The use of high temperature and low oxygen concentration air as the oxidizer for regenerative combustion has become of increasing interest because this technology results in higher thermal efficiency, low energy consumption, and reduced emission of pollutants, such as NOx and CO2, and compact size of the equipment. In this study information is provided on the effect of preheating the low oxygen concentration air on the formation and detection of chemical ions and neutral species formed in flames. These ions and species were detected directly using mass spectrometry. Such information also assists in determining the combustion mechanism. The intact ionic species have been detected only at downstream position of the flames. By applying an alkali element Li+ ion attachment technique, neutral species, such as Li+-attached ions have been also detected successfully. Three specific flame cases have been examined. They include using normal air (flame I), preheated air (flame II), and preheated air with low (diluted) oxygen concentration in air (flame III). The results show significant change in the spectra of the intact ionic species and the Li+-adduct neutral species amongst the three flames. The results also show that preheating the combustion air increases the number of chemical species formed in the flames. However, these chemical species decrease with low oxygen concentration (diluted) combustion air.

1.
Gupta, A. K., and Li, Z., 1997, “Effect of Property on the Structure of Highly Preheated Air Flames,”Proc. of the ASME 1997 International Joint Power Generation Conference (IJPGC), Denver, CO, ASME EC-Vol. 5, ASME, New York, pp. 247–258.
2.
Choi
,
G.-M.
, and
Katsuki
,
M.
,
2000
New Approach to Low Emission of Nitric Oxides from Furnaces Using Highly Preheated Air Combustion
,”
J. Inst. Energy
,
73
, pp.
18
24
.
3.
Katsuki, M., and Ebisui, K., 1997 “Possibility of Low Nitric Oxides Emissions From Regenerative Combustion Systems using Highly Preheated Air,” Proc. Asian Pacific Combustion Conference (ASPACC-97), Osaka University, Osaka, Japan, May 12–15, 1997, pp. 294–297.
4.
Ishiguro, T., Tsuge, S., Furuhata, T., Kitagawa, K., Arai, N., Hasegawa, T., Tanaka, R., and Gupta, A. K., 1998, “Homogenization and Stabilization During Combustion of Hydrocarbons with Preheated Air,” Proc. 27th Symposium (Intl.) on Combustion, The Combustion Institute, Pittsburgh, PA, pp. 3205–3213.
5.
Gupta
,
A. K.
,
Bolz
,
S.
, and
Hasegawa
,
T.
,
1999
, “
Effect of Air Preheat and Oxygen Concentration on Flame Structure and Emission
,”
ASME J. Energy Resour. Technol.
,
121
, pp.
209
216
.
6.
Konishi, N., Kitagawa, K., Arai, N., and Gupta, A. K., 2000 “Two-Dimensional Spectroscopic Analysis of Spontaneous Emission From a Flame Using Highly Preheated Air Combustion,” J. Propul. Power, to appear in Jan.-Feb. issue.
7.
Hasegawa, T., Mochida, S., and Gupta, A. K., 2001, “Development of Advanced Industrial Furnace using Highly Preheated Air Combustion,” J. Propul. Power, to appear in Jan-Feb issue.
8.
Weber
,
R.
,
Verlaan
,
A. L.
,
Orsino
,
S.
, and
Lallemant
,
N.
,
1999
, “
On Emerging Furnace Design Methodology that Provides Substantial Energy Savings and Drastic Reductions in CO2⁠, CO, and NOx Emissions
,”
J. Inst. Energy
, ,
72
, pp.
77
83
.
9.
Katsuki, M., and Hasegawa, T., 1998, “The Science and Technology of Combustion in Highly Preheated Air,” Proc. 27th Symposium (Intl.) on Combustion, The Combustion Institute, Pittsburtgh, PA, 27, pp. 3135–3146.
10.
Tsuji, H., Gupta, A. K., Katsuki, M., Hasegawa, T., Kishimoto, K., and Morita, M., 2002, High Temperature Air Combustion: From Energy Conservation to Pollution Reduction, CRC Press, Boca Raton, FL.
11.
Fujii
,
T.
,
1992
, “
A Novel Method for Detection of Radial Species in the Gas Phase: Usage of Li+ ion Attachment to Chemical Species
,”
Chem. Phys. Lett.
,
191
, Nos.
1 and 2
, pp.
162
168
.
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