The Design of Hydrogen Saline Aquifer Storage Processes Using a Machine-Learning Assisted Multiobjective Optimization Protocol

IF 3.2 3区工程技术 Q1 ENGINEERING, PETROLEUM

SPE Journal Pub Date : 2024-01-01 DOI:10.2118/218405-pa

Qian Sun, Miao Zhang, Turgay Ertekin

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引用次数: 0

Abstract

The global effort toward decarbonization has intensified the drive for low-carbon fuels. Green hydrogen, harnessed from renewable sources such as solar, wind, and hydropower, is emerging as a clean substitute. Challenges due to the variable needs and instable green hydrogen production highlight the necessity for secure and large-scale storage solutions. Among the geological formations, deep saline aquifers are noteworthy due to their abundant capacity and ease of access. Addressing technical hurdles related to low working gas recovery rates and excessive water production requires well-designed structures and optimized cushion gas volume. A notable contribution of this study is the development of a multiobjective optimization (MOO) protocol using a Kalman filter-based approach for early stopping. This method maintains solution accuracy while employing the MOO protocol to design the horizontal wellbore length and cushion gas volume in an aquifer hydrogen storage project and accounting for multiple techno-economic goals. Optimization outcomes indicate that the proposed multiobjective particle swarm (MOPSO) protocol effectively identifies the Pareto optimal sets (POSs) in both two- and three-objective scenarios, requiring fewer iterations. Results from the two-objective optimization study, considering working gas recovery efficacy and project cost, highlight that extending the horizontal wellbore improves hydrogen productivity but may lead to unexpected fluid extraction. The three-objective optimized hydrogen storage design achieves a remarkable 94.36% working gas recovery efficacy and a 59.59% reduction in water extraction. The latter represents a significant improvement compared to the reported literature data.

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利用机器学习辅助多目标优化协议设计含盐含水层储氢工艺

全球去碳化的努力加强了对低碳燃料的需求。利用太阳能、风能和水电等可再生能源生产的绿色氢气正在成为一种清洁替代品。由于绿色氢气的需求多变且生产不稳定，因此需要安全、大规模的存储解决方案。在各种地质构造中，深层含盐地下蓄水层因其储量丰富且易于获取而值得关注。要解决与工作气体回收率低和产水量过多有关的技术障碍，需要精心设计的结构和优化的缓冲气量。本研究的一个显著贡献是开发了一种多目标优化（MOO）协议，使用基于卡尔曼滤波器的方法进行早期停产。该方法在采用 MOO 协议设计含水层储氢项目中的水平井筒长度和缓冲气量的同时，保持了解决方案的准确性，并考虑了多个技术经济目标。优化结果表明，所提出的多目标粒子群（MOPSO）协议能有效识别双目标和三目标情况下的帕累托最优集（POSs），所需的迭代次数较少。考虑到工作气回收效率和项目成本，双目标优化研究的结果突出表明，延长水平井筒可提高氢气生产率，但可能导致意外的流体抽取。三目标优化储氢设计实现了 94.36% 的工作气回收率和 59.59% 的抽水量。与文献报道的数据相比，后者有了明显改善。

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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来源期刊

SPE Journal 工程技术-工程：石油

CiteScore

7.20

自引率

11.10%

发文量

229

审稿时长

4.5 months

期刊介绍： Covers theories and emerging concepts spanning all aspects of engineering for oil and gas exploration and production, including reservoir characterization, multiphase flow, drilling dynamics, well architecture, gas well deliverability, numerical simulation, enhanced oil recovery, CO2 sequestration, and benchmarking and performance indicators.