复合电铸制备Ni-石墨复合材料工艺及其沉积机理

采用复合电铸技术制备了Ni-石墨自润滑复合材料, 重点研究了工艺参数(微粒浓度、电流密度、电铸液流动速度及温度和p H 值) 对复合材料中石墨微粒含量的影响。结果表明, 提高镀液中微粒浓度使复合材料中石墨含量增大, 最后趋于稳定值。电流密度和镀液流动速度使石墨含量存在最大值, 但是温度和p H 值的增加却使之降低。复合电铸沉积机理Guglielmi 模型只在低电流密度条件下适用, 但不适用于高电流密度的条件。镀液中石墨微粒含量增大, 复合材料的硬度和摩擦系数降低, 磨损失重减小, 但是石墨微粒30 g/ L 时的磨损量增加。      

镀铜石墨/铜复合材料的组织和摩擦磨损性能

本实验以电解铜粉为基体,镀铜石墨为润滑相,采用放电等离子烧结技术(SPS)制备镀铜石墨/铜复合材料,研究了镀铜石墨含量对复合材料微观组织、硬度、孔隙率和摩擦磨损性能的影响。结果表明:镀铜石墨均匀分散在Cu基体中能细化晶粒、均匀组织,石墨表面镀铜层能够增强石墨与Cu基体的界面结合。当镀铜石墨含量超过4wt%,复合材料的硬度和孔隙率变化幅度明显增大。镀铜石墨具有细晶强化作用,能提升复合材料的硬度,其含量为4wt%时,复合材料的硬度达到最大值57.8HV,但镀铜石墨含量和孔隙率的共同作用使得复合材料的硬度呈先增大后减小的趋势。随着镀铜石墨含量增加,复合材料孔隙率逐渐增大,摩擦系数、磨损量逐渐减少,镀铜石墨含量为8wt%时,复合材料的摩擦系数、磨损量相比纯铜分别降低63.9%、96.3%。镀铜石墨作为润滑相紧密镶嵌在铜基体中,显著提高了复合材料的摩擦磨损性能。复合材料摩擦磨损机理主要为磨粒磨损、粘着磨损和氧化磨损。     

电流密度对电沉积银石墨复合镀层耐蚀和耐磨性能的影响

使用电沉积方法在铜基表面制备了银石墨复合镀层,研究了沉积电流密度对银石墨复合镀层耐蚀和耐磨性能的影响。研究表明,镀层的石墨面积分数随着沉积电流密度的上升而增大;沉积电流密度对自腐蚀电位的影响不大,沉积电流密度的增加使得自腐蚀电流密度增大;在0.1~0.5A/dm~2范围内,随着电流密度的增加,复合镀层的平均摩擦系数减小,磨损率先减小后增大。当沉积电流密度为0.3A/dm~2、搅拌速度为420r/min时,复合镀层的磨损率最小,为8.13×10~(-14) m~(-3)/N·m。该条件下制备的触头触指分合10 000次后,在触头的面状低副摩擦中,其镀层厚度迁移量小于2μm;在触指的线状高副摩擦中,其镀层磨损量小于10μm。     

石墨含量对铜-石墨-乳化沥青复合材料组织和性能的影响

以电解铜粉与石墨粉为原料,阴离子乳化沥青为粘结剂,采用粉末冶金技术制备了铜-石墨-乳化沥青复合材料,并通过XRD、EDS和SEM对石墨含量为2wt%~8wt%的铜-石墨-乳化沥青复合材料微观组织进行表征,研究了铜-石墨-乳化沥青复合材料的摩擦磨损性能、力学和电学性能,并与不含乳化沥青的铜-石墨复合材料进行比较。结果表明,乳化沥青可以有效防止石墨颗粒的聚集,对石墨和铜基体起粘结作用;在两相界面处几乎没有间隙,并且产生了层片状石墨;石墨含量为4wt%的试样磨损量最小,仅为0.0049 g,摩擦系数约为0.025;增加载荷和石墨含量会增大磨损量,但会降低摩擦系数;在滑动摩擦期间,磨损表面会出现裂纹、犁沟、凹陷、小颗粒和层片状结构,但其程度要比不含乳化沥青的复合材料低。      

滑动速度对碳纳米管-银-石墨复合材料电磨损性能的影响

采用粉末冶金法制备了碳纳米管-银-石墨复合材料,研究了圆周速度对复合材料摩擦系数、磨损量的影响。结果表明,当压力一定时,随着速度的加快,机械磨损的摩擦系数减小,而电磨损的摩擦系数增大;复合材料的电磨损量远远大于机械磨损的磨损量,电磨损时磨损量在V=10m/s处出现最小值,而机械磨损的磨损量随速度的加快而减小。     

