4.7 Article

Microstructural evolution, mechanical properties and wear behavior of in-situ TiC-reinforced Ti matrix composite coating by induction cladding

Journal

SURFACE & COATINGS TECHNOLOGY
Volume 412, Issue -, Pages -

Publisher

ELSEVIER SCIENCE SA
DOI: 10.1016/j.surfcoat.2021.127048

Keywords

Induction cladding; In-situ synthesis; Ti matrix composite coating; Microstructural evolution; Tribological behavior

Funding

  1. National Natural Science Foundation of China [52075544]
  2. National Key Research and Development Program of China [2017YFB0310703]

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In this work, in-situ fabrication of TiC/Ti composite coatings was achieved using high-frequency induction heating under an argon atmosphere, and the microstructural evolution, phase changes, mechanical properties, and tribological behavior of the coatings were systematically investigated. The results indicate that the dissolution-precipitation mechanism governs the in-situ growth of TiC reinforcements, and the morphology, dimensions, and distribution of TiC phase in the coatings are strongly influenced by various factors such as the composition of raw powders and crystal structure of TiC.
In this work, the in-situ fabrication of TiC/Ti composite coatings is realized by melting a mixture of Ti and graphite powders on Ti6Al4V substrate by a high-frequency induction heating coil under Ar atmosphere. The microstructural evolution, phase changes, micro/nano mechanical properties, and tribological behavior of the TiC/Ti composite coatings are systematically investigated. The in-situ growth mechanism of TiC and wear resistance mechanism of the TiC/Ti composite coatings are also discussed from the viewpoints of Ti-C binary phase diagram, composition of raw powders, crystal structure of TiC and solidification conditions. The results indicate that the dissolution-precipitation mechanism dictates the in-situ growth of TiC reinforcements. Moreover, the morphology, dimensions and distribution of TiC phase in the TiC/Ti composite coating are strongly influenced by the composition of raw powders, crystal structure of TiC and induction cladding process. The high induction power and optimal coil scanning speed generate less heat input for the coating formation and fast solidification speed, resulting in fine TiC reinforcements, a narrow interface transition region and a heat-affected zone. Furthermore, the in-situ formation of reinforcements endows high hardness, good elasticity and excellent tribological properties to the TiC/Ti composite coatings.

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