Preparation technology and anti-corrosion performances of black ceramic coatings formed by micro-arc oxidation on aluminum alloys

In order to prepare ornamental and anti-corrosive coating on aluminum alloys, preparation technology of black micro-arc ceramic coatings on Al alloys in silicate based electrolyte was studied. The influence of content of Na2WO4 and combination additive in solution on the performance of black ceramic coatings was studied; the anticorrosion performances of black ceramic coatings were evaluated through whole-immersion test and electrochemical method in 3.5% NaCl solution at different pH value; SEM and XRD were used to analyze the surface morphology and phase constitutes of the black ceramic coatings. Experimental results indicated that, without combination additives, with the increasing of Na2WO4 content in the electrolyte, ceramic coating became darker and thicker, but the color was not black; after adding combination additive, the coating turned to be black; the black ceramic coating was multi-hole form in surface. There was a small quantity of tungsten existing in the black ceramic coating beside α-Al2O3 phase and β-Al2O3 phase. And aluminum alloy with black ceramic coating exhibited excellent anti-corrosion property in acid, basic and neutral 3.5% NaCl solution.

Icephobic performance on the aluminum foil-based micro-/nanostructured surface

The research of superhydrophobic materials has attracted many researchers＇ attention due to its application value and prospects.In order to expand the serviceable range,people have investigated various superhydrophobic materials.The simple and easy preparation method has become the focus for superhydrophobic materials.In this paper,we present a program for preparing a rough surface on an aluminum foil,which possesses excellent hydrophobic properties after the treatment with low surface energy materials at high vacuum.The resulting contact angle is larger than 160° and the droplet cannot freeze on the surface above-10 ℃.Meanwhile,the modified aluminum foil with the thickness of less than 100 μm can be used as an ideal flexible applied material for superhydrophobicity/anti-icing.

Microstructures and properties of aluminum film and its effect on corrosion resistance of AZ31B substrate

Aluminum films with thickness of 8.78-20.82μm were deposited on the AZ31B magnesium alloys by DC magnetron sputtering.The influences of aluminum film on the micro-mechanical properties and corrosion behavior of the magnesium alloys were investigated.The morphology of aluminum film was examined by scanning electron microscopy and the microstructure of aluminum film was analyzed by X-ray diffiactometry.Nanoindentation and nanoscratch tests were conducted to investigate their micromechanical properties.Moreover,potentiodynamical polarization test performed in 3.5%NaCl solution was carried out to study their anticorrosion performances.The results show that the surface hardness of AZ31B magnesium alloy with aluminum film is 1.38-2.01 GPa,higher than that of the magnesium alloy substrate.The critical load of Al film/AZ31B substrate is in the range of 0.68-2.77 N. The corrosion current density of AZ31B with aluminum film is 2-3 orders of magnitude less than that of bare AZ31B.And the corrosion potential with aluminum film positively shifts.Thus aluminum film can increase the corrosion resistance of Mg alloys obviously.

Fabrication of Superhydrophobic Micro Post Array on Aluminum Substrates Using Mask Electrochemical Machining

Surfaces with controllable micro structures are significant in fundamental development of superhydrophobicity. However,preparation of superhydrophobic surfaces with array structures on metal substrates is not effective using existing methods. A new method was presented to fabricate super-hydrophobic post arrays on aluminum(Al) substrates using mask electrochemical machining and fluoridation. Electrochemical etching was first applied on Al plates with pre-prepared photoresist arrays to make the post array structures. Surface modification was subsequently applied to reduce the surface energy, followed by interaction with water to realize superhydrophobicity. Simulation and experimental verification were conducted to investigate how machining parameters affect the array structures. Analysis of the water contact angle was implemented to explore the relationship between wettability and micro structures.The results indicate that superhydrophobic surfaces with controllable post structures can be fabricated through this proposed method, producing surfaces with high water static contact angles.

Adhesive strength and structure of micro-arc oxidation ceramic coatings grown in-situ on LY12 aluminum alloy

The ceramic coatings containing zirconium dioxide were grown in-situ on LY12 aluminium alloy by micro-arc oxidation in mixed zirconate and phosphate solution. The phase composition and morphology of the coatings were studied by XRD and SEM. The adhesive strength of ceramic coatings was assessed by thermal shock test and tensile test. The results show that the coating is composed of m-ZrO2,t-ZrO2, and a littleγ-Al2O3. Along the section of the coating, t-ZrO2 is more on both sides than that in the middle, while m-ZrO2 is more in the middle than that on both sides. Meantime the coating is also composed of a dense layer and a loose layer. The coating has excellent thermal shock resistance under 550℃and 600℃. And tensile tests show the adhesive strength of the dense layer of the coating with the substrate is more than 17.5 MPa.

