Machines. Technologies. Materials.
Vol. 19 (2025), Issue 9, pg(s) 328-331

TECHNOLOGIES

Plasma technologies for the synthesis of wear-resistant multifunctional metal matrix composites of the Al–TiC System

  • 1 Institute of Pulse Processes and Technologies of NAS of Ukraine, Mykolaiv, Ukraine
  • 2 Kaunas University of Technology, Kaunas, Lithuania

Abstract

A novel two-stage approach for obtaining wear-resistant multifunctional powder composites based on metal powders with highmodulus Ti–TiC system fillers is proposed. The method combines high-voltage electric discharge (HVED) treatment and spark plasma sintering (SPS), offering a promising alternative to conventional techniques for producing Al–Ti–C system composites. This approach enables the development of a unified route for material synthesis using high-energy-density processing. HVED treatment prevents oxidation of metal particles, reduces contamination by tool materials, and initiates the synthesis of additional dispersed strengthening phases. For example, HVED treatment of titanium powder in a hydrocarbon liquid promotes the in situ formation of titanium carbide (TiC) particles.
The present work investigates the influence of adding Ti–TiC powder—synthesized via HVED in ethanol under reverse polarity mode with a specific energy input of 20 MJ/kg—on the structure, phase composition, and properties of Al–Ti–C metal matrix composites (MMCs). It was shown that the addition of 2 wt% of Ti–TiC powder synthesized via HVED in ethanol to aluminum powder results in an MMC with an electrical resistivity of 0.5 Ω·mm²/m and a hardness of 31 HRB. However, the heat resistance of this composite is 2.5 times lower than that of consolidated pure aluminum powder. Increasing the Ti–TiC content to 10 wt% leads to the formation of a wear-resistant Al–Ti–C composite, whose structure includes Al, Ti, TiC, the intermetallic compound Al₃ Ti, MAX phases Ti₂ AlC and Ti₃ AlC₂ , and free carbon. For the MMC sample with the addition of 10% Ti–TiC, the mass gain per cycle during the heat resistance test is 0.23%/cycle, whereas for samples made from consolidated Al powder it is 0.18%/cycle, indicating that their heat resistance is approximately the same. The wear resistance of this composite is more than three times higher than that of the consolidated base aluminum powder, with wear rates of 0.003 g/km and 0.010 g/km, respectively. This material also demonstrates a hardness of 43 HRB and relatively low electrical resistivity at the level of 0.3 Ω·mm²/m.

Keywords

References

  1. J. C. Viala, M. Peronnet, F. Bosselet, J. Bouix, Chemical compatibility between aluminium base matrices and light refractory carbide reinforcements, Int. Committee on Composite Material, ICCM- 12 Paris (1999), 9 p.
  2. V. H. López, A. R. Kennedy, J. Colloid Interface Sci. 4, 356–362 (2006).
  3. X. H. Wang, Y. C. Zhou, Z. Metallkd. 93, 66–71 (2002).
  4. M. Prystash, S. Prystash, A. Torpakov, Y. Lypian, O. Syzonenko, R. K. Janutienė, Machines. Technol. Mater. 16(8), 267–269 (2022).
  5. O. M. Syzonenko, P. I. Loboda, A. D. Zaichenko, Ye. V. Solodkyi, A. S. Torpakov, M. S. Prystash, V. O. Trehub, J. Superhard Mater. 39, 243–250 (2017).
  6. O. M. Sizonenko, M. S. Prystash, E. I. Taftai, A. S. Torpakov, Ye. V. Lypian, Mater. Sci. 57, 209–214 (2021).
  7. A. Stepanchuk, I. Bilyk, P. Boiko, Tekhnologiya poroshkovoy metallurgii (Vyshcha Shkola, Kyiv, 1989), 415 p. (In Russian).
  8. S. J. Chipera, D. L. Bish, Multireflection RIR and intensity normalizations for quantitative analyses: Applications to feldspars and zeolites, Powder Diffr. 10, 47–55 (1995).
  9. D. Gricius, R. K. Janutienė, D. Mažeika, R. Šertvytis, O. Syzonenko, A. Torpakov, Mechanika 29(2), 168–173 (2023).
  10. O. M. Syzonenko, P. Tashev, M. S. Prystash, A. S. Torpakov, Y. V. Lypian, Eng. Sci. 58, 79–94 (2021).

Article full text

Download PDF