Enhancing Reamer Drilling Performance in Deepwater Gulf of Mexico Wells

IF 1.3 4区 工程技术 Q3 ENGINEERING, PETROLEUM
Cesar Soares, M. Armenta, Neilkunal Panchal
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引用次数: 3

Abstract

Reamers are an integral part of deepwater Gulf of Mexico (GOM) drilling and their performance significantly impacts the economics of well construction. This paper presents a novel programmatic approach to model rate of penetration (ROP) for reamers and improve drilling efficiency. Three field implementations demonstrate value added by the reamer drilling optimization (RDO) methodology. Facilitated by user interface panels, the RDO workflow consists of surface and downhole drilling data filtering and visualization, detection of rock formation boundaries, frictional torque (FTRQ) and aggressiveness estimation, ROP modeling with analytical equations and machine learning (ML) algorithms [regression, random forests, support vector machines (SVMs), and neural networks], and optimization of drilling parameters. ROP model coefficients and bit and reamer aggressiveness are dependent on lithology and computed from offset well data. Subsequently, when planning a nearby well, bottomhole assembly (BHA) designs are evaluated on the basis of drilling performance and weight and torque distributions between cutting structures to avoid early reamer wear and dysfunctions. Geometric programming establishes optimal drilling parameter roadmaps according to operational limits, downhole tool ratings, rig equipment power constraints, and adequate hole cleaning. Separate ROP models are trained for reamer-controlled and bit-controlled ROP zones, defined by the proportion of surface weight on bit (WOB) applied at the reamer, in every rock formation. This novel concept enables ROP prediction with the appropriate model for each well segment depending on which cutting structure limits drilling speed. In the first of the three RDO applications with field data from deepwater GOM wells, optimal bit-reamer distances are determined by analyzing reamer weight load in uniform salt sections. Next, ROP modeling for the addition or removal of a reamer from the BHA is used in contrasting well designs to conceivably alleviate a USD 16 million casing inventory surplus. Finally, active optimization constraints are investigated to reveal drilling performance limiters, justifying equipment upgrades for a future deepwater GOM well. The proposed innovative workflow and methodology apply to any drilling optimization scenario. They benefit the practicing engineer interested in drilling performance optimization by providing insights on how different cutting structure sizes affect ROP behavior and ultimately aiding in the selection of appropriate bit and reamer diameters and optimal operational parameters.
提高墨西哥湾深水井扩眼器钻井性能
扩孔器是墨西哥湾深水钻井的组成部分,其性能对油井施工的经济性有重大影响。本文提出了一种新的程序化方法来模拟铰刀的钻速(ROP)并提高钻井效率。三个现场实施证明了扩孔器钻井优化(RDO)方法的附加值。在用户界面面板的推动下,RDO工作流程包括地表和井下钻井数据过滤和可视化、岩层边界检测、摩擦力矩(FTRQ)和攻击性估计、使用分析方程和机器学习(ML)算法[回归、随机森林、支持向量机(SVM)和神经网络]的ROP建模,以及钻井参数的优化。ROP模型系数以及钻头和扩孔器的攻击性取决于岩性,并根据偏移井数据进行计算。随后,在规划附近的井时,根据钻井性能以及切割结构之间的重量和扭矩分布来评估底部钻具组合(BHA)设计,以避免早期铰刀磨损和功能障碍。几何编程根据操作限制、井下工具额定值、钻机设备功率限制和充分的清孔建立最佳钻井参数路线图。针对每个岩层中扩孔器控制和钻头控制的ROP区域训练单独的ROP模型,该区域由扩孔器处施加的钻头表面重量(WOB)的比例定义。这种新颖的概念能够根据哪种切割结构限制钻井速度,为每个井段使用合适的模型进行ROP预测。在三种RDO应用中的第一种应用中,利用深水GOM井的现场数据,通过分析均匀盐段中的扩孔器重量载荷来确定最佳钻头扩孔器距离。接下来,在对比井设计中使用从BHA中添加或移除扩孔器的ROP建模,以减少1600万美元的套管库存盈余。最后,对主动优化约束进行了研究,揭示了钻井性能的限制因素,证明了未来深水GOM井的设备升级是合理的。所提出的创新工作流程和方法适用于任何钻井优化场景。它们通过深入了解不同的切削结构尺寸如何影响ROP行为,并最终帮助选择合适的钻头和铰刀直径以及最佳操作参数,使对钻井性能优化感兴趣的执业工程师受益。
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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