超细冷气溶胶抑制油气预混爆炸实验研究

大型油罐区火灾事故往往伴随着油气爆炸,对应急救援消防官兵生命安全带来威胁.具有可压缩性、流动性和弥散性特征的超细干粉冷气溶胶对泄漏可燃油气爆燃爆轰有抑制作用.采用三路进气20L球试验装置模拟油气-空气与超细干粉冷气溶胶预混点火燃爆过程,实验结果表明:超细干粉冷气溶胶具有物理和化学双重抑爆作用,随着抑爆剂用量的增大其最大爆炸压力和最大爆炸压力上升速率呈下降趋势,且爆炸感应期明显被滞后;抑爆过程油气爆炸指数快速下降后趋于稳定,抑爆效果与超细粉体本身特性、抑爆剂用量及油气点火时刻有关.该研究有助于优化油气环境的最佳抑爆条件,对大型储油罐区油气防火防爆防护和抑爆技术的应用具有积极意义.     

不同形状受限空间内油气爆燃特性的实验研究

基于实验对4个不同形状的20L容器内的油气爆燃过程进行了研究,探讨了不同形状受限空间内爆炸压力荷载的变化和火焰行为的区别。结果表明:管道（短管和长管）的压力时序曲线较容积式受限空间（球形容器和立方体容器）的压力时序曲线更复杂,并且出现压力振荡;随着初始浓度的增加,超压值和平均升压速率均先增大后减小,在浓度为1.74%时达到最大值,此时,超压从大到小依次为:长管>短管>立方体>球形容器,平均升压速率从大到小依次为:短管>立方体>长管>球形容器;在爆燃初期,立方体中火焰行为为半球状层流火焰→扁平层流火焰,火焰速度先增大后减小,最大速度为12.5 m/s,长管中火焰行为为半球状层流火焰→拉伸指状火焰,火焰速度一直增大,最大速度为40 m/s。     

运动受限空间内火灾研究的现状与展望

从火灾科学基础研究的角度 ,提出了运动受限空间内火灾的概念。继而阐述了三种典型运动受限空间 (即运动着的航天舱、船舶、车辆 )内火灾研究的现状 ,并对未来运动受限空间内火灾的研究作了展望。还探讨了我国当前应开展的工作。     

受限空间近壁烟羽流准稳态温度场的实验研究

本文研究了受限空间近壁烟羽流的准稳态温度场。实验结果表明水平横截面上的温度分布近似于高斯分布,最高温度与到火源的距离之间的关系近似于非受限烟羽流中二者之间的关系,但两个系数不同。本实验得到c=7.3,n=-1.62。实验中还发现,当烟羽流的葛拉晓夫数Gr<2×10~(-7)时,烟羽流处于不稳定状态,同时给出了处于不稳定状态时的温度分布。     

不同形状受限空间内油气爆燃特性的实验研究北大核心CSCD

基于实验对4个不同形状的20L容器内的油气爆燃过程进行了研究,探讨了不同形状受限空间内爆炸压力荷载的变化和火焰行为的区别。结果表明:管道(短管和长管)的压力时序曲线较容积式受限空间(球形容器和立方体容器)的压力时序曲线更复杂,并且出现压力振荡;随着初始浓度的增加,超压值和平均升压速率均先增大后减小,在浓度为1.74%时达到最大值,此时,超压从大到小依次为:长管>短管>立方体>球形容器,平均升压速率从大到小依次为:短管>立方体>长管>球形容器;在爆燃初期,立方体中火焰行为为半球状层流火焰→扁平层流火焰,火焰速度先增大后减小,最大速度为12.5 m/s,长管中火焰行为为半球状层流火焰→拉伸指状火焰,火焰速度一直增大,最大速度为40 m/s。     

七氟丙烷对狭长受限空间油气爆炸抑制实验研究

为研究七氟丙烷对油气爆炸的抑制作用,研制了主动式油气爆炸抑制装置,搭建 了狭长受限空间油气爆炸抑制实验系统,进行了油气爆炸抑制实验,并与无抑爆介质条 件进行了对比,分析了爆炸超压值、火焰传播速度和火焰强度等特性参数变化情况。实 验结果表明:当以3、4和5 kg七氟丙烷作为抑爆介质时,最大超压值分别下降34.05%、 50.78%和55.87%,平均火焰传播速度分别下降72.15%、79.87%和89.23%,火焰持续时间 明显缩短,火焰强度减弱;随着七氟丙烷质量的增加,抑爆效果越显著。     

