VŠTE:NE_SMT Engineering mat. for ec. - Course Information

NE_SMT Engineering materials for economists

Extent and Intensity

2/2/0. 5 credit(s). Type of Completion: zk (examination).

Teacher(s)

doc. Ing. Karel Gryc, MBA, Ph.D. (seminar tutor)
doc. Ing. Ladislav Socha, MBA, Ph.D. (seminar tutor)

Guaranteed by

doc. Ing. Karel Gryc, MBA, Ph.D.
Faculty of Technology – Rector – Institute of Technology and Business in České Budějovice
Supplier department: Faculty of Technology – Rector – Institute of Technology and Business in České Budějovice

Timetable of Seminar Groups

NE_SMT/NE2: Sat 25. 9. 13:05–14:35 B3, 14:50–16:20 B3, 16:30–18:00 B3, Sat 20. 11. 13:05–14:35 B2, 14:50–16:20 B2, 16:30–18:00 B2, Sat 4. 12. 11:25–12:55 B1, 13:05–14:35 B1, K. Gryc, L. Socha
NE_SMT/P01: Tue 8:00–9:30 N121, K. Gryc, L. Socha
NE_SMT/S01: Tue 9:40–11:10 N121, K. Gryc, L. Socha

Course Enrolment Limitations

The course is offered to students of any study field.

Course objectives supported by learning outcomes

The aim of the course is to acquaint students with the principles of conventional and progressive metal materials used in engineering practice. Graduates are able to orientate in basic contours in key metal materials, fundamentals of physico-chemical processes, crystalline structure and lattice defects, methods of microscopic structure analysis, mechanical tests carried out in accordance with relevant standards. The graduate is able to critically evaluate individual types of materials, to classify and evaluate information contained in protocols from measurement of basic material properties. The graduate is able to analyze basic types of binary equilibrium diagrams. The graduate is able to orientate in the range of corrosion and corrosion protection of metals. The graduate will acquire basic knowledge and skills in the field of metallic materials, which will enable him to effectively manage production processes in the company, where these materials are used within the material flow, products or goods.

Learning outcomes

Upon successful completion of this course, the student: 18.1 can define the basic distribution of metallic materials and further characterize their structural, mechanical and utility properties 18.2 can define the internal structure of matter, crystal structure of metals, point, line, area and spatial defects of crystal lattice 18.3 has a basic knowledge of thermodynamics, kinetics and diffusion of metallic systems 18.4 has basic knowledge of solidification and crystallization of metals and alloys, segregation phenomena and solid state phase transformations 18.5 has basic knowledge of metallography and mechanical testing of metals and their alloys 18.6 has a basic knowledge of corrosion and corrosion protection of metals 18.7 can perform basic analysis of binary equilibrium diagrams of iron alloys and non-ferrous metals 18.8 can apply metallographic methods and mechanical tests of metals in accordance with relevant standards 18.9 is able to critically evaluate individual types of metallic materials with respect to their properties and suitable applications in technical practice

Syllabus

• Lectures 1. Introduction to materials, basic classification and their use in engineering practice. (18.2, 18.9) 2. Matter, its inner structure, crystal structure of metals, point, line, surface and spatial defects of crystal lattice. (18.2) 3. Fundamentals of thermodynamics, kinetics and diffusion of metallic systems. (18.3) 4. Phase transformations in metals. Basic types of binary systems. Relationship between binary diagrams and properties of alloys. (18.3, 18.7, 18.9) 5. Solidification and crystallization of metals and alloys, segregation phenomena. Phase transformations in solid state. (18.3, 18.9) 6. Metallography. Light microscopy, macrostructure, metal purity, grain size. (18.6, 18.8, 18.9) 7. Mechanical properties of metals and their alloys: influence of microstructure on mechanical properties, types of deformation. (18.6, 18.8, 18.9) 8. Testing of mechanical properties of metals and their alloys. Static, hardness and bending tests. Tests for evaluation of limit states of materials. (18.6, 18.8, 18.9) 9. Iron-steel alloys. Their characteristics, properties and use. (18.8, 18.9) 10. Iron alloys - cast iron. Their characteristics, properties and use. (18.8, 18.9) 11. Brief characteristics of selected non-ferrous metal alloys and their use, part 1. (18.7, 18.9) 12. Brief characteristics of selected non-ferrous metal alloys and their use, part 2. (18.7, 18.9) 13. Corrosion of metals. Types of corrosion and consequences. Active and passive corrosion protection of metals. (18.7, 18.9) Seminar 1. Introductory information. Safety regulations, ways of working in laboratory conditions. Brief overview of exercises and credit requirements. Assignment of semestral work. (18.1 - 18.9) 2. Excursion to material laboratories and testing rooms of VŠTE industrial partners. (18.4, 18.8) 3. Basic calculations in the field of thermodynamics of metals and alloys (18.3). 4. Basic binary equilibrium diagrams. (18.7) 5. Light microscopy and optical emission spectrometry: preparation for practical exercises; work with standards for evaluation of individual types of metals and alloys. Preparation of selected types of protocols. (18.7, 18.9) 6. Light microscopy: practical exercise; preparation of metallographic samples, work with optical microscope, evaluation of microstructures on the basis of taken photographs, creation of protocol. (18.7, 18.9) 7. Optical emission spectrometry: practical exercises; sample preparation, calibration, work with optical emission spectrometer, evaluation of measurement results and creation of protocols. (18.7, 18.9) 8. Tensile and impact bending tests: preparation for practical exercises; work with standards for evaluation of individual types of metals and alloys. Preparation of selected types of protocols. (18.7, 18.9) 9. Tensile test: practical exercise; method of sample preparation, tensile testing, evaluation of test results and creation of reports. (18.7, 18.9) 10. Impact bending test: practical exercise; method of sample preparation, impact tests, evaluation of test results and creation of reports. (18.7, 18.9) 11. Binary diagrams of iron alloys: metastable (Fe-Fe3C) and stable (Fe-C). (18.3, 18.7, 18.9) 12. Selected binary diagrams of non-ferrous metals (Ni, Ti, Al, Cu, Zn, Mg). (18.3, 18.7, 18.9) 13. Final test, evaluation of semestral work. (18.1 - 18.9)