Effects of cathodic component of current on porosity and hardness characteristics of micro plasma oxidation(MPO) coatings on aluminum alloy

Micro plasma oxidation(MPO) has recently been investigated as a novel, rapid and effective means to provide modified surfaces with improved properties of load bearing and wear resistance on light alloys particularly aluminum alloys. MPO is a multifactor-controlled process, these factors must be controlled to produce high quality coatings. The main research emphasis in MPO coating development over the past years seems to be the attainment of higher hardness levels and thick coatings. The porosity of MPO coating is the most complex phenomenon affecting the distribution, levels and the measurements of the hardness; and it is controlled by suitable selection of important parameters such as the electrical conditions. Ceramics coatings were synthesized on Al substrate by MPO to examine the effects of adding a cathodic phase alternated with anodic-cathodic current on the porosity and hardness characteristics of coatings by X-ray diffraction(XRD), scanning electron microscopy(SEM), and microhardness tester. The coatings produced by the combined mode are more dense and less porous than that by the anodic-cathodic mode. (Microhardness) test shows that the coatings produced by the combined mode exhibit both the highest hardness, and less reduction percentage in hardness with increasing the coatings thickness. These improvements become more significant for the polished and thicker coatings.

Discharge Characteristic of Micro-Arc Oxidation on Aluminum Alloy under the Changing Electrolyte Temperature

The electrolyte temperature has a great influence on the performance of the coating prepared by micro-arc oxidation (MAO). The behavior of MAO discharge in the changing electrolyte temperature has been investigated. Compared to constant electrolyte temperature in conventional MAO process, the process has different discharge characteristics under the changing electrolyte temperature. The amplitude of pulse voltage was detected to study the change of discharge characteristic under the constant-current control of MAO power supply. Three successive discharge stages were differentiated by the variable the pulse voltage versus process time. Since there were significant changes in the sound, the sound signals were acquired and the audio analysis was used to describe the changing of the MAO discharge at different stages. Optical emission spectroscopy (OES) was employed in situ to unveil how the micro-discharge changed with the temperature increasing. Scanning electron microscopy (SEM) was used to characterize the morphology of the coatings on 6N01 aluminum alloy prepared by normal process with the constant-temperature control of the MAO electrolyte and by the process under the changing electrolyte temperature. A mode of film growth and micro-discharge was given to describe the effects of the changing electrolyte temperature in the whole MAO process.

SEMI-SOLID MICROSTRUCTURE AND ITS EVOLUTION OF WROUGHT ALUMINUM ALLOY BY DIRECTLYHEATING-ISOTHERMAL TREATMENT

Microstructure evolution of wrought aluminum alloy extruded rods and the mechanism of liquid phase formation during reheating were investigated. And the relation between the volume fraction of liquid phase and the recrystallization microstructure was proposed. The results show that increase in reheating temperature and time can augment the volume fraction of liquid phase and accelerate the grain spheroidization, as a result of which the requirement of semi-solid forming can be satisfied. Due to the higher aberration energy of grain boundary, the melting point is lowered as a result of the easy diffusion of atoms. At higher reheating temperature the grain boundary melts, the growth of the recrystallized grain is inhibited and the grain is refined. The composition of the low melt-point phase along the recrystallized grains was determined using EDS. It can be seen from the experimental results that when the extrusion rod of the wrought aluminum alloy is reheated at 610℃ for 20min, perfect fine equiaxial grains can be obtained, the average grain size is about 66.34μm and the volume fraction of solid phase is about 68%.

纳米Cr_(2)O_(3)对铝合金微弧氧化膜组织和性能的影响

在恒流模式下对7050铝合金开展微弧氧化试验。用SEM、EDS、XRD、膜层测厚仪、维氏硬度计、电化学工作站和磨损试验机等研究了不同纳米Cr_(2)O_(3)含量对7050铝合金微弧氧化陶瓷膜组织和性能的影响。结果表明:添加纳米Cr_(2)O_(3)能减小陶瓷膜孔径,提升致密度,优化陶瓷膜结构;当纳米Cr_(2)O_(3)由1 g/L增至5 g/L时,陶瓷膜的厚度、硬度均先增后减;与未添加相比,添加纳米Cr_(2)O_(3)的陶瓷膜的耐蚀性和耐磨性均明显提升;陶瓷膜主要由γ-Al_(2)O_(3)相和少量的α-Al_(2)O_(3)相、莫来石相、Cr_(2)O_(3)相构成;总体来看,当纳米Cr_(2)O_(3)为3 g/L时,陶瓷膜的性能最优,厚度、显微硬度、自腐蚀电流和磨耗比分别为30.98μm、1273HV0.1、5.162×10^(-8)A/cm^(2)、0.0913%。

