DeepPipe: A multi-stage knowledge-enhanced physics-informed neural network for hydraulic transient simulation of multi-product pipeline

IF 10.4 1区 计算机科学 Q1 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS
Jian Du , Haochong Li , Kaikai Lu , Jun Shen , Qi Liao , Jianqin Zheng , Rui Qiu , Yongtu Liang
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引用次数: 0

Abstract

In the chemical pipelining industry, owing to the high-pressure transportation process, an accurate hydraulic transient simulation tool plays a central role in preventing the slack line flow and overpressure from causing pipeline operation treacherous. Nevertheless, the current model-driven method often faces challenges in balancing computational efficiency with accuracy, and the existing data-driven models struggle to produce explainable results from the physics perspectives since insufficient theoretical principles are incorporated into the model training. Additionally, the existing physics-informed learning architecture fails to achieve a gradient-balanced training, resulting from the significant magnitude difference in outputs and multiple loss terms. Consequently, a Multi-Stage Knowledge-Enhanced Physics-Informed Neural Network (MS-KE-PINN) is proposed for the hydraulic transient simulation of multi-product pipelines. To enforce the neural network producing simulation results with high consistency to physical laws, the governing equations, boundary, and initial condition are incorporated into the training process for an efficient mesh-free simulation. Then, considering that the significant magnitude difference between outputs can easily lead to deficient performance in the gradient descent, the magnitude conversion on the outputs and the equivalent conversion of the governing equations are implemented to enhance the training effect of the neural network. Subsequently, to tackle the imbalanced gradient of multiple loss terms with fixed weights, a multi-stage hierarchical training strategy is designed to improve the approximation capacity of the neural network. Numerical simulation cases demonstrate a better approximation function of the proposed model than the state-of-art models, while the mean absolute percentage errors yielded by MS-KE-PINN are reduced by 77.4 %, 88.7 %, and 87.8 % in three simulation operation conditions for pressure prediction. Furthermore, experimental investigations from a real-world multi-product pipeline suggest that the proposed model can still draw accurate simulation results even under complex and dynamic hydraulic transient scenarios in practice, with root mean squared errors reduced by 94.8 % and 80 % than that of the physics-informed neural network. To this end, the proposed model can conduct accurate and effective hydraulic transient analysis, thus ensuring the safe operation of the pipeline.
DeepPipe:用于多产品管道水力瞬态模拟的多级知识增强型物理信息神经网络
在化工管道行业中,由于高压运输过程,精确的水力瞬态模拟工具在防止松弛的管线流动和超压造成管道运行危险方面发挥着核心作用。然而,目前的模型驱动方法往往面临计算效率与准确性之间的平衡问题,现有的数据驱动模型也很难从物理学角度得出可解释的结果,因为在模型训练中没有充分纳入理论原则。此外,现有的物理信息学习架构无法实现梯度平衡训练,这是因为输出和多个损失项之间存在显著的量级差异。因此,针对多产品管道的水力瞬态模拟,提出了多阶段知识增强型物理信息神经网络(MS-KE-PINN)。为使神经网络生成的仿真结果与物理规律高度一致,在训练过程中纳入了治理方程、边界和初始条件,以实现高效的无网格仿真。然后,考虑到输出量之间的巨大差异容易导致梯度下降过程中的性能缺陷,我们对输出量进行了量级转换,并对控制方程进行了等效转换,以增强神经网络的训练效果。随后,针对固定权重的多个损失项梯度不平衡的问题,设计了多级分层训练策略,以提高神经网络的逼近能力。数值模拟结果表明,与最先进的模型相比,所提出的模型具有更好的逼近功能,而在压力预测的三种模拟操作条件下,MS-KE-PINN 所产生的平均绝对百分比误差分别减少了 77.4%、88.7% 和 87.8%。此外,对实际多产品管道的实验研究表明,即使在复杂多变的液压瞬态情况下,所提出的模型仍能得出准确的模拟结果,其均方根误差比物理信息神经网络分别减少了 94.8% 和 80%。因此,所提出的模型可以进行准确有效的水力瞬态分析,从而确保管道的安全运行。
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
Journal of Industrial Information Integration
Journal of Industrial Information Integration Decision Sciences-Information Systems and Management
CiteScore
22.30
自引率
13.40%
发文量
100
期刊介绍: The Journal of Industrial Information Integration focuses on the industry's transition towards industrial integration and informatization, covering not only hardware and software but also information integration. It serves as a platform for promoting advances in industrial information integration, addressing challenges, issues, and solutions in an interdisciplinary forum for researchers, practitioners, and policy makers. The Journal of Industrial Information Integration welcomes papers on foundational, technical, and practical aspects of industrial information integration, emphasizing the complex and cross-disciplinary topics that arise in industrial integration. Techniques from mathematical science, computer science, computer engineering, electrical and electronic engineering, manufacturing engineering, and engineering management are crucial in this context.
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