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NiTi-SiC composite coating on Ti6Al4V alloy produced by SHS using induction heating

  • Anil Imak

    Anil Imak, born in 1988, completed his primary, secondary and high school education in Elazığ. 2007 won Fırat University, Faculty of Engineering, Mechanical Engineering Department and graduated in 2011. He is currently working as a research assistant at Bingöl University, Faculty of Engineering and Mechanical Engineering Department.

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Published/Copyright: November 29, 2022
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Materials Testing
From the journal Materials Testing Volume 64 Issue 12

Abstract

In this study, NiTi and NiTi-XSiC (1 wt%, 2 wt%, and 4 wt%) powders were coated on the Ti6Al4V surface by the self-propagating high-temperature synthesis (SHS) method using induction heating. Optic microscope and a scanning electron microscope (SEM) for the microstructural properties of coatings, energy dispersive spectrometry (EDS) for element distribution analysis, and X-ray diffractogram (XRD) for phase component analysis were carried out. The microhardness difference between the coating and the substrate was assessed by using the Vickers hardness scale. The microhardness increased with the addition of SiC, and the highest hardness value was 1416 Hv and detected in the sample NiTi–SiC 4 wt%. Phases formed by diffusion during solidification in the compounds Ti, Al, NiTi, NiTi2, NiAl, Ni3Al, Al3Ti, and TiO2, respectively.

Keywords: hardness; induction heating; NiTi; NiTi-XSiC; Ti6Al4V
Corresponding author: Anil Imak, Bingol University, Bingol, Turkey, E-mail:

About the author

Anil Imak

Anil Imak, born in 1988, completed his primary, secondary and high school education in Elazığ. 2007 won Fırat University, Faculty of Engineering, Mechanical Engineering Department and graduated in 2011. He is currently working as a research assistant at Bingöl University, Faculty of Engineering and Mechanical Engineering Department.

  1. Author contributions: The author has accepted responsibility for the entire content of this submitted manuscript and approved submission.

  2. Research funding: None declared.

  3. Conflict of interest statement: The author declares no conflicts of interest regarding this article.

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Published Online: 2022-11-29
Published in Print: 2022-12-16

© 2022 Walter de Gruyter GmbH, Berlin/Boston

Articles in the same Issue

  1. Frontmatter
  2. Effects of Re and Co additions on lattice parameters and lattice misfit in cast Ni-based superalloys
  3. Influence of pre- and post-weld heat treats on microstructures of laser welded GTD-111 with IN-718 as filler metal
  4. Examination of α′′, α′ and ω phases in a β-type titanium–niobium metal
  5. Corrosion resistance, thermal diffusivity and mechanical properties of Ni–SiO2 nanocomposite coatings on a 316 stainless steel for heat exchanger applications
  6. Influence of acidic media and chlorides on protective properties of epoxy coatings
  7. Effects of silver interlayer thickness on the microstructure and properties of electron beam welded joints of TC4 titanium and 4J29 Kovar alloys
  8. Influence of the mild steel coating application process, drying method and pigment on the surface topography
  9. Friction stir welding for manufacturing of a light weight combat aircraft structure
  10. Manufacturing and FSW of hybrid functionally graded metal matrix composite
  11. Effect of cryogenic treatment holding time on mechanical and microstructural properties of Sverker 21 steel
  12. Mechanical properties and microstructure evolution of Cf/SiC–Nb joints using Ti-base laminated foil
  13. Effect of nano graphene and CNT addition on coating properties in friction surfacing process
  14. Effect of ultra-high boron additions on microstructure and mechanical properties on high chromium steel
  15. Microstructure, tensile properties and fracture toughness of friction stir welded AA7075-T651 aluminium alloy joints
  16. NiTi-SiC composite coating on Ti6Al4V alloy produced by SHS using induction heating
  17. Corrosion resistance of commercial glazes of floor tiles
https://doi.org/10.1515/mt-2022-0122
Keywords for this article
hardness; induction heating; NiTi; NiTi-XSiC; Ti6Al4V

Articles in the same Issue

  1. Frontmatter
  2. Effects of Re and Co additions on lattice parameters and lattice misfit in cast Ni-based superalloys
  3. Influence of pre- and post-weld heat treats on microstructures of laser welded GTD-111 with IN-718 as filler metal
  4. Examination of α′′, α′ and ω phases in a β-type titanium–niobium metal
  5. Corrosion resistance, thermal diffusivity and mechanical properties of Ni–SiO2 nanocomposite coatings on a 316 stainless steel for heat exchanger applications
  6. Influence of acidic media and chlorides on protective properties of epoxy coatings
  7. Effects of silver interlayer thickness on the microstructure and properties of electron beam welded joints of TC4 titanium and 4J29 Kovar alloys
  8. Influence of the mild steel coating application process, drying method and pigment on the surface topography
  9. Friction stir welding for manufacturing of a light weight combat aircraft structure
  10. Manufacturing and FSW of hybrid functionally graded metal matrix composite
  11. Effect of cryogenic treatment holding time on mechanical and microstructural properties of Sverker 21 steel
  12. Mechanical properties and microstructure evolution of Cf/SiC–Nb joints using Ti-base laminated foil
  13. Effect of nano graphene and CNT addition on coating properties in friction surfacing process
  14. Effect of ultra-high boron additions on microstructure and mechanical properties on high chromium steel
  15. Microstructure, tensile properties and fracture toughness of friction stir welded AA7075-T651 aluminium alloy joints
  16. NiTi-SiC composite coating on Ti6Al4V alloy produced by SHS using induction heating
  17. Corrosion resistance of commercial glazes of floor tiles
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