Far Eastern Federal University, Vladivostok, Russia:

Yu. N. Mansurov, Professor, Head of a Chair of Material Science and Material Technology, e-mail: yulbarsmans@gmail.com

V. P. Reva, Assistant Professor of a Chair of Material Science and Material Technology

National University of Science and Technology “MISiS”, Moscow, Russia:

E. I. Kurbatkina, Post-Graduate Student of a Chair of Casting Process Technology

Far Eastern Federal University¹, Vladivostok, Russia ; Institute of Chemistry of Far Eastern Branch of Russian Academy of Sciences³,Vladivostok, Russia:
I. Yu. Buravlev, Assistant Professor of a Chair of Material Science and Material Technology¹, Researcher³

Creation of new functional and structural materials with improved performance characteristics is important in terms of basic and applied research as well as in terms of development of innovative economy. Particular attention is drawn to aluminium matrix composite material (AMCM), thanks to a good combination of performance properties, especially a high specific strength and low cost, which allows their use in various sectors of the economy, which has practical importance for the development of industrial production in the Far East. However, the question of technology for producing such materials based on the study of the mechanisms of the structure formation is still not fully understood. The reason for this is that the choice of mode of production AMCM due primarily to the need for: strengthening the material, producing a given distribution of the reinforcing component to ensure good adhesion between matrix and filler, ensure that no chemical interaction at the interface. Recently, widely used liquid phase AMCM production technology, since they are often more cost-effective, technologically easier and provide high mechanical properties of the material due to the strong coupling at the interface matrix-filler. But reinforcing the interaction with the matrix components, the formation of structure and properties is poorly understood, which complicates the industrial application of such technologies. Among AMCM composites with the main alloying element boron had received relatively widespread use, because they posses a unique combination of properties such as low specific density, strength, corrosion resistance, good thermal conductivity, and the ability to absorb thermal neutrons, which are important for nuclear energy in terms of the manufacture of radiation undertray structures. Therefore, the creation of new boron AMCM with high physical-mechanical characteristics of the liquid phase and the development of production technologies is an urgent task.

The work was based on an agreement and creative collaboration between the engineering centers of National University of Science and Technology “MISiS” and the Research and Education Center “NANO” (Far Eastern Federal University).

