LNG储罐泄漏扩散模拟分析

doi:10.16265/j.cnki.issn1003-3033.2023.02.0332

摘要/Abstract

摘要：

为预防液化天然气(LNG)储罐泄漏安全事故,利用PHAST软件,以湘潭新奥荷塘储配站的储罐为研究对象,探究不同泄漏孔径及风速2个条件对LNG蒸气云泄漏扩散距离及泄漏导致的喷射火与爆炸范围的影响机制。结果表明:蒸气云泄漏扩散距离、喷射火辐射影响半径及爆炸超压影响半径与泄漏孔径尺寸成正比,蒸气云泄漏扩散距离、爆炸超压影响半径与风速成反比。泄漏孔径为25 mm的泄漏场景,易燃易爆区临界距离、喷射火辐射死亡区半径、爆炸超压50 kPa对应超压半径分别是5 mm场景的10、7、8倍;泄漏孔径为100 mm的泄漏场景,易燃易爆临界距离、喷射火辐射死亡区半径、爆炸超压50 kPa对应超压半径分别是5 mm场景的37、21、33倍。

关键词: 液化天然气(LNG), 储罐泄漏, 蒸气云, 扩散距离, 喷射火

Abstract:

In order to prevent the leakage accident of LNG storage tank, using PHAST software, taking the storage tank of Xiangtan Xinao Hetang storage and distribution station as the research object, this study explored the influence of different leakage aperture and different wind speed on the diffusion distance of LNG steam cloud leakage and the spray fire and explosion range caused by the leakage. The simulation results show that the steam cloud leakage diffusion distance, fire radiation influence radius and explosion overpressure influence radius are directly proportional to the size of the leakage aperture, while the steam cloud leakage diffusion distance and explosion overpressure influence radius are inversely proportional to the wind speed. In the leakage scenario with a leakage aperture of 25 mm, the critical distance of the flammable and explosive zone, the radius of the blast radiation dead zone and the overpressure radius corresponding to the explosion overpressure of 50 kPa are 10, 7 and 8 times that in the 5 mm scenario, respectively. In the leakage scenario with a leakage aperture of 100 mm, the critical distance of flammability and explosion, the radius of the dead zone of jet fire radiation, and the overpressure radius corresponding to the explosion overpressure of 50 kPa are 37, 21 and 33 times that in the scenario of 5 mm, respectively.

Key words: liquefied natural gas (LNG), tank leakage, steam cloud, diffusion distance, jet fire

游波, 罗骁, 施式亮, 鲁义, 李敏, 刘勇. LNG储罐泄漏扩散模拟分析[J]. 中国安全科学学报, 2023, 33(2): 125-131.

YOU Bo, LUO Xiao, SHI Shiliang, LU Yi, LI Min, LIU Yong. Simulation analysis of leakage and diffusion in LNG storage tank[J]. China Safety Science Journal, 2023, 33(2): 125-131.

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I/(kW·m^-2)	对设备的损害	对人体的伤害 (暴露时间)
37.5	设备完全损坏	1%死亡(10 s) 100%死亡(60 s)
25	无火焰情况下,木材在此长时间辐射下燃烧的最小能量	重大损伤(10 s) 100%死亡(60 s)
12.5	有火焰情况下,在此塑料融化及木材燃烧的最低能量	1度烧伤(10 s) 1%死亡(60 s)
4	—	暴露16 s以上, 皮肤有痛感

参数	取值	参数	取值
温度/℃	17	泄漏点高度/m	1
单一储罐有效容积/m³	70.92	储存压力/MPa	0.6
风速/(m·s^-1)	1.9、1.5、3、5	储存温度/℃	-162
d/mm	5、25、100	关注时间/s	1200

泄漏孔径/mm	扩散距离/m	定义区
5	<11.1	易燃易爆区
5	>27.2	安全区
25	<105.4	易燃易爆区
25	>143.8	安全区
100	<413.9	易燃易爆区
100	>562.0	安全区

泄漏孔径/mm	I/(kW·m^-2)	辐射范围/m	定义区域
5	≥37.5	长轴7.1、短轴3.8	死亡区
	25.0 ~37.5	长轴7.9、短轴5.6	重伤区
	12.5 ~25.0	长轴4.5、短轴4.5	危险区
	4 ~12.5	长轴17.2、短轴11.8	轻伤区
	≤4	—	安全区

泄漏孔径/mm	I/(kW·m^-2)	辐射范围/m	定义区域
25	≥37.5	长轴49.6、短轴15.4	死亡区
	25.0~37.5	长轴55.1、短轴23.4	重伤区
	12.5 ~25.0	长轴60.6、短轴41.2	危险区
	4 ~12.5	长轴76.0、短轴74.6	轻伤区
	≤4	—	安全区