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Lecturer(s)
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Bílek Ondřej, doc. Ing. Ph.D.
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Course content
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Content: 1. Introduction to manufacturing technologies, overview of basic concepts, classification of manufacturing processes, relationship between design, technology, and manufacturing economics. 2. Engineering materials and normative classification 3. Physical and mechanical properties of materials and their testing 4. Technical documentation and design standards 5. Plastics processing, principles of plastic product design and selection of production technologies. 6. Production of rubber components, elastomer processing, vulcanization, design principles of rubber parts. 7. Additive manufacturing technologies - SLA, SLS/SLM, FFF/FDM, LOM, BJT, MJT, DED methods, materials used, and industrial applications. 8. Subtractive technologies - conventional machining (turning, milling, drilling) 9. Finishing technologies (grinding, honing, superfinishing, and lapping); achieved quality parameters. 10. Unconventional manufacturing technologies (electroerosion, laser, chemical, and ultrasonic processes), areas of application. 11. Metal casting and precision casting methods 12. Material forming, mass and sheet metal forming production methods 13. Manufacturing technologies in the context of production efficiency and sustainability
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Learning activities and teaching methods
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Monologic (Exposition, lecture, briefing), Methods for working with texts (Textbook, book), Methods for written tasks (e.g. comprehensive exams, written tests)
- Participation in classes
- 52 hours per semester
- Preparation for course credit
- 12 hours per semester
- Home preparation for classes
- 12 hours per semester
- Preparation for examination
- 24 hours per semester
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| prerequisite |
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| Knowledge |
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| Understanding of the physical processes on which the operation of individual technological equipment and technological processes is based is a basic prerequisite for successful completion of a bachelor's degree in Industrial Engineering. Basic knowledge and principles used in the most important production technologies that FaME graduates will encounter in practical life. |
| Understanding of the physical processes on which the operation of individual technological equipment and technological processes is based is a basic prerequisite for successful completion of a bachelor's degree in Industrial Engineering. Basic knowledge and principles used in the most important production technologies that FaME graduates will encounter in practical life. |
| learning outcomes |
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| Very good overview of the basic know-how, forming the foundations of our industrial society. Ability to apply this knowledge in all related subjects, which from various perspectives deal with the issue of monitoring, organizing and managing all aspects of manufacturing activity. A properly completed course will enable graduates who find employment in production organizations a comprehensive view of technical practice, which is the basis of activity and the reason for the existence of each such organization. |
| Very good overview of the basic know-how, forming the foundations of our industrial society. Ability to apply this knowledge in all related subjects, which from various perspectives deal with the issue of monitoring, organizing and managing all aspects of manufacturing activity. A properly completed course will enable graduates who find employment in production organizations a comprehensive view of technical practice, which is the basis of activity and the reason for the existence of each such organization. |
| define sub-manufacturing technologies in the context of an industrial firm |
| define sub-manufacturing technologies in the context of an industrial firm |
| describe the essence of basic machining methods in terms of physical and chemical interaction of the machine-workpiece-tool-preparation system |
| describe the essence of basic machining methods in terms of physical and chemical interaction of the machine-workpiece-tool-preparation system |
| characterize the basic technological approaches for individual technologies and machining methods |
| characterize the basic technological approaches for individual technologies and machining methods |
| characterize cutting conditions and basic calculations related to partial technologies of chip machining |
| characterize cutting conditions and basic calculations related to partial technologies of chip machining |
| to comprehensively describe the production process and related issues with direct relation to technical practice |
| to comprehensively describe the production process and related issues with direct relation to technical practice |
| Skills |
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| evaluate the production process with regard to input requirements |
| evaluate the production process with regard to input requirements |
| classify and apply the cutting tool (cutting tool geometry) with regard to its durability |
| classify and apply the cutting tool (cutting tool geometry) with regard to its durability |
| evaluate the cutting tool with respect to mechanisms, forms and wear criteria |
| evaluate the cutting tool with respect to mechanisms, forms and wear criteria |
| decide on the appropriate application of production technology |
| decide on the appropriate application of production technology |
| determine the necessary cutting and production conditions |
| determine the necessary cutting and production conditions |
| correctly design and determine the efficiency of the production process |
| correctly design and determine the efficiency of the production process |
| teaching methods |
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| Knowledge |
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| Methods for working with texts (Textbook, book) |
| Methods for working with texts (Textbook, book) |
| Methods for written tasks (e.g. comprehensive exams, written tests) |
| Methods for written tasks (e.g. comprehensive exams, written tests) |
| Monologic (Exposition, lecture, briefing) |
| Monologic (Exposition, lecture, briefing) |
| assessment methods |
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| Oral examination |
| Written examination |
| Written examination |
| Analysis of the student's performance |
| Analysis of the student's performance |
| Grade (Using a grade system) |
| Grade (Using a grade system) |
| Oral examination |
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Recommended literature
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AB SANDVIK COROMANT - SANDVIK CZ s.r.o. Příručka obrábění - Kniha pro praktiky. Praha, Scientia, s.r.o, 1997. ISBN 91-97 22 99-4-6.
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BÍLEK, O., LUKOVICS, I. Výrobní inženýrství a technologie. 173 s.. Zlín: UTB, 2014. ISBN 9788074544712.
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GROOVER, Mikell P. Fundamentals of modern manufacturing: materials, processes, and systems.Sixth edition.. Hoboken:Wiley, 2016. ISBN 978-1-119-12869-4.
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Kletečka, Fořt. Technické kreslení. CP Books Brno, 2005.
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KOCMAN, K., PROKOP, J. Technologie obrábění. Brno: Akademické nakladatelství CERM, s.r.o., 2005. ISBN 80-214-3068-0.
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SHAW, M.C. Metal Cutting Principles. Oxford University Press, 2005. ISBN 0-19-514206-3.
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WALKER, J.R. Machining Fundamentals. The Goodheart-Wilcox Company, Inc.,, 2004. ISBN 1-59070-249-2.
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