SiCp／Al复合材料高应变率压缩变形及损伤机理

采用真空热压工艺制备了含SiC颗粒体积分数分别为5%,15%和25%的SiC颗粒增强铝基复合材料,利用Hopkinson高速压杆冲击实验系统对其从静态到动态(应变率为3.3×10-3s-1～5.2×103s-1)的压缩破坏响应进行了研究,结合其光学显微镜分析变形组织,分析了不同体积分数SiCp/Al复合材料高应变率压缩载荷下,材料的变形和微观损伤机理.结果表明,复合材料存在应变率敏感性,SiC含量的增加导致复合材料应变率敏感性的增加,以垂直于载荷方向的增强相颗粒的剪切开裂为主要破坏模式.     

升温率和应变率对30CrMnSi拉伸强度的影响

报道了硬度ＨＲＣ为２０和４０的两种３０ＣｒＭｎＳｉ材料在１００－９００℃的力学性能及升温率，应变率和热处理条件对抗拉强度，屈服强度的影响。在低温区，材料性能随温度的升高，呈现缓慢下降，其数值与常温相差不多，热处理状态对该区影响甚大，升温率有一定影响；在高温区，材料强度大大降低，其数值随温度变化不大，不同升温速率的影响及热处理状态影响消失；在中温区，材料性能随温度升高呈现快速下降趋势，热处理状态对材     

深冲汽车簿钢板织构的表述方法

利用晶体学性质,将深冲汽车薄板的两种主要特征织构表述于反极图之中,再利用织构定量技术便能简捷地分析深冲钢板的织构与深冲性能的关系。经验证,此法与ODF定量分析所得的结果一致。     

Bi2223超导带材的机械性能的改善

通过在超导芯部引入Ag合金的方法制备了新结构单芯和多芯带材，并研究了此种带材机械性能，以及其相对于普通Bi-2223超导带材变化。这种新结构提高了Bi-2223超导带材抗拉伸应变的能力。在拉伸应力的作用下，单芯样品的屈服强度和σ0.2不可逆应变极限εirr和普通样品相比均有较大幅度的提高，其中的最大不可逆应变极限εirr约为0．32％，最大屈服强度σ0.2约为85MPa。多芯样品的最大不可逆应变极限εirr约为1．1％，最大屈服强度σ0.2约为160MPa。实验证明添加合金丝提高了纯银包套多芯带材的不可逆应变极限εirr，并减弱了临界电流的退化速度。但对合金包套的带材影响不大，这时合金包套对于带材的力学性能起主要作用。     

厚向异性板应力应变强度表述方法讨论

从希尔 (Hill)正交各向异性体二次屈服函数出发 ,可以导出厚向异性板应力强度 (等效应力 )与应变强度 (等效应变 )的两组表达式 ;本文讨论了采用两组不同表述方法的选择 ,并利用单向拉伸与双向等拉两种实验作了可比性的分析比较     

Effect of temperature on mechanical behavior of AZ31 magnesium alloy

Strain rate sensitivity and tension/compression asymmetry of AZ31 magnesium alloy at different temperatures and strainrates were investigated.Both of mechanical behaviors are temperature dependent.Strain rate sensitivity increases with increasingtemperature.Thermally activated slip is the source of strain rate sensitivity.At the temperature below or near 373 K,strain ratesensitivity is very little.Tension/compression asymmetry in yielding decreases with increasing temperature.Twinning is the reasonof tension/compression asymmetry.At the temperature above or near 573 K,the material shows little tension/compressionasymmetry of the flow stress.     

DD3单晶镍基合金蠕变—疲劳及寿命预测

从应变范围区分法(SRP),应变能区分法(SEP)的有关概念出发,研究DD3单晶镍基合金拉—拉应力状态下的蠕变—疲劳性能和保持时间的影响,并对其进行了定量计算;同时,用应变能区分法的数值法(SEP—NCM)实现对拉—拉应力状态下蠕变—疲劳的寿命预测。     

STRAIN INDUCED STRUCTURAL TRANSITION OF INTERFACES AND TWINS IN A HOT－DEFORMED DUAL－PHASE TIAL ALLOY

ＳＴＲＡＩＮＩＮＤＵＣＥＤＳＴＲＵＣＴＵＲＡＬＴＲＡＮＳＩＴＩＯＮＯＦＩＮＴＥＲＦＡＣＥＳＡＮＤＴＷＩＮＳＩＮＡＨＯＴ－ＤＥＦＯＲＭＥＤＤＵＡＬ－ＰＨＡＳＥＴＩＡＬＡＬＬＯＹＣＨＥＮＧｕｏＦｉａｎｇ；ＷＡＮＧＪｉｎｇｕｏ；ＺＨＡＮＧＬｉｃｈｕｎａｎｄ...     

多通管塑挤胀形工艺的力学分析

讨论了以聚氨酯橡胶棒为胀形介质，采用塑挤胀形复合工艺把无缝管坯一次成形为多通管成品的加工方法，分析了多通管塑挤胀形过程，提出了“应变样条”分析法，进而分析了典型剖面上应力应变状态，讨论了成形力间应具备的合理的数值关系，以使变形区处于最有利于变形的超高的静水压力和合适的偏应力状态，获得尽可能长的支管。     

Effects of temperature and blank holding force on biaxial forming behavior of aluminum sheet alloys

Biaxial forming behavior is investigated for three aluminum sheet alloys (Al 5182 containing 1% Mn (5182+Mn), Al 5754, and 6111-T4) using a heated die and punch in the warm forming temperature range of 200–350 °C. It is found that, while all three alloys exhibit significant improvement in their formability compared with that at room temperature, the non-heat-treatable alloys 5182 + Mn and 5754 give higher part depths than that of heat-treatable 6111-T4. The formability generally increases with decreasing BHP (BHP), but increasing the forming temperature and/or BHP minimizes the wrinkling tendency and improves the forming performance. The stretchability of the sheet alloys increase with increasing temperature and increasing BHP. For the alloys and forming conditions involved in the current study, the formability, measured in terms of part depth, comes mainly from the drawing of metal into the die cavity, although stretching effects do influence the overall forming behavior. The optimum formability is achieved by setting the die temperature 50 °C higher than the punch temperature to enhance the drawing component. Setting the die temperature higher than the punch temperature also improves the strain distribution in a part in such a manner that postpones necking and fracture by altering the location of greatest thinning.