中国有色金属学报(英文版)
中國有色金屬學報(英文版)
중국유색금속학보(영문판)
TRANSACTIONS OF NONFERROUS METALS SOCIETY OF CHINA
2011年
1期
45-51
,共7页
昝祥%贺跃辉%汪洋%夏源明
昝祥%賀躍輝%汪洋%夏源明
잠상%하약휘%왕양%하원명
TiAl金属间化合物%高应变率%高温%拉伸特性%断裂方式
TiAl金屬間化閤物%高應變率%高溫%拉伸特性%斷裂方式
TiAl금속간화합물%고응변솔%고온%랍신특성%단렬방식
TiAl intermetallics%high strain rate%elevated temperature character%tensile properties%fracture mode
研究Gamma等轴NG组织和近片层NL组织的Ti-46.5Al-2Nb-2Cr合金在不同温度和应变率下的力学行为和断裂模式,揭示温度和应变率对不同微观组织的力学行为和断裂特性的影响.结果表明,两种微观组织的TiAl合金均与温度和应变率相关,且具有类似的温度和应变相关性:动载下的强度明显高于静载下的强度,但在高应变率范围内(320-1 350 s-1)无明显的应变率相关性;韧脆转变温度(BDTT)随应变率的增加而升高;等轴组织的TiAl合金的真应力-真应变曲线中可以看到明显的屈服现象,而近片层组织的屈服现象不明显.在韧脆转变温度以下,随着温度的上升,两种组织的TiAl的断裂方式均由穿晶解理断裂转变为穿晶断裂与沿晶断裂的混和模式,最后转变为沿晶断裂方式.
研究Gamma等軸NG組織和近片層NL組織的Ti-46.5Al-2Nb-2Cr閤金在不同溫度和應變率下的力學行為和斷裂模式,揭示溫度和應變率對不同微觀組織的力學行為和斷裂特性的影響.結果錶明,兩種微觀組織的TiAl閤金均與溫度和應變率相關,且具有類似的溫度和應變相關性:動載下的彊度明顯高于靜載下的彊度,但在高應變率範圍內(320-1 350 s-1)無明顯的應變率相關性;韌脆轉變溫度(BDTT)隨應變率的增加而升高;等軸組織的TiAl閤金的真應力-真應變麯線中可以看到明顯的屈服現象,而近片層組織的屈服現象不明顯.在韌脆轉變溫度以下,隨著溫度的上升,兩種組織的TiAl的斷裂方式均由穿晶解理斷裂轉變為穿晶斷裂與沿晶斷裂的混和模式,最後轉變為沿晶斷裂方式.
연구Gamma등축NG조직화근편층NL조직적Ti-46.5Al-2Nb-2Cr합금재불동온도화응변솔하적역학행위화단렬모식,게시온도화응변솔대불동미관조직적역학행위화단렬특성적영향.결과표명,량충미관조직적TiAl합금균여온도화응변솔상관,차구유유사적온도화응변상관성:동재하적강도명현고우정재하적강도,단재고응변솔범위내(320-1 350 s-1)무명현적응변솔상관성;인취전변온도(BDTT)수응변솔적증가이승고;등축조직적TiAl합금적진응력-진응변곡선중가이간도명현적굴복현상,이근편층조직적굴복현상불명현.재인취전변온도이하,수착온도적상승,량충조직적TiAl적단렬방식균유천정해리단렬전변위천정단렬여연정단렬적혼화모식,최후전변위연정단렬방식.
Experimental studies were conducted on the tensile behaviors and fracture modes of TiAl (Ti-46.5Al-2Nb-2Cr) alloys with near gamma (NG) equiaxed and near lamellar (NL) microstructures over a temperature range from room temperature to 840 ℃ and a strain rate range of 0.001-1 350 s-1. The results indicate that the alloys are both temperature and strain rate dependent and they have a similar dependence. The dynamic strength is higher than the quasi-static strength but almost insensitive to high strain rate range of 320-1 350 s-1. The brittle-to-ductile transition temperature (BDTT) increases with increasing strain rates. NG TiAl yields obviously, while NL TiAl does not. Below BDTT, as the temperature increases, the fracture modes of the two alloys change from planar cleavage fracture to a mixture of transgranular and intergranular fractures, and finally to totally intergranular fracture.
