Operation optimization of selective catalytic reduction denitrification system for 350MW coal-fired power plant

doi:10.16085/j.issn.1000-6613.2016-2448

Abstract

Abstract: In order to reduce the cost of denitrification of thermal power units under the condition of satisfying the environmental emission standards,a calculation model of the denitrification cost for electricity generation was established for the selective catalytic reduction(SCR)denitrification system of a 350MW coal-fired unit. The cost of denitrification is divided into two parts:fixed denitrification cost for electricity generation and variable denitrification cost for electricity generation. The fixed denitrification cost for electricity generation includes depreciation cost,accounting cost,catalyst replacement cost,overhaul cost,labor cost,compensation price and other cost. The variable denitrification cost for electricity generation includes cost of electricity,cost of ammonia injection and cost of sewage. Taking denitrification cost for electricity generation as the evaluation index,the optimization model of denitrification system was established by using support vector machine and particle swarm coupling algorithm,and the whole load section was optimized for denitration system. The results show that the prediction model can accurately predict the denitrification cost for electricity generation,and the maximum correlation coefficient is 99.9011%,which is in accordance with the actual operation of the power plant. The amount of ammonia spray required after the model optimization is reduced to 0.1578t/h,and the denitrification cost for electricity generation is significantly reduced. The system economy is improved,which can be used to guide the economic operation of the power plant.

Key words: selective catalytic reduction (SCR), denitrification cost for electricity generation, algorithm, optimize the operation

摘要： 为了在满足环保排放标准的条件下，降低火电机组脱硝成本，本文针对某350MW燃煤机组的选择性催化还原（SCR）脱硝系统，建立了度电脱硝成本的计算模型。该模型将脱硝成本分为固定成本和变动成本两部分，度电固定脱硝成本包括折旧成本、会计成本、催化剂更换成本、大修成本、人工成本、补偿电价、其他成本，度电变动脱硝成本包括电耗成本、喷氨成本、排污成本。以度电脱硝成本作为评价指标，利用支持向量机与粒子群耦合算法建立了脱硝系统运行优化模型，对脱硝系统进行了全负荷段优化。结果表明，预测模型能精确预测度电脱硝成本，最高相关系数可达99.9011%；经模型优化后，脱硝所需喷氨量降低至0.1578t/h，度电脱硝成本显著降低，系统经济性得到提高，可用于指导电厂经济运行。

关键词: 选择催化还原, 度电脱硝成本, 算法, 优化运行

CLC Number:

TK-9

LI Bin, YANG Haonan, DENG Yu, ZHANG Bo, ZHU Yan. Operation optimization of selective catalytic reduction denitrification system for 350MW coal-fired power plant[J]. Chemical Industry and Engineering Progress, 2017, 36(08): 3100-3107.

李斌, 杨浩楠, 邓煜, 张博, 祝燕. 350MW燃煤机组选择性催化还原脱硝系统运行优化[J]. 化工进展, 2017, 36(08): 3100-3107.