表面活性剂对Ni-SiC复合镀层性能的影响

表面活性剂能改善复合镀层的性能,过去对离子型和非离子型表面活性剂影响复合镀层性能的研究报道不多.为此,利用电子探针分析仪、电化学分析方法以及摩擦磨损试验,系统地研究了表面活性剂对Ni-SiC复合镀层性能的影响.结果表明:非离子表面活性剂不易使微粒与基体金属发生共沉积,对沉积速度有一定的抑制作用;阳离子表面活性剂能够增加镀层中SiC粒子的含量,当浓度为0.12 g/L时SiC粒子含量最高,随着镀层中SiC离子含量的增加镀层的硬度增加,耐磨性能提高,其中XCG阳离子表面活性剂效果最好;非离子表面活性剂与阳离子表面活剂的协同作用,进一步促进了镀层中SiC微粒的共沉积,改善了复合镀层的性能.     

空心微珠-碳纤维共混改性聚酰亚胺复合材料的摩擦学性能

通过模压成型制备了碳纤维与空心微珠共混改性的聚酰亚胺复合材料,采用MRH-3型摩擦磨损试验机研究了空心微珠含量、滑动速度及载荷对复合材料摩擦学性能的影响,并对其磨损形貌及机制进行了分析.结果表明:空心微珠-碳纤维/聚酰亚胺复合材料摩擦学性能优于其单独填充的聚酰亚胺基复合材料;空心微珠含量对共混改性的复合材料摩擦系数影响不大,但其磨损率随着空心微珠含量的增加先减小后增大;15％空心微珠-10％碳纤维(质量分数)共混增强的复合材料的减摩耐磨性能最佳;随着滑动速度提高,空心微珠-碳纤维/聚酰亚胺复合材料的摩擦系数下降,磨损率增大;空心微珠-碳纤维/聚酰亚胺复合材料摩擦系数随着载荷增加先下降后上升,而磨损率则随着载荷增加而增大;空心微珠-碳纤维/聚酰亚胺的主要磨损机制在较低载荷时为磨粒磨损,在较高载荷时为粘着磨损和磨粒磨损.     

感应烧结石墨/铜铁基高温自润滑复合材料摩擦学性能研究

通过基体合金化和添加不同含量的石墨,采用感应加热烧结的方法制备了石墨/铜铁基高温自润滑复合材料,在力学性能试验机和MRH-3摩擦磨损试验机上考察了复合材料从室温～500℃温度条件下的力学和摩擦磨损性能,利用扫描电镜观察分析了磨损表面形貌,进而探讨了摩擦磨损机理。结果表明,复合材料的力学和摩擦磨损性能与感应加热频率和石墨含量有关;在室温条件下,随着石墨含量的升高复合材料的力学性能变差而减磨自润滑效果变好,在室温～500℃条件下,选用合适的感应加热频率和石墨的含量可以使石墨/铜铁基自润滑材料保持良好的耐磨性;而复合材料的磨损机制由粘着磨损变为犁沟磨损。     

电泳-电沉积Ni-Al2O3纳米复合层的微观结构及性能

为了改善纳米复合镀层的物理、力学性能,以电泳-电沉积工艺制备了具有较高纳米Al2O3含量的Ni-Al2O3纳米复合镀层.用SEM、TEM、显微硬度计等对复合镀层的表面微观形貌、显微硬度以及耐磨性能进行了分析;探讨了电泳液中α-Al2O3微粒浓度、电沉积电流密度对复合镀层表面微观形貌、显微硬度及其与基体的结合力的影响.结果表明:α-Al2O3纳米粒子弥散分布于镀层之中,并对基质金属晶粒产生细化作用;电泳液中α-Al2O3微粒浓度对复合镀层表面微观形貌影响较大,电沉积电流密度对微观形貌无明显影响;随着电泳液微粒浓度和电沉积电流密度的增大,复合镀层显微硬度均呈下降趋势,在电泳液微粒浓度8 g/L,电沉积电流密度0.5A/dm2时,复合镀层具有最大显微硬度442 HV,较纯镍镀层有明显提高.镀层中微粒体积分数约为30％时,镀层的耐磨性能及与基体的结合性能最为优异.     

