Enhancing safety in hydrogen storage: Understanding the dynamic process in hydrogen-methane mixtures during the pressurized leakage

IF 6.9 2区环境科学与生态学 Q1 ENGINEERING, CHEMICAL

Process Safety and Environmental Protection Pub Date : 2024-10-31 DOI:10.1016/j.psep.2024.10.100

Qin Huang, Z.Y. Sun, Ya-Long Du

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引用次数: 0

Abstract

Using natural gas pipelines for hydrogen-doped transportation represents a cost-effective solution for large-scale and long-distance hydrogen transport. However, concerns have been raised regarding the potential for leakage under high-pressure conditions, which could result in the spontaneous combustion of the leaking hydrogen. It is, therefore, imperative to understand the gas dynamics involved in methane-hydrogen mixtures during high-pressure leaks to ensure the safety of hydrogen storage. In the present work, the release process and the spontaneous ignition of hydrogen/methane mixtures with a hydrogen blending ratio from 0.1 to 1.0 from pressurized storage containers (20 MPa) have been numerically studied upon validated models. The findings indicate that spontaneous ignition occurs in the mixtures with any hydrogen blending ratios under the releasing pressure of 20 MPa, but the methane component is not involved in the initial combustion if the hydrogen blending ratio is less than 0.5. As the hydrogen blending ratio increases, more combustible components are involved in the initial ignition, and the location of the initial ignition turns closer to the leakage port. Meanwhile, as the hydrogen blending ratio rises from 0.1 to 1.0, the shockwave propagation is accelerated with the moment the shockwave first reflects is advanced from 58 to 60 μs to 22–24 μs, and the maximum temperature in the early leakage will exceed 3000 K. Furthermore, a higher hydrogen blending ratio leads to a more rapid pressure rise in the external space (reaching peak pressure at 191 μs for pure hydrogen) and forming a Mach disk structure with higher Mach numbers (around 7). These findings provide critical insights for understanding the combustion behavior of hydrogen/methane mixtures in high-pressure pipelines and offer valuable guidance for developing safety protocols and infrastructure designs.

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提高氢气储存的安全性：了解加压泄漏期间氢-甲烷混合物的动态过程

利用天然气管道进行掺氢运输是一种成本效益高的大规模长距离氢运输解决方案。然而，人们担心在高压条件下可能发生泄漏，从而导致泄漏氢气自燃。因此，当务之急是了解高压泄漏时甲烷-氢气混合物中的气体动力学，以确保氢气储存的安全性。在本研究中，我们利用经过验证的模型对氢气混合比为 0.1 至 1.0 的氢气/甲烷混合物从加压存储容器（20 兆帕）中的释放过程和自燃进行了数值研究。研究结果表明，在 20 兆帕的释放压力下，任何氢气混合比的混合物都会发生自燃，但如果氢气混合比小于 0.5，甲烷成分不会参与初始燃烧。随着氢气混合比的增加，更多的可燃成分参与了初始点火，初始点火的位置也变得更靠近泄漏口。同时，当氢混合比从 0.1 上升到 1.0 时，冲击波传播速度加快，冲击波首次反射的时刻从 58 至 60 μs 提前到 22 至 24 μs，早期泄漏的最高温度将超过 3000 K。此外，氢气混合比越高，外部空间的压力上升越快（纯氢在 191 μs 达到峰值压力），并形成马赫数较高（7 左右）的马赫盘结构。这些发现为理解高压管道中氢气/甲烷混合物的燃烧行为提供了重要见解，并为制定安全协议和基础设施设计提供了宝贵指导。

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

Process Safety and Environmental Protection 环境科学-工程：化工

CiteScore

11.40

自引率

15.40%

发文量

929

审稿时长

8.0 months

期刊介绍： The Process Safety and Environmental Protection (PSEP) journal is a leading international publication that focuses on the publication of high-quality, original research papers in the field of engineering, specifically those related to the safety of industrial processes and environmental protection. The journal encourages submissions that present new developments in safety and environmental aspects, particularly those that show how research findings can be applied in process engineering design and practice. PSEP is particularly interested in research that brings fresh perspectives to established engineering principles, identifies unsolved problems, or suggests directions for future research. The journal also values contributions that push the boundaries of traditional engineering and welcomes multidisciplinary papers. PSEP's articles are abstracted and indexed by a range of databases and services, which helps to ensure that the journal's research is accessible and recognized in the academic and professional communities. These databases include ANTE, Chemical Abstracts, Chemical Hazards in Industry, Current Contents, Elsevier Engineering Information database, Pascal Francis, Web of Science, Scopus, Engineering Information Database EnCompass LIT (Elsevier), and INSPEC. This wide coverage facilitates the dissemination of the journal's content to a global audience interested in process safety and environmental engineering.