Study on SO3 formation characteristics of a typical vanadium titanium SCR catalyst

doi:10.11949/0438-1157.20201429

Abstract

Abstract:

Selective catalytic reduction (SCR) technology is widely used in flue gas nitrogen oxide emission control due to its high denitration efficiency and good selectivity; however, currently widely used vanadium titanium SCR catalyst can oxidize SO₂ in flue gas into SO₃, and excessive SO₃ in flue gas will cause serious impact on the safe operation of power plant and also cause environmental pollution. Taking commercial V₂O₅-WO₃/TiO₂ catalyst as the research object, the effects of flue gas flowrate, temperature, O₂ concentration and SO₂ concentration on the formation of SO₃ on the catalyst during SCR denitrification were systematically studied, and the reaction kinetics of SO₃ formation was further discussed. The results show that the reaction order of SO₂ is 0.59. When the concentration of O₂ is more than 3%, the reaction order of O₂ is 0, and the activation energy of SO₃ formation on catalyst is 70.39 kJ/mol. The increase of SO₂ concentration will increase the reaction rate of SO₃formation; O₂concentration has no significant effect on the formation of SO₃on the catalyst. The temperature of flue gas has a significant effect on the formation of SO₃, and high temperature can promote the formation of SO₃.

Key words: SCR catalyst, coal fired flue gas, SO₂, SO₃, reaction kinetics

摘要：

选择性催化还原（SCR）技术由于脱硝效率高、选择性好而被广泛应用于烟气氮氧化物排放控制；然而，目前广泛采用的钒钛系SCR脱硝催化剂会使烟气中SO₂氧化成SO₃，烟气中过高的SO₃对电厂安全运行会造成严重影响，也会对环境造成污染。以典型V₂O₅-WO₃/TiO₂催化剂为研究对象，系统研究了SCR脱硝过程中烟气流量、温度、O₂浓度、SO₂浓度等对催化剂表面SO₃生成特性的影响，并进一步对SO₃生成的反应动力学特性进行了分析。研究表明：催化剂表面SO₃生成反应中SO₂的反应级数为0.59，当O₂浓度大于3%时，O₂的反应级数为0，该反应的表观活化能为70.39 kJ/mol；实验条件下，烟气中SO₂浓度增加会使SO₃生成的反应速率提高；O₂浓度对催化剂表面SO₃生成影响并不显著；烟气温度对催化剂表面SO₃生成具有显著影响，高温会促进SO₃的生成。

关键词: SCR催化剂, 燃煤烟气, SO₂, SO₃, 反应动力学

CLC Number:

X 511

YIN Zijun, SU Sheng, QING Mengxia, ZHAO Zhigang, WANG Zhonghui, WANG Lele, JIANG Long, WANG Yi, HU Song, XIANG Jun. Study on SO₃ formation characteristics of a typical vanadium titanium SCR catalyst[J]. CIESC Journal, 2021, 72(5): 2596-2603.

尹子骏, 苏胜, 卿梦霞, 赵志刚, 王中辉, 王乐乐, 江龙, 汪一, 胡松, 向军. 一种典型钒钛系SCR催化剂SO₃生成特性研究[J]. 化工学报, 2021, 72(5): 2596-2603.

Figures/Tables 15

Table 1 Test results of XRF of catalyst

Ti	W	V	S	Si	Al	Fe	Ca	其他
83.88%	6.48%	1.51%	1.42%	2.56%	1.06%	0.09%	0.93%	2.07%

Table 2 Test results of BET of catalyst

比表面积/(m²/g)	孔容/(cm³/g)	平均孔径/nm
65.38	0.32	19.17

Fig.1 Schematic diagram of experimental setup

Table 3 Experimental condition parameters of SO3 generation experiment

温度/℃	流量/(L/min)	气体成分
360	0.5~1.5	600×10^-6 SO₂、3% O₂、N₂平衡
280~400	1	600×10^-6 SO₂、3% O₂、N₂平衡
360	1	(400~1200)×10^-6 SO₂、3% O₂、N₂平衡
360	1	600×10^-6 SO₂、1.5%~10% O₂、N₂平衡

