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SURFACE OXIDATION OF AL-SI ALLOYS AT ELEVATED TEMPERATURES
Authors:
Adelina Miteva1, Anna Petrova1
, Georgi Stefanov2
1Space Research and Technology Institute, Bulgarian Academy of Sciences, Bulgaria
2Institute of Metal Science, Equipment and Technologies with Hydro- and Aerodynamics „Acad. A. Balevski“, Bulgarian Academy of Sciences, Bulgaria
Received: 23.04.2021.
Accepted: 24.08.2021.
Available: 30.09.2021.
Abstract:
Characteristic of the samples based on Al-Si alloys, that we have studied, is their propensity for oxidation at high temperatures. The few number of papers on the oxidation kinetics of aluminium alloys associated with Planar Flow Casting technology (PFC) can be found in the literature. The oxide processes and the properties of the oxide layer formed on the aluminium alloy are mainly considered.
The aim of the present work is the kinetics of oxide layer formation on aluminium alloys to clarify whether alloys are suitable for use in space and under specific conditions. The formal kinetics of Nikitin was applied for data processing. The influence of the alloying elements on the formed surface oxide coating is shown.
Keywords:
Al-Si alloys, oxide layer, hot extrusion
Keywords:
[1] V.V. Rao, Rapid solidification processing of some aluminium alloys. NML Technical Journal, 38 (4), 1996: 133-150.
[2] T. Dursun, C. Soutis, Recent developments in advanced aircraft aluminium alloys. Materials & Design, (1980-2015), 56, 2014: 862-871. https://doi.org/10.1016/j.matdes.2013.12.002
[3] A. Heinz, A. Haszler, C. Keidel, S. Moldenhauer, R. Benedictus, W.S. Miller, Recent development in aluminium alloys for aerospace applications. Materials Science and Engineering: A, 280 (1), 2000: 102-107. https://doi.org/10.1016/S0921-5093(99)00674-7
[4] B. Stojanovic, J. Glisovic, Automotive Engine Materials, in: S. Hashmi (Ed.), Reference Module in Materials Science and Materials Engineering. Elsevier, Oxford, 2016, pp.1-9.
[5] A. Vencl, Tribology of the Al-Si Alloy Based MMCs and Their Application in Automotive Industry, in: L. Magagnin (Ed.), Engineered Metal Matrix Composites: Forming Methods, Material Properties and Industrial Applications. Nova Science Publishers, New York, 2012, pp.127-166.
[6] V.I. Dobatkin, P.M. Gabidullin, B.A. Kolachev, G.S. Makarov, Gases and oxides in aluminum deformable alloys. Metallurgiya, Moscow, 1976 [in Russian].
[7] P.E. Blackburn, E.A. Gulbransen, Aluminum reaction with water vapor, dry oxygen, moist oxygen and moist hydrogen between 500° and 625°C. Jornal of The Electrochemical Society, 107, 1960: 944-950. https://doi.org/10.1149/1.2427576
[8] C. Wagner, The distribution of cations in metal oxide and metal sulphide solid solutions formed during the oxidation of alloys. Corrosion Science, 9, 1969: 91-109. https://doi.org/10.1016/S0010-938X(69)80046-6
[9] B. Barbov, A. Petrova, Oxidation of Aluminum Alloys in the Processing Condition, 14th International Scientific Conference Space, Ecology, Safety (SES 2018), 7-9 November 2018, Sofia, Bulgaria, 447-450.
[10] B. Barbov, A. Petrova, Microstructure and Mechanical Properties of NanoMicrocrystalline Aluminum Alloys, 14th International Scientific Conference Space, Ecology, Safety (SES 2018), 7-9 November 2018, Sofia, Bulgaria, pp. 451-456.
[11] A. Vencl, I. Bobić, M. Stanković, P. Hvizdoš, B. Bobić, B. Stojanović, F. Franek, Influence of Secondary Phases in A356 MMCs on Their Mechanical Properties at Macro- and Nanoscale. Journal of the Brazilian Society of Mechanical Sciences and Engineering, 42 (3), 2020: 115. https://doi.org/10.1007/s40430-020-2197-6
[12] M. Kostecki, J. Woźniak, T. Cygan, M. Petrus, A. Olszyna, Tribological properties of aluminium alloy composites reinforced with multi-layer graphene – the influence of spark plasma texturing process. Materials, 10 (8), 928, 2017: 1-14. https://doi.org/10.3390/ma10080928
[13] M. Kandeva, I. Panov, B. Dochev, Abrasive wear of a hypereutectic alloy ALSI18, modified by different modifiers. Journal of the Balkan Tribological Association, 26 (4), 2020: 661-673.
