KELLY, A., GROVES, G. W., KIDD, P. Crystallography and Crystal Defects. Wiley, John and Sons, Incorporated, 2000, 486pp.
BEKE, D. L., SZABO, I. A. Diffusion and Stresses. Scient. Publications,
Limited, 1996, 356pp.
FUENTES, M., SEVILLANO, J. G. Recrystallization. Trans Tech Publications,
Limited, 1992, 752pp.
HERTZBERG, R. W. Deformation and Fracture Mechanics of Engineering Materials.
Wiley, John and Sons, Incorporated, 1995, 786pp.
MATTSSON, E. Basic Corrosion Technology for Scientists and Engineers, 2nd Ed. IOM/Maney Publishing, 1999, 224pp.
Theory of Technological Processes
| Language of instruction | angličtina, čeština |
|---|---|
| Code | 345-0501 |
| Abbreviation | TTP |
| Course title | Theory of Technological Processes |
| Coordinating department | Department of Mechanical Technology |
| Course coordinator | doc. Ing. Lucie Krejčí, Ph.D. |
Summary
The graduate of the course understands the relationships between the internal structure of materials, their properties, and the course of technological processes. They are able to explain the influence of technological operations such as machining, forming, welding, heat treatment, and surface treatments on changes in material structure and properties. They are familiar with the mechanisms of material degradation, including fatigue, corrosion, and diffusion processes, and understand the influence of technological and operating conditions on their initiation and progression. They distinguish between elastic and plastic behavior of materials and are able to assess their significance for the design and service life of structures. The acquired knowledge is applied in evaluating the suitability of technological processes and in preventing material degradation in engineering practice.
Literature
Advised literature
NALWA, H. S.: Nanostructured Materials and Nanotechnology. Academic Press, 2002