Al3Ti颗粒增强铝基复合材料的显微组织及力学性能

本文将K2TiF6盐引入Al-Si-Ni合金熔体中,利用熔体搅拌原位反应法制备了Al3Ti/Al-Si-Ni铝基复合材料,研究了Al3Ti含量对铸态复合材料显微组织和高温力学性能的影响。结果表明,铸态复合材料由α-Al相、共晶Si、Al3Ni相和 (Al, Si)3Ti相组成。随着Al3Ti引入量的增加,(Al, Si)3Ti数量也逐渐增多,其形貌由长棒状转变成块状,共晶硅和Al3Ni相逐渐细化,三者共同作用提高了复合材料的力学性能。

Al3Ti4B中间合金对Mg-7Al-0.4Zn-0.2Mn合金显微组织和性能的影响

研究了Al3Ti4B中间合金对 Mg 7Al 0.4Zn 0.2Mn合金的显微组织、力学性能及耐腐蚀性能的影响。结果表明: 当Al3Ti4B加入量小于0.3%(质量分数)时, 合金的平均晶粒尺寸显著减小; 当 Al3Ti4B加入量为0.3%时, 合金组织显著细化, 平均晶粒尺寸由未变质合金的 135μm细化到 30μm, 合金拉伸力学性能和耐腐蚀性能最好; 当加入量超过0.3%时, 晶粒粗化; 具有密排六方结构的高熔点化合物 TiB2 (θm =2 980 ℃)和 AlB2(θm=980℃)均可作为α Mg的异质核心, 大量异质结晶核心的存在是导致α Mg晶粒细化的主要原因。

激光熔覆Al3Ti金属间化合物涂层的腐蚀及耐磨性能研究

采用5 kW横流CO2激光器在AA6063铝合金表面激光熔覆Al3Ti金属间化合物涂层,研究了熔覆层的显微组织、电化学腐蚀和摩擦磨损性能。结果表明,熔覆层由树枝晶Al3Ti和枝晶间α-Al两相组成,并与基材形成良好的冶金结合。熔覆层在w(NaCl)=3.5%溶液中发生钝化,腐蚀电流密度约为基材的1/10;在载荷10 N、摩擦距离800 m时,熔覆层的磨损质量损失低于基材的1/2,说明Al3Ti金属间化合物涂层显著提高了基材的耐腐蚀和耐磨损性能。

AA6063铝合金表面激光熔覆Al3Ti涂层

将Al和Ti粉末按照摩尔比为3∶1预涂在AA6063铝合金表面进行激光熔覆处理。试验结果表明,采用合适的激光功率和扫描速度可获得无裂纹、无孔洞且表面平整的涂层。涂层由枝晶状Al3Ti和枝晶间纯Al组成,Al3Ti枝晶靠近试样表面一侧细小、而靠近基材一侧粗大,涂层和基材之间形成了良好的冶金结合。涂层的硬度(HV)可达500,显著改善了铝合金的表面性能。

原位自生Al3Tip/Al复合材料的制备及其拉伸性能

采用直接反应法制备不同Al3Ti含量的Al3Tip/Al原位自生复合材料;分别在室温和高温下测试复合材料的拉伸性能,对比研究了Al3Ti含量和温度对复合材料拉伸性能的影响。结果表明:Al3Ti含量增大,则其抗拉强度和伸长率均明显降低;高温下复合材料的抗拉强度比室温时降低,伸长率反而有所增大。针对此现象,对Al3Tip/Al原位自生复合材料的拉伸断裂机理进行了讨论。

