Acid stimulation is a widely used well treatment technique applied to enhance oil production by creating conductive channels through the formation, resulting an improved flow property. Viscoelastic surfactant (VES)-based acids have been employedfor acidizing jobs due to their ability to build up sufficient viscosity for acid diversion and fluid loss reduction, and to break into low viscosity after the treatment is completed. This work studied rheological properties of a new zwitterionic viscoelastic surfactant-based stimulation fluid. Impacts of many variables on the rheological characteristics of the VES-based live and spent acids were examined.Rheological experiments were conducted using a high pressure/high temperature (HPHT) viscometer. Viscosity measurements were performed between the temperatures of 78 to 350?F and shear rates of 10 to 935 s^-1 at 300 psi. Examined acid additives included: corrosion inhibitor, formic acid, methanol, demulsifier, H2S scavenger, iron control agents, and mutual solvent. As a contaminant, the effect of Fe(III) was investigated. In addition, the impacts of surfactant concentration, salt type and salt concentration on the viscosity of the VES-based acid systems were tested.Experimental results indicated that the new VES-based acid system exhibits a sufficient viscosity for acid diversion at temperatures up to 270?F. Contrary to spent acid blends, VES did not build up high viscosity in live acid. Apparent viscosity of the spent acid showed a strong relation with surfactant concentration, salt type and salt concentration. Corrosion inhibitor concentration above 0.5 vol% caused a notable loss in the viscosity as the temperature increased gradually. Dependency on methanol was strong enough that it resulted in a decline of the apparent viscosity of both live and spent acid solutions. Iron control agents (citric acid and EDTA) did not alter the viscous behavior notably. H2S scavenger showed a similar effect as iron control agents, while demulsifier and mutual solvent caused a reduction in the apparent viscosity. Fe(III) contamination caused fluctuations in the live acid viscosity due to generated VES-iron complex. In spent condition, this complex caused phase separation that resulted in loss of viscosity.This study showed that the new VES-based acid has the ability to build and maintain sufficient viscosity at higher temperatures than the currently used VES types. The acid system yielded higher tolerance to corrosion inhibitor than many other VES-based acids, and showed compatibility with a wide range of salt types. On the basis of the results obtained, optimum conditions to achieve the desired rheological profile for a successful well stimulation operation are presented.
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机译:酸增产是一种广泛使用的油井处理技术,通过在地层中形成导电通道来提高产油率,从而提高了采油率。基于粘弹性表面活性剂(VES)的酸已被用于酸化作业,因为它们能够建立足够的粘度以进行酸转移和减少流体损失,并在处理完成后分解为低粘度。这项工作研究了一种新型的基于两性离子粘弹性表面活性剂的增产液的流变性能。研究了许多变量对基于VES的活酸和废酸流变特性的影响。使用高压/高温(HPHT)粘度计进行了流变实验。在300 psi下,在78至350?F的温度和10至935 s ^ -1的剪切速率之间进行粘度测量。检查的酸添加剂包括:缓蚀剂,甲酸,甲醇,破乳剂,硫化氢清除剂,铁控制剂和互溶剂。作为污染物,研究了Fe(III)的作用。此外,还测试了表面活性剂浓度,盐类型和盐浓度对VES基酸体系粘度的影响。实验结果表明,新的VES基酸体系具有足够的粘度,可在高达270°C的温度下进行酸转移?F。与废酸共混物相反,VES在活酸中没有建立高粘度。废酸的表观粘度与表面活性剂浓度,盐类型和盐浓度密切相关。当温度逐渐升高时,腐蚀抑制剂的浓度超过0.5 vol%会导致粘度显着下降。对甲醇的依赖性足够强,以致导致活性和废酸溶液的表观粘度下降。控铁剂(柠檬酸和EDTA)没有显着改变粘性行为。 H2S清除剂显示出与铁控制剂相似的作用,而破乳剂和互溶剂导致表观粘度降低。由于生成的VES-铁络合物,Fe(III)污染导致活性酸粘度发生波动。在使用过的情况下,这种络合物会引起相分离,从而导致粘度损失。这项研究表明,新型VES基酸能够在比目前使用的VES类型更高的温度下建立并保持足够的粘度。与许多其他基于VES的酸相比,该酸体系对腐蚀抑制剂的耐受性更高,并且与多种盐类型兼容。根据获得的结果,提出了实现成功的增产作业所需的流变特性的最佳条件。
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