空心微珠-碳纤维共混改性聚酰亚胺复合材料的摩擦学性能

通过模压成型制备了碳纤维与空心微珠共混改性的聚酰亚胺复合材料, 采用MRH-3型摩擦磨损试验机研究了空心微珠含量、滑动速度及载荷对复合材料摩擦学性能的影响, 并对其磨损形貌及机制进行了分析。结果表明: 空心微珠-碳纤维/聚酰亚胺复合材料摩擦学性能优于其单独填充的聚酰亚胺基复合材料; 空心微珠含量对共混改性的复合材料摩擦系数影响不大, 但其磨损率随着空心微珠含量的增加先减小后增大; 15%空心微珠-10%碳纤维(质量分数)共混增强的复合材料的减摩耐磨性能最佳; 随着滑动速度提高, 空心微珠-碳纤维/聚酰亚胺复合材料的摩擦系数下降, 磨损率增大; 空心微珠-碳纤维/聚酰亚胺复合材料摩擦系数随着载荷增加先下降后上升, 而磨损率则随着载荷增加而增大; 空心微珠-碳纤维/聚酰亚胺的主要磨损机制在较低载荷时为磨粒磨损, 在较高载荷时为粘着磨损和磨粒磨损。     

Abrasive wear of FeCr (M7C3–M23C6) reinforced iron based metal matrix composites

Abstract

The effects of volume fraction, particle size, and sintered porosity of FeCr (M₇C₃–M₂₃C₆) particulates on the abrasive wear resistance of powder metallurgy (PM) Fe alloy metal matrix composites have been studied under different abrasive conditions. It was seen that the abrasive wear rate of the composites increased with an increase in the FeCr volume fraction in tests performed with 80 grade SiC abrasive paper, but it decreased for tests conducted with 220 grade SiC abrasive paper. Furthermore, the wear rates decreased with an increase in FeCr size for composites containing the same amount of FeCr. Hence it is deduced that Fe alloy composites reinforced with larger size FeCr particles are more effective against abrasive wear than those reinforced with smaller ones. At the same time the results show that the beneficial effects of hard FeCr particulates on wear resistance far outweighed the detrimental effects of sintered porosity in the PM metal matrix composites. In addition, the fabrication of composites containing soft particles such as graphite or copper favours a reduction in the coefficient of friction, and increases the matrix hardness of the composite. For this reason graphite and copper were used in the matrix in different amounts to test their effect on the wear resistance. Increase in graphite and copper volume fraction allowed the formation of additional phases, which had high hardness and wear resistance. It was also found that the wear rate of the composites decreased considerably with graphite and copper addition.     

碳纤维含量对碳纤维／中铜石墨复合材料减摩耐磨性能的影响

在干磨擦条件下，对不同碳纤维含量的碳纤维／中铜石墨复合材料，进行了５０ｈ的摩擦磨损试验并借助扫描电镜观察了综们的磨面，结果表明，随碳纤维 增加，碳纤维．中铜石墨复合材料的摩擦系数和磨损量均明显减少。     

铜-石墨复合材料的摩擦学性能和磨损机理

采用机械合金化后冷压成型和放电等离子烧结两种不同工艺分别制备铜-石墨复合材料,在销盘式实验机上进行材料的摩擦实验,并通过扫描电镜、X射线光电子能谱仪(XPS)分析摩擦表面的形貌和化学性质。结果表明:随着石墨含量的增加,复合材料的摩擦系数与磨损率显著下降;随烧结温度的升高,摩擦系数与磨损率都呈下降趋势。摩擦系数与磨损率的显著改善是由于在磨损过程中形成一层覆盖表面的润滑膜。当形成的润滑膜几乎覆盖住整个磨损表面时,该润滑膜能够抑制滑动界面处金属与金属接触,使摩擦磨损特性得以改善。     

Abrasive wear of Al2O3-reinforced aluminium-based MMCs

The effects of volume fraction, Al₂O₃ particle size and effects of porosity in the composites on the abrasive wear resistance of compo-casting Al alloy MMCs have been studied for different abrasive conditions. It was seen that porosity in the composites is proportional to particle content. In addition, process variables like the stirring speed, and the position and diameter of the stirrer affect of the porosity content in a way similar to that observed for particle content. In addition, the abrasive wear rates of composites decreased more rapidly with increase in Al₂O₃ volume fraction in tests performed over 80 grade SiC abrasive paper than in tests conducted over 220 grade SiC abrasive paper. Furthermore, the wear rates decreased with increase in Al₂O₃ size for the composites containing the same amount of Al₂O₃. Hence, it is deduced that aluminium alloy composites reinforced with larger Al₂O₃ particles are more effective against abrasive wear than those reinforced with smaller Al₂O₃ particles. At the same time the results show that the beneficial effects of hard Al₂O₃ particles on wear resistance far surpassed that of the sintered porosity in the compocasting metal-matrix composites (MMCs). Nevertheless, the fabrication of composites containing soft particles such as graphite favors a reduction in the friction coefficient. For this reason graphite and copper were used in the matrix in different amounts to detect their effect on wear resistance. Finally, it was seen that wear rate of the composites decreased considerably with graphite additions.     

