油相对水相泡沫形成和稳定性的影响

doi:10.3969/j.issn.2097-2806.2024.06.002

摘要/Abstract

摘要：

油水混相泡沫在日用化妆品、化学工业、石油工业等领域有着广泛的应用，但是目前关于油水混相泡沫的报道多集中在探究表面活性剂、温度、pH、矿化度等外界因素对油水混相泡沫的稳定性的影响，对于油相种类和油相含量对水相泡沫的形成和稳定性影响机制缺乏系统研究。文章通过改变油相种类、油水体积比进行发泡实验，最后通过分析各泡沫体积、泡沫排液半衰期、泡沫的衰变速率、泡沫的微观粒径、油相的表面张力和油水界面张力来探究油相对水相泡沫的形成和稳定性影响机制。研究发现：随着油相碳链长度的增加水相泡沫的起泡性能下降；同时随着油相的表面张力增大，泡沫稳定性提高；油水体积比对水相泡沫的形成和稳定性有着重要的影响，在低油水体积比时，泡沫壁之间排列紧密，形成了大小不一的泡沫，且由于泡沫之间相互挤压，使其微观结构形貌杂乱无规则；随着油水体积比的升高泡沫粒径整体上变小，且大小变得越来越均匀，泡沫结构变得更加致密，使得泡沫更加稳定。

关键词: 油水混相泡沫, 油相种类, 油相含量, 形成, 稳定性

Abstract:

Oil-water miscible foams have been widely used in daily cosmetics, chemical industry, petroleum industry, etc., but the current reports on oil-water miscible foams mostly focus on the influences of external factors such as surfactants, temperature, pH and salinity on the stability of oil-water miscible foams. The effects of oil type and oil content on the formation and stability of aqueous foams have not been systematically studied. In this work, foaming experiments were conducted by changing the oil type and oil-water volume ratio. The formation and stability mechanisms of aqueous foam influencing by oil were explored by analyzing the foam volume, the half-life of foam drainage, the decay rate of foam, the microscopic particle size of foam, the surface tension of oil phase and the oil-water interfacial tension. The results were as follows: with the increase of carbon chain length of oil, the foaming property of aqueous foam was decreased; the foam stability increased with the increase of surface tension of oil; the oil-water volume ratio had important influence on the formation and stability of aqueous foam. At low oil-water volume ratio, foam lamellas were arranged closely, forming bubbles of different size. Moreover, due to the mutual extrusion between the bubbles, the microstructure morphology was chaotic and irregular. With the increase of oil-water volume ratio, the foam particle size became smaller and more uniform, and the foam structure became denser, making the foam more stable.

Key words: oil-water miscible foam, oil type, oil content, formation, stability

中图分类号:

O648.2

白凡, 燕永利, 刘江波, 严阿勇, 贺炳成. 油相对水相泡沫形成和稳定性的影响[J]. 日用化学工业（中英文）, 2024, 54(6): 630-639.

Fan Bai, Yongli Yan, Jiangbo Liu, Ayong Yan, Bingcheng He. Effects of oil on the formation and stability of aqueous foam[J]. China Surfactant Detergent & Cosmetics, 2024, 54(6): 630-639.

