IN SITU PROCESSING OF Al_(2)O_(3) WHISKERS REINFORCED Ti-Al INTERMETALLIC COMPOSITES

In situ Al2O3 whiskers reinforced Ti-Al intermetallic composites were fabricated at ~1200℃ by reaction sintering of cold-consolidated fillets consisting mainly of Ti, Al, and different additives. The phases and microstructures of the sintered composites were characterized using X-ray diffraction (XRD) and scanning electron microscopy (SEM) coupled with energy dispersive spectroscopy (EDS). The process of synthesis was investigated using differential thermal analysis (DTA). The effects of processing parameters and additives on the microstructures of the composites and the development of whisker were examined. It is found that the morphology of the whisker is strongly influenced by the additives, the exothermal reaction process, and the processing parameters.

Mechanism of anti-arterial thrombosis of Dahuangzhecong Fang screened by Ti-Al intermetallic compound porous material

The mechanism of antithrombotic of Dahuangzhechong Fang separated and purified by Ti-Al intermetallic compound porous material (TAICPM) was researched. Dahuangzhechong Fang, which was isolated and screened by TAICPM, was used to oral rats. At the end of study, their blood and thrombus were collected. The results show that TAICPM with the pore size of 1-5 μm can screen Dahuangzhechong Fang well. Dahuangzhechong Fang can increase 6-keto-PGF1α, lower content of TXD2 and platelet. Dahuangzhechong Fang has good effect to resist arterial thrombosis.

Structure of the Intermetallic Compound Ni_3Al Synthesized under Compression of the Powder Mixture of Pure Elements Part Ⅰ: Phase Composition and Microstructure of Main Phase

It was shown by TEM and X-ray analysis that there are four types of grains of the main Ni3Al phase in the structure of the intermetallic obtained by the self-propagation high temperature method (SHS). Every type of grains has its own domain and dislocation structure. There are mono- and polydomains with and without dislocations. The grains of the main phase of monoand polydomains without dislocations and polydomains with dislocations were formed by diffusion in the solid phase. In these conditions NiAl3 phase is located on the grain boundary of the main phase. The Ni2Al3 phase is located at the triple joints of the main phase.

Intermetallic growth behavior during post deformation annealing in multilayer Ti/Al/Nb composite interfaces

The tri-metal Ti-Al-Nb composites were processed through three procedures:hot pressing,rolling,and hot pressing,followed by subsequent rolling.The fabricated composites were then subjected to annealing at 600,625,and 650℃ temperatures at different times.Microstructure observation at the interfaces reveals that the increase in plastic deformation strain significantly affects TiAl_(3) intermetallic layers’evolution and accelerates the layers’growth.On the contrary,the amount of applied strain does not significantly affect the evolution of the NbAl_(3) intermetallic layer thickness.It was also found that Al and Ti atoms’diffusion has occurred throughout the TiAl_(3) layer,but only Al atoms diffuse through the NbAl_(3) layer.The slow growth rate of the NbAl_(3) intermetallic layer is due to the lack of diffusion of Nb atoms and the high activation energy of Al atoms’reaction with Nb atoms.

Multilayered Ti-Al intermetallic sheets fabricated by cold rolling and annealing of titanium and aluminum foils

Multilayered Ti-Al based intermetallic sheets were fabricated by sintering alternately layered titanium and aluminum foils.The microstructure and phase formation of the obtained sheets under different sintering conditions were evaluated by various techniques.The results reveal that when the sintering temperature is above the melting point of aluminum,the self-propagating high-temperature synthesis reaction occurs between Ti and Al,and forms various phases of Ti-based solid solutions including α-Ti Ti3Al,TiAl,TiAl2 and α-Ti including TiAl3,etc.When the sintering time increased,Ti-based solid solution,TiAl2 and TiAl3 disappeared gradually,and the sheet containing Ti3Al and TiAl phases in a multilayered structure formed finally.A lot of voids were also observed in the sintered structures,which were caused by the melting Al,Kirkendall effect and the difference of molar volumes between reactants and products.The voids were eliminated and a dense sample was obtained by the following hot press.

