Optimization of Ni-B-Mo Electroless Coating on GCr15 Steel: Effects of Main Salt Concentration and Deposition Time.

GCr15 bearing steel is widely used in the textile, aerospace, and other industries due to its excellent mechanical properties. However, traditional electroless Ni-B coatings can no longer meet the growing demand for a long service life under high-speed and heavy load conditions. This study focused on depositing Ni-B-Mo alloy coatings on GCr15 steel. An orthogonal experimental design was adopted to investigate the effects of the NiCl and NaMoO concentrations and deposition time on the deposition rate and surface hardness of the coatings. The results show that the NaMoO concentration has the most significant impact on the deposition rate. An optimal concentration of 5.6 g/L improved both the deposition rate and hardness (up to 881 HV), while excessive NaMoO (>15.6 g/L) reduced the coating adhesion and wear resistance. A deposition time of 1-2 h ensured a high deposition rate, but after 3 h, bath component depletion lowered the rate and caused coating defects. The NiCl concentration (20-30 g/L) had a relatively minor influence on the deposition rate but stabilized the Ni ion supply, enhancing the coating compactness. The optimized parameters were 5.6 g/L NaMoO, 25 g/L NiCl, and 2 h of deposition. The coating exhibited high hardness, strong adhesion, and excellent wear resistance. After heat treatment at 400 °C for 1 h, the coating transitioned from being amorphous to nanocrystalline, forming NiB, NiB, and MoC phases, increasing the hardness from 737.49 HV to 916.19 HV and reducing the friction coefficient to 0.38.