The structure and phase composition of the cermet charge in the Al‒Al₂O₃ system obtained using mechanical processing of aluminum powder in a planetary ball mill

The cermet charge in the Al‒Al₂O₃ system was obtained by mechanical processing (MP) in a planetary ball mill of aluminum powder of the industrial grade PAP-2 (GOST 5494‒95), consisting of flake particles of submicron thickness with a coating of stearin. Depending on the MP modes used, 4 types of charge were obtained, the bulk density of which varied from 0,33 to 1,1 g/cm³. For all types of charge, the synthesis of the α-Al₂O₃ phase was observed as a result of the exothermic reaction of the interaction of air oxygen with the surface of aluminum particles during the MP. It is also possible to form boehmite and gibbsite when the activated surface of Al particles interacts with atmospheric water vapor. The local X-ray spectral analysis (EDX) was used to detect X-ray amorphous carbon in the composition of the charge, the appearance of which is associated with the impact- shearing effect of grinding bodies, leading to the nucleation of X-ray amorphous carbon inclusions due to the termal destruction of stearin. The maximum bending strength of the sintered cermet was 550 MPa. This cermet is characterized by a discrete fracture: the formation of dimples as a result of the shear of layered packets under the action of tangential stresses. The revealed mechanisms cermet’s fractures allow us to establish the optimal modes of MP of powder compositions for obtaining various constructional elements from them.

1. Кузмич, Ю. В. Механическое легирование / Ю. В. Кузмич, И. Г. Колесникова, В. И. Серба, Б. М. Фрейдин. ― Апатиты : Изд-во Кольского научного центра РАН, 2004. ― 179 с.

2. Черник, Г. Г. Измельчение и механическое легирование в планетарных мельницах / Г. Г. Черник, Е. Л. Фокина, Н. И. Будим [и др.] // Наноиндустрия. ― 2007. ― № 5. ― С. 32‒35.

3. Гусев, А. И. Наноматериалы, наноструктуры, нанотехнологии / А. И. Гусев. ― М. : Физматлит, 2007. ― 416 с.

4. Аксенов, А. А. Структура и свойства композиционных материалов на основе алюминия, получаемых методом механического легирования в воздушной атмосфере / А. А. Аксенов, А. Н. Солонин, В. В. ИстоминКастровский // Изв. вузов. Цветная металлургия. ― 2004. ― № 4. ― С. 58‒66.

5. Suryanarayana, C. Synthesis of nanocomposites by mechanical alloying / C. Suryanarayana // J. Alloys Compds. ― 2011. ― 509S june. ― P. S229‒S234.

6. Внуков, А. А. Особенности применения процесса механического легирования для получения порошковых шихтовых материалов на основе системы Fe‒Cu‒C / А. А. Внуков // Технологический аудит и резервы производства. ― 2015. ― № 6/1 (26). ― С. 9‒12.

7. Al-Aqeeli, N. The synthesis of nanostructured WCbased hardmetals using mechanical alloying and their direct consolidation / N. Al-Aqeeli, N. Saheb, T. Laoui, K. Mohammad // Journal of nanomaterials. ― 2014. ― February. ― P. 1‒16.

8. Поварова, К. Б. Порошковые сплавы Fe‒Cr‒Al и NiAl / К. Б. Поварова, О. А. Скачков, А. А. Дроздов [и др.] // Заготовительные производства в машиностроении. ― 2017. ― Т. 15, № 8. ― С. 370‒377.

9. Senkevich, K. S. Fabrication of intermetallic titanium alloy based on Ti2AlNb by rapid quenching of melt / K. S. Senkevich, M. M. Serov, O. Z. Umarova // Metal and heat treatment. ― 2017. ― Vol. 59, № 7/8. ― P. 463‒466.

10. Bhuyan, Ranjan K. Structural and thermal stady of Mg2TiO4 nanoparticles synthesized by mechanical alloying method / Ranjan K. Bhuyan, D. Pamu, Basanta K. Sahoo, Ashish K. Sarangi // Micro and nanosystems. ― 2020. ― Vol. 12, № 2. ― P. 87‒91.

11. Yustanti, Erlina. Surfactant ― assisted synthesis of Ba0,7Sr0,3TiO3 nanoparticles by mechanical alloying and altrasonic irradiation / Erlina Yustanti, Mas Ayu Elita Hafizah, Azwar Manaf // International conference on engineering, science and nanotechnology. ― 2016 (ICESNANO). ― P. 030119-1‒030119-4, AIP Conference Proceedings 1788, 030119 (2017).

12. Fajarin, R. Milling time and temperature dependence on Fe2TiO5 nanoparticles synthesized by mechanical alloying method / R. Fajarin, H. Purwaningsih, A.Widyastuti [et al.] // 3rd International conference on theoretical and applied physics. ― 2013 (ICTAP). ― P. 63‒66, AIP Conference Proceedings 1617, 63 (2014).

13. Liu, L. Microstructure evolution of Ti3SiC2 powder during high-energy ball milling / L. Liu, L. Wang, L. Shi, W. Jiang // Ceram. Int. ― 2010. ― Vol. 36, № 7. ― P. 2227‒2230.

