350 MW超临界循环流化床锅炉联合脱硝技术应用与优化研究

doi:10.12096/j.2096-4528.pgt.24006

摘要/Abstract

摘要：

目的选择性催化还原(selective catalytic reduction，SCR)脱硝技术广泛应用于火力发电厂循环流化床锅炉，在实际运行过程中，氨的使用量过大，氨逃逸率高，导致空气预热器腐蚀、堵塞、压差大。为解决这些问题，对某发电厂350 MW超临界循环流化床锅炉的脱硝系统进行了改造和优化。方法在该超临界循环流化床锅炉的二级省煤器、一级省煤器之间添加一层SCR催化剂，在旋风分离器烟气出口处增加尿素喷枪；通过分层给空气、优化风量，实现低氮燃烧；通过分片区控制喷氨系统运行做到精准喷氨，并定期维护设备。结果经过改造和优化，在实现超低排放的基础上，喷氨系统投入温度降低，锅炉在30%负荷下能连续稳定运行，尿素使用量减少，氨逃逸率降低，空气预热器蓄热元件与电除尘布袋基本没有积灰，二者的压差小于设计值。结论通过对脱硝系统改造并进行运行优化，可以有效提高脱硝系统运行效率，降低氨逃逸率。

关键词: 火力发电, 煤燃烧, 循环流化床锅炉, 脱硝, 超低排放, 选择性催化还原(SCR), 氨逃逸率, NO _x 排放

Abstract:

Objectives Selective catalytic reduction (SCR) denitrification technology is widely used in circulating fluidized bed boilers in thermal power plants. During actual operation, the amount of ammonia used is too high and the ammonia escape rate is high, resulting in air preheater corrosion, blockage, and high differential pressure. In order to solve these problems, the denitration system of a 350 MW supercritical circulating fluidized bed boiler in a power plant was reformed and optimized. Methods A layer of SCR catalyst was added between the secondary economizer and the primary economizer of the supercritical circulating fluidized bed boiler, and a urea lance was added at the flue gas outlet of the cyclone separator. The low-NO _x combustion was achieved by grading the air supply and optimizing the air volume. The ammonia injection system was controlled in separate areas to achieve precise ammonia injection, and the equipment was regularly maintained. Results After modification and optimization, on the basis of achieving ultra-low emissions, the input temperature of the ammonia injection system is reduced, the boiler can run continuously and stably under 30% load. Moreover, the use of urea is reduced, the ammonia escape rate is decreased, and there is basically no ash deposit on the heat storage element of air preheater and the bag of electrostatic precipitator. The pressure difference between them is less than the design value. Conclusions The operation efficiency of the denitration system can be improved effectively and the ammonia escape rate can be reduced by reforming and optimizing the denitration system.

Key words: thermal power, coal combustion, circulating fluidized bed boiler, denitration, ultra-low emission, selective catalytic reduction (SCR), ammonia escape rate, NO _x emission

中图分类号:

TK 11

李建军, 尚曼霞, 董海龙, 李冰铭, 黄中. 350 MW超临界循环流化床锅炉联合脱硝技术应用与优化研究[J]. 发电技术, 2025, 46(5): 1014-1021.

Jianjun LI, Manxia SHANG, Hailong DONG, Bingming LI, Zhong HUANG. Application and Optimization Research on Combined Denitrification Technology in 350 MW Supercritical Circulating Fluidized Bed Boiler[J]. Power Generation Technology, 2025, 46(5): 1014-1021.

图/表 8

图1 空气预热器蓄热元件积灰情况

Fig. 1 Ash deposition on heat storage element of air preheater

图2 锅炉主要设备及脱硝工艺图

Fig. 2 Boiler main equipment and denitration process diagram

图3 催化剂安装示意图

Fig. 3 Schematic diagram of catalyst installation

图4 氨逃逸率连续监测取样装置

Fig. 4 A continuous monitoring sampling device for ammonia escape rate

表1 优化后脱硝系统运行数据 (2022年9月均值)

Tab. 1 Operation data of optimized denitrification system (average value for September in 2022)

机组	负荷/MW	SNCR平均尿素用量/(kg/h)	SCR平均尿素用量/(kg/h)	折算NO _x 质量浓度/(mg/m³)	氨逃逸率/(×10^-6)
1号	286.57	379.82	148.82	38.58	0.20
2号	282.57	383.19	126.47	38.17	0.27
3号	253.39	439.87	141.53	42.77	0.29

