Reburning Characteristics Research of Combustible Gas in CFB

Da Long Jiang; Tao Wang; Xiao Ying Hu; Han Fei Zhang; Ji Zhen Liu; Yong Ping Yang

doi:10.4028/www.scientific.net/AMM.170-173.2625

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Method for Monitoring Average Flow Velocity of Fumes by Mean of Velocity Field Constant
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Ventilation Quantity Analysis on Different Ventilation Opening Area of Courtyard Sunspace
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Hanging and Top-down Construction of a Ventilation Shaft in Soft Soils
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Reburning Characteristics Research of Combustible Gas in CFB
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System Design and Experiments Study on 120K the Segregation Linder Refrigerator with Pre-Cooling Cycle
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The Potential Analysis of Natural Ventilation in Summer Climate Conditions in Five Typical Regions for Shandong Province
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HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 170-173Reburning Characteristics Research of Combustible...

Reburning Characteristics Research of Combustible Gas in CFB

Abstract:

Experimental research on the characteristics of co-combustion coal and combustible gas has been carried out. The influence of nozzle position and combustible gas reburning ratio on N₂O and NO removal rate were carried out at CFB experimental platform. It is found that N₂O removal rate achieved a maximum value when the reburning gas was injected into furnace from nozzle C with a height-diameter ratio of 8.3, and the NO removal rate is about 50%; When the combustible gas were injected into furnace from nozzle C, the N₂O removal rate kept increasing with the increase of reburning ratio (R_m), which can reach 99% when the Rm value is 10.5%. In addition, the NO removal rate is increasd after the first reduction with the increase of R_m, when the rate is about 39% with Rm is 10.5%.

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Periodical:

Applied Mechanics and Materials (Volumes 170-173)

Pages:

2625-2628

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.170-173.2625

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Online since:

May 2012

Authors:

Da Long Jiang, Tao Wang, Xiao Ying Hu, Han Fei Zhang, Ji Zhen Liu, Yong Ping Yang

Keywords:

CFB, Combustible Gas, Reburning Ratio, Removal Rate

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References

[1] B. X. Shen, T. Mi, D. C. Liu: Fuel Processing Technology, vol. 84 (2003), pp.13-21.

Google Scholar

[2] H. Liu, B. M. Gibbs: Fuel, vol. 81(2002), pp.271-280.

Google Scholar

[3] X. S. Hou, H. Zhang, S. Yang: Chemical Engineering Journal, vol. 140(2008), pp.43-51.

Google Scholar

[4] M. Gregorio: Combustion and Flame, vol.107(1996), pp.103-113.

Google Scholar

[5] A. R. Ravishankara, S. D. John, W. P. Robert. Science Magazine, vol. 326(2009), pp.123-125.

Google Scholar

[6] H. Zhang, J. F. Lu, K. Y. Chen, in: An experimental study on N2O reduction over circulating ashes of CFB boilers, 18th International Conference on Fluidized Bed Combustion. Toronto. Canada: ASME, 2005pp. 309-317.

DOI: 10.1115/fbc2005-78047

Google Scholar

[7] Y. Zhang, B. Chen, Y. J. Ding: Journal of Tsinghua University (Science and Technology), vol. 46(2006), pp.666-669.

Google Scholar

[8] L. Armesto, H. Boerrigter, H. Bahillo: Fuel, vol. 82(2003), pp.1845-1850.

Google Scholar

[9] L. H. Shen, Z. L. Su, S. Z. Yo: Acta Scientiae Ciriumstantiae, vol. 20(2000), pp.439-444.

Google Scholar

[10] G. X. Yue, F. J. Pereira, A. F. Sarofim: Combustion Science and Technology, vol. 83(1992), pp.245-256.

Google Scholar