Influence of N2 and CO2 dilution on methane MILD combustion: Insights into temperature distribution and emission optimization

被引：0

作者：

Tian, Junjian ^{[1
]}

Ma, Yue ^{[2
]}

Song, Weiwei ^{[2
]}

Ni, Zhanshi ^{[1
]}

Liu, Xiang ^{[1
]}

Hu, Peng ^{[1
]}

Meng, Kesheng ^{[3
]}

Lin, Qizhao ^{[1
]}

机构：

[1] Univ Sci & Technol China, Dept Thermal Sci & Energy Engn, Hefei 230027, Peoples R China

[2] Anhui Boyue Kitchen Technol Co Ltd, Cross Zhengyang & Gubei 2nd Rd, Luan, Anhui, Peoples R China

[3] Anhui Commun Vocat & Tech Coll, Dept Aviat, 22 Taihu East Rd, Hefei 230051, Peoples R China

来源：

FUEL | 2025年 / 395卷

关键词：

MILD combustion; Temperature uniformity; NO emissions; CO2; dilution; NO EMISSION; DIFFUSION COMBUSTION; CARBON-DIOXIDE; FLAME; FUEL; N-2; JET; MIXTURE; BIOGAS; H2O;

D O I：

10.1016/j.fuel.2025.135202

中图分类号：

TE [石油、天然气工业]; TK [能源与动力工程];

学科分类号：

0807 ; 0820 ;

摘要：

This study investigates the effects of various diluents and their proportions on methane-based Moderate or Intense Low-oxygen Dilution (MILD) combustion in a swirl combustion chamber. The experimental analysis focuses on the modulation of the diluent effect by equivalence ratio and thermal power. Key parameters, including temperature distribution, temperature fluctuation rates, and CO and NO emissions, are systematically examined under different operating conditions. The findings demonstrate that CO2 dilution significantly lowers the combustion temperature, enhances temperature uniformity, and minimizes NO emissions (up to 70%), but increases CO emissions. However, N2 dilution slightly increases the temperature and reduces CO emissions, with comparatively less effect on NO emissions. Furthermore, variations in equivalence ratio and thermal power have marked effects on temperature and emissions behavior. Appropriate adjustments of these parameters can optimize temperature uniformity and emissions control. This work confirms that optimized MILD combustion can be achieved in a swirl combustion chamber by using CO2 and N2 to dilute CH4, which is a critical insight for advancing the practical application of MILD combustion technology.

引用

页数：16

共 79 条

[1]

Tsuji H., Gupta A.K., Hasegawa T., Katsuki M., Kishimoto K., Morita M., High temperature air combustion, From Energy Conservation to Pollution Reduction, (2002)

[2]

Katsuki M., Hasegawa T., The science and technology of combustion in highly preheated air, Symp (Int) Combust, 27, 2, pp. 3135-3146, (1998)

[3]

Gupta A.K., Thermal characteristics of gaseous fuel flames using high temperature air, J Eng Gas Turb Power, 126, 1, pp. 9-19, (2004)

[4]

Weber R., Gupta A.K., Mochida S., High temperature air combustion (HiTAC): How it all started for applications in industrial furnaces and future prospects, Appl Energy, 278, (2020)

[5]

Wunning J.A., Wunning J.G., Flameless oxidation to reduce thermal NO-formation, Prog Energy Combust Sci, 23, 1, pp. 81-94, (1997)

[6]

Yu Y., Gaofeng W., Qizhao L., Chengbiao M., Xianjun X., Flameless combustion for hydrogen containing fuels, Int J Hydrogen Energy, 35, 7, pp. 2694-2697, (2010)

[7]

Ouyang Z., Ding H., Liu W., Li S., Cao X., Effect of the staged secondary air on NO emission of pulverized semi-coke flameless combustion with coal preheating technology, Fuel, 291, (2021)

[8]

Zornek T., Monz T., Aigner M., Performance analysis of the micro gas turbine Turbec T100 with a new FLOX-combustion system for low calorific fuels, Appl Energy, 159, pp. 276-284, (2015)

[9]

Arghode V.K., Gupta A.K., Effect of flow field for colorless distributed combustion (CDC) for gas turbine combustion, Appl Energy, 87, 5, pp. 1631-1640, (2010)

[10]

Khalil A.E.E., Gupta A.K., Impact of internal entrainment on high intensity distributed combustion, Appl Energy, 156, pp. 241-250, (2015)

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