Accès libre

Pareto Optimal Multi-Objective Optimization of Antiwear Tialn/Tin/Cr Coatings

À propos de cet article


1. Dobrzańska-Danikiewicz A.D.: The development perspectives of Physical Vapour Deposition technologies. Journal of Achievements in Materials and Manufacturing Engineering 54 (2012), 103-109.Search in Google Scholar

2. Bell T., Mao K., Sun Y.: Surface engineering design: modelling surface engineering systems for improved tribological performance. Surface & Coatings Technology 108-109 (1998), 360-368.10.1016/S0257-8972(98)00623-9Search in Google Scholar

3. Bennani H. H. Takadoum J.: Finite element model of elastic stresses in thin coatings submitted to applied forces. Surface and Coatings Technology 111 (1999), 80-85.10.1016/S0257-8972(98)00708-7Search in Google Scholar

4. Djabella H., Arnell R. D.: Finite element analysis of the contact stresses in elastic coating/substrate under normal and tangential loads. Thin Solid Films 223 (1993), 87-97.Search in Google Scholar

5. Komvopoulos K.: Elastic-plastic finite element analysis of indented layered media. Journal of Tribology, 111 (1989), 430-440.10.1115/1.3261943Search in Google Scholar

6. Śliwa A., Dobrzański L.A., Kwaśny W., Staszuk M., Simulation of the microhardness and internal stresses measurement of PVD coatings by use of FEM, Journal of Achievements in Materials and Manufacturing Engineering 43 (2) (2010), 684-691.Search in Google Scholar

7. Śliwa, A., Dobrzański, L. A., Kwaśny, W., Sitek, W.: The computer simulation of internal stresses on the PVD coatings. Archives of Computational Materials Science and Surface Engineering, 1(3) (2009), 183-188.Search in Google Scholar

8. Dobrzański, L. A., Śliwa, A., Sitek, W.: Finite Element Method application for modeling of PVD coatings properties. Proceedings of the 5th International Surface Engineering Conference (2006), 26-29.Search in Google Scholar

9. Johnson K. L.: Contact Mechanics, Cambridge, 1985.10.1017/CBO9781139171731Search in Google Scholar

10. Lakkaraju R. K., Bobaru F., Rohde S. L.: Optimization of multilayer wear-resistant thin films using finite element analysis on stiff and compliant substrates. Journal of Vacuum Science & Technology A: Vacuum, Surfaces, and Films 24 (2006), 146-155.10.1116/1.2121750Search in Google Scholar

11. Kuruppu M. L., Negrea G., Ivanov I. P., Rohde S. L.: Monolithic and multilayer Cr/CrN, Cr/Cr2N, and Cr2N/CrN coatings on hard and soft substrates. Journal of Vacuum Science and Technology A 16 (1998), 1949-1956.Search in Google Scholar

12. Valle R., Leveque D., Parlier M.: Optimizing substrate and intermediate layers geometry to reduce internal thermal stresses and prevent surface crack formation in 2-D multilayered ceramic coatings. Journal of the European Ceramic Society 28 (2008), 711-716.Search in Google Scholar

13. Szparaga Ł., Ratajski J., Zarychta A.: Multi objective optimization of, wear resistant TiAlN and TiN coatings deposited by PVD techniques. Archives of Materials Science and Engineering 1/48 (2011), 33-39.Search in Google Scholar

14. Szparaga Ł., Ratajski J.: Polyoptimization of antiwear TiAlN and TiN coatings, deposited by PVD techniques on tools for wood machining. Measurement Automation and Monitoring (Pomiary Automatyka Kontrola) 57 (2011) (in Polish), 1055-1058.Search in Google Scholar

15. Szparaga Ł., Ratajski J.: Polyoptimization of gradient antiwear TiAlN/TiN coatings. Materials Science (Inżynieria Materiałowa) 5/195 (2013), (in Polish). 10.2478/adms-2014-0001Search in Google Scholar

4 fois par an
Sujets de la revue:
Materials Sciences, Functional and Smart Materials