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
2015年
1期
249-260
,共12页
蓝永庭%钟献词%权高峰%蔺若成%张克实
藍永庭%鐘獻詞%權高峰%藺若成%張剋實
람영정%종헌사%권고봉%린약성%장극실
AZ31镁合金%本构模型%单晶体%变形孪生%孪晶变体%孪晶交叉
AZ31鎂閤金%本構模型%單晶體%變形孿生%孿晶變體%孿晶交扠
AZ31미합금%본구모형%단정체%변형련생%련정변체%련정교차
AZ31 magnesium alloy%constitutive model%single crystal%deformation twin%twin variant%twin intersection
为研究 HCP 结构单晶在塑性变形中的变形孪晶和塑性各向异性,采用基于晶体塑性本构理论的有限单元法,建立包含滑移与孪生变形机制的晶体塑性本构关系,发展了以应力作为自变量的牛顿?拉普森迭代方法,通过已有文献的试验数据验证模型的有效性,并利用此模型模拟 AZ31单晶体在4种(即沿??2110,??0110,?0001?和??0111方向)拉伸与压缩变形路径下的塑性变形行为,并获得了相应加载路径下的应力?应变关系曲线。数值计算结果表明,在不同加载路径下该模型可用于预测滑移系或孪生系的活动情况,以及描述孪生变体的活动数量、主要孪生变体和孪生交叉类型。由于机械孪晶具有的极性性质及其在材料非弹性变形中的重要作用,单晶材料表现出显著的各向异性与非对称性。
為研究 HCP 結構單晶在塑性變形中的變形孿晶和塑性各嚮異性,採用基于晶體塑性本構理論的有限單元法,建立包含滑移與孿生變形機製的晶體塑性本構關繫,髮展瞭以應力作為自變量的牛頓?拉普森迭代方法,通過已有文獻的試驗數據驗證模型的有效性,併利用此模型模擬 AZ31單晶體在4種(即沿??2110,??0110,?0001?和??0111方嚮)拉伸與壓縮變形路徑下的塑性變形行為,併穫得瞭相應加載路徑下的應力?應變關繫麯線。數值計算結果錶明,在不同加載路徑下該模型可用于預測滑移繫或孿生繫的活動情況,以及描述孿生變體的活動數量、主要孿生變體和孿生交扠類型。由于機械孿晶具有的極性性質及其在材料非彈性變形中的重要作用,單晶材料錶現齣顯著的各嚮異性與非對稱性。
위연구 HCP 결구단정재소성변형중적변형련정화소성각향이성,채용기우정체소성본구이론적유한단원법,건립포함활이여련생변형궤제적정체소성본구관계,발전료이응력작위자변량적우돈?랍보삼질대방법,통과이유문헌적시험수거험증모형적유효성,병이용차모형모의 AZ31단정체재4충(즉연??2110,??0110,?0001?화??0111방향)랍신여압축변형로경하적소성변형행위,병획득료상응가재로경하적응력?응변관계곡선。수치계산결과표명,재불동가재로경하해모형가용우예측활이계혹련생계적활동정황,이급묘술련생변체적활동수량、주요련생변체화련생교차류형。유우궤계련정구유적겁성성질급기재재료비탄성변형중적중요작용,단정재료표현출현저적각향이성여비대칭성。
To investigate the deformation twinning and the plastic anisotropy of the hexagonal-close-packed (HCP) single crystal, the crystal plastic constitutive model including slip and twinning deformation was established with finite element method based on crystal plasticity theory. The model was verified by test data. Newton?Raphson iteration method was developed with the stress components directly as the basic variables of iteration. The plastic deformation behavior of single crystal AZ31 alloy was analyzed numerically under monotonic tension and compression, respectively, in four different strain paths (i.e. along ??2 1 1 0 , ??01 1 0 ,?0001?and ??01 1 1 ) with this model. The stress?strain curves were obtained in the above paths. The numerical calculation results show that this crystal model is feasible to predict the activity of slip/twinning system and to describe the number of active twin variants, the types of dominant twin variants and twin intersection. Due to the polar nature of mechanical twinning in inelastic deformation of the material, the plastic behavior of the single crystal material is demonstrated to be notably anisotropic and high asymmetry.
