自主流入控制装置AICD在阿曼南苏丹稠油优化生产中的现场应用

A. Al-Jumah, M. Gokmen, Ameera Harrasi, Ibrahim Abri, Salim Buwaiqi, G. Urdaneta
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引用次数: 1

摘要

本文总结了自主流入控制装置(AICD)在阿曼南部多个稠油油田部署和安装的结果和经验教训,以便在其他具有类似特点的油田中迅速应用。这些aicd主要在这些油田的水平井生产中进行了全面的部署和测试,并进行了严格的实验室测试,以了解其行为。本文是文献[1]工作的延续。近几十年来,用于生产井的水平钻井成为一项广为人知的技术,这是因为它们提高了整体采收率、生产效率、储层排水,并延迟了不需要的流体(例如气和水)。然而,这种解决方案并不完美,因为由于储层高度裂缝和非均质性,过早的产水和产气可能而且将会发生,导致剩余油被绕过,从而降低储层的采收率,最终降低盈利能力[2]。在阿曼苏丹国南部,许多油田都采用了水平井技术进行开发,但由于水平井技术的优势,地层的地质性质和产出流体的物理性质,为生产优化带来了重大挑战。其中一项资产包括通过长水平裸眼完井排出的天然裂缝型碳酸盐岩储层。它与水驱和GOGD系统一起开发。该资产面临的主要生产优化挑战是裂缝主导的流入,这会导致高水或高气产量。另一方面,进行试验的另一项资产包括浅层砂岩稠油油藏,具有强底层含水层和高油藏非均质性;裂缝、断层和高渗透条纹是这些储层的特征。水平井通常比直井具有更高的产液能力,因此,在不干扰油水接触的临界速率下,水平井的临界速率肯定比直井高,但即使如此,流体的流动能力更大,无论如何都会导致井底水向水平井流动得更快[3]。另一个试验田生产稠油,稠油粘度在600 ~ 1000 cP之间,渗透率在100mD ~ 10D之间。这使得流动性比非常有利于产水。有些井在开始生产时用水量不到10%,但突然增加的用水量高达90%以上。大多数井都使用了膨胀式封隔器(ezps),在水平储层段形成了2到3个段。AICD技术适用于油液流动性非常低的情况和砂面段。最后一个试验田包括由页岩屏障隔离的多层储层,具有两个主要层的石油生产潜力。该油质轻,API为42,粘度为0.9 cp。由于含水高、产能低等各种原因,目前约有13口井处于关井状态。该油田自1998年以来一直在生产9个叠层储层,这对产量分配提出了挑战。执行生产日志测试(plts)无助于改善分配问题。当涉及到决定需要关闭的区域时,断水是具有挑战性的。机械断水是一种选择,可以堵塞未分配的水域,从而增加石油产量。虽然该油田不包括水平井,但该井的总射孔长度和产层之间的水力自然隔离使得该技术的应用对该油田具有吸引力。无干预/无线技术可以促进水平井整个长度的均匀生产,延迟沿井径高生产力区域的有害流体(水或气)的产生,并促进地层其他隔层的产油量增加,这无疑是阿曼石油开发公司这些油田生产优化的一个关键方面。
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Field Application of the Autonomous Inflow Control Device AICD for Optimized Heavy Oil Production in South Sultanate of Oman
This paper summarizes the results and learnings from the Autonomous Inflow Control Device (AICD) deployment and installation in multiple heavy oil fields in south Oman, allowing for swift utilization in other fields with similar characteristics. Those AICDs were mainly deployed and tested in those oil fields comprehensively, in horizontal producers, and the results were supported by rigorous lab tests was conducted to understand their behavior. This paper is a continuation of the work in reference [1]. In recent decades, horizontal drilling for producing wells became a widely known and used technology, this is due to the fact they improve the overall recovery, efficiency of production, drainage of the reservoir, as well as delay unwanted fluids (e.g. gas & water). However, this solution was not perfect, as due to highly fractured and heterogeneous reservoirs, premature water and gas production can and will take place, causing remaining oil to be bypassed, and hence, reducing the reservoir's recovery and eventually the profitability [2]. In south Sultanate of Oman, many fields have been developed with the use of the horizontal well technology, but together with its advantages, the geological nature of the formations and the physical properties of the produced fluids, have introduced important challenges regarding production optimization. One of the assets in question comprises of naturally fractured carbonate reservoirs drained through long horizontal open-hole completions. It has been developed with water flood and GOGD system. The main production optimization challenge faced for that asset is the fracture-dominated inflow, which leads to either high water or gas production. On the other hand, another asset where the trial took place comprises of shallow sandstone reservoirs of heavy oil, with strong bottom aquifers and high level of reservoir heterogeneities; fractures, faults and high permeability streaks are characteristic of these reservoirs. A horizontal well usually has a much higher capacity–as compared to a vertical well–for producing fluids at the same drawdown, hence, when talking on critical rates that do not disturb the oil-water-contact, horizontal wells will definitely have a higher critical rate than those of vertical wells, but even so, the capacity of moving fluids are bigger, causing faster movement of bottom water towards the horizontal well regardless [3]. Another field of the trial fields had produced heavy oil, with viscosities in the range of 600 cP to 1000 cP. The permeability is variable and in the range of 100mD to 10D. This makes the mobility ratio very favorable to water production. Some wells have started production with less than 10 % WC, but a sudden increase of WC has been observed up to above 90 %. Most of the wells have been completed with inflatable packers (EZIPs), creating 2 to 3 segments at the horizontal reservoir section. The AICD technology is suitable for being applied in this case of very low oil mobility and segments at the sand-face. The last trial field comprises of multi-stacked reservoirs, isolated by shale barriers, with production potential of oil from two main layers. The oil is light, ~ 42 API and 0.9 cp viscosity. Around 13 wells are closed-in due to various reasons including high water cut and low productivity. This field is producing since 1998 from 9 stacked reservoir zones-commingled, which provides a challenge to production allocation. Performing Production Logging Tests–PLTs-have not helped to improve the allocation issues. Water shut off is challenging when it comes to the point of deciding the zone required to be closed. Mechanical water shut off is an option to choke back the non-allocated water zones and allow more oil production. Although this field does not include horizontal wells, the total perforated length of the proposed well and the hydraulic natural isolation between the producing zones makes the application of the technology attractive for this field. An interventionless/wireless technology, which promotes uniform production along the entire length of a horizontal well, delaying the production of unwanted fluids (water or gas) from high productivity zones along the well path and promoting increased oil production from other compartments of the formation, would definitively represent a key aspect of the production optimization for these Petroleum Development Oman fields.
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