容积式受限空间油气爆燃火焰特征的实验研究

根据容积式受限空间油气爆燃火焰特征实验研究的需要,设计了实验系统,进行了不同油气体积分数下的油气爆燃模拟实验。基于实验所得的瞬时火焰信号数据与火焰图像,分析了不同油气体积分数下容积式受限空间内油气爆燃的火焰形态结构、传播速度、强度与持续时间等主要行为特征,所得结果对探索油气爆燃机理与基本规律具有重要参考意义。     

受限空间开口对细水雾灭火有效性影响实验研究

为了探讨开口的位置与尺寸对受限空间内的细水雾灭火有效性的影响,设计了一个尺寸为1.2 m×1.2 m×1.2 m的特殊受限空间模拟实验台,开展了一系列细水雾灭火对比实验,测量了烟气温度以及灭火时间等实验参数,通过改变实验燃料、火源功率、开口尺寸、开口位置等因素来研究开口对特殊受限空间内细水雾灭火有效性的影响规律。结果表明:在特殊受限空间内,相同条件下,开口位置由下至上,细水雾抑制火灾有效性由低至高;开口尺寸由大至小,细水雾抑制火灾有效性由高至低。当开口尺寸足够小以后,细水雾抑制火灾有效性反而会逐渐增强。     

标准受限空间内细水雾熄灭煤油火的实验和数值模拟

在3.0m×3.0m×2.8m标准受限空间内,采用煤油模拟池火,火灾功率设定为195kW,进行了一系列细水雾灭火试验。对灭火时间做了详细记录,并实验研究了灭火时间的重现性及其相关因素。采用M-9000燃烧分析仪对细水雾施加前后火灾烟气(如氧气、二氧化碳、一氧化碳、一氧化氮、二氧化氮、二氧化硫)的浓度进行了在线测量。其结果表明:细水雾灭火系统熄灭煤油火的时间均在20s以内,灭火时间重现性保持在91.9%以内;施加细水雾后,氧气浓度降低,一氧化碳浓度升高,燃烧更加不完全。采用FDS模拟了细水雾熄灭煤油火,预测的温度场和灭火时间与实验结果吻合较好。     

Experimental and numerical study of CO2 plume diffusion in a confined space

In this paper, heavy gas diffusion in a confined space has been investigated. The effects of barrier and source intensity on CO₂ diffusion are explored by the small-scale experiments and computational fluid dynamics (CFD) methods. Six different turbulence models are selected to predict the gas concentrations. By comparing these experimental values with the simulated ones, it is found that all models can effectively predict the concentration variation with time, and SST k-ω model is most close to the ideal model compared with others. Three source-barrier distances and three CO₂ flow rates have been set up for the study. In this confined space, the main flow is concentrated in the region near the ground. The existence of barriers in the space will have a dilution effect on the high-concentration plume near the ground of the near-source area and a barrier effect on the low-concentration plume in the far-source area. The changes in source intensity have notable impact on the gas concentrations. This study can provide an experimental basis for the risk assessment in the confined spaces, as well as an experimental and data reference for large-scale CFD simulations.     

Study on the characteristics of gas explosion affected by induction charged water mist in confined space

To investigate the suppression effect of charged water mist on gas explosion, a small charged water mist generator and a gas explosion simulation device were designed based on the principle of electrostatic induction. Experiments for testing characteristics of the gas explosion in a confined space under different charged polarities, charged voltages and mist fluxes were carried out. Experimental results indicated that, compared with the normal water mist, the explosion peak overpressure and the flame propagation speed could be more effectively reduced by the charged water mist. And this suppression effect could be promoted by increasing the charged voltage. To visualize the effect of the charged water mist's polarity on gas explosion, comparative experiments were conducted. The results showed that the explosion peak overpressure, the overpressure rising rate, and the propagation speed of the flame were reduced by 64.7%, 33.0% and 19.4%, respectively, when a +8 kV charged voltage was applied. In situation where a -8 kV charged voltage was applied, 64.1%, 26.5% and 16.0% reductions were achieved for the explosion peak overpressure, the overpressure rising rate, and the flame propagation speed respectively. Comparison of this data leads to the conclusion that the gas explosion could be more efficiently suppressed by the positively charged water mist.     

