论文信息 - Spectroscopic behavior of oxygenated combustion by-products.

Spectroscopic behavior of oxygenated combustion by-products.

The oxygenated species, massively produced in the energy production plants based on combustion processes, constitute one of the most numerous categories of hazardous air pollutants. Therefore, development of real time diagnostic tools are needed in order to study their formation during combustion processes and to reveal their presence both in the exhaust and in the atmosphere. In this work, oxygenated compounds were identified inside fuel-rich premixed ethylene/air flames by means of ultraviolet fluorescence spectroscopy with the support of qualitative chemical analysis of the sampled combustion gases. Strong band progression, typical of aldehydic functionality, were recognized in fluorescence spectra (lambda(exc)=355 nm) measured in the early oxidation region of premixed flames varying the equivalence ratio from 3.0 up 21.6. Downstream of the oxidation region, spectroscopic signatures of pyrolytic species were found to prevail on those peculiar of oxygenated compound. The position and the extension of the two main flame zones were found to depend on the flame conditions (C/O ratio) due to the effect of the C/O ratio on the temperature history along the flame axis. This correlation was interpreted on the basis of the measured axial temperature profiles.

M de Joannon | A Ciajolo | R Ragucci | A Tregrossi | A Cavaliere

[1] Habib N. Najm,et al. Planar laser-induced fluorescence imaging of flame heat release rate , 1998 .

[2] Frank M. Bowman,et al. Ozone and aerosol productivity of reactive organics , 1995 .

[3] P. R. Westmoreland. Thermochemistry and Kinetics of C2H3+ 02 Reactions , 1992 .

[4] C. McEnally,et al. Experimental study of nonfuel hydrocarbon concentrations in coflowing partially premixed methane/air flames , 1999 .

[5] J. E. Harrington,et al. Laser-induced fluorescence measurements of formaldehyde in a methane/air diffusion flame , 1993 .

[6] J. A. Cole,et al. Chemical aspects of the autoignition of hydrocarbonair mixtures , 1985 .

[7] D. Golden. Interaction of combustion with the atmosphere , 2000 .

[8] A. G. Gaydon. The spectroscopy of flames , 1957 .

[9] A. Cavaliere,et al. Identification of oxygenated compounds in combustion systems. , 2001, Chemosphere.

[10] W. Carter. A detailed mechanism for the gas-phase atmospheric reactions of organic compounds , 1990 .

[11] Maria Nehse,et al. Kinetic modeling of the oxidation of large aliphatic hydrocarbons , 1996 .

[12] Jürgen Warnatz,et al. Chemistry of high temperature combustion of alkanes up to octane , 1985 .

[13] J. Jeffries,et al. Laser-induced fluorescence of formaldehyde hot bands in flames. , 2000, Applied optics.

[14] P. R. Westmoreland,et al. Measured Flame Structure and Kinetics in a Fuel-Rich Ethylene Flame 1 1 This report was prepared as , 1998 .