Журналы →  Non-ferrous Metals →  2015 →  №2 →  Назад

MATERIAL SCIENCE
Название Heat resistant alloys of Al – Zr – Sc system for electrical applications: analysis and optimization of phase composition
DOI 10.17580/nfm.2015.02.07
Автор Alabin A. N., Belov N. A., Tabachkova N. Yu., Akopyan T. K.
Информация об авторе

United Company “RUSAL”, Moscow, Russia.:

A. N. Alabin, Head of a Project

 

National University of Science and Technology “MISiS”, Moscow, Russia:
N. A. Belov, Professor of a Chair Casting Technologies and art metal processing
N. Yu. Tabachkova, Assistant Professor of a Chair of Materials Science of Semiconductors and Dielectrics


Baikov Institute of Metallurgy and Materials Science, Moscow, Russia:
T. K. Akopyan, Researcher of Engineering Center “Casting Technologies and Materials” e-mail: aktorgom@gmail.com

Реферат

Aluminium, possessing a high electrical conductivity, is widely used in electrical products, where this quality is the basic one. Recently, there has been increased the interest from power industry in thermally stable aluminium alloys, which should combine high electrical conductivity and strength stability after the heatings up to 300 oC. To solve this problem, the most promising approach is to develop alloys with zirconium and scandium additives. These elements promote the formation of L12 nanoparticles (Al3Zr, Al3Sc and Al3(Zr, Sc)), which enables both the required strengthening and thermal stability. In the present work there was studied the influence of composition and parameters of strain-thermal treatment on the structure (OM, SEM, TEM), strength (UTS, YS), electrical resistivity (ρ) and thermal stability of Al – Zr – Sc alloys containing up to 0.64% (wt.) Zr and up to 0.30% (wt.) Sc. The Thermo-Calc software was used for calculation of liquidus temperatures, the solubilities of Zr and Sc in aluminium solid solution and volume fractions of L12 nanoparticles. In hardened state the additions of Zr and Sc significantly increase  value, which is possible to decrease by application of annealing. Parameters of annealing have to be chosen proceeding from ultimate concentration of Zr and Sc in aluminium solid solution and rate of decomposition of the last one. Using desirability function it is shown that ternary alloy Al – 0.24% Zr – 0.1% Sc has the best combination of strength, electrical resistance and thermal stability. After holding at 300 oC during 500 hours, it has the following properties: ρ = 28.3.10–9 Ωm·m, YS = 165 MPa, UTS = 186 MPa.

This scientific work was carried out with the support of the grant of the Russian Scientific Funds No. 14-19-00632.

Ключевые слова Al – Zr – Sc alloys, Al3(Zr, Sc) nanoparticles, electrical resistance, strength, annealing
Библиографический список

1. Uliasz P., Knych T., Mamala A., Smyrak B. Investigation in Properties Design Heat Resistant AlZrSc Alloy Wires Assign for Electrical Application, in Aluminium Alloys. J. Hirsch, B. Skrotzki and G. Gottstein (Eds.). WILEY-VCH, Weinheim, 2008. pp. 248–255.
2. Patent US, No. 4402763. Published: June 09, 1983.
3. Patent US, No. 6867373. Published: March 15, 2005.
4. Belov N. A., Alabin A. N., Istomin-Kastrovskiy V. V., Stepanova E. G. Influence of annealing the structure and mechanical properties of cold-rolled sheets of Al–Zr-alloys. Russian Journal of Non-Ferrous Metals. 2006. Vol. 47. pp. 37–43.
5. Forbord B., Lefebvre W., Danoix F., Hallem H., Marthinsen K. Three dimensional atom probe investigation on the formation of Al3(Sc,Zr)-dispersoids in aluminium alloys. Sripta Materialia. 2004. Vol. 51. pp. 333-337.

6. Fuller C. B., Seidman D. N. Temporal evolution of the nanostructure of Al(Sc,Zr) alloys: Part II-coarsening of Al3(Sc1–xZrx) precipitates. Acta Materialia. 2005. No. 53. pp. 5415–5428.
7. Clouet E., Barbu A., Lae L., Martin G. Precipitation kinetics of Al3Zr and Al3Sc in aluminum alloys modeled with cluster dynamics. Acta Materialia. 2005. No. 53. pp. 2313–2325.
8. Belov N. A., Alabin A. N., Eskin D. G., Istomin-Kastrovskiy V. V. Optimization of hardening of Al–Zr–Sc cast alloys. Journal of Material Science. 2006. Vol. 41. pp. 5890–5899.
9. Knipling K. E., Karnesky R. A., Lee C. P., Dunand D. C., Seidman D. N. Precipitation evolution in Al–0.1Sc, Al–0.1Zr and Al–0.1Sc–0.1Zr (at.%) alloys during isochronal aging. Acta Materialia. 2010. Vol. 58. pp. 5184–5195.
10. Deschamp A., Guyo P. In situ small-angle scattering study of the precipitation kinetics in an Al–Zr–Sc alloy. Acta Materialia. 2007. Vol. 55. pp. 2775–2783.
11. Lefebvrea W., Danoixa F., Hallemb H., Forbordc B., Bostel A., Marthinsend K. Precipitation kinetic of Al3(Sc,Zr) dispersoids in aluminium. Journal of Alloys and Compounds. 200. Vol. 470. pp. 107–110.
12. Costa S., Puga H., Barbosa J., Pinto A. M. P. The effect of Sc additions on the microstructure and age hardening behaviour of as cast Al–Sc alloys. Materials and Design. 2012. Vol. 42. pp. 347–352.
13. Van Dalen M. E., Gyger T., Dunand D. C., Seidman D. N. Effects of Yb and Zr microalloying additions on the microstructure and mechanical properties of dilute Al–Sc alloys. Acta Materialia. 2011. Vol. 59. pp. 7615–7626.
14. Booth-Morrison C., Seidman D. N., Dunand D. C. Effect of Er additions on ambient and high-temperature strength of precipitation-strengthened Al–Zr–Sc–Si alloys. Acta Materilia. 2012. Vol. 60. pp. 3643–3654.
15. Booth-Morrison C., Dunand D. C., Seidman D. N. Coarsening resistance at 400 οC of precipitation-strengthened Al–Zr–Sc–Er alloys. Acta Materialia. 2011. Vol. 59. pp. 7029–7042.
16. Harrington E. The desirability function, Industrial quality control. 1965. Vol. 21. pp. 494–498

Language of full-text английский
Полный текст статьи Получить
Назад