铝酸盐体系中氧化时间对碳化硅颗粒增强铝基复合材料微弧氧化膜层的影响

[目的]探究氧化时间对碳化硅颗粒增强铝基(SiC_(p)/Al)复合材料微弧氧化膜层的影响。[方法]选用铝酸盐体系作为电解液,对SiC_(p)/Al复合材料进行微弧氧化处理,分析氧化时间对膜层组织结构、物相、厚度、粗糙度、结合力、电绝缘性及耐蚀性的影响。[结果]随着氧化时间延长,膜层逐渐变得连续均匀,厚度增加。若氧化时间过长,膜层会出现层叠现象,形成大尺寸微孔及裂纹,且生长速率越来越低。膜层结合力随氧化时间延长先增大后减小,在60 min时最大,达到39.85 N。氧化时间为10 min时,膜层的电绝缘性及耐蚀性最优,100 V和500 V电压下的绝缘电阻分别达到3.11×10^(12)Ω和1.41×10^(12)Ω,腐蚀电位为-0.6298 V,腐蚀电流密度为1.332×10^(-7)A/cm^(2)。[结论]SiC_(p)/Al复合材料表面微弧氧化膜层的连续性、均匀性及生长速率均与氧化时间有关。需选择合适的氧化时间,才能制备出连续、均匀且综合性能优异的膜层。

膜层厚度对6061铝合金黑色微弧氧化陶瓷膜层结构与性能的影响

为了明确膜层厚度对铝合金黑色微弧氧化陶瓷膜层的黑度、耐蚀性和硬度的影响规律,促进其实际应用,在硅酸盐-钒酸盐复合溶液体系中对6061铝合金进行微弧氧化处理,通过控制微弧氧化时间获得具有不同膜层厚度的铝合金黑色陶瓷膜层。利用测厚仪、粗糙度测量仪、SEM和EDS对黑色陶瓷膜层的表面结构、膜层成分和粗糙度等进行表征,并借助色差仪、维氏硬度计和电化学工作站等研究了膜层厚度对陶瓷膜层的黑度、显微硬度和耐蚀性的影响。结果表明:膜层厚度对黑色陶瓷膜层的表面形貌、粗糙度、显色特性、硬度和耐蚀性有较大影响。随着微弧氧化时间延长,膜层厚度增加,膜层表面更为粗糙,表层放电微孔数量减少,放电微孔孔径增大;当膜厚达到30.786μm时,陶瓷膜层的放电微孔显著增大,孔径达到10μm。随着膜层厚度增加,陶瓷膜层的黑度增加,显微硬度提高,但耐蚀性先增强后降低。当膜层厚度为20.781μm时,陶瓷膜层的黑度和硬度较高,耐蚀性最好,其在3.5%NaCl溶液中的自腐蚀电流密度为1.093×10^(-6) A/cm^(2)。

冷等离子体和微量润滑复合微铣削铝锂合金的表面性能研究

铝锂合金的延展性造成材料对刀具的粘附,会导致毛刺和积屑瘤等问题产生。为此,采用冷等离子体和微量润滑复合微铣削的方法加工铝锂合金,研究了工件的表面性能,并与单纯的干式、冷等离子体和微量润滑方法进行了对比。结果表明冷等离子体不仅改善了纳米流体在工件表面的浸润性,而且提高了材料的去除效率;相比于单纯的干式、冷等离子体和微量润滑方法,冷等离子体和微量润滑复合条件下的微铣削力分别降低了52.9%、42.9%和17.5%,而三维表面粗糙度Sa分别降低了67.3%、44.8%和33.3%。

硫铝酸盐水泥水化产物-铝凝胶的研究进展

硫铝酸盐水泥作为我国第三系列水泥,既是一种低碳绿色水泥,又是一种海工修补加固水泥。铝凝胶(AH_(3))是其最重要的水化产物之一,可有效提升该系列水泥石的宏观力学性能。本文结合化工中AH_(3)的基础研究,阐述了硫铝酸盐水泥石中AH_(3)的形成过程,归纳了AH_(3)的一般性特征,对比了化工中AH_(3)与硫铝酸盐水泥石中AH_(3)的异同点,具体分析了各类因素对AH_(3)微纳结构及含量的影响,总结了目前AH_(3)研究的不足之处,提出了未来研究的方向和思路。

