Course detail
Strength of Materials I
FSI-4PP Acad. year: 2021/2022 Summer semester
Basic concepts and problems of strength analysis. Basic mechanical properties of material. Concepts of stress and strain. General theorems of linear elasticity. Definition and classification of bar and beam as the simplest model of a body. Bar under simple loading – tension / compression, torsion; bending of beams. Basic limit states of ductile and brittle materials under static loading. Safety conditions. Beams and bars under combined loading. Stability of compressed bars.
Supervisor
Learning outcomes of the course unit
Basic knowledge of stress and strain related to simple cases of loaded bars and beams and the idea of the boundaries of applicability of these classical approaches. Criteria of fundamental limit states and determination of safety and dimensions of designed bodies or machine parts.
Prerequisites
Basic knowledge of statics and mathematics. Statics – conditions of static equilibrium and equivalence, free-body diagrams, assessment of static determinacy, shear force and bending moment diagrams. Mathematics – vectors and matrices, differential and integral calculus, solutions to differential equations. Knowledge of the software Matlab.
Planned learning activities and teaching methods
The course is taught through lectures explaining the basic principles and theory of the discipline. Exercises are focused on practical topics presented in lectures.
Assesment methods and criteria linked to learning outcomes
The course-unit credit is granted under the condition of active participation in seminars and passing the seminar tests of basic knowledge (at least 10 ECTS points out of 20 must be gained). The points gained in seminar tests are included in the final course evaluation.
Final examination: Written part of the examination plays a decisive role, where the maximum of 80 ECTS points can be reached. Solution of several computational problems is demanded. The problems come from typical profile areas of given subject and supplied by a theoretical question, proof, etc. The lecturer will specify exact demands like the number and types problems during the semester preceding the examination.
Final evaluation of the course is obtained as the sum of ECTS points gained in seminars and at the examination. To pass the course, at least 50 points must be reached.
Language of instruction
Czech
Aims
The objective of the course Strength Analysis I is to equip the students with methodology for determination of strain and stress in bodies and risk assessment of basic limit states. Practical experience with computations of the simplest bodies will be further supplemented with basic knowledge necessary for the strength design of real machine parts.
Specification of controlled education, way of implementation and compensation for absences
Attendance at practical training is obligatory. Head of seminars carry out continuous monitoring of student's presence, their activities and basic knowledge.
The study programmes with the given course
Programme B-FIN-P: Physical Engineering and Nanotechnology, Bachelor's
branch ---: no specialisation, 7 credits, compulsory-optional
Programme B-MET-P: Mechatronics, Bachelor's
branch ---: no specialisation, 7 credits, compulsory
Programme B-VTE-P: Production Technology, Bachelor's
branch ---: no specialisation, 7 credits, compulsory
Programme B-MAI-P: Mathematical Engineering, Bachelor's
branch ---: no specialisation, 7 credits, compulsory
Programme B-PDS-P: Industrial Design, Bachelor's
branch ---: no specialisation, 7 credits, compulsory
Programme B-ZSI-P: Fundamentals of Mechanical Engineering, Bachelor's
branch MTI: Materials Engineering, 7 credits, compulsory
Programme B-ZSI-P: Fundamentals of Mechanical Engineering, Bachelor's
branch STI: Fundamentals of Mechanical Engineering, 7 credits, compulsory
Type of course unit
Lecture
52 hours, optionally
Teacher / Lecturer
Syllabus
Definition of subject contents. Basic terms – deformation, stress, stress state, limit states, safety.
Mechanical properties of material and its computational models. Characteristics of linear elastic body. Definition of linear strength of materials.
Work done by forces, Castigliano's theorem. Saint -Venant's principle. Beam in strength of materials – definition, classification.
Geometrical characteristics of cross-section. Area moments of inertia, transformation with respect to the translated and rotated axes. Principal central area moments of inertia.
Axially loaded bars:
– Deformation, stress state and strain energy.
– Influence of deviations on deformation and stress state, notches and safety check.
– Statically indeterminate beam loaded in tension and compression.
– Truss structures and trusses.
Bars in torsion:
– Deformation, stress state, strain energy and influence of deviations on deformation and stress state.
– Statically indeterminate beam and safety check.
Beams in bending:
– Stress state, deformation, strain energy. Methods of determination of deflection.
– Influence of deviations on stress state and deformation. Shear stress resulting from shear force. Safety check.
– Statically indeterminate beam.
– Initially curved beams in bending, frames.
– Shear stress for thin-walled profiles, shear center.
Stability of columns. Influence of deviations on the critical load.
Stability of columns from real material. Eccentric compression.
Stress state in the point of a body, principal stresses.
Representation of stress state using Mohr's circle. Particular cases of stress state, plane stress state.
Criteria for materials of bodies in ductile or brittle state without a priori defects of the crack type at static loading.
Combined loading of beams.
Beams loaded by temperature. Non-linearity in bending.
Overview of problems solvable by analytical and numerical methods.
Eurocodes – Design of steel structures.
Examples of possibilities of contemporary methods of experimental strength of materials.
Guided consultation
26 hours, optionally
Teacher / Lecturer
Syllabus
Facultative tutorials will be dedicated to individual questions, discussions and possible application enhancement of the topics, presented in the time-schedule of lectures and seminars. Direct link to the time schedule of seminars is supposed.
Exercise
12 hours, compulsory
Teacher / Lecturer
Syllabus
Internal forces and moments for straight bar.
Internal forces and moments for curved beam and frame.
Area moments of inertia. Mohr's circle.
Loading in tension, stress state and deformation. Statically determinate tasks.
Loading in tension, stress state and deformation. Statically indeterminate tasks.
Loading in torsion. Statically determinate and indeterminate tasks.
Loading in bending. Stress state and deformation for statically determinate beam.
Loading in bending. Stress state and deformation for statically indeterminate beam.
Curved beams and frames. Closed beams (frames). Utilization of symmetry and antimetry.
Stability of columns. Safety for compressive loading of bars from real material.
Calculation of trusses considering the stability of columns. Truss structures.
Combined loading.
Computer-assisted exercise
14 hours, compulsory
Syllabus
Internal forces and moments for straight bar.
Internal forces and moments for curved beam and frame.
Area moments of inertia. Mohr's circle.
Loading in tension, stress state and deformation. Statically determinate tasks.
Loading in tension, stress state and deformation. Statically indeterminate tasks.
Loading in torsion. Statically determinate and indeterminate tasks.
Loading in bending. Stress state and deformation for statically determinate beam.
Loading in bending. Stress state and deformation for statically indeterminate beam.
Curved beams and frames. Closed beams (frames). Utilization of symmetry and antimetry.
Stability of columns. Safety for compressive loading of bars from real material.
Calculation of trusses considering the stability of columns. Truss structures.
Combined loading.