Effect of Hot Processing Technology on Mechanical Properties and Structure of Interface of Ti/Steel Composite Sheet

研究了热加工工艺对钛-钢复合板界面力学性能和显微组织的影响。测试了在A，B，C，D4种温度下热轧复合板界面的力学性能，用金相显微镜及扫描电镜观察了界面显微组织并分析了界面的成分。结果表明，在A，B2种温度下轧制的钛-钢复合板界面机械性能良好，延伸率高，其剪切强度不但可保持坯料原有的水平，甚至还略有增加。在C，D2种温度下轧制的钛-钢复合板界面机械性能相对较低，延伸率较高，但剪切强度要比爆炸复合坯料低，尤其是D加热温度，轧制后界面剪切强度急剧下降。热轧的终轧温度也是影响钛-钢复合板界面结合性能的重要因素。在低于相转变温度的合适温区热轧，且终轧温度合适，获得的钛-钢复合板结合界面无爆炸波纹，没有污染，生产的脆性化合物极细小，组织类同于钛材完全退火的等轴组织。

Interfacial reactions between Sn-2.5Ag-2.0Ni solder and electroless Ni(P) deposited on SiC_p/Al composites

A novel Sn-2.5Ag-2.0Ni alloy was used for soldering SiCp/Al composites substrate deposited with electroless Ni(5%P) (mass fraction)and Ni(10%P)(mass fraction)layers.It is observed that variation of P contents in the electroless Ni(P)layer results in different types of microstructures of SnAgNi/Ni(P)solder joint.The morphology of Ni3Sn4 intermetallic compounds(IMCs)formed between the solder and Ni(10%P)layer is observed to be needle-like and this shape provides high speed diffusion channels for Ni to diffuse into solder that culminates in high growth rate of Ni3Sn4.The diffusion of Ni into solder furthermore results in the formation of Kirkendall voids at the interface of Ni(P)layer and SiCp/Al composites substrate.It is observed that solder reliability is degraded by the formation of Ni2SnP,P rich Ni layer and Kirkendall voids.The compact Ni3Sn4 IMC layer in Ni(5%P)solder joint prevents Ni element from diffusing into solder,resulting in a low growth rate of Ni3Sn4 layer.Meanwhile,the formation of Ni2SnP that significantly affects the reliability of solder joints is suppressed by the low P content Ni(5%P)layer.Thus,shear strength of Ni(5%P) solder joint is concluded to be higher than that of Ni(10%P)solder joint.Growth of Ni3Sn4 IMC layer and formation of crack are accounted to be the major sources of the failure of Ni(5%P)solder joint.

The Strengthening and Toughening Mechanism of Fe-Al/Al_2O_3 Composite Material

By means of different checks and measures, we obserced and analysed the microstructure of Fe-Al/ Al2O3 composite material, We found that not only intragranular nanostructure grains and rod-like crystals but also fine-grained structure of the composite material as well as the bridging of the Fe-Al intermetallics compound contribute to the material＇s strength and toughness, It is shoun that the strengthening and toughening of the Fe- Al/ Al2O3 composite is the joint effect of a multiplicute strengthening and tougheniug mechanism.

Effect of Mg Addition on the Structure and Properties of Al-4.5 Cu-3.4 Fe <i>In-Situ</i>Cast Composite

Ternary Al-4.5 (wt%) Cu-3.4 (wt%) Fe in-situ composite was prepared at 1100&#176;C by conventional casting method. However, this particular alloy contains larger needle-shaped intermetallics of Al3Fe phase. These exert adverse effect on the mechanical properties of the alloys. The larger shape and uneven orientation of the intermetallic were found to be responsible for the degradation of properties. The main purpose of this study was to modify the geometry of those needles by adding magnesium (Mg) as a fourth material. A series of alloys were prepared by adding 4, 6, 8, 10, wt% Mg in Al-4.5 (wt%) Cu-3.4 (wt%) Fe alloy. Microstructures were observed by optical microscopy. Mechanical properties like ultimate tensile strength, % elongation, % area reduction, hardness and wear test were determined. The study revealed that Mg transformed the needles of Al3Fe into globular shape which gave the alloys better mechanical properties.

