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Recognition of the potential of NbC Composites has brought with it new approaches and the development of novel feedstock materials. Increased demand for coated and non-coated component longevity, more cost-effective coating solutions, and health and safety considerations during coating processes and post-coating machining operations proved a strong motivation to produce a new cored wire for wire arc processing.
Using HSC 10 Chemistry software package, thermodynamic models were generated as a first step in the coating design process, to determine the optimum cored wire feedstock composition. HSC 10 utilized the Gibbs Free energy minimization method to determine the ideal stoichiometries of the cored wire to achieve the desired metal matrix NbC composite coating. An example of a thermodynamic model is shown below in Figure
Figure 1. Gibbs free energy minimization plot for the Nickel base NbC Composite coating systems. With the option of changing the metal matrix between Iron, Nickel, and Aluminum, this NbC composite coating system is versatile, cost-efficient and high performing in various lab/field validation test conditions. In the case of Fe-based NbC composite coating, the resultant material is offered.
1) 6X better than uncoated carbon steel under a severe sulfidizingenvironment.
2) 20% better in erosion testing (ASTM-G76) than other competing products
3) Less fume generation because of the metallurgical reaction during spraying
4) Less toxicity considering the coating contains less Chromium, Nickel, and no Tungsten Carbide or Cobalt. 5) Broad functionality of applications – Wire Arc, Laser Cladding/ Laser – Direct Energy Deposition (DED), Plasma Transferred Arc etc.
6) Excellent ductility – The coating can be bent 25 degrees without cracking, which is ~ 25% better than other competing products in this segment.
Figure 2. Metallurgically formed NbC particles homogeneously spread within the Aluminum base metal matrix splats.
Figure 3. Post-bend testing of Al base NbC composite coating. An example of an Aluminum base NbC Composite coating microstructure and post-bend test pictures are shown in Figures 2 and 3.
The Aluminum base NbC composite (Microstructure shown in Figure 2) offers excellent ductility, and it can be bent more than 65 degrees without any cracking. The average hardness of this composite was ~ 750HV (61 HRC), which is approximately 4X greater than Stainless Steel 304 material. This coating protects any steel substrate against saltwater corrosion. All these coating features make this material an excellent candidate for marine, offshore, and Navy flight deck applications against corrosion, wear and anti-slip issues.
Though this material was tested and validated for specific component applications, this NbC composite could extend its application in broader Industrial, Metals and Mining, Pulp and Paper, Oil and Gas, Power, Wind, Hydro, and other Government agencies like DOD, DOE etc. uses.
Twin-arc and cored wire products have been in the market for many years and continuous innovations like this newly developed NbC composite coatings system can revive components making them longer lasting and more sustainable while maintaining cost-effectiveness, environmental friendliness and excellent use properties.
- In this case, a Nickel-Chromium metal matrix with an NbC composite was generated.
Figure 1. Gibbs free energy minimization plot for the Nickel base NbC Composite coating systems. With the option of changing the metal matrix between Iron, Nickel, and Aluminum, this NbC composite coating system is versatile, cost-efficient and high performing in various lab/field validation test conditions. In the case of Fe-based NbC composite coating, the resultant material is offered.
1) 6X better than uncoated carbon steel under a severe sulfidizingenvironment.
2) 20% better in erosion testing (ASTM-G76) than other competing products
3) Less fume generation because of the metallurgical reaction during spraying
4) Less toxicity considering the coating contains less Chromium, Nickel, and no Tungsten Carbide or Cobalt. 5) Broad functionality of applications – Wire Arc, Laser Cladding/ Laser – Direct Energy Deposition (DED), Plasma Transferred Arc etc.
6) Excellent ductility – The coating can be bent 25 degrees without cracking, which is ~ 25% better than other competing products in this segment.
Figure 2. Metallurgically formed NbC particles homogeneously spread within the Aluminum base metal matrix splats.
Figure 3. Post-bend testing of Al base NbC composite coating. An example of an Aluminum base NbC Composite coating microstructure and post-bend test pictures are shown in Figures 2 and 3.
The Aluminum base NbC composite (Microstructure shown in Figure 2) offers excellent ductility, and it can be bent more than 65 degrees without any cracking. The average hardness of this composite was ~ 750HV (61 HRC), which is approximately 4X greater than Stainless Steel 304 material. This coating protects any steel substrate against saltwater corrosion. All these coating features make this material an excellent candidate for marine, offshore, and Navy flight deck applications against corrosion, wear and anti-slip issues.
Though this material was tested and validated for specific component applications, this NbC composite could extend its application in broader Industrial, Metals and Mining, Pulp and Paper, Oil and Gas, Power, Wind, Hydro, and other Government agencies like DOD, DOE etc. uses.
Twin-arc and cored wire products have been in the market for many years and continuous innovations like this newly developed NbC composite coatings system can revive components making them longer lasting and more sustainable while maintaining cost-effectiveness, environmental friendliness and excellent use properties. 