Syllabus
General information
For ED |
Bachelor |
|
Knowledge area |
19 "Architecture and construction" |
|
Speciality |
192 " Building and engineering of the city" |
|
Specialization |
- |
|
Characteristics of the discipline |
||
Type |
Obligatory |
|
language of teaching |
English |
|
Total number of hours |
180 |
|
Number of credits ECTS |
6 |
|
Number of thematic modules |
5 |
|
Form of control |
test /examination |
|
Indicators of the discipline for daily learning |
||
Year of study (course) |
2 |
|
Semester |
3 |
4 |
Lectures |
30 hours. |
30 hours. |
Practical, seminar classes |
30 hours. |
30 hours. |
Independent study |
30 hours. |
30 hours. |
Teacher
Kutsenko Anastasiia Hrygorivna
Ph. D. of Physical and Mathematical Sciences, Associated Prof.
Department of Mechanics
Educational building 11, office 226.
e-mail: kutsenko@nubip.edu.ua
DESCRIPTION OF COURSE
Mechanics of materials and construction is a basic engineering subject that must be understood by anyone concerned with the strength and physical performance of structures, whether those structures are man-made or natural. The subject matter includes such fundamental concepts as stresses and strains, deformations and displacements, elasticity and inelasticity, strain energy, and load-carrying capacity. These concepts underlie the design and analysis of a huge variety of mechanical and structural systems.
The teacher main aims to help students taking courses taught in English at National University of life and environmental sciences of Ukraine, Faculty of Design and Engineering, in their studies of one of the most important and most difficult engineering topic.
Prerequisites for studying the course. Studying of the discipline assumes that you have knowledge of mathematics, physics, theoretical mechanics.
Discipline provides a number of competencies
Gc1. Ability to learn and master modern knowledge.
Gc 2. Knowledge and understanding of the subject area, professional understanding activities of the construction industry.
Gc 3. Ability to search, process and analyze information from different sources.
Gc 4. Skills in the use of information and communication technologies.
Gc 5. Ability to solve tasks and accept appropriate ones reasonable decisions.
Gc 6. Ability to apply knowledge in practical situations.
Gc 7. Ability to evaluate and ensure the quality of work performed.
A result of studying of discipline the student should know:
- The basic hypotheses and methods, which are used of calculations for strength, rigidity and stability of elements of buildings;
- The methods of determining the internal forces factors in statically determinate and statically indeterminate elastic systems;
- The relation among external forces and stresses and displacements in the different kind of simple and complex deformations.
THE STRUCTURE OF DISCIPLINE
Title of thematic modules and themes |
Hours (Lectures / Laboratory lessons/ Independent study) |
Training facts |
Tasks |
Estimation, units |
||
3 semester |
||||||
The thematic module 1. TENSION AND COMPRESSION |
20 |
|||||
2/2/2 |
Student should be know: the basic hypotheses and the definitions of the mechanics of materials and constructions Student should be able to: built the diagrams of internal forces and tensions in case of tension or compression of the bar.
|
Delivery of practicaly works. Execution of independent works. |
2 |
|||
2/2/2 |
3 |
|||||
2/2/2 |
5 |
|||||
2/2/2 |
5 |
|||||
Theme 5. The geometric characterizations of the plane cross sections. |
2/2/2 |
5 |
||||
The thematic module 2. TORSION |
30 |
|||||
Theme 1. The geometric characterizations of the plane cross sections. |
2/2/2 |
Student should be know: the main geometric characterizations of the plane cross sections; the relation among internal forces and tensions in cases of direct shear and torsion. Student should be able to: built the diagrams of internal forces and tensions in case of torsion of the bar. |
Delivery of practicaly works. Execution of independent works. |
10 |
||
2/2/2 |
2 |
|||||
2/2/2 |
5 |
|||||
2/2/2 |
5 |
|||||
Theme 5. The method of calculating the bar on strength and rigidity by torsion |
2/2/2 |
8 |
||||
The thematic module 3. BEAM BENDING |
20 |
|||||
Theme 1. The equation of Shearing force for the cantilever and simple beams |
2/2/2 |
Student should be know: the equations of bending moment and shearing force for the cantilever and simple beams. Student should be able to: built the diagrams of internal forces and tensions in case of bending of the beam |
Delivery of practicaly works. Execution of independent works. |
2 |
||
Theme 2. The equation of Bending moment for the cantilever and simple beams. |
2/2/2 |
2 |
||||
Theme 3. The calculation method cantilever beam on the strength by the normal stresses |
2/2/2 |
8 |
||||
Theme 4. The calculation method simple beam on the strength by the normal stresses. |
2/2/2 |
4 |
||||
2/2/2 |
4 |
|||||
Total for 3 semester |
30/30/30 |
- |
- |
70 |
||
Test |
30 |
|||||
Total for 3 semester |
100 |
|||||
|
|
|||||
4 semester |
|
|||||
The thematic module 4. METHODS OF DEFINDING OF BEAM DEFORMATION |
34 |
|||||
2/2/2 |
Student should be know: the basis methods for definition the deformations of beam and frame. Student should be able to: define the deformations of beam and frame by different methods. |
Delivery of practicaly works. Execution of independent works. |
4 |
|||
2/2/2 |
4 |
|||||
2/2/2 |
4 |
|||||
2/2/2 |
4 |
|||||
2/2/2 |
4 |
|||||
2/2/2 |
4 |
|||||
Theme 7. The definitions of the statically indeterminate constructions. |
2/2/2 |
Student should be know: The definitions of the statically indeterminate constructions; the three moment’s theorem. Student should be able to: applicate methods of definitions of the deformations for statically indeterminate beam and frame. |
Delivery of practicaly works. Execution of independent works. |
5 |
||
Theme 8. The application of the Castigliano´s theorem to the statically indeterminate constructions. |
2/2/2 |
5 |
||||
The thematic module 5. THE COMPLEX DEFORMATIONS |
36 |
|||||
Theme 1. The three moment’s theorem. |
2/2/2 |
Student should be know: Stress and Strain in the case of the action of complex deformations of construction.
