[1]辛保泉,党文义,喻健良.基于风险的液化烃罐区建筑物抗爆荷载评估方法[J].中国安全生产科学技术,2020,16(7):30-35.[doi:10.11731/j.issn.1673-193x.2020.07.005]
XIN Baoquan,DANG Wenyi,YU Jianliang.Risk-based evaluation method for blast resistant load of buildings in liquefied hydrocarbon tank farm[J].JOURNAL OF SAFETY SCIENCE AND TECHNOLOGY,2020,16(7):30-35.[doi:10.11731/j.issn.1673-193x.2020.07.005]
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基于风险的液化烃罐区建筑物抗爆荷载评估方法
XIN Baoquan,DANG Wenyi,YU Jianliang.Risk-based evaluation method for blast resistant load of buildings in liquefied hydrocarbon tank farm[J].JOURNAL OF SAFETY SCIENCE AND TECHNOLOGY,2020,16(7):30-35.[doi:10.11731/j.issn.1673-193x.2020.07.005]
《中国安全生产科学技术》[ISSN:1673-193X/CN:11-5335/TB]
- 卷:
- 16
- 期数:
- 2020年7期
- 页码:
- 30-35
- 栏目:
- 学术论著
- 出版日期:
- 2020-07-30
文章信息/Info
- Title:
- Risk-based evaluation method for blast resistant load of buildings in liquefied hydrocarbon tank farm
- 文章编号:
- 1673-193X(2020)-07-0030-06
- Keywords:
- vapor cloud explosion; blast resistant load; petrochemical building; liquefied hydrocarbon; quantitative risk assessment
- 分类号:
- X932;TU312+.1
- 文献标志码:
- A
- 摘要:
- 为合理确定液化烃罐区周边建筑物的抗爆设防荷载,有效进行抗爆设计和防护,建立1套系统的抗爆设防荷载定量评估方法。以某液化烃罐区建筑物为例,计算172个爆炸场景,获得4组累积爆炸频率曲线,基于风险控制标准确定抗爆设防荷载。结果表明:爆炸场景发生频率应包括初始泄漏频率、气象概率、泄漏方向概率和延迟爆炸概率;获得的爆炸超压-累积频率曲线是确定抗爆设防荷载的基础,在爆炸超压较低时,与爆炸源中心距离不同的4面墙体的超压累积频率曲线极为接近;随着爆炸超压的继续增大,累积发生频率的差异逐渐明显;液化烃罐区建筑物的抗爆设防荷载应同时满足2个准则,即万年1次的风险可接受准则和风险可接受范围内爆炸超压最大化准则;根据该准则确定的液化烃罐区附近建筑物东墙的爆炸冲击波峰值入射超压为44.6 kPa,正压作用时间为89.3 ms。
- Abstract:
- In order to reasonably determine the blast resistant fortification load of buildings around the liquefied hydrocarbon tank farm,and effectively conduct the blast resistant design and protection,a set of systematic quantitative evaluation method for the blast resistant fortification load was established.Taking a building in a liquefied hydrocarbon tank farm as an example,172 explosion scenarios were calculated,and 4 groups of cumulative explosion frequency curves were obtained.Finally,based on the risk control standard,the blast resistant fortification load was determined.The results showed that the occurrence frequency of explosion scene should include the initial leakage frequency,meteorological probability,leakage direction probability and delayed explosion probability.Obtaining the explosion overpressurecumulative frequency curve was the basis of determining the blast resistant fortification load.When the explosion overpressure was low,the cumulative frequency curve of overpressure was very close to that of four walls with different distances from the center of explosion source.With the continued increase of explosion overpressure,the difference of cumulative occurrence frequency bacame obvious gradually.Two criteria should be satisfied simultaneously for the blast resistant fortification load of buildings in the liquefied hydrocarbon tank farm,namely the risk acceptance criteria of once every 10 000 years,as well as the criteria of maximum explosion overpressure within acceptable risk standard.According to the established criterion,the peak incoming overpressure of blast wave at the east wall of the building near the liquefied hydrocarbon tank was 44.6 kPa,and the duration was 89.3 ms.
参考文献/References:
[1]傅智敏,曹菲菲.液化烃储罐区泄漏及火灾爆炸危险分析[J].科技导报,2013,31(16):41-46.