熔渗反应合成铝基表面Al3Ti/Al复合涂层

采用Al-Ti体系,通过熔渗结合原位反应法制备出Al基表面Al3Ti/Al复合涂层,研究了涂层的微观结构、相组成、过渡层形貌及显微硬度分布。结果表明:熔渗温度由700℃增加至800℃,涂层中Al3Ti颗粒长大,分布更加均匀,形状由近球形转变为短棒状,同时有少量Al3Ti相扩散至Al基体内部形成粗针状形貌。不同熔渗温度下,Al3Ti/Al复合涂层和Al基体在界面处均形成良好的冶金结合。Al∶Ti摩尔比为5∶1时,涂层中Al3Ti颗粒数量较多,团聚现象严重,涂层致密度较低;随着Al∶Ti摩尔比增加到7∶1,Al3Ti颗粒数量减少,尺寸减小至5~8μm,分布更加均匀,涂层致密度显著增加。不同成分复合涂层硬度均显著高于基体,并随Al3Ti含量增加而升高,最高可达180HV,为Al基体硬度的3.9倍。

Refining Effect of a New Al3Ti1B1RE Master Alloy on Al Sheets Used for Can Manufacture and Behavior of Rare Earths in Master Alloy

The refining effect of Al3Ti1B1RE master alloy on Al sheets used for pressure can manufacture and the behavior of mixed rare earths in master alloy were investigated with XRD, OM, SEM and EDAX. It is found that the refining effect of the refiner on the material has superiority over foreign or domestic Al5Ti1B refiner, and the refiner still retains its refining ability for 6 h after adding it to molten Al, thus improving the strength and plasticity of the material remarkably. The excellent refining effect and stability of AlTiBRE refiner result from that RE can lower the surface energy of molten Al and improve the wetting characteristics of molten Al on refinement nuclei such as TiAl 3, TiB 2, etc., thus giving full play to the effect of heterogeneous nucleation and impeding the congregating tendency of TiB 2 phase in molten Al. At the same time, RE gathering in front of solid/liquid interface are also easy to cause composition supercooling in molten Al, thus impeding the growth of α Al grains and promoting α Al nucleation on refinement nuclei. In addition, RE also play certain role in purification and grain refinement, or modification, especially their effect of purification can improve the metallurgical quality of AlTiBRE master alloy.

Microstructure and mechanical properties of a hot-extruded Al-based composite reinforced with core–shell-structured Ti/Al3Ti

An Al-based composite reinforced with core–shell-structured Ti/Al_3Ti was fabricated through a powder metallurgy route followed by hot extrusion and was found to exhibit promising mechanical properties. The ultimate tensile strength and elongation of the composite sintered at 620°C for 5 h and extruded at a mass ratio of 12.75:1 reached 304 MPa and 14%, respectively, and its compressive deformation reached 60%. The promising mechanical properties are due to the core–shell-structured reinforcement, which is mainly composed of Al_3Ti and Ti and is bonded strongly with the Al matrix, and to the reduced crack sensitivity of Al_3Ti. The refined grains after hot extrusion also contribute to the mechanical properties of this composite. The mechanical properties might be further improved through regulating the relative thickness of Al–Ti intermetallics and Ti metal layers by adjusting the sintering time and the subsequent extrusion process.

Ti/Al3Ti层状复合材料层间断裂性能研究

金属间化合物基层状复合材料Ti/Al_3Ti是采用Ti-6Al-4V箔和Al箔按照一定顺序叠加后,在真空环境下热压烧结成由韧性金属Ti和金属间化合物Al_3Ti组成的叠层结构。利用ENF(End-Notch-Flexure)和MMF(Mixed-Mode-Flexure)测试方法,对Ti/Al_3Ti层状复合材料的Ⅱ型及Ⅰ+Ⅱ型层间断裂能、层间断裂行为以及能量释放率等方面进行了研究。结果表明,Ti/Al_3Ti层间断裂时,裂纹在复合材料界面处发生起裂,而在传播过程中发生偏转,最终导致Al_3Ti层开裂。由此可见,在实验过程中裂纹的表现形式是在Ti/Al_3Ti界面及Al_3Ti层中共同扩展;Ⅰ+Ⅱ型层间起裂能量释放率G_(Ⅰ+Ⅱ)为46 J/m^2,Ⅱ型层间起裂能量释放率G_Ⅱ为1453 J/m^2,表明Ⅱ型层间断裂比Ⅰ+Ⅱ型层间断裂更困难。

