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Abstract

By injecting normal temperature air into a coal-fired boiler furnace at an evaporation capacity of 2 ton/h, flameless combustion with little noise is achieved. Numerical simulations and experimental research shows that the combustion takes place in a wide and broad area, almost the whole furnace, resulting in a voluminal reaction. For this normal temperature air flameless combustion (NTAFC), when the excess air coefficient approaches 1, the fuel combusts fully. The concentrations of NO_x and CO in flue gas are relatively low and are hardly affected by either an excess air coefficient or thermal load. In front of the jet is a low-temperature gas-mixing zone whose diameter is equivalent to that of the jet, and the temperature of this zone increases with the distance from the jet tip. A mild stable combustion reaction without a visible flame takes place in the part of the furnace where the temperature value is higher and the amplitude of variation is not large. In addition to the advantages shared with high-temperature air combustion (e.g. uniform temperature distribution, low NO_x and CO emission, high combustion efficiency, and so on), NTAFC does not require a high-temperature air-preheating system and is easier to actualize.

Keywords

flameless combustion furnace CO)high combustion efficiency

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References

Katsuki

Hasegawa

The science and technology of combustion in highly preheated air. Proc. Combust. Inst., 1998, 27, 3135–3146.

Niioka

Fundamentals and applications of high temperature air combustion. In Proceedings of the Fifth ASME/JSME Joint Thermal Engineering Conference, San Diego, CA, 1999, pp. 1–6.

Pressing

Peters

Wunning

J. G.

Laseroptical investigation of highly preheated combustion with strong exhaust gas recirculation. Proc. Combust. Inst. 1998, 27, 3197–3204.

Milani

Saponaro

Diluted combustion technologies. IFRF Combust. J., 2001, 1, 1–32.

Cavigiolo

Galbiati

M. A.

Effuggi

Gelosa

Rota

Mild combustion in a laboratoryscale apparatus. Combust. Sci. Technol., 2003, 175, 1347–1367.

You

Yuan

Emission on NO_x in high temperature combustion with low oxygen concentration (in Chinese). J. Combust. Sci. Technol., 2002, 8 (1), 17–22.

Cavaliere

de Joannon

Mild combustion. Prog. Energy Combust. Sci., 2004, 30, 329–366.

Levy

Sherbaum

Afri

Basic thermodynamics of FLOXCOM, the low-NO_x gas turbines adiabatic combustor. Appl. Thermal Eng., 2004, 24, 1593–1605.

You

Numerical research on heat transfer in honeycomb regenerator (in Chinese). J. Eng. Thermophys., 2001, 22 (5), 657–660.

10.

Shu

Zhu

Numerical simulation investigation of the combustion system modification scheme for a cell pit furnace (in Chinese). J. Eng. Thermal Energy Power, 2003, 18 (6), 636–638.

11.

Wang

You

Experimental study on heat transfer performance of honeycomb heat regenerator (in Chinese). J. Eng. Thermophys., 2003, 24 (5), 897–899.

12.

Wunning

J. A.

Wunning

J. G.

Flameless oxidation to reduce thermal NO-formation. Prog. Energy Combust. Sci., 1997, 23, 81–94.

Structure of reaction zone of normal temperature air flameless combustion in a 2 ton/h coal-fired boiler furnace

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