[14] M. Kandeva, Iv. Panov, B. Dochev, Effects of nanomodifiers on the wear resistance of aluminum-silicon alloy ALSI18 in tribosystems in case of reversive friction and lubrication. Journal of the Balkan Tribological Association, 26 (4), 2020: 637-652.
[15] V.I. Nikitin,Calculation of heat resistance of metals. Metallurgiya, Moscow, 1976. [in Russian].
[16] W. Kahl and E. Fromm, Examination of the strength of oxide skins on aluminum alloy melts. Metallurgical transactions B, 16, 1985:47-51. https://doi.org/10.1007/BF02657487
[17] S. Yaneva, L. Stojanova, T. Markov, Oxidation of solid aluminium silicon alloys in air. Cryst. Res. Technol., 22, 1987: 251-258. https://doi.org/10.1002/crat.2170220219
[18] E.J. Lavernia, J.D. Ayers, T.S. Srivatsan, Rapid solidification processing with specific application to aluminium alloys. Int. Mater., 37 (1), 1992: 1-44. https://doi.org/10.1179/imr.1992.37.1.1
[19] P. Gilman, M. Zedalis, J. Peltier, S. Das, Rapidly solidified aluminum-transition metal alloys for aerospace applications. AIAA-88-444. Aircraft Desigh, Systems and Operations Conf. Atlanta, 7-9 September, 1988. https://doi.org/10.2514/6.1988-4444
[20] S. Yaneva, A. Kalkanli, K. Petrov, R. Petrov, Ir. Yvan Houbert, S. Kassabov, Structure development in rapidly solidified Al-Fe-V-Si ribbons. Materials Science and Engineering, A 373, 2004: 90-98. https://doi.org/10.1016/j.msea.2003.12.034
This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License (CC BY-NC 4.0)
Volume 9
Number 4
December 2024
Last Edition
Volume 9
Number 4
December 2024
How to Cite
A. Miteva, A. Petrova, G. Stefanov, Surface Oxidation of Al-Si Alloys at Elevated Temperatures. Applied Engineering Letters, 6(3), 2021: 105–110.
https://doi.org/10.18485/aeletters.2021.6.3.3
More Citation Formats
Miteva, A., Petrova, A., & Stefanov, G. (2021). Surface Oxidation of Al-Si Alloys at Elevated Temperatures. Applied Engineering Letters, 6(3), 105–110.
https://doi.org/10.18485/aeletters.2021.6.3.3
Miteva, Adelina, et al. “Surface Oxidation of Al-Si Alloys at Elevated Temperatures.” Applied Engineering Letters, vol. 6, no. 3, 2021, pp. 105–10,
https://doi.org/10.18485/aeletters.2021.6.3.3.
Miteva, Adelina, Anna Petrova, and Georgi Stefanov. 2021. “Surface Oxidation of Al-Si Alloys at Elevated Temperatures.” Applied Engineering Letters 6 (3): 105–10.
https://doi.org/10.18485/aeletters.2021.6.3.3.
Miteva, A., Petrova, A. and Stefanov, G. (2021). Surface Oxidation of Al-Si Alloys at Elevated Temperatures. Applied Engineering Letters, 6(3), pp.105–110. doi: 10.18485/aeletters.2021.6.3.3.
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SURFACE OXIDATION OF AL-SI ALLOYS AT ELEVATED TEMPERATURES
Authors:
Adelina Miteva1, Anna Petrova1
, Georgi Stefanov2
1Space Research and Technology Institute, Bulgarian Academy of Sciences, Bulgaria
2Institute of Metal Science, Equipment and Technologies with Hydro- and Aerodynamics „Acad. A. Balevski“, Bulgarian Academy of Sciences, Bulgaria
Received: 23.04.2021.
Accepted: 24.08.2021.
Available: 30.09.2021.
Abstract:
Characteristic of the samples based on Al-Si alloys, that we have studied, is their propensity for oxidation at high temperatures. The few number of papers on the oxidation kinetics of aluminium alloys associated with Planar Flow Casting technology (PFC) can be found in the literature. The oxide processes and the properties of the oxide layer formed on the aluminium alloy are mainly considered.
The aim of the present work is the kinetics of oxide layer formation on aluminium alloys to clarify whether alloys are suitable for use in space and under specific conditions. The formal kinetics of Nikitin was applied for data processing. The influence of the alloying elements on the formed surface oxide coating is shown.
Keywords:
Al-Si alloys, oxide layer, hot extrusion
This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License (CC BY-NC 4.0)
Volume 9
Number 4
December 2024
Last Edition
Volume 9
Number 4
December 2024