Formation and wear behaviors of in-situ Al3Ti/Al composites using aluminum and titanium fibers under electromagnetic induction heating

Under various electromagnetic induction heating powers,different Al3Ti/Al composites were fabricated by in-situ synthesis method from aluminum and titanium fibers.Microstructures and particles distribution of the composites were examined by XRD,SEM and EDS.The results show that no other intermetallic compounds beside Al3Ti can be in-situ synthesized.Around the titanium fibers,the reaction zones and diffusion zones can be obviously found.Due to the stirring of the electromagnetic function,the formation of the micro-cracks inside the reaction zone was conducive to the peeling off of the Al3Ti particles,and ensures the continuous reaction between liquid aluminum and titanium fibers,as well as the diffusion of Al3Ti particles.At the same time,there were secondary splits of Al3Ti particles located in diffusion zones.Two-body abrasion test shows that with the increase of induction heating power,the wear rates of the composites reduced and the number of grooves decreased.

NiTi/（Al3Ti+Al3Ni）层状复合材料的热处理及力学性能

通过真空热压烧结工艺制备了NiTi/(Al3Ti+Al3Ni)层状复合材料,并分别在750、850和950℃条件下进行退火。利用XRD、SEM和EDS对材料的成分及组织进行了观察与分析。结果表明,热处理对NiTi/(Al3Ti+Al3Ni)层状复合材料结构没有影响,仍然保持热处理前的NiTi层、反应带和金属间化合物层(两相区)结构,但热处理改变了反应带的厚度,并促进了Al3Ni相的形成。Hopkinson压杆试验表明,垂直于叠层方向的抗压强度为1233 MPa,平行于叠层方向的抗压强度为1163 MPa;在垂直于叠层方向上,NiTi/(Al3Ti+Al3Ni)层状复合材料的硬度呈现周期性变化规律,反应带处达到最高值,其次是两相区,最后是NiTi层和中间带,热处理后试样的硬度仍保持这一规律,但硬度值有所降低。

AA6063铝合金表面激光熔覆TiC/Al3Ti复合材料涂层

将Al、Ti和TiC粉末预涂在AA6063铝合金表面,采用激光熔覆法制备了TiC/Al3Ti复合材料涂层,分析了激光熔覆层的显微组织和硬度分布。结果表明,采用合适的激光工艺可获得无裂纹和孔洞且表面平整的熔覆层。熔覆层由枝晶状Al3Ti、枝晶间α-Al和均匀分布的TiC颗粒组成,TiC颗粒在激光辐照过程中未发生熔解,熔覆层与基材的界面结合良好。随与熔覆层表面距离的增加,Al3Ti枝晶的尺寸变大,α-Al的含量减少。激光熔覆层的硬度可达700HV0.2,显著改善了AA6063铝合金的表面硬度。

单晶Al3Ti拉伸与剪切变形的分子动力学模拟

采用分子动力学方法研究单晶Al3Ti模型的拉伸和剪切力学性能。模拟Al3Ti在常温、恒定应变速率下的拉伸和剪切变形过程,讨论了温度和应变速率对体系拉伸和剪切性能的影响。结果表明,Al3Ti室温下很脆,弹性变形阶段结束后在短时间内体系产生的孔洞和位错迅速发展导致材料破坏。温度升高会导致Al3Ti的抗拉强度、杨氏模量、剪切强度和切变模量降低;应变速率增大能提高材料的拉伸和剪切强度,但不影响杨氏模量和切变模量大小。

