利用地球物理监测和深度强化学习对地质碳储存操作进行随机控制

IF 4.6 3区 工程技术 Q2 ENERGY & FUELS
Kyubo Noh, Andrei Swidinsky
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引用次数: 0

摘要

地质碳封存(GCS)是在地下注入并封存二氧化碳(CO2)以减少温室气体排放的过程。安全、盈利的地质碳封存操作需要在地质模型不确定的情况下做出有效决策,而地球物理监测通常可以促进这一过程。在本研究中,我们探讨了如何将顺序决策算法与地球物理测量相结合,以实现对 GCS 作业的优化控制。具体来说,我们利用深度强化学习(DRL)开发了一个人工智能模型,将地球物理延时重力和井压监测数据作为输入,并提供最佳二氧化碳注入策略。当前问题的目标是通过使用综合地质统计、储层和地球物理模拟来训练 DRL 代理,使假设的 GCS 作业利润最大化,同时降低诱发地震的可能性。与两个基准--恒定注入策略和使用商业储层模拟器工具箱优化的注入计划--的比较表明,利用深度强化学习从地下监测数据对此类操作进行随机控制是可行的。评估结果表明,DRL 代理行为产生的利润比恒定注水方法平均高出 1%-8%。此外,我们还展示了 DRL 能够生成适用于真实(但之前未见过)地下的最佳注入策略,并对不确定性水平进行了精心管理。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Stochastic control of geological carbon storage operations using geophysical monitoring and deep reinforcement learning

Geological carbon storage (GCS) is the process of injecting and storing carbon dioxide (CO2) in the subsurface to reduce greenhouse gas emissions. Safe and profitable GCS operations require effective decision-making in the presence of uncertain geological models, a process which can often be facilitated with geophysical monitoring. In this study, we examine how sequential decision-making algorithms can be combined with geophysical measurements for the optimal control of GCS operations. Specifically, we develop an artificial intelligence model using deep reinforcement learning (DRL) that takes geophysical time-lapse gravity and well pressure monitoring data as input and delivers an optimal CO2 injection policy. The objective of the problem at hand is to maximize the profit of a hypothetical GCS operation while mitigating the potential for induced seismicity, by training DRL agents using combined geostatistical, reservoir and geophysical simulation. Comparisons against two benchmarks – a constant injection strategy and an injection schedule optimized using a commercial reservoir simulator toolbox – show that the stochastic control of such operations from subsurface monitoring data using deep reinforcement learning is feasible. Evaluation results show that DRL agent behavior generates profits which are on average 1 to 8 percent higher than what is possible through a constant injection approach. Furthermore, we show that DRL can generate optimal injection policies applicable to the true (yet previously unseen) subsurface given carefully managed levels of uncertainty.

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来源期刊
CiteScore
9.20
自引率
10.30%
发文量
199
审稿时长
4.8 months
期刊介绍: The International Journal of Greenhouse Gas Control is a peer reviewed journal focusing on scientific and engineering developments in greenhouse gas control through capture and storage at large stationary emitters in the power sector and in other major resource, manufacturing and production industries. The Journal covers all greenhouse gas emissions within the power and industrial sectors, and comprises both technical and non-technical related literature in one volume. Original research, review and comments papers are included.
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