Effect of initial pressure on the lower explosion limit of nicotinic acid/acetone mixture

In the work presented in this paper, the effect of initial pressure on the lower explosion limit (LEL) of the hybrid nicotinic acid/acetone mixture was investigated through standard explosion tests carried out in the 20 L sphere. From experimental results, the flammability diagram was built in the plane (concentration/minimum explosive concentration) of nicotinic acid versus (concentration/LEL) of acetone. Interestingly, it has been found that, in going from low pressures (P < 1 atm) to high pressures (P > 1 atm), the extension of the flammability region increases. This behavior has been attributed to the fact that the turbulence kinetic energy (and thus the energy dissipation) decreases with increasing initial pressure. Bartknecht's correlation for LEL of hybrid mixtures was modified to take into account the effect of pressure, and two correlations were obtained able to give satisfactory predictions of experimental data at both low pressures and high pressures.     

基于模糊故障树的海洋立管破坏失效风险分析

针对海洋立管破坏失效事故资料不完备及发生概率缺乏精确值的现状,提出了基于模糊故障树的海洋立管破坏失效风险分析方法。通过对现有的海洋立管破坏失效事故原因的统计分析,建立了以"海洋立管破坏失效"为顶事件的故障树。在对故障树进行定性分析的基础上,得到了引起海洋立管破坏失效的105个各阶最小割集,确定了海洋立管发生破坏失效的主要模式。采用专家判断法与模糊集理论结合的方法对故障树进行了定量分析,评估了故障树底事件的发生概率,并计算了故障树顶事件的发生概率。通过模糊故障树分析得到了海洋立管系统的薄弱环节,从而可以对其采取有效措施,以降低事故发生概率及提高系统可靠性。     

试论空分装置的防爆技术

空分装置的安全运行是工业制氧安全生产的关键环节 ,也是最难控制的危险源。本文从空分爆炸原理入手 ,系统阐述了碳氢化合物在液氧中的积聚机理 ,激发能源的种类与形成 ,并提出了综合控制空分爆炸的若干措施     

矿井瓦斯爆炸传播的尺寸效应研究

基于瓦斯爆炸传播过程的理论分析 ,确定了表征瓦斯爆炸传播过程的主要物理参数 ;通过在两条巷道中进行了瓦斯爆炸传播的对比实验 ,指出了瓦斯爆炸传播过程的尺寸效应存在的原因。笔者认为 :因为巷道支护设备使巷道有效面积的减少和壁面粗糙度的变化 ,尺寸效应使大断面巷道在可比条件下 ,发生瓦斯爆炸时 ,爆炸波的火焰、压力、冲量等在更大范围内形成破坏和伤害     

超细水雾抑制甲烷爆炸的实验研究(英文)

用自行设计的三面透明的细水雾抑制甲烷爆炸的实验装置,研究了不同体积超细水雾对不同浓度甲烷爆炸的抑制现象。运用GigaView高速摄影观察了超细水雾抑制甲烷爆炸的过程,并且对现象进行了分析。采用四个E12-1-K型快速响应热电偶获取超细水雾抑爆过程中四个不同位置的温度变化情况,并且讨论了甲烷浓度和超细水雾体积对爆炸延迟时间的影响。实验结果表明,超细水雾对甲烷爆炸的抑制效果是与水雾的体积和甲烷浓度紧密相关的。初步确定了超细水雾抑制甲烷爆炸的临界体积。     

Enhancement effects of methane/air explosion caused by water spraying in a sealed vessel

Experiments about the influence of ultrafine water mist on the methane/air explosion were carried out in a fully sealed visual vessel with methane concentrations of 8%, 9.5%, 11% and 12.5%. Water mists were generated by two nozzles and the droplets' Sauter Mean Diameters (SMD) were 28.2 μm and 43.3 μm respectively which were measured by Phase Doppler Particle Anemometer (PDPA). A high speed camera was used to record the flame propagation processes. The results show that the maximum explosion overpressure, pressure rising rate and flame propagation velocity of methane explosions in various concentrations increased significantly after spraying. Furthermore, the brightness of explosion flame got much higher after spraying. Besides, the mist with a larger diameter had a stronger turbulent effect and could lead to a more violent explosion reaction.     

