Effect of Al2O3sf addition on the friction and wear properties of (SiCp+Al2O3sf)/Al2024 composites fabricated by pressure infiltration

Aluminum(Al) 2024 matrix composites reinforced with alumina short fibers(Al_2O_(3sf)) and silicon carbide particles(SiC_p) as wear-resistant materials were prepared by pressure infiltration in this study. Further, the effect of Al_2O_(3sf) on the friction and wear properties of the as-synthesized composites was systematically investigated, and the relationship between volume fraction and wear mechanism was discussed. The results showed that the addition of Al_2O_(3sf), characterized by the ratio of Al_2O_(3sf) to SiC_p, significantly affected the properties of the composites and resulted in changes in wear mechanisms. When the volume ratio of Al_2O_(3sf) to SiC_p was increased from 0 to 1, the rate of wear mass loss(K_m) and coefficients of friction(COFs) of the composites decreased, and the wear mechanisms were abrasive wear and furrow wear. When the volume ratio was increased from 1 to 3, the COF decreased continuously; however, the K_m increased rapidly and the wear mechanism became adhesive wear.

THE MICROSTRUCTURE AND PROPERTIES OF ALUMINA FIBER-REINFORCED ALUMINIUM ALLOY MATRIX COMPOSITE

The morphology of the microstructure of Al-alloy composite with variousfiber contents was examined under optical microscope.The fracture of tension specimenwas studied under scanning electron microscope(SEM).The mechanical properties,wearresistance and coefficient of thermal linear expansion of the composite were measured.Theexperiment shows that the composite studied is suitable for engine pistons due to its goodwear resistance,higher elevated temperature mechanical properties and lower coefficient ofthermal linear expansion.

Tribological behaviour of fused deposition modelling printed short carbon fibre reinforced nylon composites with surface textures under dry and water lubricated conditions

Fused deposition modelling(FDM)printed short carbon fibre reinforced nylon(SCFRN)composites were fabricated.The friction and wear behaviour of printed materials were systematically investigated under both dry sliding and water lubricated conditions.The results showed that with short fibre enhancements,the printed SCFRN achieved a lower friction coefficient and higher wear resistance than nylon under all tested conditions.Further,under water lubricated conditions,the printed SCFRN exhibited a low,stable friction coefficient due to the cooling and lubricating effects of water.However,the specific wear rate of the printed specimens could be higher than that obtained under dry sliding conditions,especially when the load was relatively low.The square textured surface was designed and created in the printing process to improve materials’tribological performance.It was found that with the textured surface,the wear resistance of the printed SCFRN was improved under dry sliding conditions,which could be explained by the debris collection or cleaning effect of surface texture.However,such a cleaning effect was less noticeable under lubricated conditions,as the liquid could clean the surface effectively.On the other hand,surface textures could increase the surface area exposed to water,causing surface softening due to the higher water absorption rate.As a result,the samples having surface textures showed higher wear rates under lubricated conditions.The work has provided new insights into designing wear resistant polymer materials using three-dimensional(3D)printing technologies,subjected to different sliding conditions.

电流密度对发动机轴瓦喷射电沉积镍-纳米氧化铝复合镀层的影响

[目的]研究电流密度对发动机轴瓦表面喷射电沉积Ni-Al_(2)O_(3)复合镀层结构、耐磨性及耐蚀性的影响。[方法]通过表面形貌观察、X射线衍射分析、显微硬度检测、摩擦磨损试验及中性盐雾试验,对比了不同电流密度下所得Ni-Al_(2)O_(3)复合镀层的性能。[结果]当电流密度为60 A/dm^(2)时,所得Ni-Al_(2)O_(3)复合镀层展现出最均匀致密的表面,晶粒尺寸最细小,显微硬度最高(约735.0 HV),同时具有最佳的耐磨性和耐蚀性。[结论]喷射电沉积Ni-Al_(2)O_(3)复合镀层能够显著提升发动机轴瓦的耐磨性和耐蚀性。

