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Lecturer(s)
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Course content
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unspecified
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Learning activities and teaching methods
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Lecturing, Demonstration, Work activities (Practical training), Practice exercises, Teamwork
- Participation in classes
- 16 hours per semester
- Home preparation for classes
- 44 hours per semester
- Preparation for course credit
- 30 hours per semester
- Preparation for examination
- 30 hours per semester
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| prerequisite |
|---|
| Knowledge |
|---|
| Knowledge of engineering technologies, material science. |
| Knowledge of engineering technologies, material science. |
| learning outcomes |
|---|
| Specify the tool materials used in the manufacture of tools. |
| Specify the tool materials used in the manufacture of tools. |
| Define the differences between the basic types of tool materials and their areas of use. |
| Define the differences between the basic types of tool materials and their areas of use. |
| Characterize the application areas of powder metallurgy. |
| Characterize the application areas of powder metallurgy. |
| Describe the principles of unconventional technologies that can be used in the production of tools. |
| Describe the principles of unconventional technologies that can be used in the production of tools. |
| Orientation in the field of production automation and control. |
| Orientation in the field of production automation and control. |
| Skills |
|---|
| To choose the appropriate type of material for a specific part of the tool. |
| To choose the appropriate type of material for a specific part of the tool. |
| To propose a technological procedure for the production of a tool using classical machining methods. |
| To propose a technological procedure for the production of a tool using classical machining methods. |
| To propose a technological procedure for tool production using foundry methods. |
| To propose a technological procedure for tool production using foundry methods. |
| To process the design of production automation and control for a specific application. |
| To process the design of production automation and control for a specific application. |
| To propose a method of inspection of the produced tool. |
| To propose a method of inspection of the produced tool. |
| teaching methods |
|---|
| Knowledge |
|---|
| Lecturing |
| Lecturing |
| Demonstration |
| Educational trip |
| Demonstration |
| Educational trip |
| Skills |
|---|
| Practice exercises |
| Practice exercises |
| Educational trip |
| Educational trip |
| Work activities (Practical training) |
| Work activities (Practical training) |
| Teamwork |
| Teamwork |
| assessment methods |
|---|
| Knowledge |
|---|
| Analysis of the student's performance |
| Oral examination |
| Analysis of works made by the student (Technical products) |
| Analysis of the student's performance |
| Written examination |
| Written examination |
| Oral examination |
| Analysis of works made by the student (Technical products) |
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Recommended literature
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Bílek, O., Lukovics, I. Výrobní inženýrství a technologie. Zlín: UTB, 2014. ISBN 978-80-7454-471-2.
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Kocman, K. Speciální technologie: obrábění. 3. přeprac. a dopl. vyd. 227 s. Učební texty vysokých škol.. Brno: CERM, 2004. ISBN 8021425628.
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Kocman, K. Technologické procesy obrábění. Brno: Akademické nakladatelství CERM, 2011. ISBN 978-80-7204-722-2.
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Rajput, R.K. A textbook of manufacturing technology: manufacturing processes: for B.E./B. Tech., A.M.I.E. - Section B, and competitive examinations. 2nd Ed.. Bengaluru: Laxmi Publications (P) Ltd, 2015. ISBN 978-81-318-0244-1.
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Smith, G.T. Cutting tool technology: industrial handbook. London: Springer, 2008. ISBN 978-1-84800-204-3.
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Stephenson, D., Agapiou, J.S. Metal cutting theory and practice. 3rd Ed.. Boca Raton: CRC Press, Taylor & Francis Group, 2016. ISBN 978-1-4665-8753-3.
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