加氢机氢气泄漏扩散数值模拟研究

doi:10.16265/j.cnki.issn1003-3033.2026.05.0886

摘要/Abstract

摘要：

为降低加氢机加注过程中因泄漏引发的事故风险,利用Fluent软件模拟35 MPa加氢机氢泄漏扩散过程,研究加氢区罩棚结构下氢泄漏扩散特性,分析泄漏孔径、风速及局部通风等因素对氢气摩尔分数、可燃区域分布的影响。研究结果表明:当加氢软管泄漏孔径为2 mm时,不会在罩棚下表面形成可燃区域,而当泄漏孔径达到5或10 mm时,可在罩棚下表面形成可燃区域,且罩棚下表面摩尔分数最高点在平行于射流中轴线附近。其中,泄漏孔径为10mm,垂直泄漏方向罩棚下侧摩尔分效呈现高斯分布;当环境风向垂直于泄漏方向,风速为2或8 m/s时,可有效减少泄漏加氢机附近氢气积聚;而风速为5 m/s时,在障碍物附近产生涡旋结构,诱导氢气积聚,增加燃爆风险;无环境风条件下,在加氢区加入风机进行局部通风,5或10 m/s均可在2 s内将流场内氢气云摩尔分数稀释至可燃范围以下,而10 m/s的风机风速对稀释泄漏源前方氢气摩尔分数作用更大。

关键词: 加氢机, 氢气泄漏, 氢气扩散, 数值模拟, 泄漏孔径, 环境风速, 局部通风

Abstract:

In order to reduce accident risks caused by leakage during the refueling process, the hydrogen leakage and diffusion behavior of a 35 MPa hydrogen dispenser was numerically simulated using Ansys Fluent. The characteristics of hydrogen leakage and diffusion under the canopy structure in the refueling zone were investigated. The effects of leakage diameters, ambient wind velocity, and local ventilation on hydrogen concentration distribution and the evolution of flammable areas were analyzed. The results show that when the leakage diameter of filling hose is 2 mm, no flammable area is formed on the underside of canopy. However, when the leakage diameter increases to 5 mm and 10 mm, a flammable area can develop on canopy underside. The location of the highest hydrogen concentration on underside of canopy is concentrated near the axis parallel to the jet direction. Specifically, when leakage diameter is 10 mm, the hydrogen concentration on underside of canopy along vertical leakage direction exhibits a Gaussian distribution. When the ambient wind is perpendicular to leakage direction, wind velocities of 2 m/s and 8 m/s can effectively reduce hydrogen accumulation near the leakage hydrogen dispenser. In contrast, at the wind speed of 5 m/s, a vortex structure was formed near obstacles, leading to hydrogen accumulation and increasing the risk of fire and explosion. Under no ambient wind conditions, local ventilation is provided in the refueling zone. When the ventilation velocity reaches 5 m/s and 10 m/s, the hydrogen cloud concentration within the flow field can be successfully diluted to below the flammable limit within 2 s. Moreover, a ventilation velocity of 10 m/s shows a more pronounced effect in reducing the hydrogen concentrations in front of the leakage source.

Key words: hydrogen dispenser, hydrogen leakage, hydrogen diffusion, numerical simulation, leakage diameter, ambient wind velocities, local ventilation

中图分类号:

X932爆炸安全与防火、防爆

谭路遥, 姚勇征, 潘傲澜, 胡茂炜. 加氢机氢气泄漏扩散数值模拟研究[J]. 中国安全科学学报, 2026, 36(5): 224-233.

Tan Luyao, Yao Yongzheng, Pan Aolan, Hu Maowei. Numerical simulation of hydrogen diffusion from hydrogen dispenser leakage[J]. China Safety Science Journal, 2026, 36(5): 224-233.

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工况序号	泄漏孔径/ mm	泄漏流量/ (kg/s)	等效直径/ mm	环境风速/ (m/s)	环境风向	风机风速/ (m/s)
1	2	0.068 8	23.25	0	—	—
2				2	+X	—
3				5	+X	—
4				8	+X	—
5				0	—	5
6				0	—	10
7	5	0.430 0	58.12	0	—	—
8	10	1.720 3	116.24	0	—	—

曲线序号	坐标
1	(9.5, 7.6, 108)	(24, 7.6, 108)
2	(9.5, 7.6, 106)	(9.5, 7.6, 106)
3	(9.5, 7.6, 104)	(24, 7.6, 104)