中国有色金属学报
中國有色金屬學報
중국유색금속학보
THE CHINESE JOURNAL OF NONFERROUS METALS
2013年
12期
3267-3274
,共8页
林楷%康志新%方强%张俊逸
林楷%康誌新%方彊%張俊逸
림해%강지신%방강%장준일
Mg-Li合金%等通道转角挤压%轧制%退火%显微组织%力学性能
Mg-Li閤金%等通道轉角擠壓%軋製%退火%顯微組織%力學性能
Mg-Li합금%등통도전각제압%알제%퇴화%현미조직%역학성능
Mg-Li alloy%equal channel angular pressing%rolling%annealing%microstructure%mechanical property
采用剧塑性变形工艺(等通道转角挤压和轧制)以及随后的短时间退火制备高性能Mg-Li合金,通过显微组织观察、扫描电镜分析、X射线衍射仪测试和室温拉伸测试等研究变形前后合金组织、力学性能及强化机制。结果表明:合金铸态晶粒粗大,主相为β相,α相分布于β相的晶界以及晶内;同时,晶内存在大量Al 2 Y和AlLi析出相。由于动态回复作用显著,合金变形时并未发生明显的动态再结晶现象;经短时间退火后,合金组织发生完全再结晶,其晶粒细化至27.1μm(12pra工艺,即等通道转角挤压、轧制及退火)。铸态合金的抗拉强度和伸长率分别为131.1 MPa和47.1%;经12pr(等通道转角挤压及轧制)变形后,合金的伸长率达到90.5%,而抗拉强度稍有提高,这主要受位错协调变形及动态回复作用的影响;退火后合金的伸长率显著降低而强度提高至237.6 MPa (12pra),出现退火致强化现象,其主要的机制是有限位错源强化及晶界强化。
採用劇塑性變形工藝(等通道轉角擠壓和軋製)以及隨後的短時間退火製備高性能Mg-Li閤金,通過顯微組織觀察、掃描電鏡分析、X射線衍射儀測試和室溫拉伸測試等研究變形前後閤金組織、力學性能及彊化機製。結果錶明:閤金鑄態晶粒粗大,主相為β相,α相分佈于β相的晶界以及晶內;同時,晶內存在大量Al 2 Y和AlLi析齣相。由于動態迴複作用顯著,閤金變形時併未髮生明顯的動態再結晶現象;經短時間退火後,閤金組織髮生完全再結晶,其晶粒細化至27.1μm(12pra工藝,即等通道轉角擠壓、軋製及退火)。鑄態閤金的抗拉彊度和伸長率分彆為131.1 MPa和47.1%;經12pr(等通道轉角擠壓及軋製)變形後,閤金的伸長率達到90.5%,而抗拉彊度稍有提高,這主要受位錯協調變形及動態迴複作用的影響;退火後閤金的伸長率顯著降低而彊度提高至237.6 MPa (12pra),齣現退火緻彊化現象,其主要的機製是有限位錯源彊化及晶界彊化。
채용극소성변형공예(등통도전각제압화알제)이급수후적단시간퇴화제비고성능Mg-Li합금,통과현미조직관찰、소묘전경분석、X사선연사의측시화실온랍신측시등연구변형전후합금조직、역학성능급강화궤제。결과표명:합금주태정립조대,주상위β상,α상분포우β상적정계이급정내;동시,정내존재대량Al 2 Y화AlLi석출상。유우동태회복작용현저,합금변형시병미발생명현적동태재결정현상;경단시간퇴화후,합금조직발생완전재결정,기정립세화지27.1μm(12pra공예,즉등통도전각제압、알제급퇴화)。주태합금적항랍강도화신장솔분별위131.1 MPa화47.1%;경12pr(등통도전각제압급알제)변형후,합금적신장솔체도90.5%,이항랍강도초유제고,저주요수위착협조변형급동태회복작용적영향;퇴화후합금적신장솔현저강저이강도제고지237.6 MPa (12pra),출현퇴화치강화현상,기주요적궤제시유한위착원강화급정계강화。
The microstructure, mechanical properties and strengthening mechanism of Mg-Li alloys processed by severe plastic deformation (equal channel angular pressing (ECAP) and rolling) and subsequent annealing were analyzed by OM, SEM, XRD and tensile testing. The results show that the initial grains of the as-cast alloy are coarse andβphase the main position, while α phase distributes inside or in the boundary. Meanwhile, there are lots of precipitate phases Al2Y and AlLi in the grain. Obvious dynamic recrystallization (DRX) does not occur during the deformation due to the significant effect of dynamic recovery (DR). After a short time annealing, the alloy is completely recrystallized with grain size refined to 27.1μm (process of 12pra:ECAP, rolling and annealing). The tensile strength and elongation of the as-cast alloy are 131.1 MPa and 47.1%, respectively. After the process of 12pr (ECAP and rolling), the elongation of the alloy reaches 90.5%, while the tensile strength is improved slightly. This can be explained based on the effect of DR and dislocation-coordinated deformation. Subsequent annealing treatment results in an increase in tensile strength (12pra:237.6 MPa) and a significant decrease in elongation because of the dislocation source-limited hardening and grain boundary strengthening mechanism.