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。

阳极氧化膜和微弧氧化膜对5A06铝合金海水腐蚀及力学性能的影响

[目的]研究氧化膜对5A06铝合金海水腐蚀与力学性能的影响。[方法]通过海水浸泡腐蚀试验和应力腐蚀试验,考察了阳极氧化和微弧氧化处理后的铝合金在海水环境中的腐蚀行为和力学性能的变化。[结果]在海水环境下,5A06铝合金及其氧化膜的腐蚀形式以点蚀为主,微弧氧化膜和阳极氧化膜具有良好的耐蚀性。动电位极化曲线和电化学阻抗谱测试结果显示,5A06铝合金裸试样、阳极氧化膜试样和微弧氧化膜试样,在为期30 d的海水浸泡试验后腐蚀电位均发生了明显负移,腐蚀电流密度和维钝电流密度均增大,电荷转移阻抗均减小,表明试样耐蚀性有所下降,其中微弧氧化膜的腐蚀电流密度和维钝电流密度最小,电荷转移阻抗最大,表明微弧氧化膜的耐蚀性高于铝合金及其阳极氧化膜。应力应变测试结果和微观断口形貌显示,相比于阳极氧化试样,应力腐蚀试验后微弧氧化试样的断后伸长损失率和断面收缩损失率均较小,分别为13.79%和6.72%,表明其塑性和韧性较好。[结论]在应力及海水腐蚀介质的耦合作用下,5A06铝合金的耐蚀性和力学性能出现一定程度的下降,微弧氧化和阳极氧化膜都可以提高5A06铝合金的耐蚀性,其中微弧氧化膜的耐蚀性和力学性能更优异。

CeO_(2)颗粒对7075铝合金微弧氧化膜生长行为及耐磨/耐蚀性能的影响

目的通过CeO_(2)颗粒复合,进一步改善铝合金微弧氧化膜的耐磨和耐蚀性能。方法在硅酸盐-磷酸盐电解液体系中加入CeO_(2)颗粒,利用微弧氧化技术在7075-T6铝合金表面制备CeO_(2)颗粒复合氧化膜;从氧化电压、放电行为及膜层厚度的变化规律探讨CeO_(2)颗粒含量对微弧氧化膜生长过程的影响;通过扫描电子显微镜、动电位极化曲线、球-盘磨损试验等研究电解液中CeO_(2)颗粒浓度对微弧氧化膜微观结构、耐磨性能和耐蚀性能的影响。结果通过CeO_(2)颗粒的复合,改变了铝合金微弧氧化成膜过程的能耗分布,加速了微弧氧化膜的放电击穿。CeO_(2)颗粒复合会使膜层的生长速率有所下降,但氧化膜的致密性、均匀性及膜基的结合强度得到明显改善。CeO_(2)颗粒主要以熔融和嵌合等方式存在于氧化膜中。相较于普通微弧氧化膜,复合膜的摩擦因数普遍降低了约0.2,比磨损率也更低,耐磨性更佳。此外,复合膜呈现出更好的耐腐蚀性,其自腐蚀电流密度至少下降了50%,且在模拟海水中浸泡2000 h后腐蚀增重更小、腐蚀更轻微。在电解液中加入10 g/L的CeO_(2)颗粒时,所得复合膜的综合性能较佳。结论CeO_(2)颗粒复合以熔融或嵌合的方式沉积到铝合金微弧氧化膜中,有效减少了膜层的微孔等缺陷,提高了膜层的致密性和硬度,改善了膜层的耐蚀性和耐磨性。

铝合金微弧氧化复合电解液的优化研究

为了得到成膜性和耐磨性良好且较厚的陶瓷膜层,以磷酸钠和六偏磷酸钠为基础电解液,同时加入钨酸钠和四硼酸钠作为添加剂,组成一种新型的复合电解液。在此复合电解液体系下,对1060铝合金进行微弧氧化处理。以膜层厚度和膜层表面孔隙率为优化指标,利用L_(9)(3^(4))正交试验优化电解液配方,研究了在此电解液配方下制备出的陶瓷膜层的微观形貌、表面孔隙率、物相组成、厚度、显微硬度和耐磨性。结果表明:用磷酸钠浓度为32.0 g/L、四硼酸钠浓度为16.0 g/L、钨酸钠浓度为4.5 g/L、六偏磷酸钠为30.0 g/L的配方制备出的陶瓷层表面微孔均匀、膜层致密,陶瓷层厚度达22.8μm,膜层孔隙率为3.86%,显微硬度达475 HV,耐磨性较基体有较大幅度提升,陶瓷层主要由γ-Al_(2)O_(3)和少量α-Al_(2)O_(3)构成。

