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| Experimental research on SNCR applied in power plant boiler: impact of temperature and urea solution injection volume flow rate |
LV Hong-kun,YANG Wei-juan, ZHOU Jun-hun,ZHOU Zhi-jun,
HUANG Zhen-yu, CEN Ke-fa |
| (State Key Laboratory of Clean Energy Utilization, Zhejiang University, Hangzhou 310027, China) |
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Abstract Selective non-catalytic reduction (SNCR) using urea solution injection was applied to a HG-410/9.8-YW15 boiler on the base of conventional pulverized-coal reburning process. Experiments were mainly conducted under 280, 345 and 410 t/h. Results showed that NOx emission was below 200 mg/m3(standard condition,6% O2 volume fraction, dry gas) when SNCR was operating, namely a NOx reduction of 40%-60%.It was favorable to injecting urea solution using the injection layer where the hearth temperature was about 950 ℃, higher or lower might be disadvantageous to NOx reduction, and the lower temperature also resulted in more ammonia slip. The increase of layers injection volume flow rate could improve NOx reduction efficiency, the economical injection volume flow rate in the experimental range was 1.0-1.6 m3·h-1, and the larger injection volume flow rate also led to lower emission of NH3 and N2O. But the water injected into the hearth resulted in a decrease of boiler efficiency by almost 0.5%.
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| Fund: 吕洪坤(1981-),男,浙江新昌人,博士生,从事低 NOx技术的研究. |
电站锅炉选择性非催化还原脱硝实验研究
——还原区温度、尿素溶液喷射体积流量的影响
对一台HG-410/9.8-YW15型煤粉锅炉,在常规煤粉再燃技术改造的基础上进一步结合了使用尿素溶液喷射的选择性非催化还原(SNCR)技术.实验主要在280、345、410 t/h 3个负荷下进行.实验结果表明,各个负荷下,SNCR技术可以将NOx排放降至低于200 mg/m3(标准状态、6%O2体积分数、干态),达到40%~60%的脱硝效率.应选择950 ℃左右的喷射层进行喷射为宜,温度过高或过低均会导致脱硝效率的降低,过低的温度还会使得尾部NH3排放大量增加.通过增加层喷射体积流量可以提高脱硝效率,在实验范围内得到的层最佳喷射体积流量为1.0~1.6 m3/h.同时,增加层喷射体积流量对NH3及N2O的减排也是有益的,而喷入的水量会对锅炉效率造成约0.5%的损失.
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| [1] 毛健雄, 毛健全, 赵树民. 煤的清洁燃烧 [M]. 北京: 科学出版社, 2000: 3-8.
[2] ROTA R, ANTOS D, ZANOELO E F, et al. Experimental and modeling analysis of the NOxOUT process [J]. Chemical Engineering Science , 2002, 57(1): 27-38.
[3] ROTA R, ZANOELO E.F. Influence of oxygenated additives on the NOxOUT process efficiency [J]. Fuel, 2003, 82(7): 765-770.
[4] JAVED M T, IRFAN N, GIBBS B M. Control of combustion-generated nitrogen oxides by selective non-catalytic reduction [J]. Journal of Environmental Management , 2007,83(3): 251-289.
[5] 王智化, 周俊虎, 周昊, 等. 炉内高温喷射氨水脱除NOx机理及其影响因素的研究 [J]. 浙江大学学报:工学版, 2004,38(4): 495-500.WANG Zhi-hua, ZHOU Jun-hu, ZHOU Hao, et al. Experimental and modeling study on the mechanism and sensitive parameters of the thermal DeNOx process [J].Journal of Zhejiang University: Engineering Science, 2004, 38 (4): 495-500.
[6] STBERG M, DAM-JOHANSEN K, JOHNSSON J. Influence of mixing on the SNCR process [J].Chemical Engineering Science, 1997, 52 (15): 2511-2525.
[7] OLIVA M, ALZUETA M U, MILLERA A, et al. Theoretical study of the influence of mixing in the SNCR process comparison with pilot scale data [J]. Chemical Engineering Science , 2000, 55(22):5321-5332.
[8] 周俊虎, 杨卫娟, 周志军, 等. 选择非催化还原过程中的N2O生成与排放 [J]. 中国电机工程学报, 2005, 25(13): 91-95.ZHOU Jun-hu, YANG Wei-Juan, ZHOU Zhi-jun, et al. Nitrous oxide formation and emission in selective non-catalytic reduction process [J]. Proceedings of the Csee, 2005, 25 (13): 91-95.
[9] SMITH G P, GOLDEN D M, FRENKLACH M, et al. GRI-MECH 3.0 [EB /OL]. [2008-01-20]. http://www.me.berkeley.edu/gri_mech.
[10] 潘维, 池作和, 李戈, 等. 四角切圆燃烧锅炉燃烧和污染物排放数值模拟 [J]. 浙江大学学报:工学版, 2004, 38(6):761-764.PAN Wei, CHI Zuo-he, LI Ge, et al. Numerical simulation of combustion and nitrogen oxides generation process in tangentially fired furnace[J]. Journal of Zhejiang University:Engineering Science, 2004, 38 (6):761-764. |
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