In fast neutron reactors, some contact areas of moving parts require a cobalt free hardfacing coatings, as under neutron flux, the 59Co, stable, can be transmuted into 60Co and, therefore, can contaminate the primary circuit. This is particularly critical for the insert holes of the diagrid for the positioning of the hexagonal fuel tubes that have to be internally coated. In this article, we propose to present the development of the cobalt free hardfacing material up to the manufacturing of the inner clads with a specific deep laser cladding nozzle.
In previous presentations, laser cladding has been identified as a deposition process that could increase the performances of the hardfacing materials compared to the standard process (Plasma Transferred Arc Welding). In parallel, the potential interest of some nickel base materials as Colmonoy® 52 or Tribaloy® T700 has been demonstrated. Unfortunately, the deposition of these fragile alloys require a preheating of the substrate over 450°C. More recently, Nucalloy® 453, a new hardfacing nickel base alloy has been evaluated and demonstrated easierdeposition conditions that requires lower preheating temperature (<300°C).
The article presents the evaluation of Nucalloy® 453 with material analysis and wear tests. The microstructural characterization is compared to Colmonoy® 52, which is a similar NiFeCrSiBC alloy. Finally, the laser cladding of a scale one demonstrator is presented: two inner zones of a cylinder with 1 m length and 100 mm diameter diameter are laser cladded thank to a deep cladding nozzle. The advantage of the laser cladding process is compared to Plasma Arc Transferred Welding.
Keywords
- Laser Cladding
- Nickel Base Hardfacing Material
- Wear Resistance