新开发理念使科威特北部油田采收率提高5倍

A. Daoud, B. Al-Otaibi, Dhuha Alkandari
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引用次数: 1

摘要

北科威特的一个碳酸盐岩油田于1957年开始生产,尽管该油田自1997年以来一直处于水驱状态,但经过60年的生产,采收率非常低。开发了一个工作流程,首先了解低采收率背后的原因,其次提出改善采收率的最佳方法。该工作流程首先建立物质平衡模型,以了解主要的油藏驱动机制。其次,采用精细尺度历史拟合模拟模型,了解当前低采收率的主要原因。提出了一种高采低注(PHIL)的概念,将所有的注入器定位在最深的区域,而将生产器定位在浅层区域。最后,将5点倒置水平井与9点倒置直井和周边PHIL概念进行对比,利用模拟模型验证最大采收率的最佳方法。上述工作流程的不同结果可以总结如下:首先,发现注水是主要驱动机制,占油藏采收率的70%;因此,在整个油田区域建立人工含水层以提供所需压力支撑的重要性,要求实施具有倒5点模式背景的PHIL概念,作为该油田的最佳开发概念。其次,在建立精细模型时所使用的全面数据审查表明,目前的采收率主要是单一层,仅占现有采收率的15%,最重要的是,发现所有已开发的井仅位于油田的30%,其余70%的油田未开发。这些是低复苏背后的主要原因。最后,倒置5点背景下开发的PHIL概念表明,与9点直井和外围PHIL概念相比,新井数量和注入水量更少,采收率可以提高5倍。采收率增加了五倍,这促使该资产进行试点,以实施拟议的开发战略。与常用的倒5点直井不同,这项工作提出了一种新的倒5点水平井方法,将水平注入器定向到最深层,将水平采油器定向到浅层。从而创造了一个人工底部含水层,使产水量最小化,并使整个油藏的注水分布最大化。
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New Development Concept Lead to Five Folds Recovery Increase in a North Kuwait Field
One of the North Kuwait Carbonate fields which starts its production in 1957 has very low recovery factor after 60 years of production although the field was under water flooding since 1997. A workflow was developed to first understand the reason behind the low recovery and second to propose the best way to improve it. The workflow starts with first building a material balance model to understand the main reservoir driving mechanisms. Second, a fine-scale history matched simulation model was used to understand the main reasons of the current low recovery. A Produce High and Inject Low (PHIL) concept was proposed with locating all the injectors at the deepest zone and the producers at the shallow zones. Finally, the proposed PHIL concept with inverted 5-spot horizontal wells was examined compared to the inverted 9-spot vertical wells and to the peripheral PHIL concept using the simulation model to examine the best approach to maximize the recovery. Different outcomes from the above-mentioned workflow can be summarized as follows; first, it was found that the main driving mechanism is water injection which represents 70% of the reservoir recovery factor. Hence the importance of creating an artificial aquifer along the whole area of the field to provide the required pressure support which calls for the implementation of the PHIL concept with inverted 5-spot pattern background as the best development concept for the field. Second, the thorough data review used on building the fine-scale model shows that the current recovery is dominated by single zone which represents only 15 % of the in-place and on top of this, it was found that all the developed wells are located only on 30% of the field leaving 70% of the field undeveloped. These are the main reasons behind the low recovery. Finally, the developed PHIL concept with inverted 5-spot background shows that the recovery can be increased by five times with less number of new wells and less water injection volume required compared to the 9-spot vertical wells and the peripheral PHIL concepts. This five-folds increase in recovery encourages the asset to do a pilot to implement the proposed development strategy. Unlike the commonly used inverted 5-spot vertical wells, this work proposes a novel approach of inverted 5-spot horizontal wells with directing the horizontal injectors at the deepest zones and the horizontal producers at the shallow zones. Hence creating an artificial bottom aquifer with minimizing the water production and maximizing the water injection distribution along the whole area of the reservoir.
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