Effects of current density on microstructure and properties of plasma electrolytic oxidation ceramic coatings formed on 6063 aluminum alloy

Plasma electrolytic oxidation (PEO) ceramic coatings were fabricated in a silicate-based electrolyte with the addition of potassium fluorozirconate (K2ZrF6) on 6063 aluminum alloy, and the effects of current density on microstructure and properties of the PEO coatings were studied. It was found that pore density of the coatings decreased with increasing the current density. The tribological and hardness tests suggested that the ceramic coating produced under the current density of 15 A/dm2showed the best mechanical property, which matched well with the phase analysis. Electrochemical impedance spectroscopy (EIS) and potentiodynamic polarization curves proved that the coating obtained under 15 A/dm2 displayed the best anti-corrosion property, which was directly connected with morphologies of coatings.

MICROSTRUCTURE AND COMPOSITION OF THE ELECTROLYTIC ETCHED PATTERN GRAINING SURFACE OF Al-Mg-Si ALLOY

After electrolytically etched pattern graining surface of aluminum alloy, it is shows that there are porous oxide film containing α Al 2O 3 and α Al 2O 3 by means of SEM XRD and XPS analysis. In the ditches, anodic oxidation makes pore density and diameter larger than other areas, and causes more coloring metal depositing and mutual cross linking. The electrolytically etched pattern surface shows relative deeper color on the ditches and lighter color on other areas, so it can be used for decoration. Electrolytic coloring metal exists in forms of Ag colloid and Ag 2O. Both anodic oxidation and electrolytic coloring affect the surface microstructure of aluminum alloy.

Review of recent trends in friction stir welding process of aluminum alloys and aluminum metal matrix composites

Welding is a vital component of several industries such as automotive,aerospace,robotics,and construction.Without welding,these industries utilize aluminum alloys for the manufacturing of many components or systems.However,fusion welding of aluminum alloys is challenging due to several factors,including the presence of non-heat-treatable alloys,porosity,solidification,and liquation of cracks.Many manufacturers adopt conventional in-air friction stir welding(FSW)to weld metallic alloys and dissimilar materials.Many researchers reported the drawbacks of this traditional in-air FSW technique in welding metallic and polymeric materials in general and aluminum alloys and aluminum matrix composites in specific.A number of FSW techniques were developed recently,such as underwater friction stir welding(UFSW),vibrational friction-stir welding(VFSW),and others,for welding of aluminum alloy joints to overcome the issues of welding using conventional FSW.Therefore,the main objective of this review is to summarize the recent trends in FSW process of aluminum alloys and aluminum metal matrix composites(Al MMCs).Also,it discusses the effect of welding parameters of the traditional and state-of-the-art developed FSW techniques on the welding quality and strength of aluminum alloys and Al MMCs.Comparison among the techniques and advantages and limitations of each are considered.The review suggests that VFSW is a viable option for welding aluminum joints due to its energy efficiency,economic cost,and versatile modifications that can be employed based on the application.This review also illustrated that significantly less attention has been paid to FSW of Al-MMCs and considerable attention is demanded to produce qualified joint.

Influence of addition of Gr_p/Al_2O_(3p )with SiC_p on wear properties of aluminum alloy 6061-T6 hybrid composites via friction stir processing

Aluminum alloy base surface hybrid composites were fabricated by incorporating with mixture of （SiC＋Gr） and （SiC＋Al2O3） particles of 20 μm in average size on an aluminum alloy 6061-T6 plate using friction stir processing （FSP）. Microstructures of both the surface hybrid composites revealed that SiC, Gr and Al2O3 are uniformly dispersed in the nugget zone （NZ）. It was observed that the addition of Gr particles rather than Al2O3 particles with SiC particles, decreases the microhardness but immensely increases the dry sliding wear resistance of aluminum alloy 6061-T6 surface hybrid composite. The observed microhardness and wear properties are correlated with microstructures and worn micrographs.

Electron beam welding of SiCp/2024 and 2219 aluminum alloy

SiCp/2024 matrix composites reinforced with SiC particles and 2219 aluminum alloy were joined via centered electron beam welding and deflection beam welding,respectively,and the microstructures and mechanical properties of these joints were investigated.The results revealed that SiC particle segregation was more likely during centered electron beam welding(than during deflection beam welding),and strong interface reactions led to the formation of many Al4C3 brittle intermetallic compounds.Moreover,the tensile strength of the joints was 104 MPa.The interface reaction was restrained via deflection electron beam welding,and only a few Al4C3 intermetallic compounds formed at the top of the joint and heat affected zone of SiCp/Al.Quasi-cleavage fracture occurred at the interface reaction layer of the base metal.Both methods yielded a hardness transition zone near the SiCp/2024 fusion zone,and the brittle intermetallic Al4C3compounds formed in this zone resulted in high hardness.

