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The Effect of Oxygen and Carbon Dioxide Concentration on Soot Formation in Nonpremixed Flames Using Time Resolved LII Technique  

Oh, Kwang-Chul (Enviromental Parts R & D Center, Korea Automotive Technology Institute)
Shin, Hyun-Dong (Department of Mechanical Engineering, Korea Advanced Institute of Science and Technology)
Publication Information
Journal of Mechanical Science and Technology / v.19, no.11, 2005 , pp. 2068-2076 More about this Journal
Abstract
The influence of oxygen concentration and CO$_{2}$ as diluent in oxidizer side on soot characteristics was studied by Laser Induced Incandescence, Time Resolved LII and Transmission Electron Microscopy photography in non-premixed co flowing flames. Through the comparison of TEM photographs and the decay rate of LII signal, suitable two delay times of TIRE-LII method and signal sensitivity ($\Delta$S$_{TIRE-LII/) were determined. The effects of O$_{2}$ and CO$_{2}$ as diluent in oxidizer side on soot formation are investigated with these calibrated techniques. The O$_{2}$+CO$_{2}$, N$_{2}$, and [Ar+CO$_{2}$] mixture in co-flow were used to isolate CO2 effects systematically. The number concentration of primary particle and soot volume fraction abruptly decrease by the addition of CO$_{2}$ to the co-flow. This suppression is resulted from the short residence time in inception region because of the late nucleation and the decrease of surface growth distance by the low flame temperature due to the higher thermal capacity and the chemical change of CO$_{2}$ including thermal dissociation. As the oxygen concentration increases, the number concentration of soot particles at the inception region increases and thus this increase of nucleation enhances the growth of soot particle.
Keywords
Soot; Laser Diagnostics (TIRE-LII, LIl); Diluents;
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1 Tree, D. R. and Foster, D. E., 1994, 'Optical Soot Particle Size and Number Density Measurements in a Direct Injection Diesel Engine,' Combust. Sci. and Tech. 95, pp. 313   DOI
2 Vander Wal, R. L., Ticich, T. M. and Stephens, B., 1999, 'Can Soot Primary Particle Size be Determined Using Laser-Induced Incandescence?,' Combust. Flame 116, pp. 291   DOI   ScienceOn
3 Will, S., Schraml, S. and Leipertz, A., 1996, 'Comprehensive Two Dimensional Soot Diagnostics Based on Laser-Induced Incandescence (LII),' Proc. Combust. Instit. 26, pp. 2277
4 Will, S., Schraml, Bader, S. K. and Leipertz, A., 1998, 'Performance Characteristics of Soot Primary Particle Size Measurements by Time-Resolved Laser-Induced Incandescence,' Appl, Opt. 37, pp. 5647   DOI
5 Zhang, C., Atreya, A. and Lee, L., 1992, 'Sooting Structure of Methane Counterflow Diffusion Flames with Preheated Reactants and Dilution by Products of Combustion,' Proc. Combust. Instit. 24, pp. 1049
6 Schraml, S., Dankers, S., Bader, K., Will, S. and Leipertz, A., 2000, 'Soot Temperature Measurements and Implications for Time-Resolved Laser-Induced Incandescence (TIRE-LII),' Combust. Flame 120, pp. 439   DOI   ScienceOn
7 Shaddix, C. R., Harrington, J. E. and Smyth, K. C., 1994, 'Quantitative Measurements of Enhanced Soot Production in a Flickering Methane/ Air Diffusion Flame,' Combust. Flame 99, pp. 723   DOI   ScienceOn
8 Shimazaki, N., Hatanak, H., Yokota, K. and Nakahira, T., 'Study of Diesel Combustion Process under the Condition of EGR and High-Pressure Fuel Injection with Gas Sampling Method,' SAE paper 96-0030
9 Quey B., Lee T. W., Ni T., and Santoro R. J., 1994. 'Spatially Resolved Measurements of Soot Volume Fraction Using LII,' Combustion and Flame, Vol. 97, pp. 384-392   DOI   ScienceOn
10 Santoro, R. J., Yen, T. T., Horvath, J. J. and Semerjian, H. G., 1987, 'The Transport and Growth of Soot Particles in Laminar Diffusion Flames,' Combust. Sci. and Tech. 53, pp. 89   DOI   ScienceOn
11 Santoro, R. J. and Semerjian, H. G., 1984, 'Soot Formation in Diffusion Flames: Flow Rate, Fuel Species and Temperature Effects,' Proc. Combust. Instit. 20, pp. 997
12 Santoro R. J., Semerjian H. G., and Dobbins R. A., 1983. 'Soot Particle Measurements in Diffusion Flames,' Combustion and Flame. Vol 51, pp 203-218   DOI   ScienceOn
13 Ni, T., Gupta, S. B. and Santoro, R. J., 1994, 'Suppression of Soot Formation in Ethane Laminar Diffusion Flames by Chemical additives,' Proc. Combust. Instit. 25, pp. 585
14 Ni, T., Pinson, J. A., Gupta, S. and Santoro, R. J., 1995, 'Two-dimensional Imaging of Soot Volume Fraction by the Use of Laser-Induced Incandescence,' Appl. Opt. 34, pp. 7083   DOI
15 Iuliis, S. De, Cignoli, F., Benecchi, S. and Zizak, G., 1998, 'Investigation of the Similarity of Soot Parameters in Ethylene Diffusion Flames with Different Heights by Extinction/Scattering Technique,' Proc. Combust. Instit. 27, pp. 1549
16 Iuliis, S. De, Barbini, M., Benecchi, S., Cignoli, F. and Zizak, G., 1998, 'Determination of the Soot Volume Fraction in an Ethylene Diffusion Flame by Multiwavelength Analysis of Soot Radiation,' Combust. Flame 115, pp. 253   DOI   ScienceOn
17 Lapuerta, M., Salavert, J. M. and Domenech, C., 'Modelling and Experimental Study about the Effect of Exhaust Gas Recirculation on Diesel Engine Combustion and Emission,' SAE paper 95-0216
18 Liu, F., Guo, H., Smallwood, G. J. and Gulder, O. L., 2001, 'The Chemical Effects of Carbon Dioxide as an Additive in an Ethylene Diffusion Flame: Implications for Soot and NOx Formation,' Combust. Flame 125, pp. 778   DOI   ScienceOn
19 Melton, L. A., 1984, 'Soot Diagnostics Based on Laser Heating,' Appl, Opt.23, pp. 2201   DOI
20 Angrill, O., Geitlinger, H., Streibel, T., Suntz, R. and Bockhorn, H., 2000, 'Influence of Exhaust Gas Recirculation on Soot Formation in Diffusion Flames,' Proc. Combust. Instit. 28, pp. 2643   DOI   ScienceOn
21 Bonczyk, P. A., 1983, 'In-situ Optical Meaof Additive Effects on Particulates in a Sooting Diffusion Flame,' Combust. Flame 51, pp. 219   DOI   ScienceOn
22 Du, D. X., Axelbaum, R. L. and Law, C. K., 1990, 'The Influence of Carbon Dioxide and Oxygen as Additives on Soot Formation in Diffusion Flames,' Proc. Combust. Instit. 23, pp. 1501
23 Glassman, Irvin, 1998, 'Sooting Laminar Diffusion flames: Effect of Dilution, Additives, Pressure and Microgravity,' Proc. Combust. Inst. 27, pp.1589
24 Guider, O. L., 1995, 'Effects of Oxygen on Soot Formation in Methane, Propane, and n-Butane Diffusion Flames,' Comb. and Flame, Vol. 101, pp. 302-310   DOI   ScienceOn