Literature

required literature
• SKÁLOVÁ, J., J. KOUTSKÝ a V. MOTYČKA, 2010. Nauka o materiálech. 4. vyd. Plzeň: Západočeská univerzita. ISBN 978-80-7043-874-9.
• SKÁLOVÁ, J., KOVAŘÍK, R., BENEDIKT, V. Základní zkoušky kovových materiálů. 4. vyd. - dotisk. Plzeň: Západočeská univerzita, 2010. 175 s. ISBN 978-80-7043-417-8.
• SILBERNAGEL, A., V. HRUBÝ, M. GREGER a J. NĚMEC 2011. Struktura, vlastnosti, zkoušení a použití kovů. Ostrava: Kovosil. ISBN 978-80-903694-6-7.
• ASKELAND, D., R. FULAY, P. P. WRIGHT a J. WENDELIN, 2010. The Science and Engineering of Materials. 6. vyd. Stamford: Cengage Learning. ISBN 978-0-495-29602-7.
• MACHEK, V. a J. SODOMKA, 2008. [Nauka o materiálu. 3. část], Speciální kovové materiály. Praha: České vysoké učení technické. ISBN 978-80-01-04212-0.vvv

recommended literature
• ASHBY, M., F. a D. R. H. JONES, 2012. Engineering Materials 1, An Introduction to Properties, Applications and Design. 4. vyd. Oxford: Elsevier. ISBN 978-0-0080-96665-6.
• MACHEK, V. a J. SODOMKA, 2007. [Nauka o materiálu]. 2. část, Vlastnosti kovových materiálů. Praha: Nakladatelství ČVUT. ISBN 978-80-01-03686-0.
• KADLEC, J. a M. POSPÍCHAL, 2010. Nauka o materiálu I. Brno: Univerzita obrany. ISBN 978-80-7231-705-9.
• SKRBEK, B., 2010. Výběr materiálových norem: pracovní pomůcka. Liberec: Technická univerzita v Liberci. ISBN 978-80-7372-634-8. PILOUS, V., 2008. Technologie kovových materiálů. 2. vyd. Plzeň: Západočeská univerzita. ISBN 978-80-7043-699-8.

Forms of Teaching

Lecture
Seminar
Exercise
Professional Practice
Tutorial
Consultation

Teaching Methods

Frontal Teaching
Group Teaching - Cooperation
Project Teaching
Brainstorming
Critical Thinking
Individual Work– Individual or Individualized Activity
Teaching Supported by Multimedia Technologies

Student Workload

Activities	Number of Hours of Study Workload
	Daily Study	Combined Study
Project - semester	26	26
Preparation for Lectures	16
Preparation for Seminars, Exercises, Tutorial	16	26
Preparation for the Final Test	20	62
Attendance on Lectures	26
Attendance on Seminars/Exercises/Tutorial/Excursion	26	16
Total:	130	130

Assessment Methods and Assesment Rate

Test – final 70 %
Project – semestral 30 %

Exam conditions

For successful completion of the course it is necessary to achieve at least 70% of the total and final evaluation under the conditions set out below. In the interim evaluation it is possible to get 30 points, ie 30%. In the final evaluation you can get a total of 70 points, ie 70%. Overall classification of the course, ie points for final evaluation (70 - 0) + points from continuous evaluation (30 - 0): 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. Full-time students are obliged to fulfill the compulsory 70% attendance at contact instruction, ie everything except lectures. If the attendance is not fulfilled, the student will be automatically classified as “F”.

Language of instruction

Czech

Teacher's information

Participation in all forms of education is solved by a separate internal standard of VŠTE (Evidence of students' attendance at VŠTE). 70% attendance is obligatory for full-time students.

• Enrolment Statistics (winter 2021, recent)
  
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