Influence of water storage on deflagration characteristics of methane in confined space

Comparative experiments were conducted under different water level heights and methane concentration conditions using a self-designed explosion experiment pipeline. The results showed that, in comparison with the scenario without water storage, when the water level was 2 cm and methane concentration was 6.5–12.5%, there was a dual effect including a pressure decrease caused by the endothermic cooling of liquid water and a pressure increase caused by the expansion of water vapour. These effects caused the pressure time history curve to exhibit a double-peak or multi-peak structure, and the average decrease in the peak deflagration pressure was 23.76%. The heat of vaporisation absorbed by the stored water and barrier effect of water vapour on the transfer of the heat slowed down the increase in the deflagration temperature. The average decrease in the peak deflagration temperature of methane was 13.82%, and the time to reach the peak deflagration temperature was extended as a whole, with an average delay of 0.22 s. Water storage also changed the shape of the deflagration flame front, which exhibited ‘knife’, ‘V’, and ‘crescent’ structures. Moreover, the flame propagation speed was significantly reduced, with the peak and average flame propagation speeds decreased by 83.3% and 83.6%, respectively. The research results can provide a certain reference for preventing gas explosions in typical confined spaces, and also help to explore new anti-explosion methods, which can be applied to marine equipment such as ships.     

受限空间内细水雾与火相互作用的实验研究

细水雾灭火系统作为卤代烷系列灭火剂的替代产品之一，以其高效无毒、经济实用的优点，近年来在国际上研究得非常活跃。本文在受限空间内利用先进的材料热释放速率测量仪研究了细水雾与火的相互作用过程，并得到了以下结论：细水雾通过汽化吸热冷却燃料及氧化剂、体积膨胀隔氧以及吸收热辐射降低对燃料的热回馈等效应与火相互作用，达到控制和扑灭火灾的目的，在受限空间内汽化隔氧效应起着重要作用。     

受限空间脉冲细水雾系统关键参数试验与数值模拟研究

为了研究脉冲细水雾的关键参数,采用FDS软件对不同周期的脉冲细水雾熄灭受限空间油盘火进行了数值模拟,分析了脉冲周期的优化设置、细水雾的灭火效果和灭火机理。根据模拟结果进行参数设置,建立了脉冲细水雾试验平台,对脉冲细水雾熄灭不同尺寸油盘火进行了试验研究,并与数值模拟结果对比。研究表明:脉冲细水雾的最佳周期应满足喷头开启时间接近雾滴降至燃料表面的时间,暂停时间接近雾滴的生存时间;脉冲细水雾能熄灭不同尺寸火源,其灭火效果优于连续细水雾,雾滴蒸发效率更高,灭火机理为水雾蒸发稀释氧气而窒息灭火。     

感温自启动灭火管系统应用于密闭空间的试验研究

为了对比Novec 1230（全氟己酮）感温自启动灭火管系统与R236fa（六氟丙烷）感温自启动灭火管系统的灭火效率,采用火灾实体试验的方法,分析了不充压,0.88,1.81 MPa下2系统的灭火时间、破裂动作温度及降温冷却效果。研究结果表明:2种灭火管系统都成功灭火,且 R236fa灭火管系统灭火时间更短;2种灭火管系统的破裂动作温度均在80 ℃以上;不充压和0.88 MPa时,2种灭火管系统降温冷却效果相差不大,但充压1.81 MPa时Novec 1230灭火管系统对环境温度的降温冷却作用更强。     

深井受限空间高温环境影响模拟试验研究

为探索研究矿井高温热害对人体生理健康和工作效率的影响,分析了矿井高温热害的来源和对人体的危害。根据人体生理反应特征选取人体响应综合指标,基于深井受限空间高温环境模拟试验装备,模拟深井受限空间高温环境,开展了矿井高温对人体生理健康及工作效率影响危害的物理模拟试验。利用高温模拟试验结果数据构建了多元线性回归预测模型,对人体响应指标与温度之间的关系进行了准确的定量分析。试验结果表明,温度对血压、心率、呼吸率、疲劳度、注意力和记忆力的影响较大,而对体温、反应时间的影响则较小,并确定了相关的影响程度的预测模型。试验结果为研究深井受限空间高温作业危害和制定相关的职业健康标准提供了科研根据。