|本期目录/Table of Contents|

[1]文建军,丁波.浮顶油罐密封圈油气分布数值模拟[J].中国安全生产科学技术,2016,12(2):57-61.[doi:10.11731/j.issn.1673-193X.2016.02.010]
 WEN Jianjun,DING Bo.Numerical simulation on oil vapor distribution in seal ring of floating roof tank[J].JOURNAL OF SAFETY SCIENCE AND TECHNOLOGY,2016,12(2):57-61.[doi:10.11731/j.issn.1673-193X.2016.02.010]
点击复制

浮顶油罐密封圈油气分布数值模拟
分享到:

《中国安全生产科学技术》[ISSN:1673-193X/CN:11-5335/TB]

卷:
12
期数:
2016年2期
页码:
57-61
栏目:
学术论著
出版日期:
2016-02-29

文章信息/Info

Title:
Numerical simulation on oil vapor distribution in seal ring of floating roof tank
文章编号:
1673-193X(2016)-02-0057-05
作者:
文建军1丁波2
1.浙江海洋学院 石化与能源工程学院,浙江 舟山 31600;
2. 中石化销售浙江石油零售分公司,浙江 杭州 310000
Author(s):
WEN Jianjun1 DING Bo2
1. School of Petrochemical and Energy Engineering, Zhejiang Ocean University, Zhoushan Zhejiang 316000, China;
2. Sinopec Zhejiang Oil Products Retail Company, Hangzhou Zhejiang 310000, China
关键词:
浮顶油罐密封空间油气分布数值模拟 风速
Keywords:
floating roof tank sealing space oil vapor distribution numerical simulation wind velocity
分类号:
X937
DOI:
10.11731/j.issn.1673-193X.2016.02.010
文献标志码:
A
摘要:
浮顶油罐一二次密封空间内的油气在雷击作用下可导致起火事故。为研究浮顶油罐一二次密封空间内的油气浓度影响因素,利用CFD方法进行了数值模拟,并建立了浮顶油罐实验模型,检测一二次密封空间内不同位置处的油气体积分数,两者表征的油气浓度情况较吻合;借助该模拟方法进一步分析温度、风速和二次密封泄漏面积对浮顶油罐一二次密封空间内的油气浓度的影响,研究结果表明:①二次密封泄漏面积增加,密封空间内的油气浓度降低。②温度上升,一二次密封空间的油气浓度升高;当风速较高时,温度对油气浓度变化趋势的影响也更大。③风速增加时,空间内的油气分布差异变大,油气浓度最大值变大。
Abstract:
The oil vapor within the primary and secondary sealing space of floating roof tank can lead to fire accident by lighting. In order to study the influence factors of oil vapor concentration within the primary and secondary sealing space of floating roof tank, the numerical simulation was carried out by using CFD method, and an experimental model of floating roof tank was established to test the volume fraction of oil vapor at different positions within the primary and secondary sealing space, both the represented oil vapor concentrations agree better. Though using the simulation method, the influence of temperature, wind velocity and leakage area of secondary seal on the oil vapor concentration within the primary and secondary sealing space of floating roof tank were further analyzed. The results showed that the oil vapor concentration in the sealing space decreases when the leakage area of secondary seal increases, and it increases when the temperature increases. The influence of temperature on the change trend of oil vapor concentration becomes greater when the wind velocity is higher. The difference of oil vapor distribution in the space and the maximum value of oil vapor concentration become greater when the wind velocity increases.

参考文献/References:

[1]郎需庆,刘全桢,宫宏.浮盘密封圈的原油挥发及结构优化的研究[J].中国安全科学学报,2009,19(5):91-95. LANG Xuqing,LIU Quanzhen,GONG Hong. Research on crude oil evaporation and structure optimization of floating roof rim seal[J].China Safety Science Journal,2009,19(5):91-95.
[2]Drabkin M M. A lighting protection of flammable storage facilities [A]. International Conference on Grounding and Earthing & 2nd International Conference on Lightning Physics and Effects[C],November,2006.
[3]Zhu L, Chen J Q, et, al. Experimental analysis of the evaporation process for gasoline[J]. Journal of Loss Prevention in the Process Industries, 2012,25(6):916-922.
[4]James I Chang, Cheng C L. A study of storage tank accidents[J].Journal of Loss Prevention in the Process Industries, 2005, 19 (1):51-59.
[5]Li Q S, Fu J Y, Xiao Y Q, et, al. Wind tunnel and full-scale study of wind effects on China’s tallest building[J]. Engineering Structures,2006, 28 (12):1745-1758.
[6]Lu C L, Li Q, Huang S H, et al. Large eddy simulation of wind effects on a long-span complex roof structure[J].Journal of Wind Engineering and Industrial Aerodynamics,2011,100(1):1-18.
[7]Fu J Y, Li Q S, Xie Z N .Prediction of wind loads on a large flat roof using fuzzy neural networks[J].Engineering Structures, 2005,28 (1):153- 161.
[8]金新阳,杨伟,金海,等.数值模拟引导下的建筑风洞试验研究[J].建筑结构,2007,37(8):104-107. JIN Xinyang, YANG Wei, JIN Hai, et,al. Numerical simulation guided wind tunnel test study for wind loads of complex buildings [J].Building Structure, 2007,37(8):104-107.
[9]Li Q S, Wu J R, Liang S G, et al.Full-scale measurements and numerical evaluation of wind-induced vibration of a 63-story reinforced concrete tall building[J].Engineering Structures, 2004, 26 (12):1779-1794.
[10]P.Broad bridge. Steady unsaturated flow in two-dimensional scaleheterogeneous porous media. [J].Mathematical and Computer Modeling, 1997, 26(3):45-54.
[11]Fu J Y, Li Q S, Wu J R, et al. Field measurements of boundary layer wind characteristics and wind-induced responses of super-tall buildings[J]. Journal of Wind Engineering and Industrial Aerodynamics, 2008, 96 (8): 1332-1358.
[12]Asghar Alizadeh dakhel,Masoud Rahimi. CFD simulation of homogenization in large-scale crude oil storage tanks[J]. Journal of petroleum science and Engineering, 2004,43(3):151-161 .
[13]Humphrey Pasley, Colin Clark. Computation fluid dynamics study of flow around floating-roof oil storage tanks[J]. Journal of Wind Engineering and and Industrial Aerodynamics, 2000, 86(1):37-54.

相似文献/References:

[1]李恩田,谢磊,王树立,等.浮顶油罐油气惰化防火防爆实验研究[J].中国安全生产科学技术,2011,7(11):68.
 LI En-tian,XIE Lei,WANG Shu-li.Experimental research on vapour deactivation for fire and explosion prevention in floating-roof tank[J].JOURNAL OF SAFETY SCIENCE AND TECHNOLOGY,2011,7(2):68.
[2]张启波,袁凤丽,付钰.大型浮顶油罐的危险性分析及安全对策[J].中国安全生产科学技术,2012,8(6):134.
 ZHANG Qi bo,YUAN Feng li,FU Yu.Risk analysis and safety countermeasures of the large floating roof tank[J].JOURNAL OF SAFETY SCIENCE AND TECHNOLOGY,2012,8(2):134.

备注/Memo

备注/Memo:
-
更新日期/Last Update: 2016-03-11