大块非晶合金的性能、制备及应用

综述了大块非晶合金的性能、制备方法及应用，对比了吸铸法制备的棒状Zr41.2Ti13.8Cu12.5Ni10Be22.5,Zr57Cu20Al10Ni8Ti5,Zr52.5Ti5Cu17.9Ni14.6Al10(原子分数)大块非晶样品的过冷温度区间宽度(△Tx)，给出了3种大块非晶合金系列的热稳定性参数Tg、Tx及△Tx，提出了大块非晶合金领域存在的问题及发展方向．     

LD钢超塑性压缩变形参数与金相组织

通过对ＬＤ（７Ｃｒ７Ｍｏ３Ｖ２Ｓｉ）模具钢起塑性压缩变形后的金相组织观察研究，分析了变形参数、原始组织对变形后金相组织的影响。     

大塑性变形制备纳米结构金属

细化晶粒是改善材料性能的有效手段，传统的压力加工技术(如轧制、挤压、拉拔和锻造等)可以细化晶粒(微米量级)。纳米结构金属由于具有很小的晶粒尺寸(20-500nm)和独特的缺陷结构，从而表现出优异的物理—力学性能。大塑性变形(SPD)具有将铸态粗晶金属的晶粒细化到纳米量级的巨大潜力，近年来已引起人们的极大关注。介绍了4种大塑性变形制备纳米结构金属的方法、原理、变形特点及应用，分析了纳米结构金属的强度和超塑性变形特征，以及当前研究中存在的主要问题，并对大塑性变形技术的应用前景进行了展望。     

Superplastic behaviour of Ti-48at.%Al two-phase titanium aluminide compacts made from mechanically alloyed powder

An HIP compact of MA-processed powder having a nominal composition of Ti-48at.% Al was produced. The compact consisted of a large amount of TiAl(λ) and a small amount of Ti₃Al (₂), in a completely ultra-fine equiaxed grain structure. This two-phase compact showed typical superplastic deformation behaviour. A maximum elongation of 550% was obtained. A strain exponent, n = 2, and grain size exponent, p = 2, were determined from the results of a strain-rate-change test and a creep test at constant initial stress using samples having various grain sizes, respectively. The activation energy for creep, Q_c at constant stress was calculated to be 350 kJ/mole. It is concluded that the superplastic deformation mechanism of the material under study is grain boundary sliding controlled by lattice diffusion in the TiAl phase.     

Stored energy analysis of Zn—5Al eutectic alloy in superplastic deformation

The stored energy and the energy release during SPD(superplastic deformation)of a Zn-5Al alloy were studied.The alloy after rolling process gains more stored energy,and the as-rolled speciment can obtain maximum elongation and minimum flow stress without hot loding treatment before SPD.Experimental results show that stroed energy release process is along with SPD process and is also an impetus to SPD.The as -rolled Zn-5Al alloy has 48J/mol stored energy which was measured with DSC(differential scanning calorimeter)and conforms well to the calcuated value.The as-rolled Zn-5Al alloy after SPD with an elongation of 2500% releases 112J/mol stored energy,Analysis shows that the strain rate is in direct ratio to the rate of stred energy release.     

超塑20钢的空洞与断裂行为

本文在获取２０钢超塑性的基础上，对其空洞与断裂行为进行了研究，通过观察空洞的产生和测定空洞的长大，提出了一种超塑材料空洞的形核模型。研究确认，超塑２０钢的断裂由沿晶和穿晶两种断裂类型组成。     

激光超塑性成型技术研究

本文探讨了激光超塑成型技术中所涉及的合金板材制备、光能耦合及成型工艺，给出了标样拉伸实验和实际工件成型的结果，并对金相组织进行了分析．     

Effect of equal channel angular extrusion on the microstructure and superplasticity of an Al-Li alloy

This research investigates the use of equal channel angular extrusion (ECAE) processing to produce a superplastic form of the aluminum alloy 2098. The starting material was a hot-rolled and precipitation-hardened plate with elongated grains of width 67–92 μm, and a composition in weight percent of 2.2% Li, 1.3% Cu, 0.73% Mg, 0.05% Zr, balance Al. Microstructural evolution was investigated with optical and transmission electron microscopy (TEM) and microhardness measurements after each step of a multipass ECAE process. ECAE produced a submicron grain structure with an average size of about 0.5 μm. The sub-grain microstructure size was a function of the magnitude of the input strain and the extrusion temperature. Misorientation angles of the developed submicron structure increase with increasing number of passes at warm working temperatures. Superplastic behavior of the ECAE-processed alloy was achieved. However, the low zirconium content of the 2098 alloy resulted in grain growth of the refined structure at the superplastic processing temperatures, placing a lower limit on the deformation rates that can be used.     

轴承钢GCr15的恒温相变超塑性

研究了ＧＣｒ１５钢在Ａｃ１相变点附近的恒温超塑性特性与变形温度的关系。结果表明，与一些材料一样，该钢也存在恒温相变超塑性现象。当初始应变速率为２．５×１０＾－４ｓ＾－１时，经预调质处理的ＧＣｒ１５钢试样，在７４８℃进行超塑性拉伸试验获得最大延伸率达８００％，流动应力为２４ＭＰａ。与已有的同类研究结果相比，其延伸率提高了２００％以上。     

镁合金及其复合材料超塑性的研究现状

以等通道角挤压和粉末冶金等方法为例，讨论了镁合金晶粒细化的处理工艺。在室温下晶粒细化可使镁合金同时具有较高的强度和韧性，而在较高的应变速率或较低的温度下，晶粒细化的镁合金具有一定的超塑性，这说明晶粒细化对改善镁合金的力学性能十分重要。镁合金超塑性变形的主要机制仍然是晶界滑移，但晶界滑移总会在晶界三叉区或材料增强相与基体的相界处产生应力集中，使晶界滑移受到阻碍，这就需要有另外的协调机制来协调晶界进一步滑移。镁合金在超塑性变形过程中更容易发生动态再结晶使晶粒细化，使晶界滑移能够继续进行。镁基复合材料中增强体颗粒很细小且弥散分布，稳定了镁合金在高温下的组织，颗粒与晶粒界面可以充当原子扩散通道，很好地协调了晶界滑移。