Experimental Study of Cuttings Transport with Non-Newtonian Fluid in an Inclined Well Using Visualization and Electrical Resistance Tomography Techniques

IF 1.3 4区 工程技术 Q3 ENGINEERING, PETROLEUM SPE Drilling & Completion Pub Date : 2021-04-01 DOI:10.2118/201709-PA
Mohammad Mojammel Huque, S. Imtiaz, S. Zendehboudi, S. Butt, M. A. Rahman, P. Maheshwari
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引用次数: 5

Abstract

Hole cleaning is a concern in directional and horizontal well drilling operations where drill cuttings tend to settle in the lower annulus section. Laboratory-scale experiments were performed with different non-Newtonian fluids in a 6.16-m-long, 114.3- × 63.5-mm transparent annulus test section to investigate cuttings transport behavior. This experimental study focused on understanding the cuttings transport mechanism in the annulus section with high-speed imaging technology. The movement of cuttings in the inclined annular section was captured with a high-speed camera at 2,000 frames/sec. Also, cuttings bed movement patterns at different fluid velocities and inner pipe rotations were captured with a digital single-lens reflex video camera. The electrical resistance tomography (ERT) system was used to quantify the cuttings volume fraction in the annulus. Different solid bed heights and cuttings movements were observed based on fluid rheology, fluid velocity, and inner pipe rotation. The mechanistic three-layer cuttings transport model was visualized with the experimental procedure. This study showed that solid bed height is significantly reduced with an increase in the inner pipe rotation. This study also identified that cuttings bed thickness largely depends on fluid rheology and wellbore inclination. The image from the high-speed camera identified a downward trend of some rolling particles in the annulus caused by gravitational force at a low mud velocity. Visual observation from a high-speed camera identified a helical motion of solid particles when the drillpipe is in contact with solid particles and rotating at a higher rev/min. Different cuttings movement patterns such as: rolling, sliding, suspension, helical movement, and downward movement were identified from the visualization of a high-speedcamera.
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基于可视化和电阻层析成像技术的斜井非牛顿流体岩屑运移实验研究
在定向井和水平井钻井作业中,井眼清洁是一个值得关注的问题,因为钻屑往往会沉降在下环空段。在一个6.16 m长、114.3 × 63.5 mm的透明环空测试段中,采用不同的非牛顿流体进行了实验室规模的实验,以研究岩屑的运移行为。本实验研究的重点是利用高速成像技术了解环空岩屑运移机理。高速摄像机以2000帧/秒的速度捕捉岩屑在倾斜环空段的运动。此外,在不同流体速度和管内旋转情况下,通过数码单镜头反光摄像机捕捉岩屑床的运动模式。电阻层析成像(ERT)系统用于量化环空岩屑体积分数。根据流体流变学、流体速度和内管旋转,观察到不同的固体床高度和岩屑运动。通过实验程序可视化了岩屑运移的三层机制模型。该研究表明,随着内管旋转的增加,固体床层高度显著降低。该研究还发现,岩屑层厚度在很大程度上取决于流体流变学和井筒倾角。高速摄像机的图像显示,在低泥浆速度下,由于重力作用,环空中一些滚动颗粒呈下降趋势。当钻杆与固体颗粒接触并以更高的转速/分钟旋转时,高速摄像机的视觉观察发现固体颗粒的螺旋运动。通过高速摄像机的可视化,可以识别出不同的岩屑运动模式,如滚动、滑动、悬浮、螺旋运动和向下运动。
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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.
期刊最新文献
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