Hypereutectic Al-Si Matrix Composites Prepared by In Situ Fe_(2)O_(3)/Al System

Al_(2)O_(3) particles reinforced hypereutectic Al-Si composites were prepared by in situ Fe_(2)O_(3)/Al reaction system.The thermodynamic analysis and microstructure evolution were investigated by differential scanning calorimetry,optical microscope,scanning electronic microscopy and transmission electron microscope.Results show that the reaction between Fe_(2)O_(3) and Al is spontaneous which can be separated into two steps at different temperatures.The in situ Al_(2)O_(3) particles in nano size distribute on the Al matrix accompanied with long needle-shapedβFe-rich intermetallic phase.With different content of Mn addition,βphase can be modified toα-Al15(Mn,Fe)3Si2 andδ-Al4(Fe,Mn)Si2.Both tensile strength and elongation results at room temperature and 300℃reveal that the optimal Fe-rich intermetallic phase is finer Chinese-script and polyhedralαphase with a Mn/Fe mass ratio 0.5 for the composites.Both in situ Al_(2)O_(3) particles andα-Fe phases contribute to the properties improvement of the composites。

Effects of slurry pack cementation temperature on microstructure and wear resistance of Ti-Al co-deposited coating on copper plated nickel layer

In order to improve the wear resistance properties of copper substrate, a layer of electroplated nickel was firstly deposited on copper substrate, subsequently these electroplated specimens were treated by slurry pack cementation process with a slurry pack cementation mixture composed of TiO2 as titanizing source, pure Al powder as aluminzing source and also a reducer for titanizing, an activator of NH4Cl and albumen （egg white） as cohesive agent. The Ti-Al coating was fabricated on the surface of electro-deposited nickel layer on copper matrix followed by the slurry pack cementation process. The effects of slurry pack cementation temperature on the microstructures and wear resistance of Ti-Al coating were studied. The results show that the microstructure of the coating changed from NiAl＋Ni3（Ti,Al） to NiAl ＋Ni3（Ti,Al）＋Ni4Ti3 to Ni4Ti3＋NiAl, and to NiAl＋Ni3（Ti,Al）＋NiTi with slurry pack cementation temperature ranging from 800 ℃ to 950 ℃ in 12 h. The friction coefficient of Ti-Al coating decreased and the hardness increased with increasing the slurry pack cementation temperature. The minimum friction coefficient was 1/3 and the minimum hardness was 5 times larger than that of pure copper.

Ti-Al/TiC陶瓷基复合材料烧结过程的研究

用DTA方法分析了Ti AI/TiC陶瓷基复合材料的烧结过程 ,测定了材料的力学性能 ,分析了不同的烧结制度对材料性能的影响。实验结果表明 :温度升高至 5 0 0℃以上时 ,Ti与Al发生反应Ti+3Al→Al3Ti,Al3Ti+2Ti→ 3TiAl,TiAl+2Ti→Ti3Al,依次生成Al3Ti,TiAl和Ti3Al,这一过程为放热过程。继续升温至 90 0℃以上时 ,体系出现吸热现象。分析认为 ,在最高温度 16 0 0℃ ,压力 30MPa烧结时得到的材料室温力学性能优于在最高温度15 2 0℃ ,压力 17 3MPa烧结时得到的材料的室温力学性能。

Ti-Al系金属间化合物基复合材料的发展

介绍了Ti-Al系金属间化合物基复合材料的研究现状和发展趋势。对近10年来有关Ti-Al系金属间化合物基复合材料制造工艺、界面特性和机械性能研究状况进行了系统的综述。