Table 4 SOx collection rate of reaction system under different SO2 concentration

SO₂体积

分数

系统入口SO₂总量/mmol

冷凝管中SO₃生成量/mmol

吸收液中SO₂含量/mmol

SO_x收集

率/%

Fig.2 Variation of SO2 conversion with flowrate

Fig.3 Variation of SO2 conversion with temperature

Fig.4 Variation of SO2 conversion with SO2 concentration

Fig.5 Variation of SO2 conversion with O2 concentration

Fig.6 Dependence of SO2 conversion rate on SO2 concentration

Fig.7 lnrSO2–lnCSO2 at various temperatures

Fig.8 Dependence of SO2 conversion rate on O2 concentration

Fig.9 lnrSO2–lnCO2 at various temperatures

Table 5 Relationship between rate constant and reaction temperature

反应温度/℃	表观速率常数×10⁷/ (L/(g?min))
280	4.80
320	8.42
360	27.74
400	68.47

Fig.10 Curve of lnkabs–1/T for SO2 oxidation

References 30

1	李高磊, 郭沂权, 张世博, 等. 超低排放燃煤电厂SO₃生成及控制的试验研究[J]. 中国电机工程学报, 2019, 39(4): 1079-1086.
	Li G L, Guo Y Q, Zhang S B, et al. Experimental research on SO₃ generation and control in ultra-low emission coal-fired power plant[J]. Proceedings of the CSEE, 2019, 39(4): 1079-1086.
2	Li X, Wu Z, Zhang L, et al. An updated acid dew point temperature estimation method for air-firing and oxy-fuel combustion processes[J]. Fuel Processing Technology, 2016, 154: 204-209.
3	Zheng C, Wang Y, Liu Y, et al. Formation, transformation, measurement, and control of SO₃ in coal-fired power plants[J]. Fuel, 2019, 241: 327-346.
4	Shen J L, Zheng C H, Xu L J, et al. Atmospheric emission inventory of SO₃ from coal-fired power plants in China in the period 2009—2014[J]. Atmospheric Environment, 2019, 197: 14-21.
5	Duan L B, Duan Y Q, Sarbassov Y, et al. SO₃ formation under oxy-CFB combustion condition[J]. International Journal of Greenhouse Gas Control, 2015, 43: 172-178.
6	Zhao K, Han W, Tang Z, et al. Investigation of coating technology and catalytic performance over monolithic V₂O₅-WO₃/TiO₂ catalyst for selective catalytic reduction of NO_x with NH₃[J]. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2016, 503: 53-60.
7	Sarbassov Y, Duan L, Jeremias M, et al. SO₃ formation and the effect of fly ash in a bubbling fluidised bed under oxy-fuel combustion conditions[J]. Fuel Processing Technology, 2017, 167: 314-321.
8	束航, 张玉华, 范红梅, 等. SCR脱硝中催化剂表面NH₄HSO₄生成及分解的原位红外研究[J]. 化工学报, 2015, 66(11): 4460-4468.
	Shu H, Zhang Y H, Fan H M, et al. FT-IR study of formation and decomposition of ammonium bisulfates on surface of SCR catalyst for nitrogen removal [J]. CIESC Journal, 2015, 66(11): 4460-4468.
9	Wijayanti K, Leistner K, Chand S. et al. Deactivation of Cu-SSZ-13 by SO₂ exposure under SCR conditions[J]. Catalysis Science & Technology, 2016, 6: 2565-2579.
10	Ye D, Qu R, Song H, et al. Investigation of the promotion effect of WO₃ on the decomposition and reactivity of NH₄HSO₄ with NO on V₂O₅-WO₃/TiO₂ SCR catalysts[J]. RSC Advances, 2016, 6(60): 55584-55592.
11	刘芳琪, 于敦喜, 吴建群, 等. 燃煤锅炉SCR对颗粒物排放特性影响[J]. 化工学报, 2018, 69(9): 4051-4057.
	Liu F Q, Yu D X, Wu J Q, et al. Effect of SCR on particulate matter emissions from a coal-fired boiler[J]. CIESC Journal, 2018, 69(9): 4051-4057.
12	Alvarez E, Blanco J, Knapp C, et al. Pilot plant performance of a SO₂ to SO₃ oxidation catalyst for flue-gas conditioning[J]. Catalysis Today, 2000, 59(3): 417-422.
13	Baltin G, Köser H, Wendlandt K P. Reactive desorption of sulfuric acid from ammonium sulfate loaded V₂O₅-WO₃/TiO₂ DeNO_x‐catalysts[J]. Chemie Ingenieur Technik, 2001, 73(6): 605.
