Delayed ignition of high-pressure hydrogen releases – Experiments and engineering models

IF 3.6 3区工程技术 Q2 ENGINEERING, CHEMICAL

Journal of Loss Prevention in The Process Industries Pub Date : 2025-02-11 DOI:10.1016/j.jlp.2025.105589

Vincent Blanchetière , Adam Armstrong , Yanshu Wang , Romain Jambut , Brian Wilkins , Nicolas Salaün

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引用次数: 0

Abstract

Before operating its first hydrogen transmission pipelines, GRTgaz is developing methods and engineering models for risk assessment and consequences analysis. In this framework, GRTgaz decided in 2022 to launch an experimental campaign to understand the consequences of delayed ignition of high-pressure pure hydrogen releases, in open field. The tests also included ignited releases of methane-hydrogen mixture, with 2% and 20% of hydrogen. GRTgaz was associated with Storengy to fund this campaign performed by Gexcon AS. The tests took place at the test facility of Gexcon in Sotra island, close to Bergen (Norway).

The campaign was divided in two test series. The phase 1 aimed at characterising gas concentration in the release axis to provide validation data for simple models and to facilitate the positioning of igniter for the explosion tests, in phase 2. In this second phase, the releases were ignited by chemical devices or electrical sparks, located in the axis at different equivalence ratio. The release system designed by Gexcon enabled to perform 40 barg releases through calibrated orifices of 4 and 6 mm. In total, 15 tests were performed for the first phase with unignited releases and 29 explosion tests for the second phase. All tests are steady-state horizontal releases.

The test results provide comprehensive data to better understand hydrogen jet explosion and challenge engineering models. The maximal overpressures were well above the blind predictions, with records over 650 mbar close to ignition region, where about 200 mbar were expected. High-speed videos showed a tremendous acceleration around the ignition source that cause these intense overpressures coupled with very short-duration positive pulses. These results tend to indicate that the overpressure is produced in a limited volume compared to the flammable plume.

Then, simulations with the PERSEE + software are compared to the experiments. Dispersion results are in good agreement with the recorded concentration with a relative deviation around ± 30%. For overpressures, the prediction in the far field is also acceptable, whereas effects in the near field are often underpredicted. The article finally discusses about improvement of engineering models to estimate consequences of a delayed ignition of high-pressure hydrogen releases.

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高压氢释放的延迟点火。实验和工程模型

在运行第一条输氢管道之前，GRTgaz正在开发风险评估和后果分析的方法和工程模型。在此框架下，GRTgaz于2022年决定启动一项实验活动，以了解在开放领域延迟点燃高压纯氢释放的后果。测试还包括点燃释放的甲烷-氢混合物，氢气含量分别为2%和20%。GRTgaz与Storengy合作，为gexon AS开展的这项活动提供资金。试验在靠近卑尔根（挪威）的索特拉岛的gexon试验设施进行。该运动分为两个测试系列。第一阶段的目的是表征释放轴上的气体浓度，为简单模型提供验证数据，并促进第二阶段爆炸试验点火器的定位。在第二阶段，释放物被位于轴线上的化学装置或电火花以不同的等效比点燃。Gexcon设计的释放系统能够通过校准的4和6mm孔进行40次bar释放。总共在第一阶段进行了15次未点燃释放试验，在第二阶段进行了29次爆炸试验。所有测试都是稳态水平释放。试验结果为更好地理解氢射流爆炸和挑战工程模型提供了全面的数据。最大超压远高于盲目预测，在接近点火区域的记录超过650毫巴，而预期约为200毫巴。高速视频显示，点火源周围有巨大的加速度，导致这些强烈的超压，加上持续时间非常短的正脉冲。这些结果倾向于表明，与可燃羽流相比，超压是在有限的体积内产生的。然后用PERSEE +软件进行了仿真与实验对比。分散结果与记录的浓度吻合较好，相对偏差在±30%左右。对于超压，远场的预测也是可以接受的，而近场的影响往往被低估。文章最后讨论了工程模型的改进，以估计高压氢释放延迟点火的后果。

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 Loss Prevention in The Process Industries 工程技术-工程：化工

CiteScore

7.20

自引率

14.30%

发文量

226

审稿时长

52 days

期刊介绍： The broad scope of the journal is process safety. Process safety is defined as the prevention and mitigation of process-related injuries and damage arising from process incidents involving fire, explosion and toxic release. Such undesired events occur in the process industries during the use, storage, manufacture, handling, and transportation of highly hazardous chemicals.