用于模拟含水层地下储氢的梯度提升时空神经网络

IF 3.8 2区 物理与天体物理 Q2 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS Journal of Computational Physics Pub Date : 2024-11-08 DOI:10.1016/j.jcp.2024.113557
Jian Wang , Zongwen Hu , Xia Yan , Jun Yao , Hai Sun , Yongfei Yang , Lei Zhang , Junjie Zhong
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引用次数: 0

摘要

含水层地下储氢(UHS)已成为解决可再生能源季节性供需不匹配问题的可行方案。地下储氢系统的数值模拟是优化储氢操作和进行系统风险评估的重要基础。然而,用于这些目的的数值模拟方法通常需要大量数据,这使得数据收集具有挑战性且计算成本高昂,尤其是在涉及多个物理场耦合的情况下。深度学习是解决这一难题的有效工具。在此,我们提出了一种具有梯度增强功能的时空神经网络架构,称为梯度增强时空神经网络(GSTNN)及其变体 GSTNN-s。GSTNN 结合了卷积神经网络(CNN)、长短期记忆网络(LSTM)和自动编码器架构。为了在网络中加入物理约束,引入了气体-水渗流方程和气体对流-扩散方程中的时空梯度算子作为正则项,在时间和空间维度上对训练过程施加物理约束。在预测同质和异质地层中 UHS 的多相流时,GSTNN 在压力场、饱和度场和 H2 浓度场的精度方面均优于 CNN 和 CNN-LSTM。在预测不同渗透率和孔隙度地层中的 UHS 方面,GSTNN-s 的性能也有所提高。所提出的 GSTNN 架构有望提高 UHS 数值模拟的效率,在未来应用于优化 UHS 操作方面具有巨大潜力。
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Gradient-boosted spatiotemporal neural network for simulating underground hydrogen storage in aquifers
Underground hydrogen storage (UHS) in aquifers has emerged as a viable solution to address the seasonal mismatch between supply and demand in renewable energy. Numerical simulation of the UHS serves as a crucial foundation for optimizing storage operations and conducting system risk assessments. However, numerical simulation methods employed for these purposes often demand substantial data, making data collection challenging and computationally expensive, especially in scenarios involving the coupling of multiple physical fields. Deep learning serves as an effective tool in resolving this challenge. Here, we proposed a spatiotemporal neural network architecture with gradient enhancement, denoted as gradient-boosted spatiotemporal neural network (GSTNN) and its variant GSTNN-s. The GSTNN combines a convolutional neural network (CNN), a long short-term memory network (LSTM), and an autoencoder architecture. To incorporate physical constraints into the network, the spatiotemporal gradient operators from the gas-water seepage and gas convection-diffusion equations are introduced as regularization terms, imposing physics-informed constraints on the training process in both temporal and spatial dimensions. In predicting the multiphase flow of UHS in both homogeneous and heterogeneous formations, GSTNN outperforms CNN and CNN-LSTM in terms of the accuracy of pressure, saturation and H2 concentration fields. In terms of predicting UHS in formations with different permeabilities and porosities, GSTNN-s demonstrates improved performance as well. The proposed GSTNN architecture is promising in improving the efficiency of UHS numerical simulation, and has great potential to be applied for optimizing UHS operations in the future.
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来源期刊
Journal of Computational Physics
Journal of Computational Physics 物理-计算机:跨学科应用
CiteScore
7.60
自引率
14.60%
发文量
763
审稿时长
5.8 months
期刊介绍: Journal of Computational Physics thoroughly treats the computational aspects of physical problems, presenting techniques for the numerical solution of mathematical equations arising in all areas of physics. The journal seeks to emphasize methods that cross disciplinary boundaries. The Journal of Computational Physics also publishes short notes of 4 pages or less (including figures, tables, and references but excluding title pages). Letters to the Editor commenting on articles already published in this Journal will also be considered. Neither notes nor letters should have an abstract.
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