1. Adebisi A. A., Maleque M. A., Rahman M. M. Metal matrix composite brake rotor: historical development and product life cycle analysis. International journal of automotive and mechanical engineering. 2011. Vol. 4. pp. 471-480.
2. Gladkovskiy S. V., Trunina T. A., Kokovikhin E. A., Smirnova S. V., Kamantsev I. S. Struktura i svoystva boralyuminievykh kompozitov, poluchennykh goryachey prokatkoy (Structure and properties of boron-aluminium composites, obtained by hot rolling). Izvestiya Samarskogo nauchnogo tsentra Rossiyskoy akademii nauk = Proceedings of Samara Science Center of Russian Academy of Sciences. 2011. Vol. 13, No. 1(2). pp. 361–364.
3. Kosnikov G. A. O perspektivakh razrabotki liteynykh nanostrukturnykh kompozitsionnykh alyumomatrichnykh splavov (About the prospects of development of casting nanostructure composite alumomatrix alloys). Liteyshchik Rossii = Russian Foundry worker. 2011. No. 9. pp. 34–40.
4. Kosnikov G. A., Baranov V. A., Petrovich S. Yu., Kalmykov A. V. Liteynye nanostrukturnye kompozitsionnye alyumomatrichnye splavy (Casting nanostructure composite alumomatrix alloys). Liteynoe proizvodstvo = Foundry. Technologies and Equipment. 2012. No. 2. pp. 4–9.
5. Panfilov A. A., Prusov E. S., Kechin V. A. Problemy i perspektivy razvitiya proizvodstva i primeneniya alyumomatrichnykh kompozitsionnykh splavov (Problems and prospects of development of production and application of alumomatrix composite alloys). Trudy Nizhegorodskogo gosudarstvennogo tekhnicheskogo universiteta imeni R. E. Alekseeva = Proceedings of Nizhniy Novgorod State Technical University named after R. E. Alekseev. 2013. No. (99). pp. 210–217.
6. Mikheev R. S., Chernysheva T. A. Alyumomatrichnye kompozitsionnye materialy s karbidnym uprochneniem dlya resheniya zadach novoy tekhniki (Alumomatrix composite materials with carbide reinforcement for solving of new technology issues). Russian Foundation for Basic Research. 2013. 356 p.
7. Prusov E. S., Panfilov A. A. Issledovanie svoystv litykh kompozitsionnykh splavov na osnove alyuminiya, armirovannykh endogennymi i ekzogennymi fazami (Research of properties of aluminium-based cast composite alloys, reinforced by endogenous and exogenous phases). Metally = Metals. 2011. No. 4. pp. 79–84.
8. Mazaheri M., Meratian R., Emadi A., Najarian R. Comparison of microstructural and mechanical properties of Al–TiC, Al–B₄C and Al–TiC–B₄C. Materials Science and Engineering. 2013. Vol. A 560. pp. 278–287.
9. Alamdari H. D., Dube’ D, Tessier P. Behavior of Boron in Molten Aluminum and its Grain Refinement Mechanism. Metallurgical and materials transactions. 2013. Vol. 44A. pp. 388–394.
10. Prusov E. S., Panfilov A. A., Kechin V. A. Perspektivy primeneniya alyumomatrichnykh kompozitsionnykh splavov v mashinostroenii (Prospects of application of alumomatrix composite alloys in mechanical engineering). Liteyshchik Rossii = Russian Foundry worker. 2012. No. 9. pp. 16–19.
11. Dobrzan’ ski A., Labisz K., Olsen A. Microstructure and mechanical properties of the Al–Ti alloy with calcium addition. Journal of Achievements in Materials and Manufacturing Engineering. 2008. Vol. 26-2. pp. 183–186.
12. Beschliesser M., Clemens H., Kestler H., Jeglitsch F. Phase stability of a c-TiAl based alloy upon annealing: comparison between experiment and thermodynamic calculations. Scripta Materialia. 2003. Vol. 49. pp. 279–284.
13. Nikolai Belov, Elena Kurbatkina, Alexander Alabin. Phase Formation And Mechanical Properties Of Al-Mg-Mn-Ti-B-Zr-Sc Composite Material. Light Metals, The Minerals, Metals & Materials Society. 2014. pp. 1367–1371.
14. Kurbatkina E. I., Belov N. A., Gorshenkov M. V. Issledovanie struktury i svoystv radiatsionnozashchitnogo kompozita na osnove alyuminievogo splava ALTEK s borsoderzhashchem napolnitelem (Research of structure and properties of radiation-protection composite on the basis of aluminium alloy ALTEK (АЛТЭК) with boroncontaining filling material). Sbornik trudov shestoy mezhdunarodnoy nauchno-prakticheskoy konferentsii “Progressivnye liteynye tekhnologii” (Collection of procee dings of the 6-th international schietific-practical conference “Progressive li near technologies”). Moscow, November 24–28, 2011. p. 48.
15. Kurbatkina E., Belov N. Structure and thermal stability of mechanical properties of Al-TiB2 composites alloyed with Mn and Zr. Book of abstracts of IVC. Paris, France, 9-13 September 2013. p. 1210.
16. GOST 11069–2001. Alyuminiy pervichnyy. Marki (State Standard 11069–2001. Primary aluminium. Grades). Introduced: January 01, 2003. (in Russian)
17. GOST 5744–85. Materialy shlifovalnye iz karbida bora. Tekhnicheskie usloviya (State Standard 5744–85. Abrasive grains from boron carbide. Specifications). Introduced: January 01, 1987. (in Russian)
18. TU 6-09-03-46-75. Borid tsirkoniya (Technical Requirements 6-09-03-46-75. Zirconium boride). (in Russian)
19. TU 113-07-11.004-89. Poroshkovaya provoloka (Technical Requirements 113-07-11.004-89. Powder wire). (in Russian)
20. GOST 1583–93. Splavy alyuminievye liteynye. Tekhnicheskie usloviya (State Standard 1583–93. Aluminium casting alloys. Specifications). Introduced: January 01, 1997. (in Russian)
21. GOST 2856–79. Splavy magnievye liteynye. Marki (State Standard 2856–79. Casting magnesium alloys. Grades). Introduced: January 01, 1981. (in Russian)
22. GOST 4784–97. Alyuminiy i splavy alyuminievye deformiruemye. Marki (State Standard 4784–97. Aluminium and wrought aluminium alloys. Grades). Introduced: July 01, 2000. (in Russian)
23. GOST R 53777–2010. Ligatury alyuminievye. Tekhnicheskie usloviya (State Standard R 53777–2010. Master alloys of aluminium. Specifications). Introduced: July 01, 2010. (in Russian)
24. GOST R 8.585–2001. Gosudarstvennaya sistema obespecheniya edinstva izmereniy. Termopary. Nominalnye staticheskie kharakteristiki preobrazovaniya (State Standard R 8.585–2001. State system for ensuring the uniformity of measurements. Thermocouples. Nominal static characteristics of conversion). Introduced: July 01, 2002. (in Russian)
25. GOST 9012–59. Metally. Metod izmereniya tverdosti po Brinellyu (State Standard 9012–59. Metals. Method of Brinell hardness measurement). Introduced: January 01, 1960. (in Russian)
26. GOST 1497–84. Metally. Metody ispytaniy na rastyazhenie (State Standard 1497–84. Metals. Methods of tension test). Introduced: January 01, 1986. (in Russian)
27. GOST 9651–84. Metally. Metody ispytaniy na rastyazhenie pri povyshennykh temperaturakh (State Standard 9651–84. Metals. Methods of tension tests at elevated temperatures). Introduced: January 01, 1986. (in Russian)
28. GOST 8.140–82. Gosudarstvennaya sistema obespecheniya edinstva izmereniy. Gosudarstvennyy pervichnyy etalon i gosudarstvennaya poverochnaya skhema dlya sredstv izmereniy teploprovodnosti tverdykh tel ot 0,1 do 5 Vt/(m·K) v diapazone temperatur ot 90 do 500 K i ot 5 do 20 Vt/ (m·K) — v diapazone temperatur ot 300 do 1100 K (State Standard 8.140–82. State system for ensuring the uniformity of mea surements. State primary standard and all-union verification schedule for means measuring heat conductivity of solid bodies in the range of 0.1 to 5 W/ (m·K) at temperatures from 90 to 500 K and in the range from 5 to 20 W/(m·K) at temperatures from 300 to 1100 K). Introduced: January 01, 1983. (in Russian)
29. GOST 8.141–75. Gosudarstvennaya sistema obespecheniya edinstva izmereniy. Gosudarstvennyy pervichnyy etalon i obshchesoyuznaya poverochnaya skhema dlya sredstv izmereniy udelnoy teploemkosti tverdykh tel v diapazone temperatur ot 273,15 do 700 K (State Standard 8.141–75. State system for ensuring the uniformity of measurements. State primary standard and all-union verification schedule for means, measuring specific heat of solid bodies within temperature range of 273.15 up to 700 K). Introduced: January 01, 1976. (in Russian)