PAP_a Flexibility and Strenght

Institute of Technology and Business in České Budějovice
summer 2018
Extent and Intensity
2/2/0. 5 credit(s). Type of Completion: zk (examination).
Teacher(s)
Ing. Josef Musílek, Ph.D. (seminar tutor)
Ing. Jan Prem (seminar tutor)
Guaranteed by
Ing. Josef Musílek, Ph.D.
Department of Civil Engineering – Faculty of Technology – Rector – Institute of Technology and Business in České Budějovice
Supplier department: Department of Civil Engineering – Faculty of Technology – Rector – Institute of Technology and Business in České Budějovice
Timetable of Seminar Groups
PAP_a/P01: Wed 8:00–9:30 A5, J. Musílek
PAP_a/Q2: Sat 17. 2. 8:00–9:30 B5, 9:40–11:10 B5, 11:25–12:55 B5, Sun 4. 3. 8:00–9:30 B5, 9:40–11:10 B5, 11:25–12:55 B5, 13:05–14:35 B5, Sat 14. 4. 8:00–9:30 B5, 9:40–11:10 B5, 11:25–12:55 B5, J. Prem
PAP_a/S01: Wed 9:40–11:10 A1, J. Musílek
PAP_a/S02: Wed 13:05–14:35 D416, J. Musílek
Prerequisites (in Czech)
MAX_KOMBINOVANYCH(40) && MAX_PREZENCNICH(48)
Course Enrolment Limitations
The course is offered to students of any study field.
The capacity limit for the course is 88 student(s).
Current registration and enrolment status: enrolled: 0/88, only registered: 0/88
Course objectives supported by learning outcomes
After completing the course the student will be able to state tension in cross-section of basic types of stress - pressure, tension, bending, shear, buckling and twisting. Further s/he can determine the deflection of basic structure by analyzing the bending equation.
Learning outcomes
Student understands solution of wall and slab structures and solution of wall and plate equation. After completing the course the student is able to evaluate and design solutions of wall and slab structures, he can determine the tension in the cross-section from the basic stresses - pressure, tension, bending, skidding, buckling pressure and twisting, and also determines the deflection of basic structures based on the analysis of the bending equation.
Syllabus
  • 1) Basic functions, concepts and assumptions of elasticity theory. Displacement. Deformation. Voltage. Saint-Venant`s principle. Linear theory of elasticity. Physical laws, working diagram. 2) Analysis of the rod - the basics. The connection components of the internal forces and stress components, components of the internal forces and external loads. 3) Simple tension and pressure - stress, strain, relocation. Effect of temperature field and the initial tension. 4) Simple bending angle and bending 5) Simple shear. Simple bending - calculation of normal stresses. Design of curved beams. 6) Transforming of the bent rods. Differential equations of the bending line. 7) Method of initial parameters and Mohr's method. Calculation of the tangential stress - a massive and thin-walled sections. The importance of shear stress in bending. The center of the skid. 8) Torsion free and bound. Big twist - solid and non-circular cross-section circular. Thin-walled cross-section of closed and open. 9) Compound load cases of the rod. The spatial and angle bending. Tension (compression) and bending . Eccentric tension and pressure. The core section. Design of beams in case of a compound stress. 10) Stability and buckling strength of compression members. Euler solutions. Critical power and voltage. Buckling strength approach. 11) The theory of strength and failure. Stress and strain in the point of the body. The principal stress in plane strain, elastic and plastic state. 12)Wall construction, types of stress, stress distribution, deformation 13) Plate structure, types of stress, stress distribution, deformation
Literature
    required literature
  • NOVOTNÝ, R. Vybrané kapitoly ze stavební mechaniky VŠTE ČB předpokládané vydání 2009.
  • ŽÁK, J. Statika, pružnost a pevnost. Brno : VUT, 2005. ISBN 80-239-4965-9.
    recommended literature
  • ŠEJNOHA, J., BITTNAROVÁ, J. Pružnost a pevnost 10. Praha : ČVUT, 2003. ISBN 80-01-02743-0.
  • BITTNAROVÁ, J. Pružnost a pevnost 20 – příklady. Praha : ČVUT, 2003. ISBN 80-01-02709-0.
  • ŠEJNOHA, J., BITTNAROVÁ, J. Pružnost a pevnost 20. Praha : ČVUT, 2004. ISBN 80-01-03082-2.
  • BITTNAROVÁ, J. Pružnost a pevnost 10 – příklady. Praha : ČVUT, 2003. ISBN 80-01-02742-2.
  • ŽÁK, J., PĚNČÍK, J. Stavební mechanika: statika, pružnost a pevnost. Praha : Antikva, 2005. ISBN 80-239-4965-9.
Forms of Teaching
Lecture
Exercise
Teaching Methods
Frontal Teaching
Group Teaching - Cooperation
Critical Thinking
Individual Work– Individual or Individualized Activity
Student Workload
ActivitiesNumber of Hours of Study Workload
Daily StudyCombined Study
Preparation for Seminars, Exercises, Tutorial2323
Preparation for the Final Test5555
Attendance on Lectures2626
Attendance on Seminars/Exercises/Tutorial/Excursion2626
Total:130130
Assessment Methods and Assesment Rate
Exam – written 70 %
Semestr evaluation 30 %
Exam conditions
Successful graduates of the course have to get totally at least 70 points: A 100 – 90, B 89,99 – 84, C 83,99 – 77, D 76,99 – 73, E 72,99 – 70, FX 69,99 – 30, F 29,99 - 0.
Language of instruction
Czech
The course is also listed under the following terms winter 2015, Summer 2016, winter 2016, summer 2017, winter 2017, winter 2018, summer 2019, winter 2019, summer 2020, winter 2020, summer 2021, summer 2022, SUMMER 2023, summer 2024, summer 2025.
  • Enrolment Statistics (summer 2018, recent)
  • Permalink: https://is.vstecb.cz/course/vste/summer2018/PAP_a