铜基石墨复合材料的研究进展

铜基石墨复合材料是一种广泛应用于摩擦材料和电接触材料等领域的金属基复合材料.综述了铜基石墨复合材料在改善铜基体与石墨增强体结合方面的研究进展,主要包括基体合金化、石墨的表面处理、添加粘结剂等,重点介绍了铜基石墨复合材料的制备工艺方法,并概述了其导电导热性能、摩擦磨损性能、工艺性能及应用,最后展望了铜基石墨复合材料的研究重点和发展方向,认为取代现有的易切削铅黄铜合金将成为铜基石墨复合材料今后研究和应用的一个亮点.     

Effect of the SiC particle size on the dry sliding wear behavior of SiC and SiC–Gr-reinforced Al6061 composites

The effect of size of silicon carbide particles on the dry sliding wear properties of composites with three different sized SiC particles (19, 93, and 146 μm) has been studied. Wear behavior of Al6061/10 vol% SiC and Al6061/10 vol% SiC/5 vol% graphite composites processed by in situ powder metallurgy technique has been investigated using a pin-on-disk wear tester. The debris and wear surfaces of samples were identified using SEM. It was found that the porosity content and hardness of Al/10SiC composites decreased by 5 vol% graphite addition. The increased SiC particle size reduced the porosity, hardness, volume loss, and coefficient of friction of both types of composites. Moreover, the hybrid composites exhibited lower coefficient of friction and wear rates. The wear mechanism changed from mostly adhesive and micro-cutting in the Al/10SiC composite containing fine SiC particles to the prominently abrasive and delamination wear by increasing of SiC particle size. While the main wear mechanism for the unreinforced alloy was adhesive wear, all the hybrid composites were worn mainly by abrasion and delamination mechanisms.     

Microstructural investigation on antifriction characteristics of self-lubricating copper hybrid composite

Abstract

Owing to good antifriction properties and high wear resistance, copper hybrid composites reinforced with hard ceramic particles and solid lubricant components are regarded as promising materials for applications in sliding electrical contacts. The present work investigates the antifriction mechanism of a (SiC+Gr)/Cu composite from a microstructural viewpoint, so as to assist the development and application of this material. A graphite rich tribolayer formed on the worn surface was responsible for good tribological properties of the composites. Testing results showed that nanoparticles of graphite were involved in a mechanically mixing process by adhering to both the other wear debris and the two contacting surfaces, thereby developing a solid lubricant tribolayer. The nanographite to nanographite contacting mode, formed between the composite and the counterface, significantly improved wear resistance and friction stability. The forming and failure process of the graphite rich tribolayer was studied. A mechanism has been developed based on the experimental results.     

铝/石墨复合材料高速高温下的摩擦磨损特性

本文研究了用中间法新工艺制造的铝石墨复合材料在高速高温下的摩擦磨损特性。试验在销盘式试验机上进行。滑动线速度最高达9.4米/秒。在2米/秒干摩擦时,所有测试的复合材料磨损量均小于基体合金。200℃时,含石墨2～5%的复合材料磨损量也此基体合金小。在9.4米/秒干摩擦时,含石墨2%的复合材料耐磨性能最好。以前曾有报导:滑动线速度大于1米/秒,铝石墨复合材料的磨损量大于基体合金[12,13]。本文认为新工艺制造的复合材料在9.4米/秒的高速摩擦时摩擦系数和磨损量下降是由于石墨与基体界面结合良好。      

Friction and wear of epoxy/TiO2 nanocomposites: Influence of additional short carbon fibers, Aramid and PTFE particles

An epoxy-based nanocomposite containing graphite powder (7 vol%) and nano-scale TiO₂ (4 vol%) was developed for tribological evaluation. A series of composites containing additional fillers such as short carbon fibers (SCF), Aramid and polytetrafluoroethylene (PTFE) particles was developed and evaluated in adhesive and low amplitude oscillating wear modes. The incorporation of SCF and Aramid particles resulted in a remarkable improvement in the sliding wear resistance. However, SCF impaired the low amplitude oscillating wear resistance. The further addition of PTFE to the SCF filled nanocomposites reduced the friction and wear under both wear conditions. However, an adverse effect of PTFE was found for the Aramid particles filled nanocomposites. Under sliding conditions, the lowest wear rate and coefficient of friction showed the 2–4 vol% PTFE filled SCF nanocomposite. Aramid particles containing nanocomposites (without PTFE) exhibited the best wear and friction behavior under low amplitude oscillating wear conditions among the selected composites. The wear mechanisms were studied by scanning electron microscopy.