Effect of electromagnetic and ultrasonic cast rolling on microstructure and properties of 1050 aluminum substrate for presensitized plate

The 1050 aluminum alloy strip was prepared by means of electromagnetic and ultrasonic cast rolling on the modified asymmetric twin roll caster, and then the aluminum substrate for presensitized plate was prepared through cold rolling and annealing.The effects of electromagnetic and ultrasonic cast rolling on microstructure, mechanical properties, surface roughness and electrolytic corrosion properties of 1050 aluminum substrate were studied. The results show that electromagnetic and ultrasonic cast rolling can decrease the average crystallite size of aluminum substrate by 5 μm, increase the crystal boundaries with uniform distribution, and make the second-phase particles with smaller size distributed dispersively in the substrate, meanwhile, it can increase the tensile strength, elongation and micro-hardness by 4.58%, 9.85% and HV 2, respectively, reduce the surface roughness, make the surface appearance more even, electrolytic corrosion polarization curve of aluminum substrate more smooth and the surface corrosion pits with regular shape more dispersive.

Production and characterization of rich husk ash particulate reinforced AA6061 aluminum alloy composites by compocasting

Rice husk ash(RHA) is a potential particulate reinforcement to produce aluminum matrix composites(AMCs)economically.Compocasting method was applied to produce aluminum alloy AA6061 reinforced with various amounts(0,2%,4%,6%and 8%,mass fraction) of RHA particles.The prepared composites were characterized using X-ray diffraction and scanning electron microscopy.X-ray diffraction patterns of AA6061/RHA AMCs revealed the presence of RHA particles without the formation of any other intermetallic compounds.The scanning electron micrographs showed a homogeneous distribution of RHA particles all over the aluminum matrix.Intragranular distribution of RHA particles was observed.Further,RHA particles were bonded well with the aluminum matrix and a clear interface existed.The reinforcement of RHA particles enhanced the microhardness and ultimate tensile strength(UTS) of the AMCs.The tensile behavior is correlated to the microstructure of the AMCs.

Effect of alumina short fiber and air-cooling processing on solidification microstructure and tensile properties of Al_2O_3/Al-15Si composites

The effect of microstructure variation by addition of alumina short fiber and optimization of tensile properties by air cooling processing in Al 2O 3/Al 15Si composites were studied. The results show that in Al 15Si alloy matrix composites with 14% and 30%(volume fraction) fiber, the primary silicon is hardly refined, but the eutectic silicon is effectively refined and granulated. Granulation of some eutectic silicon mainly happens in fiber segregation areas. Refining and granulation of the eutectic silicon are related to the physical constraint arising from the fiber. After the 30%Al 2O 3/Al 15Si composite was remelted and air cooled, the number of the eutectic silicon on the surface of the fiber increases, which results in the improvement of fiber/matrix interface and tensile properties for the as cast composite. Air cooling processing may be reliable for the optimization of the microstructure and properties of fiber reinforced hypereutectic Al 15Si alloy composites.

Enhanced mechanical properties of 6082 aluminum alloy via SiC addition combined with squeeze casting

In order to improve mechanical properties of 6082 aluminum alloy,the SiC_(p)/Al 6082 composites were prepared by the addition of the micron-sized SiC_(p)articles combined with the squeeze casting.The effects of the SiC_(p)content and squeeze casting on the microstructure and mechanical properties of the 6082 aluminum alloy were investigated by SEM,EDS,TEM,tensile testing and hardness testing analysis methods.Research results exhibited that the SiC_(p)content and squeeze casting had a significant impact on the microstructure and mechanical properties of the 6082 aluminum alloy.The addition of the SiC_(p)refined the grain size of the 6082 aluminum alloy while caused the increase of the porosity with increasing the SiC_(p)content,especially in the permanent mold casting condition.Compared to the permanent mold casting,the squeeze casting obviously reduced pore defects,refined grain size and made the SiC_(p)distribute evenly as well as bond tightly with the Al matrix.The tensile strength,yield strength,elongation,elastic modulus and hardness of the 6082 aluminum alloy obtained with the SiC_(p)and squeeze casting were remarkably improved,and the optimal mechanical properties were obtained with a 2 wt.%SiC_(p),and they increased 10.73%,72.7%,193.9%,23.5%and 25.2%,respectively,compared to those of the6082 aluminum alloy obtained without SiC_(p)and squeeze casting.The fracture surface of the SiC_(p)/Al 6082 composites obtained with the squeeze casting was dense and exhibited a ductile fracture mode.

