粉末冶金材料科学与工程
粉末冶金材料科學與工程
분말야금재료과학여공정
POWDER METALLURGY MATERIALS SCIENCE AND ENGINEERING
2013年
5期
680-686
,共7页
罗涛%刘伯威%刘咏%刘延斌%刘彬
囉濤%劉伯威%劉詠%劉延斌%劉彬
라도%류백위%류영%류연빈%류빈
钛基复合材料%粉末冶金%显微组织%力学性能%断裂机理
鈦基複閤材料%粉末冶金%顯微組織%力學性能%斷裂機理
태기복합재료%분말야금%현미조직%역학성능%단렬궤리
titanium matrix composites%powder metallurgy%microstructure%mechanical property%fracture mechanism
在Ti粉中同时加入Mo2C、VC、NbC、WC粉末,通过多组元合金化与原位合成TiC颗粒,来制备TiC颗粒增强钛基复合材料TiC/Ti-Mo-V-Nb-W,通过X射线衍射和扫描电镜分析该复合材料的相成分和显微组织,测试其室温力学性能,并分析其断裂机理。结果表明:Ti与Mo2C等反应原位生成的TiC颗粒,呈等轴状或近等轴状;TiC颗粒总体分布均匀,但局部有团聚现象;Mo、V、Nb、W等固溶在Ti基体中,基体为近β-Ti合金;TiC/Ti-Mo-V-Nb-W复合材料在室温下具有较好的塑性,抗拉强度和伸长率分别为1023.6 MPa和17.4%,断裂失效主要由TiC颗粒断裂和基体断裂引起。
在Ti粉中同時加入Mo2C、VC、NbC、WC粉末,通過多組元閤金化與原位閤成TiC顆粒,來製備TiC顆粒增彊鈦基複閤材料TiC/Ti-Mo-V-Nb-W,通過X射線衍射和掃描電鏡分析該複閤材料的相成分和顯微組織,測試其室溫力學性能,併分析其斷裂機理。結果錶明:Ti與Mo2C等反應原位生成的TiC顆粒,呈等軸狀或近等軸狀;TiC顆粒總體分佈均勻,但跼部有糰聚現象;Mo、V、Nb、W等固溶在Ti基體中,基體為近β-Ti閤金;TiC/Ti-Mo-V-Nb-W複閤材料在室溫下具有較好的塑性,抗拉彊度和伸長率分彆為1023.6 MPa和17.4%,斷裂失效主要由TiC顆粒斷裂和基體斷裂引起。
재Ti분중동시가입Mo2C、VC、NbC、WC분말,통과다조원합금화여원위합성TiC과립,래제비TiC과립증강태기복합재료TiC/Ti-Mo-V-Nb-W,통과X사선연사화소묘전경분석해복합재료적상성분화현미조직,측시기실온역학성능,병분석기단렬궤리。결과표명:Ti여Mo2C등반응원위생성적TiC과립,정등축상혹근등축상;TiC과립총체분포균균,단국부유단취현상;Mo、V、Nb、W등고용재Ti기체중,기체위근β-Ti합금;TiC/Ti-Mo-V-Nb-W복합재료재실온하구유교호적소성,항랍강도화신장솔분별위1023.6 MPa화17.4%,단렬실효주요유TiC과립단렬화기체단렬인기。
TiC/Ti-Mo-V-Nb-W composite was prepared through the multi-component in-situ synthesis reaction using Ti, Mo2C, VC, NbC and WC mixed powders as raw materials. The phase composition of the prepared composite were identified by X-ray diffraction (XRD), and the microstructures as well as the fracture surface and mechanism were examined by scanning electron microscopy (SEM). Beside, the tensile properties were tested at room temperature. The results show that the reactions between Ti and Mo2C, VC, NbC, WC result in the formation of equiaxial or similar equiaxial shape TiC particles and nearβ-Ti alloy. The TiC particles distribute uniformly but agglomerate locally in the matrix alloy as a whole. Mo, V, Nb, W dissolve in Ti matrix, and the matrix is similar as near β-Ti alloy. The TiC/Ti-Mo-V-Nb-W composite has better plasticity property with tensile strength of 1 023.6 MPa and elongation of 17.4%at room temperature. The rupture of TiC particles and matrix are the main cause for the fracture of composites.
