利用网络优化技术进行多分支井大规模下井

G. Al-Qahtani, Noah E. Berlow
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引用次数: 0

摘要

分支井是由水平井演化而来的分支井,分支井由主井向外辐射。在过去的二十年中,多分支井越来越多地用于油气开采。与常规井和单井相比,使用这种技术的主要优势在于,通过使用更少的资源,最大限度地接触储层,从而增加了对储层岩石的接触。如今,分支井在设计和结构上正迅速变得更加复杂(即大位移井、最大油藏接触井和极端油藏接触井)。某些多边设计模板在行业中很流行,例如叉形和鱼骨形,它们往往分布在整个感兴趣的储层中,对原始结构没有重大改变,因此可能无法充分发挥储层的潜力。最优分支井的布置是一个多变量问题,它是一个以最大化产能和采收率为最终目标,确定油气储层中最佳井位和井眼轨迹的函数。分支井的布置可能受到许多限制,例如所需的井数、最大长度限制和整体经济效益。本文介绍了一种利用转运网络优化方法在油气储层中布置分支井的新技术。该方法生成了多口不同设计的井的场景,以满足油藏中最有利的完井点。此外,该算法还可以在局部和全局范围内为分支井找到最有利的位置和轨迹。采用了一种独特的分区算法,以减少该过程的计算成本。所提出的方法不仅会产生不同的多边设计;它将证明生成的每个井眼段的轨迹。这种创新的方法能够在大型油藏中建造数百口设计变化的分支井。由于储层的复杂性(例如,影响流体流动性的主动作用力)和非均质性决定了储层不同区域的动态变化,因此应建造多分支井以捕获产量最高的区域。新方法还允许分支的不同级别(即,分支可以从母孔,从其他分支或从后续分支发出)。这些特征为新一代分支井实现最有效的油藏接触奠定了基础。
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Large Scale Placement For Multilateral Wells Using Network Optimization
Multilateral wells are an evolution of horizontal wells in which several wellbore branches radiate from the main borehole. In the last two decades, multilateral wells have been increasingly utilized in producing hydrocarbon reservoirs. The main advantage of using such technology against conventional and single-bore wells comes from the additional access to reservoir rock by maximizing the reservoir contact with fewer resources. Today, multilateral wells are rapidly becoming more complex in both designs and architecture (i.e., extended reach wells, maximum reservoir contact, and extreme reservoir contact wells). Certain multilateral design templates prevail in the industry, such as fork and fishbone types, which tend to be populated throughout the reservoir of interest with no significant changes to the original architecture and, therefore, may not fully realize the reservoir's potential. Placement of optimal multilateral wells is a multivariable problem, which is a function of determining the best well locations and trajectories in a hydrocarbon reservoir with the ultimate objectives of maximizing productivity and recovery. The placement of the multilateral wells can be subject to many constraints such as the number of wells required, maximum length limits, and overall economics. This paper introduces a novel technology for placement of multilateral wells in hydrocarbon reservoirs utilizing a transshipment network optimization approach. This method generates scenarios of multiple wells with different designs honoring the most favorable completion points in a reservoir. In addition, the algorithm was developed to find the most favorable locations and trajectories for the multilateral wells in both local and global terms. A partitioning algorithm is uniquely utilized to reduce the computational cost of the process. The proposed method will not only create different multilateral designs; it will justify the trajectories of every borehole section generated. The innovative method is capable of constructing hundreds of multilateral wells with design variations in large-scale reservoirs. As the complexity of the reservoirs (e.g., active forces that influence fluid mobility) and heterogeneity dictate variability in performance at different area of the reservoir, multilateral wells should be constructed to capture the most productive zones. The new method also allows different levels of branching for the laterals (i.e., laterals can emanate from the motherbore, from other laterals or from subsequent branches). These features set the stage for a new generation of multilateral wells to achieve the most effective reservoir contact.
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