The Effect of Inclination on the Stability of Foam Systems in Drilling and Well Operations

IF 1.3 4区 工程技术 Q3 ENGINEERING, PETROLEUM
Abhishek Govindu, R. Ahmed, Subhash N. Shah, M. Amani
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引用次数: 7

Abstract

To minimize fluid loss and the associated formation damage, foam is a preferred fluid to perform cleanout operations and reestablish communication with an open completion interval. Because of their high viscosity and structure, foams are suitable cleanout fluids when underbalanced well-cleanout operations are applied. Although several studies have been conducted to better understand foam-flow behavior and hydraulics, investigations performed on foam stability are very limited. Specifically, very little is known regarding the impact of wellbore inclination on the stability of foams. Unstable foams do not possess high viscosity, and as a result, they are not effective in cleanout operations, especially in inclined wellbores. Predicting the downhole instability of foam could reduce the number of drilling problems associated with excessive liquid drainage, such as temporary overbalance, formation damage, and wellbore instability. The objectives of this study are to investigate the effects of wellbore inclination on the stability of various types of foams and develop a method to account for the effect of inclination on foam stability in inclined wells. In this study, foam-drainage experiments were performed using a flow loop that consists of a foam-drainage-measurement section and pipe viscometers. To verify proper foam generation, foam viscosity was measured using pipe viscometers and compared with previous measurements. Drainage experiments were performed with aqueous, polymer-based, and oil-based foams in concentric annulus and pipe under pressurized conditions. Tests were also conducted in vertical and inclined orientations to examine the effect of wellbore inclination on the stability of foams. The foam-bubble structure was examined and monitored in real time using a microscopic camera to study bubble coarsening. The foam quality (i.e., gas volume fraction) was varied from 40 to 80%. Results show that the drainage rates in the pipe and annular section were approximately the same, indicating a minor effect of column geometry. More importantly, the drainage rate of foam in an inclined configuration was significantly higher than that observed in a vertical orientation. The inclination exacerbated foam drainage and instability substantially. The mechanisms of foam drainage are different in an inclined configuration. In inclined wellbores, drainage occurs not only axially but also laterally. As a result, the drained liquid quickly reaches a wellbore wall before reaching the bottom of foam column. Then, a layer of liquid forms on the low side of the wellbore. The liquid layer flows downward because of gravity and reaches the bottom of the test section without facing the major hydraulic resistance of the foam network. This phenomenon aggravates the drainage process considerably. Although foam-drainage experiments have been reported in the literature, there exists only limited information on the effects of geometry and inclination on foam drainage and stability. The information provided in this paper will help to account for the effect of inclination on foam stability and subsequently improve the performance of oilfield operations involving foam as the working fluid.
井斜对钻井作业中泡沫体系稳定性的影响
为了最大限度地减少流体损失和相关的地层损害,泡沫是执行清理操作和与开放完井层段重新建立连通的首选流体。由于泡沫的高粘度和高结构,当应用欠平衡井清洗操作时,泡沫是合适的清洗液。尽管已经进行了几项研究来更好地了解泡沫的流动行为和水力学,但对泡沫稳定性的研究非常有限。具体而言,关于井筒倾角对泡沫稳定性的影响,目前知之甚少。不稳定泡沫不具有高粘度,因此,它们在清洗操作中无效,尤其是在倾斜井筒中。预测泡沫的井下不稳定性可以减少与过度排液相关的钻井问题的数量,如暂时失衡、地层损坏和井筒不稳定。本研究的目的是研究井筒倾角对各种类型泡沫稳定性的影响,并开发一种方法来解释倾斜井中倾角对泡沫稳定性的作用。在本研究中,使用由泡沫排水测量段和管道粘度计组成的流动回路进行泡沫排水实验。为了验证正确的泡沫生成,使用管道粘度计测量泡沫粘度,并与以前的测量结果进行比较。在加压条件下,在同心环空和管道中使用水性、聚合物基和油基泡沫进行排水实验。还进行了垂直和倾斜方向的测试,以检查井筒倾角对泡沫稳定性的影响。使用显微镜相机实时检查和监测泡沫气泡结构,以研究气泡粗化。泡沫质量(即气体体积分数)在40%至80%之间变化。结果表明,管道和环形截面的排水率大致相同,表明立柱几何形状的影响较小。更重要的是,在倾斜配置中的泡沫的排出速率显著高于在垂直方向中观察到的排出速率。倾斜大大加剧了泡沫的排出和不稳定性。在倾斜配置中,泡沫排出的机制是不同的。在倾斜井筒中,排水不仅在轴向发生,而且在横向发生。结果,排出的液体在到达泡沫柱底部之前迅速到达井筒壁。然后,在井筒的低侧形成一层液体。液体层由于重力而向下流动,并在不面对泡沫网络的主要水力阻力的情况下到达测试段的底部。这种现象大大加剧了排水过程。尽管文献中已经报道了泡沫排水实验,但关于几何形状和倾斜度对泡沫排水和稳定性的影响,信息有限。本文提供的信息将有助于解释倾斜度对泡沫稳定性的影响,从而提高以泡沫为工作流体的油田作业的性能。
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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来源期刊
SPE Drilling & Completion
SPE Drilling & Completion 工程技术-工程:石油
CiteScore
4.20
自引率
7.10%
发文量
29
审稿时长
6-12 weeks
期刊介绍: Covers horizontal and directional drilling, drilling fluids, bit technology, sand control, perforating, cementing, well control, completions and drilling operations.
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