表2 改造优化前后脱硝系统效率变化

Tab. 2 Efficiency change of denitrification system before and after retrofit optimization

负荷/MW	原始排放NO _x 质量浓度/(mg/m³)	改造优化前		改造优化后		脱硝效率增量/%
负荷/MW	原始排放NO _x 质量浓度/(mg/m³)	净烟气NO _x 质量浓度/(mg/m³)	脱硝效率/%	净烟气NO _x 质量浓度/(mg/m³)	脱硝效率/%	脱硝效率增量/%
350.0	226	60.4	73.27	38.5	82.96	22.6
272.0	194	58.5	69.85	39.3	79.74	21.2
175.5	187	54.6	70.80	35.5	81.02	26.4
106.0	184	55.2	70.00	41.5	77.45	22.2

表3 改造优化前后机组参数

Tab. 3 Parameters of unit before and after retrofit optimization

年度	发电量/(亿kW⋅h)	供汽量/万t	尿素使用量/t	尿素发电单耗/[g/(kW⋅h)]
2018	32.19	17.62	2 478.5	0.770
2019	44.59	221.74	2 944.8	0.660
2020	65.08	337.99	2 519.25	0.387
2021	68.85	395.56	2 895.25	0.421
2022	62.25	424.51	2 720.33	0.422