镍-钴-氧化铝复合电刷镀工艺及其性能

[目的]研究不同工艺参数和Al_(2)O_(3)纳米颗粒用量对45钢表面复合电刷镀Ni-Co-Al_(2)O_(3)的影响,提升45钢的耐磨性。[方法]通过扫描电子显微镜观察不同条件下所得镀层的表面形貌及截面形貌,以确定合适的工艺参数。再在此基础上研究了Al_(2)O_(3)纳米颗粒质量浓度对Ni-Co-Al_(2)O_(3)复合镀层显微硬度和耐磨性的影响,结合磨损形貌观察和元素组成分析,探讨了复合镀层的磨损机理。[结果]复合电刷镀的较佳工艺参数为:电压10 V,温度40~50℃,镀笔速率6~8 m/min。镀液中Al_(2)O_(3)纳米颗粒的质量浓度为20 g/L时,Ni-Co-Al_(2)O_(3)复合镀层的显微硬度最高(约为850 HV),耐磨性最好。Ni-Co-Al_(2)O_(3)复合镀层的磨损机理以疲劳磨损为主,并伴随轻微的粘着磨损。[结论]通过电刷镀技术可在45钢表面获得高硬度、耐磨损的Ni-Co-Al_(2)O_(3)复合镀层。

氧化铝颗粒耐热钢基复合材料的高温磨损特性

采用化学气相沉积技术对氧化铝颗粒表面进行涂层处理,通过负压铸渗工艺制备了氧化铝颗粒耐热钢基复合材料,并对其在900℃下的高温磨料磨损特性进行了研究,结果表明:耐热钢在高温下的磨损主要是由磨料的滚压形成的挤出唇、翻边脱落所引起,磨损量较大,而复合材料高温磨损时颗粒突出于基体,承受载荷多,阻碍了磨粒对基体的损伤,因而抗磨性较好,其高温耐磨性是基体材料的33倍多.

氧化铝/石墨-硫酸钡层状复合材料的摩擦学性能及润滑机理

将石墨和硫酸钡按一定比例复合作为弱界面层,通过铺层-冷压-放电等离子烧结工艺制备了Al2O3/Graphite-BaSO4层状复合材料.考察了复配润滑剂的组分对层状复合陶瓷在室温至800℃连续加热过程中自润滑性能的影响规律,并通过磨损表面分析探讨了其在宽温域下的协同润滑机制.结果表明:通过复配在室温和中高温度段具有优异自润滑性能的固体润滑剂,并借助仿贝壳材料独特的层状结构特征,可有效改善氧化铝陶瓷在不同温度段的摩擦学性能,进而实现材料在较宽温度范围内的连续润滑.基于润滑相组分优化的复合材料在室温至800℃温度范围内与Al2O3栓对摩时的摩擦系数可保持在0.28~0.48之间,比块体Al2O3陶瓷/Al2O3栓摩擦副的摩擦系数降低了近60%.

低铝含量Cu-Al合金的表面弥散强化及其性能

以Cu2 O为氧化剂,在氩气保护下用内氧化技术对不同低Al含量的Cu Al合金表面进行了弥散强化处理(内氧化温度为112 3～12 73K ,保温时间10～96h) ,研究了硬化层的组织形貌及性能。用Wagner高温氧化理论分析了铝含量、工艺参数与内氧化层深及内氧化速度之间的定量关系。结果表明:试样表面通过内氧化后,固溶在Cu基体内部的Al以Al2 O3形态从基体析出,基体纯化,导电率提高。同时铜基体中弥散分布的纳米级的Al2 O3颗粒强化了铜基体,使硬度及磨损抗力提高。Al含量的多少直接影响内氧化层的厚度、组织形貌及硬度和导电率,Cu Al合金的内氧化动力学曲线呈抛物线变化规律。

硅酸铝短纤维增强 ZL109 复合材料的磨损机制

采用挤压铸造法制备了硅酸铝（Ａｌ２Ｏ３·ＳｉＯ２）短纤维增强ＺＬ１０９复合材料，并研究了该材料在干摩擦条件下的磨损行为．结果表明：Ａｌ２Ｏ３·ＳｉＯ２短纤维／ＺＬ１０９复合材料的耐磨机制为纤维断裂并在亚表层重新分布和排列形成高硬度的硬化层．这种硬化层的形成使复合材料具有比基体合金更优越的耐磨性．

硅酸铝短纤维增强Al-12Si合金复合材料的磨损行为

用挤压铸造法制备了低体积分数（３％～７％）的硅酸铝短纤维增强Ａｌ１２Ｓｉ合金复合材料，并利用销盘磨损试验机研究了材料在干摩擦条件下的磨损行为。磨损试验结果表明：硅酸铝短纤维加入到Ａｌ１２Ｓｉ合金明显提高抗磨损能力，随纤维体积分数的增加该复合材料的耐磨性逐渐增强。金相观察和测试表明：基体合金和复合材料的磨损区由硬化层和变形层组成，断裂的ＡｌＳｉ共晶相沿滑动方向重新分布排列形成了硬化层；而复合材料硬化层由于破断的硅酸铝纤维和破碎的ＡｌＳｉ共晶相的共同作用，使该硬化层硬度高于基体合金硬化层的硬度，从而使复合材料表现出优异的耐磨性。