A356铝合金微弧氧化黑色膜层的制备及耐蚀性

[目的]在Na_(2)SiO_(3)-Na_(3)PO_(4)复合电解液中研究着色盐Na_(2)WO_(4)的质量浓度对A356铝合金表面微弧氧化膜层结构和性能的影响。[方法]采用比例分割分批试验设计方法优选出Na_(2)WO_(4)的添加方案。利用色差宝、涡流测厚仪、扫描电镜(SEM)、能谱仪(EDS)和X射线衍射仪(XRD),分别对膜层的颜色、厚度、微观形貌、元素分布和物相组成进行表征。膜层的耐蚀性通过硝酸点滴腐蚀试验和在3.5%NaCl溶液中测量动电位极化曲线来检测。[结果]随着电解液中Na_(2)WO_(4)的质量浓度增大,所得膜层的颜色逐渐加深,添加22.05 g/L Na_(2)WO_(4)时所得膜层颜色最深,而添加19.98 g/L Na_(2)WO_(4)时所得膜层的耐蚀性最佳。[结论]在基础电解液中加入着色盐Na_(2)WO_(4)后,膜层中沉积出使膜层显深色的钨氧化物,令膜层颜色加深,并提高了膜层的致密性和耐蚀性。

利用机械臂制备的微弧氧化陶瓷涂层的相关性能研究

为解决目前微弧氧化(MAO)体系在实际应用中所面临的问题,例如对大尺寸工件表面的难以处理和对工件局部区域进行MAO的精确调控存在挑战,利用机械臂设计了移动式MAO系统,对1060铝合金表面进行MAO处理成功制备了陶瓷涂层,并通过扫描电镜、X射线衍射、摩擦磨损试验和电化学腐蚀试验等手段,对涂层的微观结构、成分、耐磨性和耐腐蚀性进行了分析。结果表明,基于机械臂辅助的移动式MAO技术能够成功在铝合金表面制备陶瓷涂层,并有效提高了铝合金的耐磨性和耐腐蚀性。这项研究为基于机械臂的移动式MAO技术在铝合金表面制备高性能陶瓷涂层方面提供了重要的理论依据和试验基础。

不同复盐电解液中NaVO_(3)对铝合金微弧氧化热控膜层结构和性能影响的对比研究

目的在以Na_(2)SiO_(3)为主导的Na_(2)SiO_(3)-Na_(3)PO_(4)复盐电解液和以Na_(3)PO_(4)为主导的Na_(3)PO_(4)-Na_(2)SiO_(3)复盐电解液中加入相同浓度梯度的NaVO_(3),研究着色盐NaVO_(3)对微弧氧化膜层结构的影响,分析膜层的黑度、热控性能、耐蚀性和结合力的变化。方法在A356铝合金表面制备微弧氧化膜层,采用比例分割分批法设计试验。利用ColorReader、涡流测厚仪、SEM、EPMA、EDS、LSCM、XRD、辐射计、太阳光谱反射计,分别表征膜层的颜色、厚度、微观形貌、元素分布、表面粗糙度、物相组成、发射率和吸收率。采用电化学、点滴及盐雾等实验检测膜层耐蚀性,采用热震实验检测结合力。结果在2种复盐电解液中,当NaVO_(3)的质量浓度均为12.06 g/L时,所得膜层颜色最深,且Na_(3)PO_(4)主盐系的颜色更深,其黑度值可低至20.31;热控性能最佳,吸收率和发射率分别高达0.934、0.888;加入着色盐NaVO_(3)后,微弧氧化膜表面出现了自封孔现象,对提高膜层耐蚀性很有利,Na_(3)PO_(4)主盐系膜层的耐蚀性优于Na_(2)SiO_(3)主盐系的,而且也是当NaVO_(3)的质量浓度为12.06 g/L时,膜层的耐蚀性最好;此时,Na_(3)PO_(4)主盐系膜层抗热冲击的次数可高达65。结论在2种复盐电解液中加入着色盐NaVO_(3)后,沉积出了使膜层显深色的钒氧化物。当NaVO_(3)的质量浓度为12.06 g/L时,在各自体系中均可获得同时具有优良耐蚀性、良好结合力、高吸收率、高发射率的热控膜层,且Na_(3)PO_(4)主盐系膜层的性能略高一筹。