图5 空气预热器冷端蓄热元件积灰情况

Fig. 5 Ash deposition on cold-end heat storage element of air preheater

参考文献 19

[1]	曲立涛，齐晓辉，王德鑫，等．基于CEMS数据的超低排放燃煤机组大气污染物排放特性分析[J]．中国电力，2023，56(2)：171-178． doi:10.11930/j.issn.1004-9649.202203075
	QU L T， QI X H， WANG D X，et al ．Analysis of air pollutant emission characteristics of ultra-low emission coal-fired units based on CEMS data[J]．Electric Power，2023，56(2)：171-178． doi:10.11930/j.issn.1004-9649.202203075
[2]	张鹏新，高明明，解沛然，等．基于数据驱动的循环流化床机组深度调峰NO _x 预测[J]．发电技术，2025，46(3)：627-636．
	ZHANG P X， GAO M M， XIE P R，et al ．NO _x prediction for deep peaking regulation of circulating fluidized bed units based on data-driven[J]．Power Generation Technology，2025，46(3)：627-636．
[3]	胡昌华，卢啸风．600 MW超临界循环流化床锅炉设备与运行[M]．北京：中国电力出版社，2012：89-110．
	HU C H， LU X F ．Equipment and operation of 600 MW supercritical circulating fluidized bed boiler[M]．Beijing：China Electric Power Press，2012：89-110．
[4]	李枭鸣．电袋复合除尘器在循环流化床锅炉的应用效果研究[J]．电力科技与环保，2024，40(5)：544-551．
	LI X M ．Study on the application effect of electrostatic-fabric integrated precipitator in circulating fluidized bed boiler[J]．Electric Power Technology and Environmental Protection，2024，40(5)：544-551．
[5]	张思海，李超然，万广亮，等．330 MW循环流化床锅炉深度调峰技术[J]．发电技术，2024，45(2)：199-206．
	ZHANG S H， LI C R， WAN G L，et al ．Deep peak shaving technology for 330 MW circulating fluidized bed boiler[J]．Power Generation Technology，2024，45(2)：199-206．
[6]	张文伟，王维庆，樊小朝，等．利用风电制氧的富氧燃煤电厂低碳能源系统容量优化配置[J]．电力系统保护与控制，2023，51(5)：70-83．
	ZHANG W W， WANG W Q， FAN X C，et al ．Optimal capacity configuration of a low carbon energy system of oxygen-enriched coal-fired power plant using wind power to produce oxygen[J]．Power System Protection and Control，2023，51(5)：70-83．
[7]	李小双，冷亚军，吴坚．基于多目标投影寻踪模型的电力发展水平评价方法[J]．电力科学与技术学报，2024，39(5)：46-57．
	LI X S， LENG Y J， WU J ．Evaluating method for power development level based on multi-objective projection pursuit model[J]．Journal of Electric Power Science and Technology，2024，39(5)：46-57．
[8]	崔勇，韩一春，郑谦，等．多能联盟低碳运营决策方法研究框架与展望[J]．电测与仪表，2024，61(3)：10-19． doi:10.1002/ese3.1659
	CUI Y， HAN Y C， ZHENG Q，et al ．Research framework and prospect of multi-energy alliance low-carbon operation decision-making method[J]．Electrical Measurement & Instrumentation，2024，61(3)：10-19． doi:10.1002/ese3.1659
[9]	陈裕楼．电厂锅炉脱硫脱硝及烟气除尘技术[J]．中国设备工程，2020(13)：196-197． doi:10.3969/j.issn.1671-0711.2020.13.099
	CHEN Y L ．Desulfurization，denitrification and flue gas dust removal technology for power plant boilers[J]．China Plant Engineering，2020(13)：196-197． doi:10.3969/j.issn.1671-0711.2020.13.099
[10]	罗晨，马素霞，冯于川，等．选择性非催化还原烟气脱硝技术的研究现状与发展[J]．电力科技与环保，2024，40(6)：603-614．
	LUO C， MA S X， FENG Y C，et al ．Research status and development of flue gas denitrification technology in selective non-catalytic reduction[J]．Electric Power Technology and Environmental Protection，2024，40(6)：603-614．
[11]	罗志刚，何成兵，孟浩然，等．燃煤电厂SCR脱硝系统精准控氨优化方法研究[J]．发电技术，2023，44(4)：525-533．
	LUO Z G， HE C B， MENG H R，et al ．Research on optimization method of precise ammonia injection in SCR de-NO _x system of coal-fired power plant[J]．Power Generation Technology，2023，44(4)：525-
[533]	. doi:10.1023/a:1010650624155
[12]	朱法华，徐静馨，王圣，等．中国燃煤电厂大气污染物治理历程及展望[J]．电力科技与环保，2023，39(5)：371-384．
	ZHU F H， XU J X， WANG S，et al ．Processes and prospects of air pollutant control in coal-fired power plants in China[J]．Electric Power Technology and Environmental Protection，2023，39(5)：371-384．
[13]	国家市场监督管理总局，中国国家标准化管理委员会．危险化学品重大危险源辨识： [S]．北京：中国标准出版社，2019．
	State Administration of Market Supervision and administration，Standardization Administration of China ． Identification of major hazards for hazardous chemicals： [S]．Beijing：Standards Press of China，2019．
[14]	童家麟，邹玉凤，郑建平，等．低负荷下四角切圆锅炉NO _x 优化控制[J]．广东电力，2023，36(10)：137-147．
	TONG J L， ZOU Y F， ZHENG J P，et al ．NO _x optimal control of tangentially-fired boiler under low load[J]．Guangdong Electric Power，2023，36(10)：137-147．
[15]	赵强，向轶，冷健，等．SNCR脱硝技术在中高温分离器型循环流化床锅炉上的运行分析[J]．工业炉，2020，42(1)：41-45． doi:10.3969/j.issn.1001-6988.2020.01.012
	ZHAO Q， XIANG Y， LENG J，et al ．Operation analysis of SNCR denitration technology on circulating fluidized bed boiler with medium and high temperature separators[J]．Industrial Furnace，2020，42(1)：41-45． doi:10.3969/j.issn.1001-6988.2020.01.012
[16]	罗朝晖，王恩禄．循环流化床锅炉选择性非催化还原技术及其脱硝系统的研究[J]．动力工程，2008，28(3)：442-446． doi:10.3321/j.issn:1000-6761.2008.03.024
	LUO Z H， WANG E L ．Study on selective non-catalytic reduction technology and its denitrification systems used in CFB boilers[J]．Journal of Power Engineering，2008，28(3)：442-446． doi:10.3321/j.issn:1000-6761.2008.03.024
[17]	黄中．循环流化床锅炉技术1 000问[M]．北京：中国电力出版社，2016：202-206．
	HUANG Z ．1 000 questions about circulating fluidized bed boiler technology[M]．Beijing：China Electric Power Press，2016：202-206．
[18]	卢刚，胡宗阳，郑瑞祥．采用在线自适应增益规划方法的电厂脱硝控制优化[J]．电力科技与环保，2023，39(1)：35-42．
	LU G， HU Z Y， ZHENG R X ．Optimization of denitrification control in power plant by online adaptive gain planning method[J]．Electric Power Technology and Environmental Protection，2023，39(1)：35-42．
[19]	严新荣，胡志勇，张鹏威，等．煤电机组运行灵活性提升技术研究与应用[J]．发电技术，2024，45(6)：1074-1086．
	YAN X R， HU Z Y， ZHANG P W，et al ．Research and application of operation flexibility improvement technology for coal-fired power unit[J]．Power Generation Technology，2024，45(6)：1074-1086．