Eurasian Chemico-Technological Journal (Dec 2018)

Fabrication of Cu-W Nanocomposites by Integration of Self-Propagating High-Temperature Synthesis and Hot Explosive Consolidation Technologies

  • S. V. Aydinyan,
  • H. V. Kirakosyan,
  • M. K. Zakaryan,
  • L. S. Abovyan,
  • S. L. Kharatyan,
  • A. Peikrishvili,
  • G. Mamniashvili,
  • B. Godibadze,
  • E. Sh. Chagelishvili,
  • D. R. Lesuer,
  • M. Gutierrez

DOI
https://doi.org/10.18321/ectj763
Journal volume & issue
Vol. 20, no. 4
pp. 301 – 309

Abstract

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Manufacturing W-Cu composite nanopowders was performed via joint reduction of CuO and WO3 oxides with various ratios (W:Cu = 2:1, 1:1, 1:3, 1:13.5) using combined Mg–C reducer. Combustion synthesis was used to synthesize homogeneous composite powders of W-Cu and hot explosive consolidation (HEC) technique was utilized to fabricate dense compacts from ultrafine structured W-Cu powders. Compact samples obtained from nanometer sized SHS powders demonstrated weak relation between the susceptibility and the applied magnetic field in comparison with the W and Cu containing micrometer grain size of metals. The density, microstructural uniformity and mechanical properties of SHS&HEC prepared samples were also evaluated. Internal friction (Q-1) and Young modulus (E) of fabricated composites studied for all samples indicated that the temperature 1000 °С is optimal for full annealing of microscopic defects of structure and internal stresses. Improved characteristics for Young modulus and internal friction were obtained for the W:Cu = 1:13.5 composite. According to microhardness measurement results, W-Cu nanopowders obtained by SHS method and compacted by HEC technology were characterized by enhanced (up to 85%) microhardness.

Keywords