6181H18铝合金同步冷却热成形工艺研究

利用Gleeble3500热/力模拟试验机模拟6181H18铝合金同步冷却热成形工艺,采用正交试验研究工艺参数——变形温度T、保温时间t、冷却速度v对成形性的影响,同时对其微观组织进行了研究。结果表明:同步冷却热成形工艺使6181H18铝合金的成形性能得到明显改善,同时使其成形时效后得到很高的强度,达到了变形和强化同步实现的目的,此工艺可以应用于该铝合金。工艺参数合适的组合为:T=500℃,v=60℃/s,t=220s。成形后α基体中析出大量强化相,但较T4状态强化相略粗大,弥散均匀度略差。     

热处理对激光快速成形TC21钛合金组织和硬度的影响

采用激光快速成形技术制备出TC21钛合金块状坯料,研究了去应力退火及固溶时效热处理对成形件组织和硬度的影响。结果表明:去应力退火后,成形件组织和显微硬度基本无变化;固溶+时效热处理后,原沉积态明暗两区统一,硬度基本无差别,表明组织已均匀化。随着固溶温度的升高,网篮组织中的α片变宽,球状α相的数量增多,晶界α相发生粗化。当固溶温度为932℃时,成形件沉积态中粗大的柱状晶发生再结晶,转变为较细小的等轴晶。     

GJB 150/150A、GJB 4239和MIL-STD-810F/G的特性和相互关系分析

文章阐述了美国军用标准MIL-STD-810的演变过程及810系列标准各个阶段版本的性质特点,介绍了GJB 150与810C之间的关系,GJB 150A和GJB 4239与810F、810G之间的关系,以及GJB 150A与GJB 4239的关系,最后说明了GJB 4239、GJB 150A和810F/G标准存在的问题并提出了一些建议。     

Ti_2AlNb基合金电子束焊接头的显微组织

利用透射电子显微镜和能谱,研究电子束焊接过程中Ti_2AlNb基合金显微组织演变过程以及焊缝区组成、焊后热处理对接头显微组织的影响.结果表明:焊接过程中焊缝区Al元素损失较为严重,这有利于B_2相的形成而不利于O相的形成,使得接头焊缝区主要由B_2和α_2两相组成;在随后的热处理过程中,焊缝区的B_2相转变为β相和板条状的O相,使焊缝区由α_2、O和β相组成.     

TiAl合金粉床电子束选区熔化成形研究进展

粉床电子束选区熔化成形是增材制造脆性TiAl合金复杂构件的理想技术。从原料粉末、致密化、化学成分、微观组织、凝固及相变、后处理、力学性能、成形精度与表面粗糙度等几个方面综述了粉床电子束选区熔化成形TiAl合金的研究现状,对目前存在的问题及应对措施进行了评述,并对其未来研究方向进行了展望。     

The application of micro-CT in monitoring bone alterations in tail-suspended rats in vivo

Osteopenia is a pathological process that affects human skeletal health not only on earth but also in long-time spaceflight. Micro-computed tomography (micro-CT) is a nondestructive method for assessing both bone quantity and bone quality. To investigate the characteristics of micro-CT on evaluating the microgravity-induced osteopenia (e.g. early detection time and the sensitive parameters), the bone loss process of tail-suspended rats was monitored by micro-CT in this study. 8-Week-old female Sprague Dawley rats were divided into two groups: tail suspension (TS) and control (CON). Volumetric bone mineral density (vBMD) and microstructure of the femur and tibia were evaluated in vivo by micro-CT at 0, 7, 14, 22 days. Biomechanical properties of the femur and tibia were determined by three-point bending test. The ash weight of bone was also investigated. The results showed that (1) bone loss in the proximal tibia appeared earlier than in the distal femur. (2) On day 7, the percent bone volume (BV/TV) of the tibia 15.44% decreased significantly, and the trabecular separation (Tb.Sp) 30.29% increased significantly in TS group, both of which were detected earlier than other parameters. (3) Biomechanical properties (e.g. femur, −22.4% maximum load and −23.75% Young’s modulus vs. CON) and ash weight of the femur and tibia decreased significantly in the TS group in comparison to CON group. (4) vBMD of the femur and tibia were clearly related to bone ash and dry weight (r = 0.75–0.87, p < 0.05). (5) BV/TV of both femur and tibia were clearly related to maximum load and Young’s modulus (r = 0.66–0.87, p < 0.05). Similarly, trabecular vBMD and BV/TV of the femur and tibia were clearly related to Young’s modulus (r = 0.73–0.89, p < 0.05). These indicated that BV/TV and Tb.Sp were more sensitive than other parameters for evaluating bone loss induced by tail suspension, moreover, trabecular vBMD and other parameters might be used to evaluate bone strength. Therefore, micro-CT is a reliable and sensitive method for predicting unloading-induced bone loss in small animals.     