14	Dunn J P, Koppula P R, Stenger H G, et al. Oxidation of sulfur dioxide to sulfur trioxide over supported vanadia catalysts[J]. Applied Catalysis B: Environmental, 1998, 19(2): 103-117.
15	张悠. 烟气中SO₃测试技术及其应用研究[D]. 杭州: 浙江大学, 2013.
	Zhang Y. Research and application of SO₃ measurement in flue gas[D]. Hangzhou: Zhejiang University, 2013.
16	Li Y, Xiong J, Lin Y, et al. Distribution of SO₂ oxidation products in the SCR of NO over a V₂O₅/TiO₂catalyst at different temperatures[J]. Industrial & Engineering Chemistry Research, 2020, 59: 5177-5185.
17	Maddalone R F, Newton S F, Rhudy R G, et al. Laboratory and field evaluation of the controlled condensation system for SO₃ measurements in flue gas streams[J]. Journal of the Air Pollution Control Association, 1979, 29(6): 626-631.
18	Xiong J, Li Y R, Wang J, et al. Evaluation of sulfur trioxide detection with online isopropanol absorption method[J]. Journal of Environmental Sciences, 2018, 72: 25-32.
19	Kamata H, Ohara H, Takahashi K, et al. SO₂ oxidation over the V₂O₅/TiO₂ SCR catalyst[J]. Catalysis Letters, 2001, 73(1): 79-83.
20	Kwon D W, Park K H, Hong S C. Enhancement of SCR activity and SO₂ resistance on VO_x/TiO₂ catalyst by addition of molybdenum[J]. Chemical Engineering Journal, 2016, 284: 315-324.
21	唐昊, 李文艳, 王琦, 等. 商用选择性催化还原催化剂SO₂氧化率控制研究进展[J]. 化工进展, 2017, 36(6): 2143-2149.
	Tang H, Li W Y, Wang Q, et al. Research progress on the control of SO₂ oxidation by commercial SCR catalyst[J]. Chemical Industry and Engineering Progress, 2017, 36(6): 2143-2149.
22	Qing M, Su S, Wang L L, et al. Effects of H₂O and CO₂ on the catalytic oxidation property of V/W/Ti catalysts for SO₃ generation[J]. Fuel, 2019, 237: 545-554.
23	Kobayashi M, Hagi M. V₂O₅-WO₃/TiO₂-SiO₂-SO₄^2- catalysts: influence of active components and supports on activities in the selective catalytic reduction of NO by NH₃ and in the oxidation of SO₂[J]. Applied Catalysis B: Environmental, 2006, 63(1/2): 104-113.
24	Qing M, Su S, Wang L L, et al. Getting insight into the oxidation of SO₂ to SO₃ over V₂O₅-WO₃/TiO₂ catalysts: reaction mechanism and effects of NO and NH₃[J]. Chemical Engineering Journal, 2019, 361: 1215-1224.
25	Ji P, Gao X, Du X, et al. Relationship between the molecular structure of V₂O₅/TiO₂ catalysts and the reactivity of SO₂ oxidation[J]. Catalysis Science & Technology, 2016, 6: 1187-1194.
26	Dunn J P, Stenger H G, Wachs I E. Oxidation of SO₂ over supported metal oxide catalysts[J]. Journal of Catalysis, 1999, 181: 233-243.
27	李萍, 李长明, 段正康, 等. 低温烟气脱硝催化剂适用条件与动力学[J]. 化工学报, 2019, 70(8): 2981-2990.
	Li P, Li C M, Duan Z K, et al. Application conditions and kinetics simulation over SCR catalyst for flue gas denitrification under low temperature[J]. CIESC Journal, 2019, 70(8): 2981-2990.
28	Xiong J, Li Y, Lin Y, et al. Formation of sulfur trioxide during the SCR of NO with NH₃ over a V₂O₅/TiO₂ catalyst[J]. RSC Advances, 2019, 9: 38952-38961.
29	Zheng C, Xiao L, Qu R, et al. Numerical simulation of selective catalytic reduction of NO and SO₂ oxidation in monolith catalyst[J]. Chemical Engineering Journal, 2019, 361: 874-884.
30	Mu J, Li X, Sun W, et al. Enhancement of low-temperature catalytic activity over a highly dispersed Fe-Mn/Ti catalyst for selective catalytic reduction of NO_x with NH₃[J]. Industrial & Engineering Chemistry Research, 2018, 57: 10159-10169.

