Distributed Real-Time Multi-Pad Steam Allocation Optimization

Day 1 Wed, March 15, 2023 Pub Date : 2023-03-10 DOI:10.2118/212757-ms

Najmudeen Sibaweihi, J. Trivedi

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引用次数: 1

Abstract

In Steam-Assisted Gravity Drainage (SAGD) recovery, optimal real-time steam allocation from a shared steam generator to the physically coupled multi-pads can significantly improve long-term performance goals. However, multi-pad real-time optimization (RTO) with first-principle models can be computationally intensive. Furthermore, general-purpose optimization algorithms in RTO do not consider the future state beyond the prediction horizons to be optimized and treat the optimization problem as a long-term optimization process. Since steam is the primary cost factor in SAGD, Key Performance Indicators (KPI) such as Net Present Value (NPV), when used in RTO, result in low steam injection impeding steam chamber growth during the build-up and normal SAGD operational phase. Therefore, balancing steam chamber development and economics becomes essential for SAGD well-pads using RTO to meet long-term goals. In this contribution, we implement the Alternating Direction Method of Multipliers (ADMM) and a dynamic data-driven model to reduce the computational cost of RTO. ADMM coordinates in real-time field-wide use of shared steam generation. The shared steam generation is a market commodity traded between the pads, with global coordination in real-time perturbation of their market prices. Four SAGD KPIs are implemented for a multi-pad RTO of the SAGD normal operations phase to see which KPI eventually grows the steam chamber without negatively affecting the long-term economic performance. A SAGD field with four pads with 33 well-pairs shows that for all four pads, an economic-based KPI limits the achievement of long-term goals because it cannot account for the future state beyond the horizon under consideration due to hindered steam chamber growth. For the steam chamber expansion and bitumen recovery KPI, high recovery and economic performance are achieved, but with a high resource requirement, leading to a high carbon footprint. On the other hand, an alternating economic and bitumen recovery KPI achieves high economic performance while minimizing resource requirements that decrease carbon footprint.

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分布式实时多pad蒸汽分配优化

在蒸汽辅助重力排水(SAGD)采油中，从共享蒸汽发生器到物理耦合多平台的最佳实时蒸汽分配可以显著提高长期性能目标。然而，基于第一原理模型的多pad实时优化(RTO)可能需要大量的计算。此外，RTO中的通用优化算法不考虑超出预测范围的未来状态进行优化，而是将优化问题视为一个长期的优化过程。由于蒸汽是SAGD的主要成本因素，关键绩效指标(KPI)，如净现值(NPV)，在RTO中使用时，会导致低蒸汽注入，阻碍了SAGD正常运行阶段的蒸汽室增长。因此，平衡蒸汽室开发和经济效益对于使用RTO的SAGD井台实现长期目标至关重要。在这篇贡献中，我们实现了乘法器的交替方向方法(ADMM)和动态数据驱动模型来降低RTO的计算成本。ADMM实时协调现场共享蒸汽发电的使用。共享的蒸汽发电是一个市场商品之间的交易垫，与全球协调实时扰动他们的市场价格。在SAGD正常作业阶段的多pad RTO中实施了四个SAGD KPI，以查看哪个KPI最终会增加蒸汽室，而不会对长期经济性能产生负面影响。一个拥有4个区块、33口井对的SAGD油田表明，对于所有4个区块，基于经济的KPI限制了长期目标的实现，因为它无法考虑由于阻碍蒸汽室增长而超出考虑范围的未来状态。对于蒸汽室膨胀和沥青回收KPI，虽然实现了高采收率和经济效益，但资源要求高，导致碳足迹高。另一方面，交替的经济和沥青回收KPI实现了高经济效益，同时最大限度地减少了资源需求，减少了碳足迹。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Day 1 Wed, March 15, 2023

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