ISSN   1004-0595

CN  62-1224/O4

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基于大豆基础油的聚多巴胺改性黑磷纳米添加剂的摩擦学性能研究

Tribological Properties of Polydopamine-Modified Black Phosphorus Nano-Additives Based on Soybean Oils

  • 摘要: 根据多巴胺在碱性环境下自聚合的特性,利用Tris缓冲液和NaOH提供的碱性环境下制备了黑磷/聚多巴胺(BP-PDA)纳米复合材料. 采用球盘摩擦试验仪以钢/钢为摩擦接触副,研究了BP-PDA作为大豆油润滑添加剂的摩擦学性能. 结果表明:添加了质量分数为0.16%的BP-PDA分散油,其摩擦系数和磨痕宽度相比于大豆油分别降低了约43%和52%. 通过对磨痕表面的成分和形貌特征的分析发现,在摩擦过程中的高接触压力和剪切作用下,大豆油与BP-PDA发生摩擦化学反应形成复合摩擦膜,其主要由非晶碳、BP以及磷的碳氧化物组成,复合膜的形成使得摩擦界面的摩擦磨损减小. 此外,对BP-PDA在大豆油中的分散情况进行了探究,发现其分散稳定性相比于BP,由7天提升到20天. 此研究为生物质润滑油中的添加剂设计提供了思路,为揭示BP纳米复合材料在生物质润滑油中的减摩抗磨机理提供了数据支持和理论指导.

     

    Abstract: Surface modification is an important way to improve the dispersion stability and lubrication performance of black phosphorus (BP) in lubricating base oils. In this paper, black phosphorus/polydopamine (BP-PDA) nanocomposites were prepared based on the self-polymerization of dopamine in an alkaline environment provided by Tris buffer and NaOH. The crystal structure, particle size distribution and physicochemical composition of the BP-PDA composites were systematically analyzed using atomic force microscopy (AFM), scanning electron microscopy (SEM), dynamic light scattering (DLS), X-ray diffraction (XRD), Raman spectroscopy (Raman) and X-ray photoelectron spectroscopy (XPS). In addition, the tribological and dispersive properties of BP-PDA in soybean oil were investigated using a UMT-TriboLabball-on-disk tribometer with steel/steel as the sliding contacting partner. The friction and wear mechanism of BP-PDA composites in soybean oil was emphasized. Firstly, the effect of additives on friction properties was investigated at different concentrations, and the results showed that the friction coefficient was found to increase and then decrease with the increase of concentration at a load of 10 N, a rotational speed of 200 r/min, and a temperature of 22~25 ℃. The optimum concentration was 0.16% by mass fraction. Next, it was explored that the addition of BP-PDA dispersed oil with a mass fraction of 0.16% reduced the friction coefficient and the width of the abrasion marks by about 43% and 52%, respectively, compared to soybean oil. Through the analysis of the morphology and composition of the friction products on the surface of the friction marks, it was found that during the sliding process, BP-PDA as an additive could catalyze and induce the generation of amorphous carbon films from soybean oil molecules under the action of high contact pressure and shear force as well as frictional heat. With the sliding process, the amorphous carbon film and other friction products form a composite tribo-film. The tribo-film is mainly composed of amorphous carbon, BP and PDA, and phosphorus oxides. The formation of the composite tribo-film avoided direct contact at the sliding interface, which resulted in reduced friction and wear. In addition, the dispersion of BP-PDA in soybean oil was investigated, and the dispersion stability of PDA modified BP was improved from 7 days to about 20 days compared with that of pure BP because of the presence of hydrogen-bonding groups in both PDA and soybean oil. This study provided ideas for the design of additives in biomass lubricants, and provided data support and theoretical guidance for revealing the friction-reducing and anti-wear mechanism of BP nanocomposites in biomass lubricants.

     

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