Student should be able to: calculate beam and frame by acting of complex Stress and Strain. |
Delivery of practicaly works. Execution of independent works. |
5 |
||
Theme 2. The application of the Verescagin´s rule to the statically indeterminate constructions. |
2/2/2 |
5 |
||||
Theme 3. Analysis of Stress and Strain in the case of the action of compression and bending at one time |
2/2/2 |
4 |
||||
Theme 4. Analysis of Stress and Strain in the case of the action of tension and bending at one time |
2/2/2 |
4 |
||||
Theme 5. Analysis of Stress and Strain in the case of the action of two bending moments at one time, which acting in perpendicular planes |
2/2/2 |
4 |
||||
Theme 6. The calculation method of column. |
2/2/2 |
6 |
||||
Theme 7. Analysis of Stress and Strain in the case of the action of bending and torsion at one time. |
2/2/2 |
8 |
||||
Total for 4 semester |
30/30/30 |
- |
- |
70 |
||
Exam |
30 |
|||||
Total for course |
100 |
|||||
EVALUATION POLICY
Deadline and retake policy: |
The student must submit the work within the time specified by the teacher. Works that are submitted in violation of deadlines without good reason are evaluated at a lower grade. Rearrangement of modules takes place with the permission of the lecturer if there are good reasons (for example, hospital). |
Academic Integrity Policy: |
Write-offs during tests and exams are prohibited (including the use of mobile devices). Course papers, abstracts must have correct text references to the literature used |
Visiting policy: |
The student is obliged to attend classes of all kinds every day in accordance with the established schedule, not to be late, to have the appropriate appearance. For objective reasons (for example, illness, international internship) training can take place individually (in online form in consultation with the dean of the faculty) |
STUDENT EVALUATION SCALE
Student rating, points |
Evaluation results on national exam tests |
|
Exams |
Tests |
|
90-100 |
Excellent |
Accepted |
74-89 |
Great |
|
60-73 |
Satisfactory |
|
0-59 |
Unsatisfactorily |
Not accepted |
Recommended Literature
- Main:
1. Mechanics of materials: Theory and Problems. Maual / A. Kutsenko, M. Bondar, V. Pryshliak. – Nizhyn: „Vidavnitstvo „Aspekt-Poligraf”, 2016. – 360 p.
2. Mechanics of Materials and structures. Tutorial / M.G. Chausov, V.M. Shvayko, A.P. Pylypenko, M.M. Bondar, V.B. Berezin; edited by M.G. Chausov. – K: CP „Komprint”, 2015. – 259 p.
– ancillary:
1. Beer F.P., Johnston E.R., et. al.: Mechanics of materials., 8th Edition, Graw – Hill. Inc., 2020. – 896 p.
2. Bansal R. K.: Strength of Materials., 5th Edition, Laxmi Publications., 2014. – 1106 p.
3. John C.J., Ross C.T.F.: Strength of Materials and Structures. Arnold. – 719 p.
4. Dupen B.: Applied Strength of Materials for Engineering Technology. Indiana University - Purdue University Fort Wayne., 2014. – 151 p.
5. R.K. Rajput. A Textbook of Strength of Materials (Mechanics of Solids) in SI Units., 2018 – 1312 p.
6. Sohor M.: Strength_of_materials., 2011. – 210 p.
Video materials
Modulus 1. https://www.youtube.com/results?search_query=compression+of+bar
Modulus 2. https://www.youtube.com/results?search_query=geometric+characteristics+in+strength+of+materials
https://www.youtube.com/results?search_query=torsion
Modulus 3. https://www.youtube.com/results?search_query=bending
Mjdulus 4. https://www.youtube.com/results?search_query=deformation+of+beam
Modulus 5. https://www.youtube.com/results?search_query=column