References

[1] 中华人民共和国国家发展和改革委员会. 《中华人民共和国国民经济和社会发展第十三个五年规划纲要》辅导读本[M]. 北京:人民出版社,2006.
[2] 耿春香,刘文蓉,柴倩倩,等. Mn-Ce/TiO₂低温脱硝催化剂的性能[J].化工进展,2012,31(6):1353-1356. GENG Chunxiang,LIU Wenrong,CHAI Qianqian,et al.Study on the denitration characteristics of Mn-Ce/TiO₂ catalyst at low temperature[J].Chemical Industry and Engineering Progress,2012,31(6):1353-1356.
[3] 顾卫荣,周明吉,马薇,等. 选择性催化还原脱硝催化剂的研究进展[J]. 化工进展,2012,31(7):1493-1500. GU Weirong,ZHOU Mingji,MA Wei,et al. Research progress on selective catalytic reduction De-NO_x catalysts[J]. Chemical Industry and Engineering Progress,2012,31(7):1493-1500.
[4] 陈焕章,李宏,李花. 负载型Mn-Fe/γ-Al₂O₃低温脱硝催化剂的性能[J]. 化工进展,2016,35(4):1107-1112. CHEN Huanzhang,LI Hong,LI Hua. Denitration performance of supported Mn-Fe/γ-Al₂O₃ catalyst at low temperature[J]. Chemical Industry and Engineering Progress,2016,35(4):1107-1112.
[5] 李小海,王虎,於承志.平板式脱硝催化剂的基本性能[J]. 化工进展,2012,31(s2):147-151. LI Xiaohai,WANG Hu,YU Chengzhi.Properties of the plate-type De-NO_x catalysts[J]. Chemical Industry and Engineering Progress,2012,31(s2):147-151.
[6] 李想,李俊华,何煦,等. 烟气脱硝催化剂中毒机制与再生技术[J]. 化工进展,2015,34(12):4129-4138. LI Xiang,LI Junhua,HE Xu,et al. Poisoning mechanism and regeneration process of the denitration catalyst[J]. Chemical Industry and Engineering Progress,2015,34(12):4129-4138.
[7] YANG J,MA H,YAMAMOTO Y,et al. SCR catalyst coated on low-cost monolith support for flue gas denitration of industrial furnaces[J]. Chemical Engineering Journal,2013,230:513-521.
[8] LIU Z,IHL WOO S. Recent advances in catalytic DeNO_x science and technology[J]. Catalysis Reviews,2006,48(1):43-89.
[9] 高岩,栾涛,彭吉伟,等. 燃煤电厂真实烟气条件下SCR催化剂脱硝性能[J]. 化工学报,2013,64(7):2611-2618. GAO Yan,LUAN Tao,PENG Jiwei,et al. DeNO_x performance of SCR catalyst for exhaust gas from coal-fired power plant[J]. CIESC Journal,2013,64(7):2611-2618.
[10] 汤志刚,贺志敏,EBRAHIM,等. 焦炉烟道气双氨法一体化脱硫脱硝:从实验室到工业实验[J]. 化工学报,2017,68(2):496-508. TANG Zhigang,HE Zhimin,EBRAHIM,et al. Desulfurization and denitration integrative process for coke oven flue gas using dual ammonia solution:from laboratory to industrial test[J]. CIESC Journal,2017,68(2):496-508.
[11] 孙墨杰,姜佳旭,于大禹. 基于反硝化菌的烟气脱硝技术研究进展[J]. 化工进展,2012,33(6):1179-1183. SUN Mojie,JIANG Jiaxu,YU Dayu. Research process in flue gas denitration by denitrifying bacteria[J]. Chemical Industry and Engineering Progress,2012,33(6):1179-1183.
[12] 樊庆锌,王明轩,关心,等. 某燃煤电厂300MW机组SCR烟气脱硝装置结构优化[J]. 化工进展,2014,35(10):2806-2814. FAN Qingxin,WANG Mingxuan,GUAN Xin,et al. Optimal design of a SCR-DeNO_x system for a 300MW coal-fired power plant[J]. Chemical Industry and Engineering Progress,2014,35(10):2806-2814.
[13] 胡志光,朱怡儒. 1000MW燃煤机组SCR脱硝系统设计[J]. 化工进展,2014,35(s1):308-311. HU Zhiguang,ZHU Yiru. The design of SCR DeNO_x system in a 1000MW coal-fired units project[J]. Chemical Industry and Engineering Progress,2014,35(s1):308-311.
[14] 韩发年,闫志勇. SCR烟气脱硝工艺喷氨混合装置研究进展[J]. 化工进展,2015,36(12):4151-4157. HAN Fanian,YAN Zhiyong. Advances in ammonia injection and mixing device of SCR-DeNO_x system[J]. Chemical Industry and Engineering Progress,2015,36(12):4151-4157.
[15] 王为术,上官闪闪,姚明宇,等. 300MW燃煤锅炉SCR脱硝系统导流装置的设计优化[J]. 煤炭学报,2015,40(7):1634-1640. WANG Weishu,SHANGGUAN Shanshan,YAO Mingyu,et al. Design and optimization of guide vanes in a 300 MW coal-fired boiler SCR system[J]. Journal of China Coal Society,2015,40(7):1634-1640.
[16] 张文志,曾毅夫. SCR脱硝系统烟道内流场优化[J]. 环境工程学报,2015,9(2):883-887. ZHANG Wenzhi,ZENG Yifu. Optimization of flow field in the SCR denitrification system[J].Chinese Journal of Environmental Engineering,2015,9(2):883-887.
[17] CHO J M,CHOI J W,HONG S H,et al. Application of computational fluid dynamicsanalysis for improving performance of commercial Engineering,2006,23(1):43-56.
[18] 李军,罗国华,魏飞. 催化裂化再生过程脱硝技术[J]. 化工学报, 2014,65(7):2426-2436. LI Jun,LUO Guohua,WEI Fei. A novel multi-layer and multi-zone redox FCC regenerator design for removing NO_x gas system[J]. CIESC Journal,2014,65(7):2426-2436.
[19] 杨加强,梅毅,王驰,等. 湿法烟气脱硝技术现状及发展[J]. 化工进展,2017,36(2):695-704. YANG Jiaqiang,MEI Yi,WANG Chi,et al. Current status and trends on wet flue gas denitration technology[J] Chemical Industry and Engineering Progress,2017,36(2):695-704.
[20] XU Y Y,ZHANG Y,WANG J C,et al. Application of CFD in the optimal design of aSCR-DeNO_x system for a 300MW coal-fired power plant[J]. Computers and Chemical Engineering,2013,49:50-60.
[21] 杨勇平,袁星,徐钢. 火电机组湿法脱硫系统能耗的回归分析[J]. 工程热物理学报,2012,33(11):1854-1859. YANG Yongping,YUAN Xing,XU Gang. Regressive analysis of energy consumption of the wet desulfurization system in thermal power plant[J].Journal of Engineering Thermophysics,2012,33(11):1854-1859.
[22] 刘延泉,牛成林,程海燕,等. 350MW机组湿法烟气脱硫控制系统目标值优化[J]. 中国电力,2012,45(4):68-72. LIU Yanquan,NIU Chenglin,CHENG Haiyan,et al. Target optimization of wet flue gas desulfurization control system in 350MW unit[J]. Electric Power,2012,45(4):68-72.