| 光谱学与光谱分析 |
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| Research on Radiation Spectrum of Pulverized Coal Combustion Flame |
| GUI Xin-yang, Aymeric Alliot, YANG Bin*, ZHOU Wu, PING Li, CAI Xiao-shu |
| Institute of Particle and Two-Phase Flow Measurement/Shanghai Key Laboratory of Multiphase Flow and Heat Transfer in Power Engineering, University of Shanghai for Science and Technology, Shanghai 200093, China |
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Abstract In order to study on radiation spectrum of pulverized coal flame, radiation spectrums of pulverized coal flame on flat flame burner were measured with fiber optic spectrometer and the radiation characteristic was analyzed in detail. Distribution curves of radiation intensity of flame with wavelength were obtained based on Planck’s Law and calibration by using blackbody furnace. Then, combustion parameters such as temperature and emissivity were calculated by using least square method. Therefore, the measurement method based on radiation spectrum of pulverized coal flame was proposed. And the experimental investigations on pulverized coal flame under different conditions were carried out with this method. The result shows that the radiation spectrum of pulverized coal flame is significant and continuous in the wavelength ranging from 200 to 1 100 nm.The temperature and emissivity of flame can be determined by using Planck’s Law and least square method. Meanwhile, emission peaks of alkali metal such as sodium and potassium appear on the radiation spectrum of pulverized coal combustion flame near 590, 766, 769 and 779 nm, and the appearance of these emission lines is related with temperature. When the concentration of pulverized coal is increasing, the temperature of pulverized coal flame has a little change but the emissivity changes obviously. The intensity of radiation is increasing greatly with emissivity. It can provide important reference for combustion optimization of boiler.
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Received: 2015-09-05
Accepted: 2016-01-15
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Corresponding Authors:
YANG Bin
E-mail: yangbin@usst.edu.cn
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[1] China Energy Statistical Yearbook 2013(中国能源统计年鉴2013). Department of Energy Statistics, the National Bureau of Statistics, the People’s Republic of China(国家统计局能源统计司), 2013.
[2] CHE De-fu(车德福). Boilers——Theory, Design and Operation(锅炉——理论、设计及运行). Xi’an Jiaotong University Press(西安交通大学出版社), 2008.
[3] Holman J P. Heat Transfer(传热学). China Machine Press(机械工业出版社), 2011.
[4] Modest Michael F. Radiation Heat Transfer, Elsevier, 2013.
[5] Aleksandar Saljnikov, Mirko Komatina, Vasilije Manovic, et al. International Journal of Heat and Mass Transfer, 2009, 52(5): 2871.
[6] ZHANG Xiao-bo, ZHAO Hong, YANG Jian-guo(张骁博, 赵 虹, 杨建国). Journal of China Coal Society(煤炭学报), 2011, 36(6): 999.
[7] Robert Johansson, Bo Leckner, Klas Andersson, et al. International Journal of Heat and Mass Transfer, 2013, 65: 143. |
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