Mechanical properties optimization of Cr3C2-NiCr coatings produced by compact plasma spray process.

Chromium carbides are widely used as functional coatings on steel structures in high-end applications, from energy to marine and aerospace sectors thanks to their corrosion and wear resistance at elevated temperatures. In the present work, a low-power compact plasma spray (CPS) equipment was used to deposit Cr 3 C 2 -based cermet coatings on carbon steel substrate. Design of experiment was applied to select and optimize the spraying parameters, namely current, stand-off distance, scanning speed, plasma gas rate and powder feeding rate. ANOVA analysis was conducted to estimate the effect of the spraying variables on morphology and mechanical properties of the coatings and evaluate the optimal spraying condition. Dense and compact coatings were fabricated by using the CPS. By optimizing the processing parameters, coating hardness equal to approximately 600 HV and average thickness ranging around 600 μm were obtained, while the adhesion strength was approximately equal to 14 MPa. Intermediate phases of Cr carbides were produced by the dissolution of the primary Cr 3 C 2 induced by melting and re-solidification of the particles. The presence of weaker carbide phase, inter-lamellae different features and porosity also caused the scattered hardness values observed in the coatings. • Low power compact plasma spray technique demonstrated to produce sound chromium carbide-based cermet coatings. • The properties of the Cr 3 C 2 -NiCr coating are mainly influenced by current, stand-off distance and plasma flow rate. • Coating adherence and hardness obtained under optimal configuration meet the requirements for applications in CSP plants. • The inflight dissolution of Cr 3 C 2 and the related porosity led to a decrease in the mechanical properties of the coatings. [ABSTRACT FROM AUTHOR]