SiC_p/Al_2O_(3f) 混杂增强 2024Al 复合材料摩擦磨损性能的研究

研究了２０２４铝合金、ＳｉＣｐ／Ａｌ２Ｏ３ｆ混杂增强２０２４Ａｌ复合材料与汽车刹车材料对磨时的摩擦磨损性能．借助扫描电镜对磨损形貌的观察，分析了材料的磨损机理．在本研究的试验条件下，２０２４铝合金的磨损极为严重，ＳｉＣｐ／Ａｌ２Ｏ３ｆ混杂增强２０２４Ａｌ复合材料的耐磨性能良好．由于ＳｉＣｐ／Ａｌ２Ｏ３ｆ混杂增强２０２４Ａｌ复合材料的密度较低，因而该材料在汽车工业中有广泛的应用前景．

断裂方式对氧化铝基复合陶瓷耐磨性的影响

通过磨粒磨损试验测定了氧化铝陶瓷、氧化铝／碳化硅复合陶瓷和氧化铝／莫来石复合陶瓷的耐磨性．利用透射电子显微镜(TEM)观察了样品的微观结构,采用扫描电子显微镜(SEM)分析了样品的断口形貌和磨损表面的剥落情况．研究了断裂方式对磨损表面剥落和耐磨性的影响．结果表明:氧化铝陶瓷的磨损主要由断裂磨损机制控制,氧化铝／碳化硅复合陶瓷的磨损主要由塑性磨损机制控制,氧化铝／莫来石复合陶瓷受这两种磨损机制共同作用．相对于氧化铝陶瓷,氧化铝／碳化硅复合陶瓷和氧化铝／莫来石复合陶瓷的耐磨性提高2-4倍,这主要是由于其断裂方式转变为以穿晶断裂为主,减少了磨损面的脆性剥落．

颗粒含量对含污染物油润滑条件下纳米复合电刷镀层摩擦学性能的影响

研究了电刷镀液中纳米Al2O3颗粒含量对复合镀层中纳米颗粒含量、镀层表面形貌、显微硬度以及摩擦学性能的影响。结果表明,随着镀液中纳米Al2O3颗粒含量的增加,镀层组织细化,显微硬度提高,镀层在含细沙油润滑条件下的耐磨性比不加纳米颗粒的快速镍镀层提高了80%。当镀液中Al2O3含量为20g/L时,镀层具有最佳的耐磨性,进一步提高镀液中的纳米颗粒含量,镀层性能反而下降。

Strength and Wear Behavior of Mg Alloy AE42 Reinforced with Carbon Short Fibers

In addition to the advantage of the lightweight of magnesium alloys, magnesium composites have moderate strength and elastic modulus. The proposed application of magnesium composites as diesel truck pistons makes it necessary to assess their wear performance. Little research data have been discussed on wear behavior of Mg alloy AE42 matrix and its composites. Thus, this paper reports wear behavior of magnesium alloy AE42(Mg–Al–Mn—RE; rare earth) and its composite AE42-C, which contains 23 vol% of randomly oriented carbon short fibers. Materials characterization, including density measurements, hardness testing, microstructures investigation, and compression testing at temperatures of 25, 150,and 300 °C, were conducted. Wear tests were performed under various loads and sliding distances. Wear mechanisms were also proposed based on the examination of worn surfaces using optical microscopy and scanning electron microscopy equipped with EDX(energy-dispersive X-ray spectrometry) analysis system. The hardness of AE42-23 vol% C composite is twice the hardness of the Mg matrix alloy AE42. Significant improvements to yield stress and compressive strength at temperatures of 25, 150, and 300 °C of the composite versus the AE42 alloy are achieved. Wear resistance of the composite is improved considerably versus that of the Mg alloy AE42 at the various sliding distances. Smearing of graphite on the worn surface produces a lubricating film that delays change from mild to severe wear of the composite, especially at high loads. EDX analysis of the worn surface shows oxidation of the matrix alloy at higher wear loads, and this mechanism decreases in the presence of carbon fibers under the same loads. Abrasive wear, oxidation, and plastic deformation are the dominant wear mechanisms for the alloy matrix AE42, whereas mainly abrasive wear is the wear mechanism of AE42-23 vol% C composite under the proposed testing conditions.

