Symposium on Combustion and Flame, and Explosion Phenomena最新文献

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The oxidation of sulphur dioxide in combustion processes 燃烧过程中二氧化硫的氧化

Symposium on Combustion and Flame, and Explosion Phenomena

Pub Date : 1948-01-01 DOI: 10.1016/S1062-2896(49)80058-4

G. Whittingham

引用次数: 3

Theory of propagation of flames. Part II: Approximate solutions 火焰传播理论。第二部分:近似解

Symposium on Combustion and Flame, and Explosion Phenomena

Pub Date : 1948-01-01 DOI: 10.1016/S1062-2896(49)80016-X

M.J. Henkel, W.P. Spaulding, J.O. Hirschfelder

引用次数: 3

Initiation of detonation of explosives 炸药的起爆

Symposium on Combustion and Flame, and Explosion Phenomena

Pub Date : 1948-01-01 DOI: 10.1016/S1062-2896(49)80075-4

G.B. Kistiakowsky

引用次数: 7

A note on the calculation of multicomponent propellant gas compositions 多组分推进剂气体成分计算注记

Symposium on Combustion and Flame, and Explosion Phenomena

Pub Date : 1948-01-01 DOI: 10.1016/S1062-2896(49)80085-7

G.F. Sachsel, M.E. Mantis, J.C. Bell

引用次数: 0

Transition from deflagration to detonation: The physico-chemical aspects of stable detonation 从爆燃到爆轰的过渡:稳定爆轰的物理化学方面

Symposium on Combustion and Flame, and Explosion Phenomena

Pub Date : 1948-01-01 DOI: 10.1016/S1062-2896(49)80076-6

A.R. Ubbelohde

引用次数: 5

Aerodynamical effects of heat released by combustion of steadily flowing gases 稳定流动气体燃烧释放热量的空气动力学效应

Symposium on Combustion and Flame, and Explosion Phenomena

Pub Date : 1948-01-01 DOI: 10.1016/S1062-2896(49)80029-8

Bruce L. Hicks

引用次数: 1

The ignition of gaseous explosive media by hot wires 用热线点燃气体爆炸性介质

Symposium on Combustion and Flame, and Explosion Phenomena

Pub Date : 1948-01-01 DOI: 10.1016/S1062-2896(49)80039-0

H.P. Stout, E. Jones

引用次数: 7

Mixing and combustion in turbulent gas jets 湍流气体射流中的混合和燃烧

Symposium on Combustion and Flame, and Explosion Phenomena

Pub Date : 1948-01-01 DOI: 10.1016/S1062-2896(49)80035-3

W.R. Hawthorne , D.S. Weddell , H.C. Hottel

Visible flame lengths and concentration patternshave been obtained in turbulent jets of flame formed by combustible gas issuing from circular nozzles into stagnant air. The nozzle velocities were above those which, in a previous paper, were found necessary to insure that the mixing should be turbulent. As a basis for analysis of the data a simplified treatment is presented for mixing of nozzle and ambient fluids in a vertical jet. The simplifying assumption of constant velocity and composition in a cross-section normal to the axis of flow is combined with a force-momentum balance, continuity, and the perfect gas laws to obtain a relation between mean concentration and jet spread. The relation allows for initial difference in density of nozzle and ambient streams, density variation due to combustion, and buoyancy. The qualitative agreement between the analysis and the experimental data on visible flame lengths and axial concentration patterns indicates plainly that the process of mixing resulting from the momentum and buoyancy of the jet is the controlling factor in determining progress of the combustion. For tree flames in which the effects of buoyancy are small (high nozzle velocity, small diameter) the analysis leads to the following simple relation for the length of free turbulent flame jets:

$L / D = \frac{5.3}{C_{τ}} \sqrt{\frac{T_{F}}{α_{T} T_{N}} [C_{τ} + (1 - C_{τ}) \frac{M_{S}}{M_{N}}]}$

where L=visible flame length D=nozzle diameter T_F=adiabatic flame temperature, absolute T_N=absolute temperature of nozzle fluid M_S, M_N=molecular weights of surrounding and nozzle fluids, respectively C_T=mol fraction of nozzle fluid in the unreacted stoichiometric mixture α_T=mols of reactants/mols products, for the stoichiometric mixture. It is to be noted that fuel gas flow rate is no factor, as long as it is great enough to prodace a turbulent jet. Although data for testing this relation covered the small range of port diameter of 0.12 to 0.30 inches, a wide variety of fuels was studied, including propane, acetylene, hydrogen, carbon monoxide, city gas, mixtures of carbon dioxide with city gas, and mixtures of hydrogen with propane. Turbulent flame lengths varying from 40 to 290 nozzle diameters are predicted with average and

在可燃气体从圆形喷嘴向静止空气中喷射形成的湍流射流中，已经获得了可见的火焰长度和浓度模式。喷嘴的速度高于先前一篇论文中发现的确保混合应该是紊流所必需的速度。作为数据分析的基础，提出了垂直射流中喷嘴与周围流体混合的简化处理方法。将简化的匀速假设和垂直于流轴截面的成分假设与力-动量平衡、连续性和完美气体定律相结合，得到了平均浓度与射流扩散的关系。这种关系考虑了喷嘴和周围气流的初始密度差异、燃烧引起的密度变化和浮力。可见火焰长度和轴向浓度分布的分析与实验数据的定性一致表明，由射流动量和浮力引起的混合过程是决定燃烧进展的控制因素。对于浮力影响较小的树状火焰(喷嘴速度大，直径小)，分析得出自由湍流火焰射流长度的简单关系式:L/D=5.3CτTFαTTN[Cτ+(1−Cτ)MSMN]，其中L=可见火焰长度D=喷嘴直径TF=绝热火焰温度，TN=喷嘴流体的绝对温度MS, MN=周围和喷嘴流体的分子量，分别为CT=未反应化学计量混合物中喷嘴流体的摩尔分数αT=反应物的摩尔数/生成物的摩尔数。需要注意的是，燃气流量不是影响因素，只要它大到足以产生湍流射流即可。虽然测试这种关系的数据涵盖了端口直径0.12至0.30英寸的小范围，但研究了各种各样的燃料，包括丙烷，乙炔，氢气，一氧化碳，城市气体，二氧化碳与城市气体的混合物以及氢气与丙烷的混合物。紊流火焰长度在40 ~ 290喷嘴直径范围内，用平均值和

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引用次数: 249

The determination of radical concentrations and reactivities in chemical reactions 化学反应中自由基浓度和反应活性的测定

Symposium on Combustion and Flame, and Explosion Phenomena

Pub Date : 1948-01-01 DOI: 10.1016/S1062-2896(49)80055-9

H.W. Melville

引用次数: 0

Spectroscopic studies of low-pressure flames 低压火焰的光谱研究

Symposium on Combustion and Flame, and Explosion Phenomena

Pub Date : 1948-01-01 DOI: 10.1016/S1062-2896(49)80068-7

A.G. Gaydon, H.G. Wolfhard

引用次数: 21

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