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Журналы →  Tsvetnye Metally →  2021 →  №5 →  Назад

MATERIALS SCIENCE
Название Improving physical and mechanical properties of foil for anodes of high-voltage electrolytic capacitors by introducing an intermediate annealing
DOI 10.17580/tsm.2021.05.08
Автор Sarkisov T. S., Belov N. A., Sarkisov S. S., Dolbachev A. P.
Информация об авторе

Сhair for Metal Forming, NUST MISiS, Moscow, Russia:

T. S. Sarkisov, Graduate Student
N. A. Belov, Chief Researcher, Doctor of Technical Sciences, Professor, e-mail: nikolay-belov@yandex.ru
S. S. Sarkisov, Leading Project Expert, Candidate of Technical Sciences
A. P. Dolbachev, Graduate Student
Реферат

The results of studies of influence of intermediate and final annealing on the level of physical and mechanical properties of foil for anodes of highvoltage capacitors made of high-purity aluminum (99.99%) are presented. A comparative analytical analysis of efficiency of introduction of the intermediate annealing stage in the thermo-deformation processing mode in comparison with its absence in the scheme was performed. The starting material for the research is a strip with a thickness of 0.45 mm, obtained from hot-rolled strip with a thickness of 8 mm by cold rolling (deformation degree is 0.9437). The chemical composition of the strip corresponds to the A99 aluminum grade according to GOST 11069–2019. Content of basic impurities in the initial strip by the actual chemical composition,%: 0,0018 Si; 0.0012 Fe; 0.0020 Cu. A set of studies of physical and mechanical properties, which allowed to determine the dependence of the maximum value of specific capacity of high-voltage anode foil on the average grain size and crystallographic orientation (in this case - the maximum value of cubic texture, with allowable values of foil ultimate strength). It is shown that with an increase in the intensity of the cubic texture from 90 to 95%, the specific capacitance increases from 29 to 32 μF/dm2. This is achieved through the use of intermediate annealing at 380 оC and further final annealing at 550 оC. The hereditary character of the average grain size of samples with a thickness of 0.45 mm during intermediate annealing and the grain size of the foil with a thickness of 0.100 mm after the final annealing is shown.
Ключевые слова Aluminum foil, high-purity aluminum, anodes of highvoltage capacitors, annealing, specific capacity, cubic texture
Библиографический список

1. Novikov I. I., Zolotorevskiy V. S., Portnoy V. К., Belov N. А., Livanov D. V. et. al. Metal science. Vol. 1. Basics of metal science. Moscow : Izdatelskiy Dom MISiS, 2014. 496 p.
2. Luts А. R., Suslina А. А. Aluminum and its alloys: textbook. Samara: Samarskiy gosudarstvenny tekhnicheskiy universitet, 2013. 81 p.
3. Sarkisov S. S. Understanding the effect of final annealing regimes on the performance of aluminium foil for high-voltage electrolytic capacitor anodes. Tsvetnye Metally. 2019. No. 3. pp. 58–63. DOI: 10.17580/tsm.2019.03.08
4. GOST 11069–2019. Primary aluminium. Grades. Introduced: 01.06.2020. Moscow : IPK Izdatelstov standartov, 2019.
5. GOST 25905–2018. Aluminium foil for condensers. Specificatins. Introduced: 01.03.2019. Moscow : Standartinform, 2018.
6. Hatch J. E. Aluminium: properties and physical metallurgy. Translated from English. Moscow : Metallurgiya, 1989. 324 p.
7. Sarkisov S. S., Akopov Е. S., Agadzhanov V. М., Zlotin L. B., Silvestrov К. G. et. al. Production of aluminum foil for capacitors. Tsvetnaya metallurgiya. 1990. No. 11. pp. 44–46.
8. Jiayi Zhang, Mingyang Ma, Fanghua Shen, Danqing Yi, Bin Wang. Influence of deformation and annealing on electrical conductivity, mechanical properties and texture of Al – Mg – Si alloy cables. Materials Science and Engineering A. 2018. Vol. 710. pp. 27–37.
9. Xiaoli Cui, Yuying Wu, Guojun Zhang, Yibo Liu, Xiangfa Liu. Study on the improvement of electrical conductivity and mechanical properties of low alloying electrical aluminum alloys. Composites. Part B. 2017. Vol. 110. pp. 381–387.
10. Belov N. А., Korotkova N. О., Dostaeva А. М., Akopyan Т. К. Influence of termomechanical treatment on electrical resistivity and hardening of alloys Al – 0,2 % Zr и Al – 0,4 % Zr. Tsvetnye Metally. 2015. No. 10. pp. 13–18. DOI: 10.17580/tsm. 2015.10.02.
11. Alabin A. N., Belov N. A., Tabachkova N. Yu., Akopyan T. K. Heat resistant alloys of Al – Zr – Sc system for electrical applications: analysis and optimization of phase composition. Non-ferrous Metals. 2015. No. 2. pp. 36–40. DOI: 10.17580/tsm. 2015.02.07.
12. Pan F. S., Peng J., Tang A. T., Lu Y. Increasing cube texture in high purity aluminium foils for capacitors. Materials Science and Technology. 2005. Vol. 21, No. 12. pp. 1432–1435.
13. Lentz M., Laptyeva G., Engler O. Characterization of second-phase particles in two aluminium foil alloys. Journal of Alloys and Compounds. 2016. Vol. 660. pp. 276–288.
14. Haiyan Gao, Wuqiang Feng, Jing Gu, Jun Wang, Baode Sun. Aging and recrystallization behavior of precipitation strengthened Al – 0.25 Zr – 0.03 Y alloy. Journal of Alloys and Compounds. 2017. Vol. 696. pp. 1039– 1045.
15. Hou J. P., Wang Q., Zhang Z. J., Tian Y. Z., Wu X. M. et al. Nanoscale precipitates: The key to high strength and high conductivity in Al alloy wire. Materials and Design. 2017. Vol. 132. pp. 148–157.
16. Zongli Dou, Rong Xu, Alfonso Berduque. The development of electrolytes in aluminium electrolytic capacitors for automotive and high temperature applications. Carts Europe 2008. Conference Proceedings. 2008. pp. 7–11.
17. Post H. A., Meinema W., Rekers D. Aluminium capacitors for automotive high temperature applications. Carts USA. 2005. pp. 65–70.
Language of full-text русский
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