[1]	Cheng CHENG, Zhongdi DUAN, Haoran SUN, Haitao HU, Hongxiang XUE. Lattice Boltzmann simulation of surface microstructure effect on crystallization fouling [J]. CIESC Journal, 2023, 74(S1): 74-86.
[2]	Linzheng WANG, Yubing LU, Ruizhi ZHANG, Yonghao LUO. Analysis on thermal oxidation characteristics of VOCs based on molecular dynamics simulation [J]. CIESC Journal, 2023, 74(8): 3242-3255.
[3]	Mengmeng ZHANG, Dong YAN, Yongfeng SHEN, Wencui LI. Effect of electrolyte types on the storage behaviors of anions and cations for dual-ion batteries [J]. CIESC Journal, 2023, 74(7): 3116-3126.
[4]	Jin YU, Binbin YU, Xinsheng JIANG. Study on quantification methodology and analysis of chemical effects of combustion control based on fictitious species [J]. CIESC Journal, 2023, 74(3): 1303-1312.
[5]	Chen CHEN, Qian YANG, Yun CHEN, Rui ZHANG, Dong LIU. Chemical kinetic study on coal volatiles combustion for various oxygen concentrations [J]. CIESC Journal, 2022, 73(9): 4133-4146.
[6]	Cong HE, Wenqi ZHONG, Guanwen ZHOU, Xi CHEN. Study on decomposition characteristics of cement raw meal in suspension furnace at high altitude [J]. CIESC Journal, 2022, 73(5): 2120-2129.
[7]	Min WANG, Jinlan CHENG, Xin LI, Jingjing LU, Chongxin YIN, Hongqi DAI. Delignification mechanism study of acid hydrotropes [J]. CIESC Journal, 2022, 73(5): 2206-2221.
[8]	Xiao YANG, Rui DING, Mohan LI, Zhengchang SONG. Effect of oxygen concentration on homogeneous/heterogeneous coupled reaction characteristics of methane in microchannel [J]. CIESC Journal, 2022, 73(12): 5427-5437.
[9]	Shunjin HUANG, Li ZHANG, Jingchong YAN, Zhigang WANG, Zhiping LEI, Zhanku LI, Shibiao REN, Zhicai WANG, Hengfu SHUI. Investigation on cofiring high-alkali coal with coal gangues: SO₂, NO reduction and ash slagging inhibition [J]. CIESC Journal, 2022, 73(12): 5581-5591.
[10]	Xiang GONG, Linsen LI, Zhao JIANG. Employing PdCo/SiO₂ catalyst in high activity dehydrogenation reaction of heterocyclic H₂ storage carrier [J]. CIESC Journal, 2022, 73(10): 4448-4460.
[11]	Lihe ZHANG, Fan ZHANG, Changlun LI, Deping XU, Zhengang XU, Yonggang WANG. Construction and verification of BGL coal gasification kinetic model [J]. CIESC Journal, 2022, 73(10): 4668-4678.
[12]	Xu ZHAO, Changsheng BU, Xinye WANG, Xin ZHANG, Xiaolei CHENG, Naiji WANG, Guilin PIAO. