Hydrogen Tank Rupture in Fire in the Open Atmosphere: Hazard Distance Defined by Fireball

Макаров, Д. Н.; Shentsov, Volodymyr; Кузнецов, М.; Molkov, Vladimir

doi:10.3390/hydrogen2010008

Cited by 12 publications

(10 citation statements)

References 17 publications

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“…Hydrogen fires pose distinct difficulties because of the gas's elevated flammability and the imperceptible quality of the flame fire [55][56][57][58]. Specialized and highly effective fire-suppression techniques are necessary for hydrogen refueling stations.…”

Section: Fire-suppression Techniques For Hydrogen Firesmentioning

confidence: 99%

An Exploration of Safety Measures in Hydrogen Refueling Stations: Delving into Hydrogen Equipment and Technical Performance

Genovese,

Blekhman,

Fragiacomo

2024

Hydrogen

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The present paper offers a thorough examination of the safety measures enforced at hydrogen filling stations, emphasizing their crucial significance in the wider endeavor to advocate for hydrogen as a sustainable and reliable substitute for conventional fuels. The analysis reveals a wide range of crucial safety aspects in hydrogen refueling stations, including regulated hydrogen dispensing, leak detection, accurate hydrogen flow measurement, emergency shutdown systems, fire-suppression mechanisms, hydrogen distribution and pressure management, and appropriate hydrogen storage and cooling for secure refueling operations. The paper therefore explores several aspects, including the sophisticated architecture of hydrogen dispensers, reliable leak-detection systems, emergency shut-off mechanisms, and the implementation of fire-suppression tactics. Furthermore, it emphasizes that the safety and effectiveness of hydrogen filling stations are closely connected to the accuracy in the creation and upkeep of hydrogen dispensers. It highlights the need for materials and systems that can endure severe circumstances of elevated pressure and temperature while maintaining safety. The use of sophisticated leak-detection technology is crucial for rapidly detecting and reducing possible threats, therefore improving the overall safety of these facilities. Moreover, the research elucidates the complexities of emergency shut-off systems and fire-suppression tactics. These components are crucial not just for promptly managing hazards, but also for maintaining the station’s structural soundness in unanticipated circumstances. In addition, the study provides observations about recent technical progress in the industry. These advances effectively tackle current safety obstacles and provide the foundation for future breakthroughs in hydrogen fueling infrastructure. The integration of cutting-edge technology and materials, together with the development of upgraded safety measures, suggests a positive trajectory towards improved efficiency, dependability, and safety in hydrogen refueling stations.

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Section: Fire-suppression Techniques For Hydrogen Firesmentioning

confidence: 99%

An Exploration of Safety Measures in Hydrogen Refueling Stations: Delving into Hydrogen Equipment and Technical Performance

Genovese,

Blekhman,

Fragiacomo

2024

Hydrogen

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“…The hazards of these substances are also taken into account here, as it can be expected that, in a spill, alternative fuels come into contact with water. The hazards of thermolyzed substances are considered as well because of the temperature of hydrogen fires (2400 K) [33]. This chapter provides a comprised hazard identification of the hydrogen carriers mentioned in the previous section, starting with two LOHCs and followed by the borohydrides, ammonia and methanol.…”

Section: Hazard Identification Of Hydrogen Carriers and Selected Refe...mentioning

confidence: 99%

Hazard Identification of Hydrogen-Based Alternative Fuels Onboard Ships

van Rheenen,

Scheffers,

Zwaginga

et al. 2023

Sustainability

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It is essential to use alternative fuels if we are to reach the emission reduction targets set by the IMO. Hydrogen carriers are classified as zero-emission, while having a higher energy density (including packing factor) than pure hydrogen. They are often considered as safe alternative fuels. The exact definition of what safety entails is often lacking, both for hydrogen carriers as well as for ship safety. The aim of this study is to review the safety of hydrogen carriers from two perspectives, investigating potential connections between the chemical and maritime approaches to safety. This enables a reasoned consideration between safety aspects and other design drivers in ship design and operation. The hydrogen carriers AB, NaBH4, KBH4 and two LOHCs (NEC and DBT) are taken into consideration, together with a couple reference fuels (ammonia, methanol and MDO). After the evaluation of chemical properties related to safety and the scope of the current IMO safety framework, it can be concluded that safety remains a vague and non-explicit concept from both perspectives. Therefore, further research is required to prove the safe application of hydrogen carriers onboard ships.

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“…또한 소방대원에 대한 복사열에 대한 안전기준은 Makarov 와 Tretsiakova (4) 의 자료를 참고할 수 있으며, 안전온도 기 준은 ISO 19880-1. gaseous hydrogen-fueling stations. Part 1 에서 위험거리(hazard distance)의 기준으로 3가지 온도영역 을 Table 2와 같이 제시하고 있다 (5) .…”

Section: 제트화염 위험성과 안전기준unclassified

Experimental Study on the Thermal Effect according to the Distance around a Hydrogen Jet Flame

Kwon¹,

Cho²,

Park³

2021

Fire Sci. Eng.

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In this study, the safe distance in the case of a hydrogen vehicle fire was analyzed according to the temperature distribution around a hydrogen gas jet flame formed by the thermally activated pressure relief device operation of a hydrogen storage container. The experiment was conducted while 70 MPa hydrogen gas was released from a 1.8-mm-diameter nozzle to a 1.8- × 1.8 m fire-resistant structure wall for distances of 2 and 4 m between the nozzle output and the wall. To analyze the temperature around the hydrogen gas jet flame, five fire-fighting heat-protective hood test samples, certified by the Korea Fire Institute, and temperature sensors were installed every 1 m from the center of the jet flame in the vertical direction to the direction of the flame. In the experiment, the temperature around the jet flame was measured to observe the safe distance for firefighters. The results show that the safe distances at 70°C or less, which is harmless to firefighters, were 5 m without a heat-protective hood and 3 m with a heat-protective hood. In addition, it was confirmed that the direction of the jet flame and blocking by obstacles affect the safe distance during fire-fighting and rescue activities by firefighters.

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Hydrogen Tank Rupture in Fire in the Open Atmosphere: Hazard Distance Defined by Fireball

Cited by 12 publications

References 17 publications

An Exploration of Safety Measures in Hydrogen Refueling Stations: Delving into Hydrogen Equipment and Technical Performance

An Exploration of Safety Measures in Hydrogen Refueling Stations: Delving into Hydrogen Equipment and Technical Performance

Hazard Identification of Hydrogen-Based Alternative Fuels Onboard Ships

Experimental Study on the Thermal Effect according to the Distance around a Hydrogen Jet Flame

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