基于增强人工智能方法的复杂海上油田快速高效注水优化

S. Ghedan, M. Surendra, Agustin Maqui, M. Elwan, Rami Kansao, Hesham Mousa, R. Jha, Mahmoud Korish, Feyi Olalotiti-Lawal, E. Shahin, Mohamed El Sayed, T. Eid, Lamia Rouis, Qingfeng Huang
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引用次数: 0

摘要

注水开发是油田开发中应用最广泛的方法之一。尽管它们的实施范围很广,但由于缺乏监控和优化工具来指导快节奏的决策,这些操作瓶颈导致大多数都不是最优的。本文提出了一种新颖的机器学习,简化物理方法来优化苏伊士湾异常复杂的海上注水。利用混合数据驱动和物理方法,Nezzezat油藏的水驱方案进行了优化,通过识别井的潜力,提高了储层空隙的替换,提高了产油量,减少了产水量。作为研究的副产品,对复杂的断层系统也有了更好的了解。包括地质认识及其不确定性是必须保存的关键因素之一。利用所有地质属性以及产量来解决压力和井间通信问题。随后通过机器学习算法进行补充,以解决井间连接的分流问题。结合井间连通性和分段流动,进行了优化,以达到采油和降低含水率的最佳条件。由于这种方法的计算需求较低,因此可以实现全局优化,因为必须运行数千到数百万个实现才能在满足所有约束的情况下获得最佳解决方案。所有这些都是在运行传统油藏模拟所需时间的一小部分内完成的。对于本案例,本文将介绍基础物理和数据驱动算法,以及为验证结果而进行的盲测。除了方法的内部工作外,本文将更多地关注结果以指导操作决策。这包括海上油田的所有复杂限制条件,以及在达到每口井的最佳生产和注入速度时的最佳油藏管理实践。在一定程度上降低了含水率的同时,实现了产量的增加,同时满足了油井和平台的限制。虽然这些代表了特定月份的收益,但优化场景可以每周或每月运行一次,以捕获问题的动态性质和可能出现的任何操作限制。能够毫不费力地更新模型和运行优化场景,从而实现前瞻性的操作决策,从而最大化资产的价值。本文采用的方法解决了该问题的关键物理问题,并用机器学习算法补充了其余问题。这种新颖且非常实用的方法有助于做出最佳操作油田的决策。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Rapid and Efficient Waterflood Optimization Using Augmented AI Approach in a Complex Offshore Field
Waterfloods are amongst the most widely implemented methods for oil field development. Despite their vast implementation, operational bottlenecks such as lack of surveillance and optimization tools to guide fast paced decisions render most of these sub-optimal. This paper presents a novel machine-learning, reduced-physics approach to optimize an exceptionally complex off-shore waterflood in the Gulf of Suez. Leveraging a hybrid data-driven and physics approach, the water flooding scheme in Nezzezat reservoir was optimized to improve reservoir voidage replacement, increase oil production, and reduce water production by identifying potential in wells. As a by-product of the study, a better understanding of the complex fault system was also achieved. Including the geological understanding and its uncertainty is one of the key elements that must be preserved. All geological attributes, along with production rates are used to solve for pressure and inter-well communication. This is later supplemented by machine-learning algorithm to solve for the fractional flow of inter-well connections. Combining the inter-well connectivity and fractional flow, an optimization was performed to reach the best possible conditions for oil gains and water-cut reduction. A global optimization is possible thanks to the low computational demand of this approach, as thousands to millions of realizations must be run to reach the best solution while satisfying all constraints. This is all done in a fraction of the time it takes to run a traditional reservoir simulation. For the present case, the paper will present the underlying physics and data-driven algorithms, along with the blind tests performed to validate the results. In addition to the method's inner workings, the paper will focus more on the results to guide operational decisions. This is inclusive of all the complex constraints of an offshore field, as well as the best reservoir management practices, when reaching optimal production and injection rates for each well. An increase in production was achieved with some reduction in water-cut, while honoring well and platform level limitations. While these represent the gains for a particular month, optimization scenarios can be run weekly or monthly to capture the dynamic nature of the problem and any operational limitations that might arise. The ability to update the models and run optimization scenarios effortlessly allows pro-active operational decisions to maximize the value of the asset. The approach followed in this paper solves for the critical physics of the problem and supplements the remaining with machine learning algorithms. This novel and extremely practical approach facilitate the decision making to operate the field optimally.
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