Microstructure of Ni–Al powder and Ni–Al composite coatings prepared by twin-wire arc spraying

Ni–Al powder and Ni–Al composite coatings were fabricated by twin-wire arc spraying（TWAS）. The microstructures of Ni-5wt%Al powder and Ni-20wt%Al powder were characterized by scanning electronic microscopy（SEM） and energy dispersive spectroscopy（EDS）. The results showed that the obtained particle size ranged from 5 to 50 μm. The morphology of the Ni–Al powder showed that molten particles were composed of Ni solid solution, NiAl, Ni_3Al, Al_2O_3, and NiO. The Ni–Al phase and a small amount of Al_2O_3 particles changed the composition of the coating. The microstructures of the twin-wire-arc-sprayed Ni–Al composite coatings were characterized by SEM, EDS, X-ray diffraction（XRD）, and transmission electron microscopy（TEM）. The results showed that the main phase of the Ni-5wt%Al coating consisted of Ni solid solution and Ni Al in addition to a small amount of Al_2O_3. The main phase of the Ni-20wt%Al coating mainly consisted of Ni solid solution, Ni Al, and Ni_3Al in addition to a small amount of Al and Al_2O_3, and Ni Al and Ni_3Al intermetallic compounds effectively further improved the final wear property of the coatings. TEM analysis indicated that fine spherical NiAl_3 precipitates and a Ni–Al–O amorphous phase formed in the matrix of the Ni solid solution in the original state.

时效前预拉伸处理对TiB_(2)/7056复合材料组织与性能的影响

采取扫描电镜、透射电镜等显微组织表征方法并结合室温拉伸、室温摆锤冲击实验和应力腐蚀等测试手段,研究时效前预拉伸处理对TiB_(2)/7056复合材料组织与性能的影响。研究结果表明:随着时效前预拉伸量增加,TiB_(2)/7056复合材料的位错密度显著增加,经时效热处理后的晶内析出相直径增大,晶界析出相形貌由链状转变为粗大不连续状,无沉淀析出带宽化;TiB_(2)/7056复合材料的强度先增大后减小,冲击韧性能与延伸率降低;与无预拉伸相比,预拉伸的TiB_(2)/7056复合材料的应力腐蚀抗力显著提升(扩展速率降低1个量级),其主要原因是不连续粗大的晶界析出相阻断了应力腐蚀裂纹的扩展。

碱蚀对铝合金表面性能的影响

[目的]氢氧化钠碱蚀对铝合金的外观和表面性能影响极大。[方法]利用铜离子置换法检测铝合金自然氧化膜的去除效果,用三维形貌仪考察样品的微观形貌和粗糙度,用光泽度仪测量样品表面光泽。[结果]在10℃以上采用50g/L NaOH溶液或在20℃用质量浓度20g/L以上的NaOH溶液碱蚀2min,均可完全去除6061铝合金表面的自然氧化膜,但不能消除车抛划痕。随着碱蚀温度的升高,铝合金析氢越来越剧烈。经碱蚀的铝合金在除灰后光泽明显增大,但相对于除油未碱蚀的试样,光泽都下降,在高于30℃下碱蚀会大大降低铝合金表面的光泽。在10~30 g/L的NaOH溶液中碱蚀并除灰后,铝合金表面的光泽优于采用高NaOH浓度下碱蚀的试样。铝合金经过NaOH碱蚀后表面粗糙度增大,20℃和30℃碱蚀后的表面较平整,在30~50℃范围内随着碱蚀温度上升,表面粗糙度Ra增大。碱蚀后铝合金表面挂灰的颜色随着温度的升高而加深,40℃以上的碱蚀会导致铝合金表面发生点蚀。[结论]铝合金的光泽和表面粗糙度受氢氧化钠碱蚀的影响很大,应注意碱蚀液温度和浓度的选择。

