稀有金属材料与工程
稀有金屬材料與工程
희유금속재료여공정
RARE METAL MATERIALS AND ENGINEERNG
2005年
6期
845-849
,共5页
闫蕴琪%张廷杰%邓炬%周廉%陈昌麒%刘培英
閆蘊琪%張廷傑%鄧炬%週廉%陳昌麒%劉培英
염온기%장정걸%산거%주렴%진창기%류배영
变形Mg-Nd合金%组织%拉伸特征%超塑性行为%机制
變形Mg-Nd閤金%組織%拉伸特徵%超塑性行為%機製
변형Mg-Nd합금%조직%랍신특정%초소성행위%궤제
wrought Mg-Nd alloy%microstructures%tensile properties feature%superplasticity behavior
研究不同变形条件对Mg-2.2Nd-0.5Zn-0.5Zr合金室温拉伸性能和组织的影响.经过不同条件的热挤压变形后,该合金的强度和延性都有不同程度的增加,屈强比从0.58提高到0.87左右.固定变形温度时,强度随变形速率增大而降低,延性反之.固定变形速率时,升高变形温度则强度降低,延性增加.弥散于晶界的Mg9Nd化合物细化了晶粒.变形态Mg-Nd合金的高温超塑拉伸研究发现,375℃是该合金的最佳超塑变形温度,应变速率在1×10-2s-1时,延伸率达到329%;当变形速率提高到2×10-2s-1时,该合金的延伸率仍可达到213%.分析不同真应变下的组织发现,在变形初期发生动态再结晶,晶粒得到破碎而变得细小,随着变形程度的增加,晶粒长大程度较小.在变形后的断口形貌中发现,Mg-Nd合金的超塑变形机制为晶界滑移控制下的孔洞连接协调机制.
研究不同變形條件對Mg-2.2Nd-0.5Zn-0.5Zr閤金室溫拉伸性能和組織的影響.經過不同條件的熱擠壓變形後,該閤金的彊度和延性都有不同程度的增加,屈彊比從0.58提高到0.87左右.固定變形溫度時,彊度隨變形速率增大而降低,延性反之.固定變形速率時,升高變形溫度則彊度降低,延性增加.瀰散于晶界的Mg9Nd化閤物細化瞭晶粒.變形態Mg-Nd閤金的高溫超塑拉伸研究髮現,375℃是該閤金的最佳超塑變形溫度,應變速率在1×10-2s-1時,延伸率達到329%;噹變形速率提高到2×10-2s-1時,該閤金的延伸率仍可達到213%.分析不同真應變下的組織髮現,在變形初期髮生動態再結晶,晶粒得到破碎而變得細小,隨著變形程度的增加,晶粒長大程度較小.在變形後的斷口形貌中髮現,Mg-Nd閤金的超塑變形機製為晶界滑移控製下的孔洞連接協調機製.
연구불동변형조건대Mg-2.2Nd-0.5Zn-0.5Zr합금실온랍신성능화조직적영향.경과불동조건적열제압변형후,해합금적강도화연성도유불동정도적증가,굴강비종0.58제고도0.87좌우.고정변형온도시,강도수변형속솔증대이강저,연성반지.고정변형속솔시,승고변형온도칙강도강저,연성증가.미산우정계적Mg9Nd화합물세화료정립.변형태Mg-Nd합금적고온초소랍신연구발현,375℃시해합금적최가초소변형온도,응변속솔재1×10-2s-1시,연신솔체도329%;당변형속솔제고도2×10-2s-1시,해합금적연신솔잉가체도213%.분석불동진응변하적조직발현,재변형초기발생동태재결정,정립득도파쇄이변득세소,수착변형정도적증가,정립장대정도교소.재변형후적단구형모중발현,Mg-Nd합금적초소변형궤제위정계활이공제하적공동련접협조궤제.
Effects of various deformed conditions on microstructures and tensile properties of Mg-2.5Nd-0.5Zn-0.5Zr wt% (Mg-Nd) alloy were investigated. Mg-Nd alloy as-extruded exhibit higher strength and better ductility compared to that of as-T6 condition, while its ratio of yield strength to ultimate strength is enhanced from 0.58 to 0.87. With increasing of the extrusion strain rate, both yield strength and ultimate strength increase at the constant extrusion temperature. Nevertheless, the ductility obeys the opposite regulation. At the same extrusion strain rate, both yield strength and ultimate strength decrease with increasing of the extrusion temperature. Fine Mg9Nd compound particles precipitated in the grain boundaries refine the grains resulting in improving the mechanical properties of as-extruded Mg-Nd alloy. The alloy superplasticity behavior was also exploited in the tensile tests at high temperatures. The results depict that 375℃ is the optimal deformation temperature,while the elongation amounts to 329% at the strain rate of 1 × 10-2s-1. The fracture surface indicates that mechanism of the superplasticity of Mg-Nd alloy is controlled by the grain boundary sliding accommodated with cavities interlinked.