铸铁烘缸检验策略的制定

文章首先介绍了一起铸铁烘缸爆炸事故的分析结果,对铸铁烘缸的损伤模式进行了识别,依据损伤模式制定了铸铁烘缸定期检验的策略,以宏观检验、壁厚测定、水压试验为主。实践证明该检验策略实现了检验有效性和经济性的统一。     

氧气瓶爆炸事故性质认定及原因分析

在事故现场勘查的基础上,通过材料成分、力学性能、金相组织与断口、碎片附着物以及充装气体成分等检测和试验,结合爆炸能量的理论估算,对一起氧气瓶爆炸事故的性质和原因进行了系统分析。结果表明：瓶体存在的脱碳、微裂纹及局部腐蚀凹坑这些类裂纹缺陷在爆炸产生的巨大载荷下诱发了气瓶的开裂及扩展,其宏观断口表现为韧脆交替的快速断裂特征。依据碎片抛射距离估算的气瓶实际爆炸能量远大于其发生物理爆炸所产生的能量,气瓶爆炸属于化学爆炸。气瓶内存在的碳烃类油脂有机物以及瓶阀关闭时产生的摩擦热或静电火花是氧气瓶发生化学爆炸的直接原因。     

Scaling of dust explosion violence from laboratory scale to full industrial scale – A challenging case history from the past

The standardized K_St parameter still seems to be widely used as a universal criterion for ranking explosion violence to be expected from various dusts in given industrial situations. However, this may not be a generally valid approach. In the case of dust explosion venting, the maximum pressure P_max generated in a given vented industrial enclosure is not only influenced by inherent dust parameters (dust chemistry including moisture, and sizes and shapes of individual dust particles). Process-related parameters (degree of dust dispersion, cloud turbulence, and dust concentration) also play key roles. This view seems to be confirmed by some results from a series of large scale vented dust explosion experiments in a 500 m³ silo conducted in Norway by CMI, (now GexCon AS) during 1980–1982. Therefore, these results have been brought forward again in the present paper. The original purpose of the 500 m³ silo experiments was to obtain correlations between P_max in the vented silo and the vent area in the silo top surface, for two different dusts, viz. a wheat grain dust collected in a Norwegian grain import silo facility, and a soya meal used for production of fish farming food. Both dusts were tested in the standard 20-L-sphere in two independent laboratories, and also in the Hartmann bomb in two independent laboratories. P_max and (dP/dt)_max were significantly lower for the soya meal than for the wheat grain dust in all laboratory tests. Because the available amount of wheat grain dust was much larger than the quite limited amount of available soya meal, a complete series of 16 vented silo experiments was first performed with the wheat grain dust, starting with the largest vent area and ending with the smallest one. Then, to avoid unnecessary laborious changes of vent areas, the first experiment with soya dust was performed with the smallest area. The dust cloud in the silo was produced in exactly the same way as with the wheat grain dust. However, contrary to expectations based on the laboratory-scale tests, the soya meal exploded more violently in the large silo than the wheat grain dust, and the silo was blown apart in the very first experiment with this material. The probable reason is that the two dusts responded differently to the dust cloud formation process in the silo on the one hand and in the laboratory-scale apparatuses on the other. This re-confirms that a differentiated philosophy for design of dust explosion vents is indeed needed. Appropriate attention must be paid to the influence of the actual dust cloud generation process on the required vent area. The location and type of the ignition source also play important roles. It may seem that tailored design has to become the future solution for tackling this complex reality, not least for large storage silos. It is the view of the present author that the ongoing development of CFD-based computer codes offers the most promising line of attack. This also applies to design of systems for dust explosion isolation and suppression.     

Effect of concentration and ignition position on vented methane–air explosions

Experiments were conducted in a 1 m³ vessel with a top vent to investigate the effect of methane concentration and ignition position on pressure buildup and flame behavior. Three pressure peaks (p₁, p₂, and P_ext) and two types of pressure oscillations (Helmholtz and acoustic oscillations) were observed. The rupture of vent cover results in p₁ that is insensitive to methane concentration and ignition position. Owing to the interaction between acoustic wave and the flame, p₂ forms in the central and top ignition explosions when the methane–air mixture is near–stoichiometric. When the methane–air mixture is centrally ignited, p₂ first increases and then decreases with an increase in the methane concentration. The external explosion-induced P_ext is observed only in the bottom ignition explosions with an amplitude of several kilopascals. Under the current experimental conditions, flame–acoustic interaction leads to the most serious explosions in central ignition tests. Methane concentration and ignition position have little effect on the frequency of Helmholtz and acoustic oscillations; however, the Helmholtz oscillation lasts longer and first decreases and then increases as the methane concentration increases for top ignition cases. The ignition position significantly affects the Taylor instability of the flame front resulting from the Helmholtz oscillation.