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Adhesive wear behavior of gas tungsten arc welded FeB-FeMo-C coatings

  • Mehmet Yaz

    Mehmet Yaz, born in 1962, completed his higher education in 1986 at the Gazi University Technical Education Faculty, Machining Department. In the fall of 1996, he started his graduate studies at the Institute of Science, Department of Mechanical Education. After completing his Master’s degree in 1999, he started his Ph.D. at the Institute of Science, Department of Metallurgical Education. In 2005, he successfully completed his Ph.D. Currently, he is an Associate Professor in the field of Materials and Metallurgical Engineering.

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Published/Copyright: March 9, 2022
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Materials Testing
From the journal Materials Testing Volume 64 Issue 2

Abstract

In this article, a gas tungsten arc welding is used as a high energy density beam to form a surface over 0.15% carbon steel with FeB, FeMo, and graphite powders. The microstructure, microhardness, and dry-sliding wear behavior of the composite coating were investigated using optical micrography, X-ray diffraction, scanning electron microscopy, and energy-dispersive X-ray spectrometry. Microstructural investigations reveal that FeB-reinforced coating exhibited a homogeneous microstructure that consists of dendrites and eutectic. A lot of types of carbide and borides were formed. MoB4, Fe2MoC, B8C, Mo2BC, MoB, Fe3Mo, Fe3B, B25C, Fe7C3, FeB, Mo2B5, and MoC were seen in coated surfaces. Graphite iron boride coatings obtained by the gas tungsten arc welding process improved the wear resistance of carbon steel.

Keywords: adhesive wear; coating; FeB; FeMo; gas tungsten arc welding
Corresponding author: Mehmet Yaz, Technical Sciences of Vocational High School, Firat University, Elazig, Turkey, E-mail:

Funding source: Firat University Scientific Research Projects Unit

Award Identifier / Grant number: Project No: 1809

About the author

Mehmet Yaz

Mehmet Yaz, born in 1962, completed his higher education in 1986 at the Gazi University Technical Education Faculty, Machining Department. In the fall of 1996, he started his graduate studies at the Institute of Science, Department of Mechanical Education. After completing his Master’s degree in 1999, he started his Ph.D. at the Institute of Science, Department of Metallurgical Education. In 2005, he successfully completed his Ph.D. Currently, he is an Associate Professor in the field of Materials and Metallurgical Engineering.

Acknowledgments

The author wishes to thank the Firat University Scientific Research Projects Unit.

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

  2. Research funding: This work was supported by Firat University Scientific Research Projects Unit (FUBAP) (Project No: 1809).

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

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Published Online: 2022-03-09
Published in Print: 2022-02-23

© 2021 Walter de Gruyter GmbH, Berlin/Boston

Articles in the same Issue

  1. Frontmatter
  2. Utilisation of the X-ray emission of an electron beam capillary for visualisation of the beam-material interaction
  3. Effect of Re and Ru additions on morphology and long-term stability of gamma prime particles in new modified superalloys prepared by a vacuum arc melting process
  4. Microstructure and fatigue performance of Cu-based M7C3-reinforced composites
  5. Influence of peroxide cross-linking temperature and time on mechanical, physical and thermal properties of polyethylene
  6. Fatigue behavior of bolted boreholes under various preloads
  7. Application of machine vision-based NDT technology in ceramic surface defect detection – a review
  8. An approach for obtaining surface residual stress based on indentation test and strain measurement
  9. Adhesive wear behavior of gas tungsten arc welded FeB-FeMo-C coatings
  10. Structural design optimization of the arc spring and dual-mass flywheel integrated with different optimization methods
  11. Tribological and adhesion properties of microwave-assisted borided AISI 316L steel
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https://doi.org/10.1515/mt-2021-2001
Keywords for this article
adhesive wear; coating; FeB; FeMo; gas tungsten arc welding

Articles in the same Issue

  1. Frontmatter
  2. Utilisation of the X-ray emission of an electron beam capillary for visualisation of the beam-material interaction
  3. Effect of Re and Ru additions on morphology and long-term stability of gamma prime particles in new modified superalloys prepared by a vacuum arc melting process
  4. Microstructure and fatigue performance of Cu-based M7C3-reinforced composites
  5. Influence of peroxide cross-linking temperature and time on mechanical, physical and thermal properties of polyethylene
  6. Fatigue behavior of bolted boreholes under various preloads
  7. Application of machine vision-based NDT technology in ceramic surface defect detection – a review
  8. An approach for obtaining surface residual stress based on indentation test and strain measurement
  9. Adhesive wear behavior of gas tungsten arc welded FeB-FeMo-C coatings
  10. Structural design optimization of the arc spring and dual-mass flywheel integrated with different optimization methods
  11. Tribological and adhesion properties of microwave-assisted borided AISI 316L steel
  12. Mechanical properties of wire arc additive manufactured carbon steel cylindrical component made by cold metal transferred arc welding process
  13. Improvement of the structural, thermal, and mechanical properties of polyurethane adhesives with nanoparticles and their application to Al/Al honeycomb sandwich panels
  14. Mechanical behavior of a friction welded AA6013/AA7075 beam
  15. Effects of carbon nanotubes on mechanical behavior of fiber reinforced composite under static loading
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