Reprint

Technologies of Coatings and Surface Hardening for Tool Industry II

Edited by
January 2024
220 pages
  • ISBN978-3-0365-8888-9 (Hardback)
  • ISBN978-3-0365-8889-6 (PDF)

This is a Reprint of the Special Issue Technologies of Coatings and Surface Hardening for Tool Industry II that was published in

Chemistry & Materials Science
Engineering
Summary

The innovative multi-component, nanocomposite, self-healing adaptive, and nano-thin coatings, technologies of their deposition, surface hardening and engineering developed in recent years allow us to obtain practically any physical–mechanical or crystal–chemical properties of the surface for prolongation of the service life of responsible product working under the conditions of intensive mechanical and thermal loads, and moisture. The scientific approach to improving the operational parameters of the product's surface made of traditional industrial materials is a highly costly and long-lasting process. Different technological techniques, such as plasma vapor deposition (radio frequency magnetron sputtering, high-power impulse magnetron sputtering, closed-field unbalanced magnetron sputtering, filtered cathodic vacuum arc deposition), atomic layer deposition, and other solutions are used for this. The edition aims to provide a review of the current state of the research and developments in the field of coatings and surface hardening technologies for cutting tools and microelectronics components, diagnostic solutions of the sputtering systems that can ensure a substantial increase in the reliability and operational life of the product. The main emphasis lies in the results of the research and engineering works that have proven successful in laboratory or manufacturing conditions. The presented studies are aimed at completing the previously published advances in the first Special Issue and contributing to the transfer of the tool industry to the next technological paradigm.

Format
  • Hardback
License and Copyright
© 2022 by the authors; CC BY-NC-ND license
Keywords
multilayer composite multicomponent coating; diffusion; wear; metal-cutting tool; plastic deformation; oxidation; coatings; nickel alloy; wear; diffusion; CrZrSiN coating; bilayer period; hardness; friction coefficient; adhesion strength; CrAlN coating; interlayer; friction coefficient; adhesion strength; thermal stability; room temperature-ALD; high-performance computing; ASIC; wear-out test; uHAST; MoSi2-based coatings; magnetron sputtering; microstructure; hardness; Young’s modulus; tribological properties; impact wear resistance; oxidation resistance; hexagonal boron nitride coatings; in-situ generated composite; tribochemistry; high temperature low friction; ceramic inserts; surface layer; diamond grinding defects; lapping and polishing; vacuum arc coatings; hardened steel milling; dispersion of resistance; tool reliability; microtexturing; carbide tool; thermal force parameters; mathematical modeling; electrical discharge plasma; analyzing methods; Physical Vapor Deposition (PVD); energy distribution; counter milling; nanostructured composite multilayer coatings; titanium alloys; wear resistance; tool durability period; cutting path length; adhesion component of friction coefficient; temperature; cutting forces; nanostructured coatings; yttrium nitride; tool wear; oxidation; metal cutting; n/a