激光熔覆Ti-Al金属间化合物复合涂层的显微组织和性能

以Ti和Al在高温下的化学反应热力学条件为依据,利用激光熔覆技术在ZL117铝活塞零件表面制备金属间化合物TiAl_3增强的Al基复合涂层。借助XRD、EDS和XPS分析涂层的物相组成和结构特征,通过OM和SEM观察涂层的表面宏观形貌及其内部显微组织,运用马弗炉测试了熔覆涂层在静态空气中的高温抗氧化性能。结果表明,复合涂层主要由浅灰色网状组织TiAl_3、暗灰色网状间隙相α(Al)和少量晶须状Si组成。复合涂层中Ti以TiAl_3形式存在,在TiAl_3中结合能分别为460.53 eV(Ti2p1峰)和454.96 eV(Ti2p3峰);Al则以TiAl_3、Al_2O_3和Al的形式存在,3种物相中Al的结合能分别为73.60、75.82和72.90 eV。600℃恒温80 h下的氧化动力学曲线显示,相同氧化条件下,涂层氧化增质较为平缓,氧化速率小,具有较好的相对高温抗氧化性能,相对高温抗氧化值最大为2.64。熔覆涂层表面氧化产物为Al_2O_3和TiO_2,铝合金基体表面氧化产物为Al_2O_3和少量SiO_2。

热处理条件下激光原位合成高铌Ti-Al金属间化合物复合涂层的微结构特征

为了提高钛合金的高温抗氧化性能,推动钛合金在高温和复杂工况环境下的进一步工程应用,利用高能激光束作用下Ti、Al、Nb三种元素混合粉末之间的原位反应在BT3-1钛合金表面制备了高温抗氧化的高铌Ti-Al金属间化合物复合涂层。针对原位反应所制备涂层存在的缺陷,通过自行设计的热处理工艺优化了涂层和界面微观组织。借助光学显微镜(OM)、X射线衍射仪(XRD)、扫描电镜(SEM)分析了热处理前后复合涂层的物相结构及显微形貌。结果表明:热处理前的涂层主要由单质Nb、金属间化合物γ-TiAl、α_2-Ti_3Al、Ti_3Al_2等物相组成;热处理后的复合涂层,单质Nb固溶到γ-TiAl和α_2-Ti_3Al中,同时形成了新相Ti_3AlNb_(0.3),涂层近似为γ-TiAl+α_2-Ti_3Al双相层片状等轴晶组织。此外,涂层中并未观察到减弱抗氧化性的单质Nb颗粒和Ti_3Al_2相,Ti、Al、Nb的宏观偏析得以消除,涂层与基材界面位置的气孔和裂纹均以消失,出现了明显的白亮带冶金结合过渡层,涂层组织也更加均匀致密。热处理对提高钛合金表面Nb的合金化程度和改善Ti-Al金属间化合物的高温抗氧化性能起到了显著的促进作用。

浸渗-反应合成C_f/Ti-Al复合材料的反应机理

以Ti粉、纯Al和碳纤维为原料,采用浸渗-反应合成法研制了Cf/Ti-Al复合材料,根据DSC测试结果确定反应合成温度。结果表明:在后期加热过程中,随着反应温度的升高,TiAl3的含量先增多后减少,碳纤维与Al的界面反应逐渐增强,Al4C3和TiC逐渐增多,在高温阶段,氧参与反应,复合材料中有Al2O3生成。通过SEM和XRD测试分析了复合材料内部的显微组织及相组成,同时探讨了Cf/Ti-Al复合材料中各物相形成过程的反应机理。

