轻质油自动入流控制阀多相流性能研究

S. Taghavi, E. Gisholt, H. Aakre, Stian Håland, K. Langaas
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引用次数: 2

摘要

早期的水/气突破是石油生产的主要挑战之一,导致采收率低。由于高气油比(GOR)和/或含水率(WC),现有的成熟井必须停止生产并关闭,尽管沿储层仍存在大量石油。开发能够提高边际油藏、成熟油藏和具有挑战性油藏产量和采收率的技术非常重要。在大多数油田中,泄油机制是气体和/或水的压力支撑,多相流性能尤为重要。自动流入控制阀(AICV)可以通过平衡水平段的流入来延迟井眼的发生,并在井眼发生时控制或完全关闭不需要的流体生产。AICV在位于挪威Porsgrunn的世界领先的全尺寸多相流回路中进行了测试。除单相性能外,还在实际储层条件下进行了测试,包括储层压力和温度、原油、地层水和烃气在不同气油比和含水下的性能。总结了流量回路、测试条件、操作程序和测试结果。此外,还讨论了在标准油藏模拟模型中如何用aicv表示井。介绍、讨论了AICV单相和多相流动性能曲线,并与常规流入控制装置(ICD)性能进行了比较。试验结果表明,AICV的流动性能明显优于常规ICD。给出了AICV对薄油环油藏简化模型的影响,并讨论了模型的局限性。模拟结果和实验结果表明,在薄油环油藏中部署AICV具有显著的效益。此外,本文还介绍了一种测试AICV在轻油完井设计中的应用的新方法,以及如何将AICV的流动性能结果应用于边际油藏、成熟油藏和其他具有挑战性的油藏。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Autonomous Inflow Control Valve Multiphase Flow Performance for Light Oil
Early water and/or gas breakthrough is one of the main challenges in oil production which results in inefficient oil recovery. Existing mature wells must stop the production and shut down due to high gas oil ratio (GOR) and/or water cut (WC) although considerable amounts of oil still present along the reservoir. It is important to develop technologies that can increase oil production and recovery for marginal, mature, and challenging oil reservoirs. In most fields the drainage mechanism is pressure support from gas and/or water and the multiphase flow performance is particularly important. Autonomous Inflow Control Valve (AICV) can delay the onset of breakthrough by balancing the inflow along the horizontal section and control or shut off completely the unwanted fluid production when the breakthrough occurs. The AICV was tested in a world-leading full-scale multiphase flow loop located in Porsgrunn, Norway. Tests were performed with realistic reservoir conditions, i.e. reservoir pressure and temperature, crude oil, formation water and hydrocarbon gas at various gas oil ratio and water cut in addition to single phase performances. A summary of the flow loop, test conditions, the operating procedures, and test results are presented. In addition, how to represent the well with AICVs in a standard reservoir simulation model are discussed. The AICV flow performance curves for both single phase and multiphase flow are presented, discussed, and compared to conventional Inflow Control Device (ICD) performance. The test results demonstrate that the AICV flow performance is significantly better than conventional ICD. The AICV impact on a simplified model of a thin oil rim reservoir is shown and modelling limitations are discussed. The simulation results along with the experimental results demonstrated considerable benefit of deploying AICV in this thin oil rim reservoir. Furthermore, this paper describes a novel approach towards the application of testing the AICV for use within light oil completion designs and how the AICV flow performance results can be utilized in marginal, mature, and other challenging oil reservoirs.
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