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Fuel, combustion flames

J.A. Miller and C.F Melius. Kinetic and Thermodynamic Issues in the Formation of Aromatic Compounds in Flames of Aliphatic Fuels. Combust. Flame, 91 21-39, 1992. [Pg.830]

E. Ranzi, A. Sogaro, P. Gaffuri, G. Pennati, C.K. Westbrook, and W.J. Pitz. A New Comprehensive Reaction Mechanism for Combustion of Hydrocarbon Fuels. Combust. Flame, 99 201-211,1994. [Pg.833]

Keller M, Leion H, Mattisson T, Lyngfelt A. Gasification inhibition in chemical-looping combustion with solid fuels. Combust Flame 2011 158 393. [Pg.275]

Yajima, T. Murakami, S. Miyake S. Manufacturing Technique to the Spherical Inorganic Oxide Particles with the Oxy-Fuel Combustion Flame Method. NIPPON SANSO Technical Report. 1998, 17,43-53. [Pg.26]

Yamamoto, Y Hagihara, Y Kitamura, Y. Investigation of Particle Behavior in the Oxy-Fuel Combustion Flame Using Numerical Simulation. TAIYO NIPPON SANSO Technical Report. 2008, 27, 6-11. [Pg.26]

Westbrook, C.K., Naik, C.V., Herbinet, O., Pitz, W.J., Mehi, M., Sarathy, S.M., Curran, H.J. Detailed chemical kinetic reaction mechanisms for soy and rapeseed biodiesel fuels. Combust. Flame 158, 742-755 (2011)... [Pg.52]

Liang, L., Stevens, J.G., Raman, S., Farrell, J.T. The use of dynamic adaptive chemistry in combustion simulation of gasoline surrogate fuels. Combust. Flame 156, 1493-1502 (2009b) Liao, J.C., Lightfoot, E.N. Lumping analysis of biochemical reaction systems with time scale separation. Biotechnol. Bioeng. 31, 869-879 (1988)... [Pg.301]

Niemeyer, K.E., Sung, C.J. Mechanism reduction for multicomponent surrogates a case study using toluene reference fuels. Combust. Flame 161, 2752-2764 (2014)... [Pg.304]

Westbrook CK, Naik CV, Herbinet O, et al. Detailed chemical kinetic reaction mechanisms for soy and rapeseed biodiesel fuels. Combust Flame. April 2011 158 742-755. [Pg.176]

Luminometer index for the combustion flame of a jet fuel as a function of its volumetric content in aromatics. [Pg.227]

Stewart, F. R. 1964. Linear flame heights for various fuels. Combustion and Flame 8 171-178. [Pg.155]

Initial preheating of the combustion chamber by gas or oil is normally required in order to provide the necessary temperature environment to release the volatiles that provide the stabilization in the base of the flame. Some small PF systems have used another fuel for flame support, but this compromises the economics. A typical pulverized fuel burner is shown in Figure 24.17. [Pg.381]

Lamprecht, A., Atakan, B., and Kohse-Hoinghaus, K., Fuel-rich propene and acetylene flames A comparison of their flame chemistries. Combust. Flame, 122, 483, 2000. [Pg.13]

Yang, B. et al.. Identification of combustion intermediates in isomeric fuel-rich premixed butanol-oxygen flames at low pressure. Combust. Flame, 148, 198, 2007. [Pg.13]

Eraslan, A. N., Chemiionization and ion-molecule reactions in fuel-rich acetylene flame, Combust. Flame, 74,19, 1988. [Pg.34]

Huang, Y, Sung, C.J., and Eng, J.A., Laminar flame speeds of primary reference fuels and reformer gas mixtures, Combust. Flame, 139, 239, 2004. [Pg.45]

Diagram and photograph of a model gas turbine combustor operating on CH4/air at atmospheric pressure. Fuel is injected from an annulus separating two swirhng air streams. (From Meier, W., Duan, X.R., and Weigand, R, Combust. Flame, 144,225,2006. With permission.)... [Pg.160]

Alsairafi, A., Lee, S.T., and T ien, J.S., Modeling gravity effects on diffusion flames stabilized around a cylindrical wick saturated with liquid fuel. Combust. Sci. Technol., 176, 2165, 2004. [Pg.177]

Vapor-phase fuel-distribution image converted to an equivalence-ratio field downstream of the maximum liquid-phase fuel penetration. Quantitative planar images are obtained in the optical engine using PLRS. (From Espey, C., Dec, J.E., Litzinger, T.A., and Santavicca, D.A., Combust. Flame, 109,65,1997.)... [Pg.191]

Altenkirch, R.A., Eichhorn, R. and Shang, P.C., Buoyancy effects on flames spreading down thermally thin fuels, Combustion and Flame, 1980, 37, 71-83. [Pg.219]

The required heat for the brazing cycle shall be produced by a controlled fuel gas flame. The fuel gas (e.g., acetylene, propane, or natural gas) is to be combusted with air, compressed air, or oxygen. The specific combination selected is dependent on the amount of heat required to bring the particular components to the brazing temperature in the required time. [Pg.61]

Skreiberg, O., Kilpinen, P., Glarborg, P. Ammonia chemistry below 1400 K under fuel-rich conditions in a flow reactor, Combustion Flame, 136, 501-518, (2004). [Pg.181]

See other pages where Fuel, combustion flames is mentioned: [Pg.509]    [Pg.520]    [Pg.509]    [Pg.520]    [Pg.141]    [Pg.147]    [Pg.216]    [Pg.525]    [Pg.229]    [Pg.483]    [Pg.492]    [Pg.367]    [Pg.364]    [Pg.272]    [Pg.783]    [Pg.8]    [Pg.177]    [Pg.13]    [Pg.546]    [Pg.332]    [Pg.1175]    [Pg.544]    [Pg.545]    [Pg.689]    [Pg.841]    [Pg.180]   
See also in sourсe #XX -- [ Pg.221 , Pg.230 , Pg.231 , Pg.233 , Pg.241 ]



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