Influence of physico-chemical parameters of surface-active systems components for minimization of evaporation of hydrocarbon liquids

Catalysis and Petrochemistry Pub Date : 2021-01-01 DOI:10.15407/kataliz2021.31.084

O. Spaska, AV.L. Chumak, M. Maksymyuk, V. Rudenko, O.I. Kosenko, E. V. Polunkin, O.O. Gaidai

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Abstract

Highly efficient stable aerated hydrophilic compositions containing fluorotensides and ultralight microdisperse systems using gas-filled glass, aluminosilicate and polymer microspheres have been developed. Designing the compositions of PAS based on the surface activity of surfactants, their solubility in water and the ability to bind water and the formation of hydrogen bonds between the components. The main condition for the stability of the coating when mixing the components - the chemical interaction between them and the formation of a system that does not dissolve in hydrocarbons and does not break down in terms of use. The best film-forming characteristics necessary for the operation of the coating (simultaneous reduction of surface tension and film formation) active substances (FPAR), the non-polar part of the molecules of which contains a fluorocarbon chain, so they are insoluble in hydrocarbons, well soluble in water and easily distributed on the surface of hydrocarbon liquids, creating a protective film. The choice of co-surfactants was based on the ability to stabilize hydrophilic films on the surface of hydrocarbons not only at favorable HLB, but also at the lowest, although higher than the critical concentration of micelle formation (CCM), concentrations for forming a mixed adsorption layer of increased strength. This surfactant was water-oil-soluble twin-80, which will significantly increase the hydrophilic part and enhance the stability of the PAS and the stability of the aerated system. The introduction of glass microspheres into the components of the system has significantly enhanced its strength and stability. In the study of the stability and gas permeability of the developed surfactant systems, it was found that the insulating ability of the coating increases with increasing hydrophilic-lipophilic balance of the system and due to chemical interaction between the carboxyl group of fluorotenside and hydroxyl groups of surfactants.

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表面活性体系组分理化参数对减少烃类液体蒸发的影响

高效稳定的含氟张醛的曝气亲水组合物和使用充气玻璃、硅酸铝和聚合物微球的超轻微分散系统已经开发出来。根据表面活性剂的表面活性、在水中的溶解度、与水的结合能力以及组分之间形成氢键的能力来设计PAS的组成。当混合组分时，涂层稳定性的主要条件-它们之间的化学相互作用以及形成不溶于碳氢化合物且在使用中不分解的系统。涂层运行所需的最佳成膜特性(同时降低表面张力和成膜)活性物质(FPAR)，其分子的非极性部分含有碳氟化合物链，因此不溶于碳氢化合物，溶于水好，易于分布在碳氢化合物液体表面，形成保护膜。助表面活性剂的选择是基于稳定碳氢化合物表面亲水性膜的能力，不仅在有利的HLB下，而且在最低(尽管高于胶束形成的临界浓度)下，形成混合吸附层的浓度增加了强度。该表面活性剂为水-油溶性twin-80，将显著增加PAS的亲水性部分，增强PAS的稳定性和加气体系的稳定性。在系统组件中引入玻璃微球，大大提高了系统的强度和稳定性。在对所开发的表面活性剂体系的稳定性和透气性的研究中，发现涂层的绝缘能力随着体系亲水性-亲脂性平衡的增加以及氟张苷的羧基与表面活性剂的羟基之间的化学相互作用而增加。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Catalysis and Petrochemistry

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