Journal of Materials Research and Technology (May 2024)

Effect of B4C content and particle sizes on the laser cladded B4C/Inconel 625 composite coatings: Process, microstructure and corrosion property

  • Chunhuan Guo,
  • Shicheng Xu,
  • Zubin Chen,
  • Huabing Gao,
  • Guorui Jiang,
  • Wenyao Sun,
  • Xuhong Wang,
  • Fengchun Jiang

Journal volume & issue
Vol. 30
pp. 6278 – 6290

Abstract

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B4C/Inconel 625 composite coatings were successfully prepared on 20 pipeline steel by laser cladding, in which B4C ceramic was selected as reinforcement phase to improve the microstructure and corrosion property of Inconel 625 coating. The laser cladding parameters were optimized and the effect of B4C content and B4C particle sizes on the microstructure and properties of B4C/Inconel 625 composite coatings were studied in detail. With increasing liner energy density and decreasing powder feeding speed, the crack ratio of the composite coatings reduces. NiB phase forms due to the in-situ reaction of B4C with Ni element in Inconel 625, and a thin layer of planar crystal also forms at the coating/substrate interface. As the addition of B4C content ranged 5 wt.%∼10 wt.% and the particle sizes ranged 10 μm–60 μm, the quantities of equiaxed crystals increase obviously and the coarse columnar crystals are also refined, which contributes to the improved microhardness and corrosion resistance of the B4C/Inconel 625 composite coatings. When the B4C content is 10 wt.% and particle size is 10 μm, the maximum microhardness of the composite coating is about 567HV0.2, which is 241.2% to that of Inconel 625 coating. The optimal corrosion resistance of B4C/Inconel 625 composite coatings is obtained when the B4C content is 5 wt.% and particle size is 60 μm.

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