System Resilience of a Liquid Hydrogen Terminal During Loading and Unloading Operations

Q3 Engineering IFAC-PapersOnLine Pub Date : 2024-01-01 DOI:10.1016/j.ifacol.2024.08.147
Lucas Claussner, Federico Ustolin
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Abstract

Hydrogen technologies are playing an increasing role in transportation and industry. Key for taking maximum advantage out of the great gravimetric energy density of hydrogen are feasible and safe storage and transfer concepts. For the successful implementation of a hydrogen-based society with several green industrial initiatives, it is indispensable to develop an infrastructure of liquid hydrogen (LH2) terminals and tanker ships with the capability to bunker LH2. Liquid hydrogen might be used to store and transport large quantities of hydrogen. LH2 is a cryogenic fluid, so double-walled vacuum insulated tanks are required to keep it cold for long periods of time until further distribution or use. Whether transportation sector or industry, to date there is little knowledge on safety related issues available. Main concern when handling hydrogen are accidental releases that can lead to integrity damage on materials and structures, fires, and explosions. Assuming that LH2 infrastructures will be widely deployed and in use all over the globe, accidents are possible to occur during loading and unloading of LH2 bunkering facilities. Therefore, it is necessary to conduct a detailed risk assessment that focuses on system resilience to improve the capabilities of the facility to keep its functionality up when errors occur. This study refers to the LH2 storage tank installed in the LH2 terminal in Kobe, Japan. This stationary storage tank is an essential element of the terminal that was constructed by the Hydrogen Energy Supply Chain Technology Research Association (HySTRA). HySTRA aims at the distribution of hydrogen in liquified form by ship from Australia to Japan. To date, there is only little data available regarding the facility in Kobe. Nevertheless, due to the novelty of the technology the risk for accidents to occur might be higher than in conventional fuel distribution terminals. Accidents might happen due to technical failures, human errors, or external causes such as natural events. The consequences could be catastrophic. Some of these may expose structures and personnel to extreme low temperatures, fires, and explosions which may hinder bunkering operations of the facility in Kobe. This study gives an overview on possible scenarios that lead to loss of containment and provides an insight in the process of evaluating system resilience during such a scenario. This work details with a framework for assessing system resilience applied to LH2 storage facilities. The system resilience calculation involves the examination of a critical hydrogen accident database and provides suitable preventive and mitigative safety barriers.

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液氢终端在装卸作业期间的系统恢复能力
氢技术在交通和工业领域发挥着越来越重要的作用。要最大限度地利用氢的巨大重力能量密度,关键在于可行且安全的储存和传输概念。要成功实现一个以氢为基础的社会,并采取多项绿色工业措施,就必须发展液氢(LH2)码头和具备液氢燃料舱能力的油轮等基础设施。液氢可用于储存和运输大量氢气。液氢是一种低温液体,因此需要双层真空绝热罐来长期保持低温,直至进一步分配或使用。无论是运输部门还是工业部门,迄今为止对安全相关问题的了解都很少。处理氢气时的主要问题是意外释放,这可能导致材料和结构的完整性受损、火灾和爆炸。假设 LH2 基础设施将在全球范围内广泛部署和使用,那么在装卸 LH2 加氢设施时就有可能发生事故。因此,有必要进行详细的风险评估,重点关注系统的恢复能力,以提高设施在发生错误时保持功能正常的能力。本研究指的是安装在日本神户 LH2 终端的 LH2 储罐。该固定式储罐是氢能供应链技术研究协会(HySTRA)建造的终端的重要组成部分。HySTRA 的目标是用船将液化氢从澳大利亚运往日本。迄今为止,有关神户设施的数据还很少。然而,由于该技术的新颖性,发生事故的风险可能高于传统的燃料配送终端。发生事故的原因可能是技术故障、人为失误或自然事件等外部原因。其后果可能是灾难性的。其中一些事故可能会使结构和人员暴露在极端低温、火灾和爆炸中,从而阻碍神户设施的加油作业。本研究概述了导致安全壳损失的可能情况,并深入分析了在这种情况下评估系统恢复能力的过程。这项工作详细介绍了适用于 LH2 储存设施的系统复原力评估框架。系统复原力计算涉及对关键氢事故数据库的检查,并提供适当的预防和缓解安全屏障。
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来源期刊
IFAC-PapersOnLine
IFAC-PapersOnLine Engineering-Control and Systems Engineering
CiteScore
1.70
自引率
0.00%
发文量
1122
期刊介绍: All papers from IFAC meetings are published, in partnership with Elsevier, the IFAC Publisher, in theIFAC-PapersOnLine proceedings series hosted at the ScienceDirect web service. This series includes papers previously published in the IFAC website.The main features of the IFAC-PapersOnLine series are: -Online archive including papers from IFAC Symposia, Congresses, Conferences, and most Workshops. -All papers accepted at the meeting are published in PDF format - searchable and citable. -All papers published on the web site can be cited using the IFAC PapersOnLine ISSN and the individual paper DOI (Digital Object Identifier). The site is Open Access in nature - no charge is made to individuals for reading or downloading. Copyright of all papers belongs to IFAC and must be referenced if derivative journal papers are produced from the conference papers. All papers published in IFAC-PapersOnLine have undergone a peer review selection process according to the IFAC rules.
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