Hot deformation behavior and microstructure evolution of the laser solid formed TC4 titanium alloy

Hot compressive experiments of the laser solid formed (LSFed) TC4 titanium alloy were conducted at a wide temperature range of 650–950 °C and strain rate of 0.01–10 s⁻¹. The Arrhenius-type constitutive models of the LSFed TC4 alloy were established at the temperature range of 800–950 °C and of 650–800 °C, respectively. The average relative error between the predicted stresses and experimental values in those two temperature ranges are 10.4% and 8.3%, respectively, indicating that the prediction models constructed in this paper are in a good agreement with experimental data. Processing maps were established by the principle of dynamic materials modeling on the basis of the data achieved from the hot compression experiments. The processing parameters corresponding to the stable and unstable regions of material deformation can be determined from the processing maps. The microstructure evolution of the stable and unstable regions of the samples after tests were observed. Finally, the effect of hot compressive parameters on the microstructure were investigated to research the dynamic recrystallization and the texture of the deformed LSFed TC4 alloy.     

Li含量对Mg-6Y-3Zn-xLi合金微观组织和力学性能的影响

采用氩气保护真空熔炼的方法制备了铸态Mg-6Y-3Zn-xLi（x=0,5,8,11,wt%）合金,并对其进行了均匀化处理和热挤压变形。通过OM、SEM以及拉伸试验等手段研究了Li含量对合金微观组织与力学性能的影响。结果表明：随着Li含量的增加,铸态Mg-6Y-3Zn-xLi合金基体由α单相结构逐渐转变为（α+β）双相结构,晶粒尺寸和共晶化合物的形貌及分布规律也发生明显变化。均匀化处理后Mg-6Y-3Zn-xLi合金中形成的块状长周期有序（LPSO）结构相,随Li含量的增加其体积分数逐渐降低,（Mg,Zn）₂₄Y₅相数量则逐渐增多。Mg-6Y-3Zn-8Li合金进过均匀化处理和热挤压变形后表现出最优的综合力学性能,抗拉强度和延伸率分别达到278 MPa和11.6%,这主要是由于均匀分布的被破碎细化的块状LPSO相和大量细小动态再结晶的共同强化作用。     

多级环境下轴流压气机反方法改型设计

基于全三维黏性流场求解,对多级轴流压气机叶片反方法改型设计技术进行了研究。介绍了所采用的数值求解方法,之后阐述了压气机叶片反方法设计的基本原理和流程。为验证方法的有效性,对某型高压压气机后四级初始设计结果进行了数值模拟和反方法改型设计,基于对数值结果的分析提出了多级环境下叶片表面载荷分布调整的具体方法。反方法改型设计结果表明,通过合理调整多个叶片表面载荷分布,提升了四级压气机整体气动性能。设计点绝热效率基本保持不变,压比提高6.57%。      

Wetting behavior of AgCu-4.5Ti filler reinforced by carbon nanotubes on C/C composite

The effect of Carbon Nanotubes (CNTs) content on the wettability of AgCu-4.5Ti + x CNTs (wt%) composite filler alloys on C/C composite was investigated. The results show that the added CNTs reacted with element Ti in the filler and produced the dispersed fine in situ synthesized TiC particles, which increased the consumption of element Ti and provided the nucleus for the growth of Ti-Cu compounds simultaneously. The above effects of introducing CNTs, inhibited the formation of Ti-Cu compounds, also changed the distribution of compounds, which dramatically influenced the interfacial microstructure and characteristics of wetting behavior. The increase of CNTs content refined and dispersed coarse Ti-Cu compounds, decreased the initial spreading temperature, and improved the wettability, but high content of CNTs (more than 0.3wt%) decreased the wettability of the filler alloy. The wetting interfacial microstructure of corresponding composite filler alloys were analyzed by Scanning Electron Microscope (SEM), Energy Dispersive X-ray Spectrometer (EDS) and Transmission Electron Microscope (TEM), which consisted of TiC, TiCu, TiCu₂ and TiCu₄ compound. The typical wetting behavior of AgCu-4.5Ti + 0.3wt% CNTs composite filler on C/C composite was divided into four stages. The effect mechanism of CNTs content on the wetting behavior was proposed.