Ti6Al4V合金表面激光熔覆原位合成TiN/Ti-Al-Nb基复合涂层

目的为探究Ti6Al4V钛合金表面TiN/Ti-Al-Nb基复合涂层的激光熔覆制备新工艺,研究Nb含量对TiN/Ti-Al-Nb基复合涂层微结构及显微硬度的影响规律。方法以Nb原子数分数分别为10%、15%和25%的Ti+Nb+AlN混合粉末为原材料,采用基于挤压预置粉末法的激光熔覆原位合成技术,制备出TiN/Ti-Al-Nb基复合涂层。通过X射线衍射仪(XRD)物相定性分析,并结合扫描电子显微镜(SEM)和能量分散谱仪(EDS),对TiN/Ti-Al-Nb基复合涂层中的物相进行定性分析,结合二元平衡相图,进一步分析激光原位化学反应机理。借助显微硬度计,研究TiN/Ti-Al-Nb基复合涂层微结构对截面显微硬度分布的影响规律。结果在高能密度激光束作用下,混合粉末中Ti和AlN发生了充分的激光原位化学反应,生成了TiN陶瓷增强相,TiN陶瓷增强相的含量与Ti粉和AlN粉末的含量正相关。Nb含量的增加显著影响了Ti-Al-Nb基体相的种类,而不改变增强相的种类,随着Nb含量的增加,含Nb基体相的种类增多,发生Ti3Al→Ti3AlNb→Ti2AlNb→Ti39Nb→Nb7Al的转变。随着TiN增强相含量减少,复合涂层截面平均显微硬度从993.2HV0.5降至701.4HV0.5。结论Nb含量的增加,不会改变TiN/Ti-Al-Nb基复合涂层增强相的种类,但可以降低TiN增强相的含量,从而降低复合涂层截面平均显微硬度。

Ti-Al-C系复合材料的微观组织演变(英文)

以Ti粉、纯Al和碳纤维为原料,采用浸渗-反应合成法制备出Ti-Al-C系复合材料。首先将Ti粉和碳纤维制成预制件,再将熔融的纯Al压入预制件,制备出铸态的复合材料。随后将铸态的复合材料分别在600至1260℃间进行原位反应,保温时间为1h。通过SEM和EDX分析了复合材料的显微组织和产物的元素成分,同时,采用XRD分析复合材料的相组成。结果表明,在较低温下,TiAl3和Al4C3首先生成;随着温度的进一步升高,TiAl3分解,TiC析出;在高温下,氧化现象发生,有Al2O3生成。Ti-Al-C系复合材料在原位反应过程中遵循生成-分解-析出-氧化机制。

Ti-Al金属间化合物/陶瓷复合材料的制备技术及其研究现状和发展趋势

Ti-Al金属间化合物/陶瓷基复合材料是近年来发展起来的一种新型复合材料,其发展与Ti-Al金属间化合物和高技术陶瓷的发展密切相关。Ti-Al金属间化合物材料具有优秀的性能,利用Ti-Al金属间化合物的性能介于金属和陶瓷之间的特点,可以将Ti-Al金属间化合物与陶瓷材料相复合制备Ti-Al金属间化合物/陶瓷基复合材料,能使Ti-Al金属间化合物/陶瓷基复合材料具有很多优异的性能。本文主要介绍Ti-Al金属间化合物/陶瓷基复合材料的制备工艺和力学性能以及研究进展,研究和开发的Ti-Al金属间化合物/陶瓷基复合材料主要包括Ti-Al/Al2O3和Ti-Al/TiC复合材料,Ti-Al/ZrO2复合材料,Ti-Al/TiB2复合材料。本文对Ti-Al金属间化合物/陶瓷基复合材料未来的发展趋势进行分析和预测。

TiB_2粒子增强Ti-Al基复合材料的合成机理

采用Ti、Al和B元素粉末,经燃烧反应合成了TiB_2粒子增强的Ti Al金属间化合物基复合材料,并用DSC、EMPA和XRD等方法研究了其合成机理。结果发现,Ti和Al粉末间的放热反应促进了 TiB_2粒子的形成,所形成的 TiB_2粒子的尺寸约为2μm。将所得复合材料重熔后,TiB_2粒子的尺寸、相对含量和形貌没有明显变化,并且其显微组织比铸态Ti Al基合金组织明显细化。