OH^(-)/F^(-)比与SiO_(3)^(2-)的关系对铝合金微弧氧化膜层的影响

目的探明不同氢氧化钠/氟化钾质量之比与硅酸钠浓度的关系对A356铝合金微弧氧化膜层耐蚀性的影响机制,寻找电解液中电解质之间的配比需求。方法利用SEM、EPMA、XRD分析所制得膜层的微观结构、元素分布及物相组成,并通过动电位极化曲线及电化学阻抗谱(EIS)研究膜层的电化学耐蚀性和腐蚀行为。结果当电解液中NaOH/KF之比(均为质量比)为0∶1、1∶2和2∶1时,均无法形成表观质量良好的微弧氧化膜层。而将NaOH/KF之比调整为1∶1时,便在基体表面得到了覆盖完整、均匀连续、光滑平整的膜层。但因此时电解液中主成膜剂Na_(2)SiO_(3)的不足,致使所获膜层与NaOH/KF之比为1∶0时相较而言,膜层表面的微孔尺寸增大,大尺寸的微孔个数也增加,在一定程度上削弱了膜层的抗腐蚀能力。继而保持NaOH/KF之比为1∶1但将主成膜剂Na_(2)SiO_(3)的浓度翻倍后,所制得膜层表面缺陷减少,厚度增加,致密度得到改善,膜层中α-Al_(2)O_(3)、γ-Al_(2)O_(3)、Mullite及AlF_(3)等优质耐蚀物相的含量也明显增多,进而提高了膜层在酸性腐蚀介质和中性Na Cl腐蚀介质中的耐蚀性。结论在硅酸盐电解液中,NaOH和KF都是微弧氧化成膜过程中的重要组分。NaOH促使A356铝合金基体表面形成充分的钝化膜,并显著提高了溶液的电导率,为微弧氧化反应的击穿发生创造了先决条件。KF可增进微弧氧化击穿发生后的放电效应,引发更多的放电火花产生,提高膜层的生长速率,加快成膜物质的沉积速率。NaOH与KF浓度相近,且二者浓度均小于Na_(2)SiO_(3)浓度时,SiO_(3)^(2-)、OH^(-)、F-三者之间交互作用对提高膜层的耐蚀性最为显著。

高熵合金增强铝基复合材料的研究进展

多主元高熵合金具有优异的综合性能,以其做增强体的铝基复合材料极具研究价值和应用潜力。综述了高熵合金增强铝基复合材料的制备、显微组织和性能的研究进展,并展望了该材料未来的研究方向。

Al-Ca-Fe合金中Al_(10)CaFe_(2)化合物的形成与表征

采用热力学计算和实验技术研究铝角的Al-Ca-Fe体系相图,包括液相面投影图和凝固反应。结果表明,与铝固溶体(Al)平衡的不是Al_(3)Fe相,而是一种组成符合化学式Al_(10)CaFe_(2)的三元化合物。通过包晶转变L+Al_(3)Fe→(Al)+Al_(10)CaFe_(2)(638℃,3.3%Ca和0.5%Fe,摩尔分数)发生从二元化合物到三元化合物的转变。与针状Al_(3)Fe相夹杂物不同,三元化合物的初晶和共晶具有致密的形貌。使用第一性原理计算和X射线衍射分析确定三元化合物Al_(10)CaFe_(2)的晶格结构。此外,近共晶合金Al-6%Ca-1%Fe(质量分数)在500~600℃退火后具有细晶组织,过量相的总体积分数约为25%。因此,Al-Ca-Fe体系可用于制造新的铝基复合合金。

轨道车辆铝合金长大薄壁脉冲复合磁控高效弧焊工艺研究

利用外加磁场改善电弧焊焊接工艺,具有成本低、附加耗能少、易操作等优点,已成为当今研究的热点之一。针对高速MIG焊时焊缝成形不良及焊接接头质量差等问题,在焊枪上装配一紧凑型脉冲复合磁场发生器,同时调控电弧和熔滴的左右摆动及前倾行为;并开展不同焊接参数下的铝合金车体长大薄壁型材对接接头焊接工艺试验,以研究高速焊条件下的最佳焊接工艺。研究发现,对于铝合金车体焊缝,励磁参数为8A、120 Hz,焊接参数为265A、23.5 V、1.2 m/min时,焊缝成形质量最佳。利用金相显微镜以及背向散射电子衍射(EBSD)技术表征了不同焊接参数下焊接接头的微观组织,分析了外加脉冲复合磁场对焊接接头组织的影响。结果表明,在高速焊接条件下(>1.0 m/min),焊接接头的晶粒相较于常规焊速时明显粗化,且熔合区宽度有所增加。然而,引入脉冲复合磁场后,晶粒尺寸和熔合区宽度均降低至与常规焊速相当的水平。开展不同焊接参数下的焊接接头力学性能测试,结果表明,外加脉冲复合磁场对焊接接头的机械性能具有显著的改善作用,焊缝区的平均硬度提高了21.37%,而接头的平均抗拉强度达到187 MPa,与传统焊接速度时的193 MPa相当接近。在保证焊缝成形质量和接头机械性能的前提下,最终将焊接速度从0.75 m/min提高到1.2 m/min,实现了优质高效的焊接过程。