Al3Ti/A356铝基复合材料的显微组织及拉伸力学性能

在A356铝合金熔体中加入K2TiF6盐,通过熔体搅拌原位反应法制备了Al3Ti/A356铝基复合材料,研究了Al3Ti含量对铝基复合材料显微组织及室温和高温拉伸力学性能的影响。结果表明,Al3Ti/A356复合材料的铸态组织由α-Al、共晶Si和(Al, Si)3Ti相组成。随着K2TiF6盐添加量的增加,(Al, Si)3Ti相也逐渐增多,其形状由大块状和棒状转变为小块状,同时,基体中的共晶Si细化效果也越显著。在生成不同Al3Ti含量的复合材料中,2wt%Al3Ti/A356复合材料的常温拉伸抗拉强度和屈服强度均为最高,分别为179.7 MPa和74.1 MPa。350℃高温拉伸时,6wt%Al3Ti/A356复合材料的抗拉强度和屈服强度分别比基体提高22.1%和12.6%,分别达到66.3 MPa和57.9 MPa,最高抗拉强度达到或超过了一些现役汽车活塞用的铝硅合金,表明Al3Ti/A356复合材料具有作为新型耐热铝合金应用于汽车发动机耐热部件的潜力。

热压复合制备Ti-Al_3Ti层状复合材料组织结构研究

采用热压复合工艺在不同工艺参数下制备了Ti-Al3Ti层状复合材料,利用SEM和EDS对材料的组织结构进行了观察,研究了热压复合工艺参数对Ti/Al扩散反应及反应层微观组织结构的影响规律.结果表明,在不同工艺参数下,Ti/Al叠层热压复合反应的初生相均为Al3Ti.600℃时Ti/Al叠层只发生少许反应,在界面处生成一薄层Al3Ti,650和700℃时,Al层完全反应,各层界面处结合状态良好,层间结合紧密.650℃时Al3Ti为唯一生成相,但700℃时,由于反应动力学的影响Al3Ti/Ti层之间有TiAl层生成,Ti-Al系金属间化合物的生成顺序为Al3Ti→TiAl.反应过程中液相的存在能够使Ti、Al持续紧密接触,加快反应速度,促进反应顺利进行.

原位合成Al_3Ti增强轻金属基复合材料的研究现状

综述了原位合成Al3Ti/Al和Al3Ti/Mg基复合材料的研究现状。重点介绍了原位合成Al3Ti的反应体系、复合材料的制备方法及微观组织特点,指出了原位合成Al3Ti/Al和Al3Ti/Mg基复合材料在目前研究中所存在的主要问题及今后的研究方向。

高能超声对原位合成Al_3Ti/6070复合材料凝固组织的影响及机制

以Al-K2TiF6为反应体系,采用熔体反应法,在高能超声场下原位合成Al3Ti/6070复合材料。采用XRD、SEM、EDS等手段研究不同超声参数如超声时间和超声强度对Al3Ti/6070复合材料增强体形貌及尺寸的影响。建立了超声作用下熔体中颗粒行为模型,并对其机制进行了探讨。结果表明:在一定的超声强度下(0.66kW/cm2),颗粒尺寸随超声作用时间的延长(1～7min)先减小后增大,当作用时间为3min时,颗粒最细小,尺寸为1～2μm,形貌主要为小块状或短棒状;当超声作用时间大于3min时,颗粒数量随时间增加而急剧减少;在相同的超声作用时间(3min)下,颗粒尺寸随超声强度的增加而减小,当超声强度为0.82kW/cm2时,颗粒尺寸为0.5～1μm,颗粒形貌主要为小块状或粒状,当超声功率大于0.82kW/cm2时,颗粒数量随超声功率增加而急剧减少。高能超声作用下Al3Ti/6070复合材料的最佳制备工艺为:超声强度0.66～0.82kW/cm2,超声作用时间3min。

原位反应法制备Al/Al_3Ti复合材料组织和性能

本研究采用一种新型的原位反应工艺，使ＴｉＯ２粉剂与纯铝熔体反应，生成Ａｌ３Ｔｉ颗粒，然后采用搅拌铸造法制备Ａｌ／Ａｌ３Ｔｉ复合材料。生成的Ａｌ３Ｔｉ颗粒尺寸细小，为２～３μｍ，而且分布均匀，与基体结合好。当ＴｉＯ２加入量为纯铝基体的３０ｗｔ％、反应温度为９２０℃时，复合材料的抗拉强度比纯铝基体提高７１．５％，硬度提高１３４％，而延伸率较纯铝稍有下降。