氧化铝短纤维、石墨混杂增强ZL108复合材料的摩擦特性

采用挤压铸造法制备了氧化铝短纤维(80％Al_2O_3·20％SiO_2)、石墨(Gr)混杂增强铝基复合材料。对其组织、强度、摩擦磨损特性等进行了研究。发现由氧化铝短纤维和石墨混杂增强的铝基复合材料具有优良的摩擦性能。这种复合材料随着其中石墨含量的增加,摩擦系数明显降低。在短纤维含量较高的铝基复合材料中,石墨的作用尤为突出。在大载荷下,石墨能显著降低短纤维增强铝基复合材料的摩擦系数和磨损量。从实验和分析来看,石墨改变了复合材料的磨损类型。

Al_2O_3的质量分数对衬瓷层组织及耐磨性的影响

针对表面工程领域对耐磨材料的迫切需要及制备耐磨材料的复杂性,发明了钢水余热衬瓷技术,并利用该技术对耐磨衬瓷层进行了研究.通过将不同比例的Al2O3和金属粉料混合、合成,制备出陶瓷复合粉,并将其涂覆在沾有高温胶的砂型型腔工作面上,通过正常的钢水浇铸工艺,利用钢水凝固时释放出的热量将陶瓷复合粉烧结到钢的表面,达到耐磨效果.利用扫描电镜观察分析了衬瓷层的组织、表面形貌、是否有脱落现象以及衬瓷层与基体的结合情况,利用能谱分析了衬瓷层的成分,利用磨损试验机检测了衬瓷铸件的耐磨程度.结果表明:Al2O3的质量分数在35%～45%之间的衬瓷效果最好,其耐磨性是淬火45号钢的80倍.

纤维取向对复合材料摩擦磨损性能的影响

利用挤压铸造法制备了Al2O3f/ZL109短纤维筒形复合材料,在转速675r/min、载荷100N条件下,对复合材料的纤维平行取向和纤维垂直取向磨损表面各进行了4组样品的试验,根据试验结果绘出纤维取向及体积分数对复合材料磨损性能影响的曲线图。结果表明,该复合材料纤维垂直取向比纤维平行取向耐磨,即纤维垂直取向有利于复合材料耐磨性能的提高。

热处理工艺对Al__2O3-SiO_2/Al-Si复合材料微屈服行为的影响

以Al2O3-SiO2/Al-Si复合材料为研究对象,采用连续加载法,详细研究了热处理工艺对Al-Si基复合材料微屈服行为的影响规律及其原因。结果表明,复合材料经淬火处理后的微屈服强度最低,而经时效处理后的微屈服强度则好于其他热处理工艺的效果。时效处理是提高Al-Si基复合材料微屈服强度的有效途径之一。

反应等离子喷涂合成Fe-FeAl_2O_4-Al_2O_3复合涂层的研究

利用机械团聚法制备了适合等离子喷涂的Fe2O3Al复合粉体,将此粉体送入等离子焰流,通过复合粉的自反应制备含有Fe、Al2O3和FeAl2O4的复合陶瓷涂层。利用扫描电镜(SEM)、X射线衍射仪(XRD)和透射电镜(TEM)等检测手段对反应等离子制备的复合涂层进行了研究。结果表明:涂层具有以层状陶瓷为骨架,球形金属为弥散相的组织,反应生成涂层的过程是分步进行的,由于反应生成的部分纳米颗粒以及金属的存在,使得涂层的耐磨性和韧性比普通Al2O3涂层有了较大的提高,尤其在高载荷作用下,复合涂层的耐磨性比普通Al2O3提高近两倍。

脉冲电镀镍–纳米氧化铝复合镀层及其组织结构与性能表征

采用脉冲电镀法在Q235钢上制备了Ni–纳米Al_2O_3复合镀层。通过正交试验得到最佳工艺条件为:六水合硫酸镍234 g/L,六水合氯化镍30 g/L,硼酸35 g/L,十二烷基硫酸钠0.6 g/L,糖精1 g/L,纳米Al_2O_3 10 g/L,p H 3.5,电流密度2 A/dm^2,占空比60%,频率1 000 Hz,温度40°C,搅拌速率200 r/min,时间60 min。在最佳工艺条件下所得Ni–纳米Al_2O_3复合镀层表面平整、致密,晶粒细小,弥散分布着纳米Al_2O_3,显微硬度、耐磨性和耐蚀性都比Ni镀层好。