TiCN particle reinforce composite coating in-situ synthesized by nitrogen arc cladding technique 被引量：1

TiCN particle reinforce composite coating in-situ synthesized by nitrogen arc cladding technique

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摘要 An in-situ synthesized TiCN particle reinforce composite coating was fabricated on Q235 steel substrate by nitrogen arc cladding technique, wherein the titanium powder and the graphite powder as original material were intensively mixed by ball-miU and glued with starch binder, then preplaced onto the Q235 steel substrate. The microstructures and interfacial behavior were investigated by scanning electron microscopy. The phase of the coatings was investigated by X-ray diffractometer. The microhardness was tested by microhardness tester. The anti-abrasive pe^Cormance was tested by abrasion machine. The results show that an excellent bonding between the coatings and carbon steel substrate is ensured by the strong metallurgical inteoCace and phases of the coatings are mainly composed of TiCN. The highest microhardness of the coatings reaches 810HV0. 5, which is about 3 times more than that of the Q235 substrate. The anti-abrasive test results indicate that the coating is more anti-abrasive than the Q235 substrate. An in-situ synthesized TiCN particle reinforce composite coating was fabricated on Q235 steel substrate by nitrogen arc cladding technique, wherein the titanium powder and the graphite powder as original material were intensively mixed by ball-miU and glued with starch binder, then preplaced onto the Q235 steel substrate. The microstructures and interfacial behavior were investigated by scanning electron microscopy. The phase of the coatings was investigated by X-ray diffractometer. The microhardness was tested by microhardness tester. The anti-abrasive pe^Cormance was tested by abrasion machine. The results show that an excellent bonding between the coatings and carbon steel substrate is ensured by the strong metallurgical inteoCace and phases of the coatings are mainly composed of TiCN. The highest microhardness of the coatings reaches 810HV0. 5, which is about 3 times more than that of the Q235 substrate. The anti-abrasive test results indicate that the coating is more anti-abrasive than the Q235 substrate.

作者郝建军张利李建昌赵建国马璐萍马跃进

机构地区 College of Mechanical and Electrical Engineering

出处《China Welding》 EI CAS 2013年第2期30-33,共4页 中国焊接（英文版）

基金 This research was financially supported by Natural Science Foundation of Hebei Province for Distinguished Young Scientists （ No. E2011204036）.

关键词 nitrogen arc cladding TiCN composite coating in situ synthesis nitrogen arc cladding, TiCN composite coating, in situ synthesis

分类号 TG174.442 [金属学及工艺—金属表面处理] TB333 [一般工业技术—材料科学与工程]

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