螺旋弯曲井眼对水平井岩屑去除影响的数值研究

IF 1.3 4区 工程技术 Q3 ENGINEERING, PETROLEUM SPE Drilling & Completion Pub Date : 2021-11-01 DOI:10.2118/201789-pa
M. Khaled, Hicham Ferroudji, M. A. Rahman, Ibrahim Hasan Galal, A. Hasan
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引用次数: 5

摘要

水平井设计有光滑(直)、弯曲和水平段。然而,实际的钻井路径通常会受到计划井眼轨迹的不必要波动,即井筒弯曲度。井筒弯曲会减缓钻井速度,加剧钻柱振动和屈曲,使套管和固井作业复杂化,并导致井眼定位不准确。本文建立了一个经过验证的计算流体动力学(CFD)模型来研究井筒弯曲度对井眼清洗的影响。采用欧拉-欧拉方法,用多面体网格模拟了环形几何中的固液层流。然后,研究了井筒弯曲度对岩屑积聚、环空压力损失和流体速度的影响,并与直井中的流动特性进行了比较。通过对螺旋周期长度、螺旋幅值、钻柱旋转、流量、环空偏心率、钻速(ROP)和岩屑尺寸等参数的分析,评估了它们对螺旋弯曲井中岩屑运移的影响,以及它们与其他设计或操作因素的相对量级。仿真结果表明,多面体网格是一种最优的螺旋轮廓几何网格划分方法。根据螺旋周期长度和/或螺旋振幅,井筒弯曲度会加剧横向段的井眼清洁。在螺旋形状的顶部(波峰)观察到岩屑速度的降低,与螺旋形状的底部(槽)相比,在该区域沉积了大量岩屑。钻柱旋转0 ~ 200转/分钟是有效清洗螺旋结构井眼的关键范围。如果颗粒尺寸大于位于床层速度剖面附近的粘性层,则岩屑尺寸可以改善岩屑堆积。钻井机械钻速和环空偏心加剧了螺旋井中的岩屑堆积和地层沉积,这与通常在直水平井中观察到的情况类似。
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Numerical Study on the Impact of Spiral Tortuous Hole on Cuttings Removal in Horizontal Wells
Horizontal wells are designed to have smooth (straight), curved, and lateral sections. However, the actual drilled path usually suffers from unwanted undulations from the planned well trajectory known as wellbore tortuosity. Wellbore tortuosity can slow the drilling penetration rate, aggravate drillstring vibration and buckling, complicate the casing and cement job, and lead to inaccurate wellbore position. This paper presents a validated computational fluid dynamics (CFD) model to investigate the impact of wellbore tortuosity on hole cleaning. The Eulerian-Eulerian approach is used to simulate solid-liquid laminar flow in annular geometry using polyhedral mesh. Then, the impact of wellbore tortuosity on cuttings accumulation, annular pressure loss, and fluid velocity was investigated and compared with the flow behavior in a straight horizontal well. A parametric analysis of spiral period length, spiral amplitude, drillstring rotation, flow rate, annular eccentricity, drilling rate of penetration (ROP), and cuttings size was conducted to assess their influence on cuttings transport in spiral tortuous holes and their relative magnitude to other design or operating factors. Simulation results show that polyhedral mesh is an optimum meshing technique for spiral profile geometry. Wellbore tortuosity aggravates hole cleaning in lateral sections based on the length of the spiral period and/or the spiral amplitude. Reduction in cuttings velocity was observed in the top part of the spiral geometry (crest), causing large deposition of cuttings in this area compared to the spiral lower part (trough). Drillstring rotation from 0 to 200 rev/min is the critical range for efficient hole cleaning in spiral geometry. Cuttings size can improve cuttings accumulation if the particle size is larger than the viscous layer located near the bed velocity profile. The drilling ROP and annular eccentricity aggravate cuttings accumulation and bed deposition in a spiral hole, similar to what is normally observed in straight horizontal wells.
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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
Combining Magnetic and Gyroscopic Surveys Provides the Best Possible Accuracy Applications of Machine Learning Methods to Predict Hole Cleaning in Horizontal and Highly Deviated Wells Experimental Investigation of Geopolymers for Application in High-Temperature and Geothermal Well Cementing Analysis of Riser Gas Pressure from Full-Scale Gas-in-Riser Experiments with Instrumentation Correlating Surface and Downhole Perforation Entry Hole Measurements Leads to Development of Improved Perforating Systems
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