Rheological Characteristics of Surfactant-Based Fluids: A Comprehensive Study

Volume 7: Fluids Engineering Pub Date : 2018-11-09 DOI:10.1115/IMECE2018-86044

A. Kamel

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Abstract

Surfactant-based fluids, SB fluids exhibit complex rheological behavior due to substantial structural change caused by the molecules self-assembled colloidal aggregation. Various factors affect their rheological properties. Among these factors, surfactant concentration, shear rate, temperature, and salinity are investigated. One of the most popular surfactants, Aromox® APA-T viscoelastic surfactant (VES) is examined. The study focuses on four different concentrations (1.5%, 2%, 3%, and 4%) over a shear rate ranging from 0.0526 sec−1 to 1944 sec−1 using Bohlin rheometer. For salinity effects, two brine solutions are used; 2 and 4% KCl while for temperature effects, a wide range from ambient temperature of 72°F up to 200°F is covered. The results show that SB fluids exhibit a complex rheological behavior due to its unique nature and the various structures form in the solution. In general, SB fluids at all concentrations exhibit a non-Newtonian pseudo-plastic shear thinning behavior. As the surfactant concentration and/or shear increases, a stronger shear thinning behavior can be seen. Increasing solution salinity promotes formation of rod-like micelles and increases its flexibility. Salinity affects micelles’ growth and their rheological behavior is very sensitive to the nature and structure of the added salt. Different molecular structures are formed; spherical micelles occur first and then increased shear rate and/or salinity promotes the formation of rod-like micelles. Later, rod-like micelles are aligned in the flow direction and form a large super ordered structure of micellar bundles or aggregates called shear induced structure (SIS). Different structures implies different rheological properties. Likewise, rheology improves with increasing temperature up to 100°F. Further increase in temperature reverses the effects and viscosity decreases. However, the effects of temperature and salinity diminish at higher shear rates. Furthermore, a rheology master curve is developed to further understand the rheological behavior of SB fluids and correlate rheological properties to its microscopic structure.

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表面活性剂基流体流变特性的综合研究

基于表面活性剂的SB流体表现出复杂的流变行为，这是由于分子自组装的胶体聚集引起的实质性结构变化。影响其流变性能的因素很多。其中，表面活性剂浓度、剪切速率、温度和矿化度是影响因素。最流行的表面活性剂之一，Aromox®APA-T粘弹性表面活性剂(VES)进行了研究。使用Bohlin流变仪，研究了四种不同的浓度(1.5%、2%、3%和4%)，剪切速率范围为0.0526 sec - 1至1944 sec - 1。对于盐度效应，使用两种盐水溶液;2和4% KCl，而对于温度影响，从环境温度72°F到200°F的范围很广。结果表明，SB流体由于其独特的性质和在溶液中形成的各种结构而表现出复杂的流变行为。总的来说，所有浓度的SB流体都表现出非牛顿的伪塑性剪切变薄行为。随着表面活性剂浓度和/或剪切力的增加，可以看到更强的剪切变薄行为。增加溶液盐度促进棒状胶束的形成，并增加其柔韧性。盐度影响胶束的生长，其流变行为对添加盐的性质和结构非常敏感。形成了不同的分子结构;球状胶束首先形成，然后增加剪切速率和/或盐度促进棒状胶束的形成。随后，棒状胶束沿流动方向排列，形成胶束束或聚集体的大型超有序结构，称为剪切诱导结构(shear induced structure, SIS)。不同的结构意味着不同的流变性能。同样，当温度升高至100°F时，流变性也会改善。温度的进一步升高逆转了这种影响，粘度下降。然而，温度和盐度的影响在较高的剪切速率下减弱。此外，建立了流变主曲线，进一步了解SB流体的流变行为，并将流变特性与其微观结构联系起来。

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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Volume 7: Fluids Engineering

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