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终电压对铝合金Mo和V黑色微弧氧化膜形成过程的影响OA北大核心CSTPCD

Influence of Final Voltage on Formation Process of Black Micro-arc Oxidation Coating on Aluminum Alloy with Mo and V

中文摘要英文摘要

目的 以钼酸盐和钒酸盐为着色剂,探究终电压对黑色微弧氧化膜形成过程的影响.方法 在六偏磷酸钠和硅酸钠的微弧氧化体系中,添加NH4VO3和Na2MoO4 作为着色剂,在清洁的 6063 铝合金表面获得不同终电压下的微弧氧化膜,通过SEM、XRD、XPS分析膜层的形貌、结构和成分,通过色差仪和紫外可见分光光度计表征膜层的颜色特性和吸光率,通过极化曲线和电化学阻抗谱分析膜层的电化学性能.结果 膜层的主要成分为O、Al、P、Si、Mo、V,其中Mo、V以MoO3、MoO2、V2O5、V2O3 的形式存在.当终电压从350 V提高至550 V时,微弧氧化膜层的微孔变得少而大,颜色由褐色逐渐变为黑色,L从65.01减小到22.63,对可见光(波长250~800 nm)的吸收率从69.4%增至96.5%以上,膜层厚度和粗糙度从4.00、0.55 μm分别增至 35.00、2.41 μm,自腐蚀电流密度降至1.48×10-6 A/cm2,自腐蚀电位(vs.SCE)正移至-0.07 V,阻抗值大幅提高,达到2.48×105 Ω·cm2.结论 NH4VO3、Na2MoO4 是铝合金黑色微弧氧化的有效着色剂,反应生成的V2O5、V2O3、MoO3、MoO2是膜层呈现黑色的根本原因,随着终电压的升高,膜层吸光率和耐蚀性均提高,氧化膜的完整性对膜层性能的影响显著.

NH4VO3 and Na2MoO4 were chosen as colorants to investigate the influence of different final voltages on properties of black micro-arc oxidation coatings on aluminum alloys,and the formation process of the coatings.In the micro-arc oxidation system of sodium hexametaphosphate and sodium silicate,NH4VO3 and Na2MoO4 were added as colorants to obtain micro-arc oxidation films on the clean surface of 6063 aluminum alloy at different final voltages(350,400,450,500,550 V),with micro-arc oxidation electrical parameters set as constant current mode,with a current density of 10 A/dm2,frequency of 800 Hz,and a duty cycle of 10%.The morphology,structure,and composition of the coatings were analyzed by SEM,XRD,and XPS.The roughness and thickness of micro-arc oxidation coatings were conducted with a white light interferometer and a thickness gauge.The color characteristics and absorbance of the coatings were characterized with a colorimeter and a UV-visible spectrophotometer,and the electrochemical properties of the coatings were analyzed by polarization curves and electrochemical impedance spectroscopy.The crystallinity of the micro-arc oxidation coating was relatively low.The main components of the coating were O,Al,P,Si,Mo and V,with Mo and V existed as MoO3,MoO2,V2O5 and V2O3.The micro-arc oxidation coatings at different final voltage tightly bonded with the substrate,there were no obvious cracks between the coating and the substrate.As the final voltage increased from 350 V to 550 V,the micro-arc oxidation coating underwent remelting,the surface discharge channels on the coating transited from small and dense to large and sparse.And the average pore size increased from(0.82±0.64)μm to(2.58±1.8)μm.The color of the micro-arc oxidation coatings changed gradually from brown to black,the L value decreased from 65.01 to 22.63,the light absorption for visible light(wavelength 250-800 nm)increased from 69.4%to over 96.5%.The thickness and roughness of the coatings increased from 4.00 μm and 0.55 μm to 35.00 μm and 2.41 μm,respectively.With the increase of the final voltage of micro-arc oxidation,the corrosion resistance of the coating was significantly enhanced.The coating prepared at a final voltage of 550 V exhibited optimal corrosion resistance.The self-corrosion current density decreased to 1.48×10-6 A/cm2,the self-corrosion potential relative to the substrate increased from-0.84 V to-0.07 V,and the impedance increased to 2.48×105 Ω·cm2.NH4VO3 and Na2MoO4 were effective coloring agents for black micro-arc oxidation of aluminum alloys.In the process of micro-arc oxidation,the reaction of NH4VO3 and Na2MoO4 in the plating solution under the action of a strong electric field generated V2O5,V2O3,MoO3,and MoO2,which had their own color characteristics.Under the combined action of the generated substances,the micro-arc oxidation coating became black.The increase in final voltage promoted the accumulation of coloring components in the coating,thus enhancing the blackness of the membrane.With the increase of final voltage,both the light absorption performance and corrosion resistance of the coating were significantly enhanced.

刘圆敬;刘丹;单大勇;韩恩厚

广东腐蚀科学与技术创新研究院,广州 510530

金属材料

铝合金黑色微弧氧化耐蚀性着色机理吸光率电化学

aluminum alloyblack micro-arc oxidationcorrosion resistancecoloration mechanismabsorbanceelectrochemistry

《表面技术》 2024 (009)

34-42 / 9

广州市基础研究计划(SL2022A04J00598) Guangzhou Basic Research Program(SL2022A04J00598)

10.16490/j.cnki.issn.1001-3660.2024.09.004

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