Microstructure of in situ Al_3Ti/6351Al composites fabricated with electromagnetic stirring and fluxes

The 6351 wrought aluminum alloy and K2TiF6-CaF2-LiCl components were selected as raw materials to fabricate in situ Al3Ti particulate reinforced aluminum alloy at 720℃via direct melt reaction method with electromagnetic stirring(EMS).CaF2 and LiCl acted as fluxes to lower the reaction temperature of the system.It is shown that the electromagnetic stirring and fluxes accelerate the emulsion process of K2TiF6.Optical microscopy,scanning electron microscopy,transmission electron microscopy and energy dispersive spectrum were utilized to analyze the microstructure and components of composites.Compared to composites fabricated without EMS and fluxes,the sizes of endogenetic Al3Ti are refined from 10-15μm to 2-4μm,which are often accompanied with silicon element.The morphology of Al3Ti or Al3TiSi0.22 exhibits triangle,quadrilateral and other clumpy patterns. Because of the Ca elements from CaF2,the sizes of Mg2Si decrease from 8-10μm to 1-2μm due to the formation of Ca2Si.

Effect of Cu addition on microstructural evolution and hardening of mechanically alloyed Al-Ti-O in-situ composite

The microstructure formation and strengthening of an Al-5 wt.%TiO2 composites with additions of 5 wt.%Cu and 2 wt.% stearic acid(as a process control agent, PCA) during mechanical alloying and subsequent thermal exposure were studied. The powder composites were prepared by high-energy ball milling for up to 10 h. Single line tracks of the powders were laser melted. Optical and scanning electron microscopy, XRD analysis and differential scanning calorimetry were used to study microstructural evolution. The results showed that the Cu addition promotes an effective mechanical alloying of aluminum with Ti O2 from the start of milling, resulting in higher microhardness(up to HV 290), while the PCA, on the contrary, postpones this process. In both cases, the composite granules with uniform distribution of Ti O2 particles were formed. Subsequent heating of mechanically alloyed materials causes the activation of an exothermic reaction of Ti O2 reduction with aluminum, the start temperature of which, in the case of Cu addition,shifts to lower values, that is, the transformation begins in the solid state. Besides, the Cu-added material after laser melting demonstrates a more dispersed and uniform structure which positively affects its microhardness.

Microstructures and mechanical properties of in-situ TiB2/Al−xSi−0.3Mg composites

In-situ 2 vol.%TiB2 particle reinforced Al−xSi−0.3Mg(x=7,9,12,15 wt.%)composites were prepared by the salt−metal reaction,and the microstructures and mechanical properties were investigated.The results show that the TiB2 particles with a diameter of 20−80 nm and the eutectic Si with a length of 1−10μm are the main strengthening phases in the TiB2/Al−xSi−0.3Mg composites.The TiB2 particles promote grain refinement and modify the eutectic Si from needle-like to short-rod shape.However,the strengthening effect of TiB2 particles is weakened as the Si content exceeds the eutectic composition,which can be attributed to the formation of large and irregular primary Si.The axial tensile test results and fractography observations indicate that these composites show more brittle fracture characteristics than the corresponding alloy matrixes.

Multi-wall carbon nanotubes reinforced aluminum composites synthesized by hot press sintering and squeeze casting

Multi-wall carbon nanotubes (MWNTs) have high mechanical properties and are considered a kind of realistic reinforcement for polymers, ceramics and metals. The hot press sintering and squeeze casting were adopted to synthesize MWNTs reinforced aluminum composites. In hot press sintered MWNTs/Al composites, MWNTs agglomerates distribute along aluminum powders and have low bonding strength with aluminum. But MWNTs agglomerates distribute evenly in the squeeze cast MWNTs/Al composites. Some dispersed nanotubes bond well with aluminum matrix and few dislocations can be found in the nanotube areas, which implies little thermal residual stress in squeeze cast MWNTs/Al composites. This indicates that the strengthen mechanisms in nanometer sized MWNTs/Al composites may be different from that in micrometer sized whisker composites.