激光技术
激光技術
격광기술
LASER TECHNOLOGY
2014年
2期
186-190
,共5页
激光技术%碳化铬-镍基复合涂层%激光熔覆%微观组织%碳化铬%硬度
激光技術%碳化鉻-鎳基複閤塗層%激光鎔覆%微觀組織%碳化鉻%硬度
격광기술%탄화락-얼기복합도층%격광용복%미관조직%탄화락%경도
laser technique%chromium carbide Ni-base composite coating%laser cladding%microstructure%chromium carbide%microhardness
为了制备陶瓷增强镍基复合涂层,采用激光熔覆技术在45#钢表面原位合成了碳化铬-镍基复合涂层,研究了涂层的显微组织、相结构特征及显微硬度。碳化铬陶瓷的形状主要有四边形(菱形)、六边形和不规则块状;四边形碳化铬为Cr3 C2,六边形碳化铬为Cr7 C3,不规则块状碳化铬成分不确定,可能为Cr3 C2或Cr7 C3;涂层的平均显微硬度达到基体的3.5倍;涂层具有较高的硬度和致密的组织。结果表明,涂层主要由Cr-Ni-Fe-C,C,Cr7 C3和Cr3 C2四相组成,显微组织均匀致密,与基体呈良好的冶金结合。该研究对激光原位碳化铬-镍基复合涂层的理论研究和实际应用是有一定帮助的。
為瞭製備陶瓷增彊鎳基複閤塗層,採用激光鎔覆技術在45#鋼錶麵原位閤成瞭碳化鉻-鎳基複閤塗層,研究瞭塗層的顯微組織、相結構特徵及顯微硬度。碳化鉻陶瓷的形狀主要有四邊形(蔆形)、六邊形和不規則塊狀;四邊形碳化鉻為Cr3 C2,六邊形碳化鉻為Cr7 C3,不規則塊狀碳化鉻成分不確定,可能為Cr3 C2或Cr7 C3;塗層的平均顯微硬度達到基體的3.5倍;塗層具有較高的硬度和緻密的組織。結果錶明,塗層主要由Cr-Ni-Fe-C,C,Cr7 C3和Cr3 C2四相組成,顯微組織均勻緻密,與基體呈良好的冶金結閤。該研究對激光原位碳化鉻-鎳基複閤塗層的理論研究和實際應用是有一定幫助的。
위료제비도자증강얼기복합도층,채용격광용복기술재45#강표면원위합성료탄화락-얼기복합도층,연구료도층적현미조직、상결구특정급현미경도。탄화락도자적형상주요유사변형(릉형)、륙변형화불규칙괴상;사변형탄화락위Cr3 C2,륙변형탄화락위Cr7 C3,불규칙괴상탄화락성분불학정,가능위Cr3 C2혹Cr7 C3;도층적평균현미경도체도기체적3.5배;도층구유교고적경도화치밀적조직。결과표명,도층주요유Cr-Ni-Fe-C,C,Cr7 C3화Cr3 C2사상조성,현미조직균균치밀,여기체정량호적야금결합。해연구대격광원위탄화락-얼기복합도층적이론연구화실제응용시유일정방조적。
In order to prepare ceramic reinforced Ni-base composite coating , chromium carbide Ni-base composite coating was prepared on the surface of 45#steel by laser cladding , the microstructure , phase structure and microhardness of the coating were studied .The shapes of chromium carbide ceramic particles were quadrangular , hexagonal and irregular block.By the analysis, quadrangular chromium carbide was Cr 3 C2 , hexagonal chromium carbide was Cr 7 C3 , the composition of irregular blocky chromium carbide was indeterminacy , may be Cr3 C2 or Cr7 C3 .The microhardness of the coating was 3.5 times of the substrate.The coating had high microhardness and dense microstructure .The results indicated that the coating was mainly composed of Cr-Ni-Fe-C, C, Cr7 C3 and Cr3 C2 .The microstructure of the composite layer was proved to be homogeneous and dense .A good metallurgical combination was formed at the boundary of the coating layer and substrate.The research plays a vital role in theoretical research and practical application of the in-situ synthesized chromium carbide Ni-base composite coating .