A Machine Learning Pressure Emulator for Hydrogen Embrittlement
Abstract
A recent alternative for hydrogen transportation as a mixture with natural gas is blending it into natural gas pipelines. However, hydrogen embrittlement of material is a major concern for scientists and gas installation designers to avoid process failures. In this paper, we propose a physics-informed machine learning model to predict the gas pressure on the pipes' inner wall. Despite its high-fidelity results, the current PDE-based simulators are time- and computationally-demanding. Using simulation data, we train an ML model to predict the pressure on the pipelines' inner walls, which is a first step for pipeline system surveillance. We found that the physics-based method outperformed the purely data-driven method and satisfy the physical constraints of the gas flow system.
Cite
Text
Chau et al. "A Machine Learning Pressure Emulator for Hydrogen Embrittlement." ICML 2023 Workshops: SynS_and_ML, 2023.Markdown
[Chau et al. "A Machine Learning Pressure Emulator for Hydrogen Embrittlement." ICML 2023 Workshops: SynS_and_ML, 2023.](https://mlanthology.org/icmlw/2023/chau2023icmlw-machine/)BibTeX
@inproceedings{chau2023icmlw-machine,
title = {{A Machine Learning Pressure Emulator for Hydrogen Embrittlement}},
author = {Chau, Minh and de Sousa Almeida, João Lucas and Alhajjar, Elie and Jr, Alberto Costa Nogueira},
booktitle = {ICML 2023 Workshops: SynS_and_ML},
year = {2023},
url = {https://mlanthology.org/icmlw/2023/chau2023icmlw-machine/}
}