基于无交变聚合物NAP概念的采油机理研究

M. Battashi, R. Farajzadeh, A. Bimani, M. Abri, R. Mjeni, V. Karpan, A. Fadili, J. van Wunnik
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引用次数: 5

摘要

本文讨论了聚合物注入在阿曼苏丹国南部稠油油藏中的应用,该稠油油藏的稠油粘度为300-800cP,底层为强自下而上含水层。由于含水层水与油的流动性比不利,以及尖锥的发育,大量的石油仍未被波及。为了克服这些问题,2013年开始了聚合物注入试验,在油水接触面上方几米处安装了三个水平注入器。最初,以高注入速率连续注入粘度为100 cP的聚合物溶液。然而,由于地面设施、水和聚合物质量问题,维持注入能力是一项挑战。这导致喷油器频繁关闭。有趣的是,在关井期间,含水率逆转和产油量增加仍在继续。这一观察结果导致了一种新的循环聚合物注入策略的发展,其中聚合物注入与关井交替进行。这种策略被称为无交替聚合物(NAP)。本文从NAP策略的角度探讨了采油机理。建立了一个三维模型来匹配实际试验结果并捕捉观察到的行为。注入的聚合物挤压锥体,部分恢复了含水层和油柱之间的屏障,抑制了含水层通量,从而抑制了锥体的负面影响。研究发现,在聚合物注入过程中,油通过常规的聚合物前缘运移和波及增强机制被回收。此外,在这一阶段,注入的聚合物在含水层和油柱之间形成了一道屏障,抑制了含水层通量,从而抑制了锥体或水通道的负面影响(覆盖机制)。此外,聚合物的注入将石油推向枯竭的水锥,然后在关井期间由来自含水层的水产生(补给机制)。在关井或NAP期间,含水层水也会推动现有的聚合物层,从而导致额外的石油产量。NAP策略减少了聚合物进入含水层的损失,提高了以kg-polymer/桶原油表示的聚合物利用率,从而获得了良好的经济效益。
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Insights into Oil Recovery Mechanism by Nothing-Alternating-Polymer NAP Concept
This paper discusses the application of polymer injection in a heavy oil reservoir in the South of the Sultanate of Oman containing oil with a viscosity of 300-800cP underlain by a strong bottom-up aquifer. Due to unfavorable mobility ratio between aquifer water and oil and the development of the sharp cones significant amount of oil remains unswept. To overcome these issues, a polymer injection pilot started in 2013 with three horizontal injectors, located a few meters above the oil/water contact. Initially a polymer solution with a viscosity of 100 cP was continuously injected at high injection rates. However, it was challenging to sustain the injectivity mainly due to surface facilities, water, and polymer quality issues. This resulted in frequent shutdowns of the injectors. Interestingly, the water cut reversal and oil gain continued during the shut-in periods. This observation has led to the development of a new cyclic polymer injection strategy, in which the injection of polymer is alternated with shut-ins. The strategy is referred to as Nothing-Alternating-Polymer (NAP). This paper discusses the oil recovery mechanism from the NAP strategy. A 3D model was constructed to match the actual pilot results and capture the observed behavior. The injected polymer squeezes the cones and partly restores the barrier between the aquifer and the oil column, suppressing the aquifer flux and hence the negative affect of the cones. It was found that during polymer injection, the oil is recovered by conventional mobility and sweep enhancement mechanisms ahead of the polymer front. Additionally, during this stage the injected polymer creates a barrier between the aquifer and the oil column, suppressing the aquifer flux and hence the negative effect of the cones or water channels (blanketing mechanism). Moreover, injection of polymer pushes the oil to the depleted water cones, which is then is produced by the water coming from the aquifer during shut-in period (recharge mechanism). During the shut-in or NAP period, the aquifer water also pushes the existing polymer bank and hence leads to extra oil production. The NAP strategy reduces polymer loss into aquifer and improves the polymer utilization factor expressed in kg-polymer/bbl of oil, resulting in a favorable economic outcome.
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