FU Zhimin,CAO Feifei.Leakage and fire & explosion hazards of liquefied hydrocarbon in storage tanks [J].Science & Technology Review,2013,31 (16):41-46.
[2]GEOFFREY C,ELAINE O,ANDRZEJ P.Detonations in industrial vapour cloud explosions[J].Journal of Loss Prevention in the Process Industries,2019,62(11):1-8.
[3]KRENTOWSKI J,ZIMINSKI K.Consequences of an incorrect assessment of a structure damaged by explosion[J].Engineering Failure Analysis,2019,101(7):135-144.
[4]王世茂,杜扬,杨文旭,等.单侧弱面受限空间油气爆炸超压荷载的实验研究[J].中国安全生产科学技术,2018,14(4):133-139.
WANG Shimao,DU Yang,YANG Wenxu,et al.Experimental study on overpressure load of gasoline-air mixture explosion in confined space with an unilateral weak plane [J].Journal of Safety Science and Technology,2018,14 (4):133-139.
[5]ALONSO F D,FERRADS E G,PREZ J F S,et al.Consequence analysis to determine damage to buildings from vapour cloud explosions using characteristic curves[J].Journal of Hazardous Materials,2008,159(2):264-270.
[6]BRZEZINSKA D,MARKOWSKI A S.Experimental investigation and CFD modelling of the internal car park environment in case of accidental LPG release[J].Process Safety and Environmental Protection,2017,110(8):5-14.
[7]吴赛,赵均海,张冬芳,等.自由空气中爆炸冲击波的数值分析[J].工程爆破,2019,25(3):1-6,31.
WU Sai,ZHAO Junhai,ZHANG Dongfang,et al.Numerical analysis of explosion wave in free air [J].Engineering Blasting,2019,25 (3):1-6,31.
[8]SARI A.Comparison of TNO multienergy and baker-strehlow-tang models[J].Process Safety Progress,2010,30(1):23-26.
[9]PITBLADO R,ALDERMAN J,THOMAS J K.Facilitating consistent siting hazard distance predictions using the TNO Multi-Energy Model[J].Journal of Loss Prevention in the Process Industries,2014,30:287-295.
[10]陈利琼,冯雨翔,宋利强,等.大型油罐火灾爆炸危害范围研究[J].中国安全生产科学技术,2018,14(1):100-105.
CHEN Liqiong,FENG Yuxiang,SONG Liqiang,et al.Study on damage range of fire and explosion of large oil tank [J].Journal of Safety Science and Technology,2018,14 (1):100-105.
[11]中华人民共和国住房和城乡建设部 中华人民共和国国家质量监督检验检疫总局.石油化工控制室抗爆设计规范:GB 50779—2012[S].北京:中国计划出版社,2012.
[12]Task Committee on Blast Resistant Design of the Petrochemical Committee of the Energy Division of ASCE.Design of blast resistant buildings in petrochemical facilities[M].USA:American Society of Civil Engineers,2010.
[13]胡昆,陈国华,周志航,等.爆炸冲击波作用下化工设备易损性研究评述[J].化工进展,2019,38(4):1634-1645.
HU Kun,CHEN Guohua,ZHOU Zhihang,et al.Review of the vulnerability of chemical equipment subjected to blast wave [J].Chemical Progress,2019,38 (4):1634-1645.
[14]LI J,ABDEL-JAWAD M,MA G.New correlation for vapor cloud explosion overpressure calculation at congested configurations[J].Journal of Loss Prevention in the Process Industries,2014,31(8):16-25.
[15]王超强,杨石刚,方秦,等.点火位置对泄爆空间甲烷-空气爆炸荷载的影响[J].爆炸与冲击,2018,38(4):898-904.
WANG Chaoqiang,YANG Shigang,FANG Qin,et al.Effect of ignition position on overpressure in vented explosion of methane-air mixtures [J].Explosion and Shock Waves,2018,38 (4):898-904.
[16]International Association of Oil & Gas Producers.Risk assessment date directory-storage incident frequencies[R].London:OGP,2010.
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备注/Memo
- 备注/Memo:
-
收稿日期: 2020-02-20
* 基金项目: 国家自然科学基金项目( 51574056,51604057)
作者简介: 辛保泉,博士研究生,工程师,主要研究方向为高危气体泄漏扩散、爆炸防护及定量风险评估。