14. Tasha, Mohammed A. Review on nanocomposites fabricated by mechanical alloying / Mohammed A. Tasha, Rasha A. Youness, M. E. Zawrah // International journal of minerals, metallurgy and materials. ― 2019. ― № 9. ― P. 1047‒1058.

15. Mattli, Manohar Reddy. Microstructure and compressive behavior of Al‒Y2O3 nanocomposites prepared by microwave ― assisted mechanical alloying / Manohar Reddy Mattli, R. A. Shakoor, Panchal Reddy Matli, Adel Mohamed Amer Mohamed // Metals. ― 2019. ― № 9. ― P. 414‒422.

16. Stalin, B. Synthesis of metal matrix composites and alloys by mechanical alloying: a review / B. Stalin, M. Meignanamoorthy, M. Ravichаndran // 2nd International conference on advances in mechanical engineering. ― 2018 (ICAME). ― P. 1‒5, IOP Conference series: materials science and engineering 402, 012097 (2018).

17. Jam, Ali Reza. Effect of mechanical alloying on the synthesis of Fe‒TiC nanocomposite / Ali Reza Jam, Mansour Razavi, Leila Nikzad // Science engineering composites materials. ― 2017. ― Vol. 24, № 5. ― P. 739‒745.

18. Lee, H. B. Characterization of mechanically alloyed Ti‒Al‒B nanocomposite consolidated by spark plasma sintering / H. B. Lee, S. H. Kim, S. W. Kang, Y. H. Han // British Сeramic Trans. ― 2003. ― Vol. 102, № 6. ― P. 231‒236.

19. Zhang, Guoquan. Synthesis of nanocrystalline TiC reinforced W nanocomposites by high-energy mechanical alloying: microstructural evolution and its mechanism / Guoquan Zhang, Dongdong Gu // Applied Surface Science. ― 2013. ― Vol. 273. ― February. ― P. 364‒371.

20. Alizadeh, A. Preparation and investigation of Al‒ 4 wt. % B4C nanocomposite powders using mechanical milling / A. Alizadeh, E. Taheri-Nassay, H. R. Baharvandi // Bull. Mater. Sci. ― 2011. ― Vol. 34, № 5. ― P. 1039‒1048.

21. Иванов, Д. А. Физико-химические закономерности процессов получения композиционных материалов на основе высокодисперсного алюминиевого порошка ПАП-2 / Д. А. Иванов : дис. ... д. т. н. ― М., 2019. ― 301 с.

22. Dinesh, K. Properties and characterization of Al‒ Al2O3 composites processed by casting and powder metallurgy routes (review) / K. Dinesh, A. Geeta, P. Rajesh // Intern. Jour. of latest trends in engineering and technology. ― 2013. ― Vol. 2, № 4, july. ― P. 486‒496.

23. Woo, K. D. Fabrication of Al alloy matrix composite reinforced with subsive-sized Al2O3 particles by the in situ displacement reaction using high-energy ball-milled powder / K. D. Woo, H. B. Lee // Mater. Sci. Engn. ― 2007. ― A 449‒451. ― P. 829‒832.

24. Липсон, Г. Интерпретация порошковых рентгенограмм / Г. Липсон, Г. Стипл. ― М. : Мир, 1972. ― 384 с.

25. Ivanov, D. A. Preparation of porous ceramic based on Al2O3 as a result of zonal compaction during sintering of powder workpieces of very fine aluminum powder PAP-2 combustion products / D. A. Ivanov, A. I. Sitnikov, G. E. Val´yano [et al.] // Refract. Ind. Ceram. ― 2019. ― Vol. 59, № 5. ― P. 459‒465. (Иванов, Д. А. Получение пористой керамики на основе Al2O3 в результате зонального уплотнения при спекании порошковых заготовок из высокодисперсных продуктов сгорания алюминиевого порошка ПАП-2 / Д. А. Иванов, А. И. Ситников, Г. Е. Вальяно [и др.] // Новые огнеупоры. ― 2018. ― № 9. ― С. 28‒34.)

26. Практикум по технологии керамики и огнеупоров ; под ред. Д. Н. Полубояринова и Р. Я. Попильского. ― М. : Изд-во лит-ры по стр-ву, 1972. ― 352 с.

27. Ivanov, D. A. Investigation of physical-mechanical properties and structure of layered cermet Al‒Al2O3‒Al4C3 / D. A. Ivanov // Refract. Ind. Ceram. ― 2020. ― Vol. 61, № 4. ― P. 393‒398. (Иванов, Д. А. Изучение физико-механических свойств и структуры слоистого кермета Al‒Al2O3‒Al4C3 / Д. А. Иванов // Новые огнеупоры. ― 2020. ― № 7. ― С. 45‒50.)

28. Энгель, Л. Растровая электронная микроскопия. Разрушение / Л. Энгель, Г. Клингеле. ― М. : Металлургия, 1986. ― 232 с.