将地面和井下射孔入口测量相关联,可以开发改进的射孔系统

IF 1.3 4区 工程技术 Q3 ENGINEERING, PETROLEUM
David Cramer, Matt White, Cody Douglas
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引用次数: 0

摘要

研究表明,在套管(即进入井眼)中实现一致的射孔孔尺寸和零相位射孔枪定向,可以改善射孔塞射孔有限进入井眼的多个射孔簇之间的处理分布。定向射孔除了通过建立均匀的射孔枪间隙和射孔射流在套管壁上的入射角来减少射孔进入孔内的变化外,还可以最大限度地减少支撑剂在射孔段中与压裂液分离的趋势(惯性效应),并减轻由重力引起的支撑剂分层造成的进入孔不均匀侵蚀。该研究的主要目标是确定影响射孔枪定向精度和入孔尺寸的可控射孔枪元件和附件。在制造设施进行了表面试验,以确定采用不同系统配置的聚能炸药在管道中产生的入口孔的特性和各种枪定向装置的稳健性。然后将有前景的射孔系统用于井筒中,以创建校准入孔(井下测试),在进行处理之前,使用高分辨率声学成像测量等效直径和定向精度。该过程可以根据需要评估和修改影响进入孔尺寸和射孔枪方向的射孔系统组件。影响入井尺寸和一致性的射孔系统和井下环境因素包括套管类型、水泥环特性、射孔枪间隙和定向、射孔药类型和密度、多药包封布置、装药管和装药载体设计、射孔枪起爆系统、静水压力和锁定装置。通过对这些元素的严格控制,可以显著减少入井尺寸的变化。与地面和井下测试结果的偏差通常归因于现场使用的射孔系统元件与制造商在地面测试中使用的元件不同。影响射孔枪定向精度和一致性的因素包括:重杆类型、射孔枪管柱长度、重量和刚度、改进的防区带的存在、射孔枪在发射过程中的逐渐变形、井筒弯曲度和自定向装置。发现几种定位系统在目标20°窗口内实现了定位。为了评估该工作流程的价值,本文包括了用于评估超声波测量设备准确性的诊断测试结果、用于确定双组分射孔侵蚀模型系数的推导过程,以及使用推导的侵蚀速率系数来计算压裂过程中进入每个射孔和射孔簇的支撑剂质量。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Correlating Surface and Downhole Perforation Entry Hole Measurements Leads to Development of Improved Perforating Systems
Summary Studies have shown that achieving a consistent perforation hole size in casing (i.e., entry hole) and zero-phase perforation gun orientation led to improved treatment distribution among multiple perforation clusters in plug-and-perf limited entry treatments. In addition to reducing variation in the perforation entry hole by establishing uniformity in gun clearance and the angle of incidence of the perforation jet at the wall of the casing, oriented perforating has been shown to minimize the tendency of proppant to separate from the fracturing fluid while traveling across the perforated intervals (inertial effect) and mitigate nonuniform entry hole erosion due to gravity-induced proppant stratification. The primary goal of this study was to determine the controllable perforating gun elements and accessories that effect the accuracy of gun orientation and entry hole dimensions. Surface tests were conducted at manufacturing facilities for determining the characteristics of the entry holes in pipe produced by shaped explosive charges using various system configurations and the robustness of various gun orientation devices. Promising perforating systems were then used in wellbores to create calibration entry holes (downhole tests) that were measured for equivalent diameter and orientation accuracy using high-resolution acoustic imaging before conducting treatments. This process enabled components of the perforating system influencing entry hole size and gun orientation to be evaluated and modified, as necessary. Elements of the perforating system and downhole environment that influenced entry hole size and consistency included casing type, cement sheath characteristics, perforating gun clearance and orientation, perforating charge type and density, packing arrangement of multiple charges, charge tube and charge carrier design, gun detonation system, hydrostatic pressure, and locking devices. Achieving tight control of these elements significantly reduced variation in entry hole size. Deviations from surface and downhole testing results were commonly attributed to using perforating system elements in the field that differed from those used by the manufacturer in surface testing. Factors affecting gun orientation accuracy and consistency included weight bar type, gun string length, weight, and stiffness, the presence of modified standoff bands, progressive gun deformation during firing, wellbore tortuosity, and self-orienting devices. Several orientation systems were found that achieved orientation within the target 20°-window. To assess the value of this workflow process, the paper includes information on the results of diagnostic tests for evaluating the accuracy of the ultrasonic measuring device, the derivation process used for determining coefficients for a two-component perforation erosion model, and the use of the derived erosion rate coefficients for computing the mass of proppant that enters each perforation and perforation cluster during a fracturing treatment.
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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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