ISSN   1004-0595

CN  62-1224/O4

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NP油溶性离子液体添加剂的制备及其结构对摩擦学性能影响

Preparation and Effect of Structure on Tribological Properties of NP Oil-Soluble Ionic Liquid Additive

  • 摘要: 制备了2种新的磷酸季铵离子液体N22216P和N12121216P,研究了这2种离子液体(ILs)的溶解性能、黏温性能、热稳定性能和防腐性能,探究了室温和高温下它们作为PAO10润滑添加剂的摩擦学性能,并分析了ILs的结构对其润滑性能的影响. 结果发现,质量分数为1%的N22216P和N12121216P表现出比1%商业添加剂T204更优异的润滑性能. 根据电接触电阻、石英晶体微天平测量、能谱和X射线光电子能谱表征结果,推测这2种ILs在摩擦过程中易吸附在基底表面形成吸附膜,这有助于在钢表面发生摩擦化学反应形成摩擦保护膜,从而起到减摩抗磨作用. 此外,还发现:室温和高温润滑下,具有较低空间位阻结构的ILs更易吸附在基底上形成更致密的吸附膜并进一步在钢表面发生反应形成更多的含有抗磨化合物的更致密的润滑膜,因此,空间位阻较小的N22216P具有更优异的润滑性能,这表明ILs作为基础油添加剂的润滑性能受空间位阻结构的影响.

     

    Abstract: Two ammonium phosphate ionic liquids, N.N-Tridodecyl-N-hexadecyldi(2-ethylhexyl) ammonium phosphate (N22216P) and N.N-triethyl-N-hexadecyl di(2-ethylhexyl) ammonium phosphate (N12121216P) were prepared. The dissolution performance, the viscosity temperature performance, thermal stability performance and corrosion performance of two ionic liquids were evaluated in PAO10. The results indicated that the N22216P and N12121216P could be dissolved in base oil PAO10. And the viscosity temperature performance of both ionic liquids was better than that of PAO10. The thermal stability performance of 1% N22216P and 1%N12121216P was higher than that of PAO10 and 1% T204. These results showed that the viscosity temperature performance and thermal stability of ionic liquids were enhanced with the increase of alkyl chains. The addition of ionic liquids additives could reduce the corrosion of base oil on friction pairs. What’s more, the tribological properties of the N22216P and N12121216P as the additives of PAO10 were explored at room and high temperatures. The effect of alkyl chain structure of the prepared ionic liquids was studied on their lubrication performance. Compared with the commercial additive 1% T204, it was found that 1% N22216P and 1% N12121216P exhibited a better lubrication performance and abrasion resistance at room temperature and high temperature. The electrical contact resistance (ECR) measurement, energy dispersive spectrometer (EDS) measurement, Quartz Crystal Microbalance (QCM) measurement and X-ray photoelectron spectroscopy (XPS) measurement were carried out to understand the lubrication mechanism of two ionic liquids as additives more clearly. Based on these characterization results, it was speculated that these two ionic liquids were prone to adsorb on the substrate surface to form an adsorption film during the friction process. This helped to form a dense friction protective film on the steel surface through further frictional chemical reactions. This protective film effectively prevented the direct contact of sliding pairs and played an important role in reducing friction and anti-wear. In addition, the N22216P with lower steric hindrance structures were easier to adsorb on the substrate to form a denser adsorption film according to the results of the QCM. And further formed more dense lubrication films containing anti-wear compounds on the steel surface by the reactions. Thus, the N22216P with smaller steric hindrance had better lubrication performance than that of the N121216P. This indicated that the lubrication performance of ionic liquids as an additive was influenced by the steric hindrance structure. Therefore, so-prepared two ionic liquids (N22216P and N12121216P) with efficient tribological properties would improve the comprehensive performance of base oil to produce a cost-effective lubricant additive applied in oil-based fluid.

     

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