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

Research output: Contribution to journalArticlepeer-review

7 Citations (Scopus)

Abstract

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.

Original languageEnglish
Pages (from-to)301-309
Number of pages9
JournalEurasian Chemico-Technological Journal
Volume20
Issue number4
DOIs
Publication statusPublished - 2018

Keywords

  • Hot explosive consolidation
  • Mechanical properties
  • Microhardness
  • SHS
  • Tungsten-copper nanocomposite

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