Czech

Not applicable.

Students will be familiar with physics and other aspects of machining. They will be able to define technological processes for all fundamental manufacturing methods and will have an overview of principles applied for technological assembly.

Successful completion of the subject ”Production Technologies II”, knowledge of fundamental methods of machining. Knowledge of mathematics, physics and material science.

Not applicable.

The course is taught through lectures explaining the basic principles and theory of the discipline. Teaching is suplemented by practical laboratory work.

Examination consists of a written and an oral part. The written part is focused on the solution of a technological problem. The assessment reflects student’s professional skills. The oral part tests student's knowledge of a topic selected randomly from the concerned areas to assess the depth of understanding.

Lecture 1. Fundamentals of machining.
2. Physics of cutting, chip formation.
3. Metal cutting phenomena.
4. Tool materials for cutting. HSS, cemented carbides, ceramics, diamond, etc.
5. Turning. Outer and inner surfaces.
6. Milling. Face and shoulder milling,grooving, copying, special operations.
7. Drilling and boring, reaming.
8. Finishing technologies. Non-conventional methods of machining.
9. Machine tools for automatic production.CNC machining.
10. Economics of machining. Productivity, costs.
11. Gear production. Machine tools. Rapid prototyping.
12. Special technologies - HSM/HSC/HFM.
13. Fundamentals of technology and assembly managements.
Labs and studios 1. Fundamentals of machining.
2. Calculations.
3. Metal cutting phenomena.
4. Tool materials for cutting.
5. Productivity and economics of machining.
6. Machine tools.
7. Turning.
8. Drilling and boring.
9. Milling.
10. Grinding and other finishing methods.
11. Machine tools for automatic production.
12. NC/CNC machining. Sinumerik 810D.
13. Gear production. Non-conventional methods of machining.

Not applicable.

The aim of the course is for students to master fundamental machining technologies based on the principles of physical and chemical interactions of the machine-workpiece-tool system. In addition, manufacturing assembly and other concerned disciplines are dealt with.

The student’s own work and knowledge is assessed in practicals. According to the studied topic some lessons will be practicals - carried out in the lab, and some will be focused on the theory - calculations carried out in the classroom in a seminar form. Absence from seminars should be substituted for by attending a seminar with another study group or individually by the agreement with the teacher. Lessons may be occasionally inspected by the head of the department.

Not applicable.

Not applicable.

AB SANDVIK COROMANT - SANDVIK CZ s.r.o. Příručka obrábění - Kniha pro praktiky. (Přel. z: Modern Metal Sutting - A Practical Handbook. Překlad M. Kudela.), 1. vyd., Praha, Scientia, s.r.o.. ed. J. Machač, J. Řasa, 1997. ISBN 91-97 22 99-4-6. (CS)
De Vos, P.., STAHL, J.-E. Aplikovaná fyzika v obrábění kovů - praktické zkušenosti. Fagersta. Seco Tools AB. 2016 (CS)
KOCMAN, K., PROKOP, J. Technologie obrábění. 2. vyd.. CERM, s.r.o., Brno, 1996. ISBN 80-214-1996-2. (CS)
SHAW, M.C. Metal Cutting Principles. Oxford University Press, 2nd ed., 2005, ISBN 0-19-514206-3 (EN)
TLUSTY, J. Manufacturing Process and Equipment. Prentice Hall, 1999. ISBN 10-0201498650. (EN)
Walker, J.R.: Machining Fundamentals. The Goodheart-Wilcox Company, Inc., 7th ed., pp. 640, 2007, ISBN 1-59070-249-2 (EN)

Not applicable.