Microstructure and properties of TiC ceramic powder on a cobalt-based alloy obtained via electromagnetic-assisted laser metal deposition

The crack sensitivity of laser metal ceramic deposition is an important factor restricting its development. In this paper, a TiC-reinforced cobalt-based alloy was deposited on 300M steel using electromagnetic-assisted laser metal deposition technology. The electromagnetic composite effect on the microstructure, mechanical properties, magnetic properties, wear resistance and crack sensitivity of the laser metal deposition layer was discussed. Under the action of an electromagnetic field, the size of the TiC decreased by 54.6% compared with that of the deposited layer without an electromagnetic field. The effect of the electromagnetic composite field can reach the bottom of the molten pool, thus refining the grain size at the bottom of the coating. This resulted in a 22% increase in the hardness of the deposition layer. The electromagnetic field effect reduces the elastic modulus of the deposition layer, thus improving the mechanical properties of the coatings. In addition, compared with that of the deposition layer without an external field, the wear of the deposition layer with an electromagnetic force is obviously reduced. With increasing electromagnetic parameters, the wear resistance of the deposit increased gradually, and the thermal expansion coefficient decreased significantly, which played an important role in improving the crack resistance and comprehensive properties of the deposition layer under extreme working conditions.