一种新型气体分散泡沫技术可以提高非常规油藏高采收率注气工艺的效率

K. Díez, A. Ocampo, A. Restrepo, Jonny Patiño, Juan Rayo, Diego Ayala, Luis Rueda
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引用次数: 1

摘要

注气已成为非常规油藏提高采收率研究最多的方法之一。然而,天然裂缝和诱导裂缝的存在会对注气效率产生负面影响,因为它们会流向附近的井,或者由于缺乏一致性而导致处理区域的覆盖不足。为了克服这些困难,通过注气提高采收率,本文提出了一种新型的气体分散泡沫技术,以提高非常规IOR/EOR项目注气的波及效率。该技术的开发和评估已经通过了一系列实验室保证阶段,包括流体表征、相容性和广泛的岩心驱油测试。研究人员还提出了一种建模方法,并利用该技术在哥伦比亚一个极低孔隙度、致密、天然裂缝的石英-砂质凝析气藏中实施的实验室和现场数据进行了验证。这里介绍的工作流程包括跨学科的组成部分,如实验室评估、油藏建模、处理设计、井场设置和执行。实验室测试和井间现场应用结果,以及现象学建模方法的开发和测试表明,气体分散性泡沫注入是非常规油藏采油和/或凝析油的一种高潜力技术,因为它能够改善深层储层的气体一致性,并避免非常规油气藏注气IOR/EOR过程中缺乏气体密封。在致密的天然裂缝样品中,实验结果表明,估计的原油采收率增加了~36%,有效气体迁移率降低了~45%。该技术还表现出较少的化学吸附损失,这有助于更好的化学放置和更长的耐用性。现场应用的主要结果,包括气体注入器的气体注入能力逐渐降低,GOR持续降低,受影响的生产井的产油量增加,以及据报道的约6个月的处理耐久性,都可以用该模型正确地表示。本文提出的工作流程的每个步骤不仅确保了基于天然气的项目的成功,而且还允许在井位的更小的物流足迹,以及更少的水消耗,从而转化为更便宜、更高效的注气作业。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A Novel Gas Dispersible Foam Technology Can Improve the Efficiency of Gas Injection Processes for IOR-EOR Operations in Unconventional Reservoirs
Gas injection has become one of the most investigated methods for enhanced oil recovery in unconventional reservoirs. Nonetheless, the presence of natural and induced fractures negatively impacts the gas injection efficiency due to its channeling towards nearby wells or poor coverage in the treated area due to lack of conformance. To overcome these difficulties and boost the oil recovery process by gas injection, this work presents a novel gas dispersible foam technology to improve the sweep efficiency of gas injection in unconventional IOR/EOR projects. The development and evaluation of this technology has passed through a series of laboratory assurance stages that include fluids characterization, compatibility, and extensive coreflooding tests. A modelling approach is also presented, which was validated using lab and field data taken from the implementation of the technique in an extremely low porosity, tight and naturally fractured quartz-arenite gas condensate reservoir in Colombia. The workflow herein presented encompasses interdisciplinary components such as laboratory evaluation, reservoir modeling, treatment design, and wellsite setup and execution. Laboratory testing and inter-well field applications results, along with the development and testing of a phenomenological modelling approach, demonstrate that the gas dispersible foam injection can be a high potential technique for oil and/or condensate recovery in unconventional reservoirs given its proven ability to improve the deep reservoir gas conformance and avoid the lack of gas containment during gas injection IOR/EOR in unconventional plays. Lab results in a tight naturally fractured sample, suggest that the estimated incremental oil recovery was ~36% and the effective gas mobility reduction was ~45%. This technique also exhibited less chemical adsorption losses, which contributes to better chemical emplacement and longer durability. The main results of the field application, including a progressive decrease in gas injectivity at the gas injector, a consistent reduction in GOR with an associated oil increase at the influenced producer well, and a reported treatment durability of ~ 6 months, were all properly represented by the model. Each step of the workflow herein proposed not only assures the gas-based projects success, but also allows for smaller logistics footprint at the well location, along with less water consumption, which translates into cheaper and more efficient gas injection conformance operations.
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