特殊设计聚合物在高含水井中的应用——科威特Umm Gudair油田整体修井技术的应用

A. Al-Azmi, T. Al-Yaqout, D. Al-Jutaili, K. Bhatia, Amr Abdelbaky, A. Alboueshi
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引用次数: 2

摘要

油气藏出水量过多是油气行业面临的一个严重问题,尤其是成熟油田。较高的含水率会对生产井的经济效益产生不利影响,因此是不可取的。不断增加的采出水的处理和回注带来了额外的责任。成熟的Umm Gudair油田面临的一个重大挑战是确保油气在高含水层段的流动。近年来,油田开发战略已经开始优先考虑新的油井干预技术,因为它具有最小化含水率、更高产量和提高总储量采收率(油气储量)的优势。本文讨论了井下化学方法的现场实施,该方法的设计和应用是“同类首创”,对整体生产力产生了积极影响。为了解决这些问题,该处理方法进行了高度改进,以适应电潜泵(ESP)驱动的井作业、地层技术难题、高风险经济效益和这些地层的高含水潜力的独特挑战。在一口高含水井中,采用了一种独特的有机交联聚合物(OCP)体系和尾端刚性坐封材料(RSM)体系作为孔隙填充密封胶,以选择性地降低产水量。在处理前进行预冲洗,去除可能阻碍聚合物有效凝胶化的沉积物。然后用盐水过度置换处理。OCP系统作为一种低粘度的溶液,通过压头注入到地层中。它会在预定时间激活,形成三维刚性水凝胶,完全封闭基质渗透率、裂缝、裂缝和通道,从而在储层中形成人工屏障密封。尾入式近井RSM系统可迅速形成高抗压强度,避免坐封前地层损失。这种整体方法有助于形成一种坚固的密封剂,用于封堵不需要的产水层,阻碍水流,促进油气流动。将该系统的应用与常规的水泥挤压处理进行了直接比较,以说明在该领域具有较深的基质穿透能力,可以实现更有效的堵水。实施后的一个直接结果是,作业后的试井和生产数据显示,该技术以较低的速率实现了高持续产量,并显著降低了含水率,这证实了该技术是该油田成功的化学关水技术之一。本文总结了备选方案的选择、设计过程、遇到的挑战和生产响应,可以被认为是解决其他油田类似条件下高含水产量挑战的最佳实践。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Application of Specially Designed Polymers in High Water Cut Wells- A Holistic Well-Intervention Technology Applied in Umm Gudair Field, Kuwait
Excessive water production from hydrocarbon reservoirs is a serious issue faced by the industry, particularly for mature fields. Higher water cut adversely affects the economics of the producing wells, thus it is undesirable. Disposal and reinjection of ever-increasing volumes of produced water poses additional liability. A significant challenge faced in the mature Umm Gudair field is assuring hydrocarbon flow through high water-prone intervals. In recent times, field development strategies have begun to prioritize new well intervention technology because of the advantages of minimized water cut, higher production rates, and improved overall reserve recovery (hydrocarbon in place). This paper discusses the field implementation of a downhole chemical methodology, "first of its kind" designed and applied, that has created a positive impact in overall productivity. To solve these challenges, the treatment was highly modified as fit-for-purpose to address the unique challenges of electric submersible pump (ESP)-driven well operations, formation technical difficulties, high-stakes economics, and high-water potential from these formations. A unique Organically Crosslinked Polymer (OCP) system with a tail-in Rigid Setting Material (RSM) system was implemented as a porosity-fill sealant in a high-water-cut well to selectively reduce water production. A pre-flush was pumped ahead of the treatment to remove deposits that could have prevented the polymer from effective gelation. The treatment was then overdisplaced with brine. The OCP system is injected into the formation as a low viscosity solution using the spot and hesitation squeeze method via bullheading. It activates at a predicted time to form a 3-D rigid hydrogel to completely shut off matrix permeability, fractures, fissures, and channels, thus creating an artificial barrier seal in the reservoir. The tail-in near wellbore RSM system rapidly develops a high compressive strength to avoid any formation loss before setting. This holistic approach helps to create a robust sealant for blocking the unwanted water-producing zone, impeding water flow, and facilitating increased hydrocarbon flow. A direct comparison of the application of this system with conventional cement squeeze treatments is presented to illustrate the advantage of having a deep matrix penetration for a more efficient water shutoff in this field. A direct result of the implemented treatment is that the post-operation well test and production data showed a high-sustained production at lower rate with significantly reduced watercut, confirming this technology is one of successful chemical water shut off techniques this field. This paper summarizes the candidate selection, design processes, challenges encountered, and production response, and can be considered a best practice for addressing high water production challenges in similar conditions in other fields.
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