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参考文献 28

[1]	Weaire D L, Hutzler S. The physics of foams[M]. Oxford: Oxford University Press, 1999.
[2]	Wang Mengmeng, Guo Donghong. Foaming properties of foams and its influencing factors[J]. Advances in the Petrochiemicals, 2007, 8 (12) : 40-47.
[3]	Mensire R, Lorenceau E. Stable oil-laden foams: Formation and evolution[J]. Advances in Colloid and Interface Science, 2017, 247: 465-476. doi: S0001-8686(17)30222-1 pmid: 28821347
[4]	Buhl T F, Christensen C H, Hammershøj M. Aquafaba as an egg white substitute in food foams and emulsions: Protein composition and functional behavior[J]. Food Hydrocolloids, 2019, 96: 354-364.
[5]	Yu X, Jiang N, Miao X, et al. Comparative studies on foam stability, oil-film interaction and fire extinguishing performance for fluorine-free and fluorinated foams[J]. Process Safety and Environmental Protection, 2020, 133: 201-215.
[6]	Parsa M, Trybala A, Malik D J, et al. Foam in pharmaceutical and medical applications[J]. Current Opinion in Colloid & Interface Science, 2019, 44: 153-167.
[7]	Fameau A L, Saint-Jalmes A. Non-aqueous foams: current understanding on the formation and stability mechanisms[J]. Advances in Colloid and Interface Science, 2017, 247: 454-464.
[8]	Farajzadeh R, Andrianov A, Krastev R, et al. Foam-oil interaction in porous media: implications for foam assisted enhanced oil recovery[J]. Advances in Colloid and Interface Science, 2012, 183-184: 1-13.
[9]	Mannhardt K, Novosad J, Schramm L. Comparative evaluation of foam stability to oil[J]. SPE Reservoir Evaluation & Engineering, 2000, 3 (1) : 23-34.
[10]	Pu W, Wei P, Sun L, et al. Investigation on stabilization of foam in the presence of crude oil for improved oil recovery[J]. Journal of Dispersion Science and Technology, 2019, 40 (5) : 646-656.
[11]	Lee J, Nikolov A, Wasan D. Surfactant micelles containing solubilized oil decrease foam film thickness stability[J]. Journal of Colloid and Interface Science, 2014, 415: 18-25. doi: 10.1016/j.jcis.2013.10.014 pmid: 24267325
[12]	Wang Hongtao, Feng Lijuan, He Meng, et al. Synthesis and properties of polyoxyethylene ether naphthalene blowing agents with different alkyl chain lengths[J]. Chinese Science Bulletin, 2016, 3 (1) :1-10.
[13]	Pu W, Jiang R, Pang S, et al. Experimental investigation of surfactant-stabilized foam stability in the presence of light oil[J]. Journal of Dispersion Science and Technology, 2020, 41 (11) : 1596-1606.
[14]	Hussain A, Vincent-Bonnieu S, Bahrim R K, et al. The impacts of solubilized and dispersed crude oil on foam in a porous medium[J]. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2019, 579: 123671.
[15]	Piroird K, Lorenceau E, Biance A L. Oil repartition in a foam film architecture[J]. Soft Matter, 2014, 10 (36) : 7061-7067. doi: 10.1039/c4sm00538d pmid: 24975425
[16]	Simjoo M, Rezaei T, Andrianov A, et al. Foam stability in the presence of oil: Effect of surfactant concentration and oil type[J]. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2013, 438: 148-158.
[17]	Wang C, Fang H, Gong Q, et al. Roles of catanionic surfactant mixtures on the stability of foams in the presence of oil[J]. Energy & Fuels, 2016, 30 (8) : 6355-6364.
[18]	Wang Jiexiang, Han Lei, Li Songyan, et al. Current situation and prospect of foam fluid application in oilfield[J]. Applied Chemical Industry, 2012, 41 (8) : 1408-1411.
[19]	Harkins W D. A general thermodynamic theory of the spreading of liquids to form duplex films and of liquids or solids to form monolayers[J]. The Journal of Chemical Physics, 1941, 9 (7) : 552-568.
[20]	Aveyard R, Binks B, Fletcher P, et al. Aspects of aqueous foam stability in the presence of hydrocarbon oils and solid particles[J]. Advances in Colloid and Interface Science, 1994, 48: 93-120.
[21]	Wei P, Pu W, Sun L, et al. Oil recovery enhancement in low permeable and severe heterogeneous oil reservoirs via gas and foam flooding[J]. Journal of Petroleum Science and Engineering, 2018, 163: 340-348.
[22]	Wang J, Nguyen A V, Farrokhpay S. A critical review of the growth, drainage and collapse of foams[J]. Advances in Colloid and Interface Science, 2016, 228: 55-70. doi: 10.1016/j.cis.2015.11.009 pmid: 26718078
[23]	Rashed Rohani M, Ghotbi C, Badakhshan A. Foam stability and foam-oil interactions[J]. Petroleum Science and Technology, 2014, 32 (15) : 1843-1850.
[24]	Arnaudov L, Denkov N D, Surcheva I, et al. Effect of oily additives on foamability and foam stability. 1. Role of interfacial properties[J]. Langmuir, 2001, 17 (22) : 6999-7010.
[25]	Jia Xinggang, Yan Yongli, Qu Chengtun, et al. Research progress on the mechanism of crude oil stabilizing aqueous foam[J]. China Surfactant Detergent & Cosmetics, 2010, 40 (1) : 54-59.
[26]	Kusaka A, Sonoda J, Tajima H, et al. Dynamics of liquid oil that flows inside aqueous wet foam[J]. The Journal of Physical Chemistry B, 2018, 122 (42) : 9786-9791.
[27]	Chen J, He L, Luo X, et al. Foaming of crude oil: Effect of acidic components and saturation gas[J]. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2018, 553: 432-438.
[28]	Osei-Bonsu K, Shokri N, Grassia P. Foam stability in the presence and absence of hydrocarbons: From bubble-to bulk-scale[J]. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2015, 481: 514-526.