasticity and Strength I, including the derivation of all the basics. relationships.

Prerequisites

knowledge of advanced mathematics, knowledge of differencial, integral, vector and tensor mathematics

Assessment methods and criteria

Combined exam, Seminar work
Understanding of the topic within the frame given by the plan. Assesment methods and criteria linked to learning outcomes: credit: attendance of seminars, min 75%, passing the test to min 75%. exam: passing the test min 75%, proof of knowledge at the oral exam min 75%.

Recommended literature


Michalec, J., a kol.: Pružnost a pevnost I, Vydavatelství ČVUT v Praze 2006/2008.

Michalec, J., a kol.: Pružnost a pevnost I, Vydavatelství ČVUT v Praze 2006/2008.

Michalec, J., a kol.: Pružnost a pevnost II, Vydavatelství ČVUT v Praze 2006.

Michalec, J., a kol.: Pružnost a pevnost II, Vydavatelství ČVUT v Praze 2006.

Řezníček, J., Řezníčková, J.: Pružnost a pevnost v technické praxi  Příklady I, Vydavatelství ČVUT 2005.

Řezníček, J., Řezníčková, J.: Pružnost a pevnost v technické praxi  Příklady II, Vydavatelství ČVUT 2006.

Řezníček, J., Řezníčková, J.: Pružnost a pevnost v technické praxi  Příklady III, Vydavatelství ČVUT 2008.

Valenta, Fr., a kol.: Pružnost a pevnost III, Vydavatelství ČVUT v Praze 2006.

Valenta, Fr., a kol.: Pružnost a pevnost III, Vydavatelství ČVUT v Praze 2006.
