(1. 北京科技大學 機械工程學院,北京100083;2. 哈爾濱工業(yè)大學 材料科學與工程學院,哈爾濱 150001)
摘 要: 通過真空退火處理得到具有不同β相含量的TA15板材,并對其進行室溫單軸拉伸試驗,獲得不同β相含量板材的真應力-應變曲線,并采用Bridgman公式對頸縮階段應力進行了修正。結(jié)果表明:隨著β相含量的增加,拉伸斷裂應變明顯增大。分別考慮α與β相室溫變形行為,基于連續(xù)損傷力學建立了一套耦合位錯密度和微觀損傷的單軸拉伸本構(gòu)模型。通過不同β相含量試樣的應力-應變曲線,采用遺傳算法確定本構(gòu)方程常數(shù)。利用β相含量為18.63%和20.04%的試樣的應力-應變曲線對所建模型進行驗證,計算值與試驗值吻合較好。
關(guān)鍵字: TA15鈦合金;塑性損傷;位錯密度;本構(gòu)模型;遺傳算法
(1. School of Mechanical Engineering, University of Science and Technology Beijing, Beijing 100083, China;
2. School of Materials Science and Engineering, Harbin Institute of Technology, Harbin 150001, China)
Abstract:The sheet specimens of TA15 sheet with different volume fractions of β phase were obtained by vacuum annealing. Then, the stress-strain curves of sheet with different volume fractions of β phase were obtained by tensile test at room temperature, and the true stress after necking was corrected through the well-known Bridgman equations. The results indicate that the tensile strength increases slightly with the volume fraction of β phase. With increasing volume fraction of β phase, the fracture strain increases significantly. Considering the flow behavior of two phases, respectively, a set of constitutive equations coupling dislocation density and damage based on the continuum damage mechanics were developed. The model constants were determined using genetic optimization algorithm (GA). The stress-strain curves of the sheet with 18.63% and 20.04% β phase were used to evaluate the proposed model. The good agreements between the experimental and computed results are obtained.
Key words: TA15 Ti alloy; ductile damage; dislocation density; constitutive model; genetic algorithm
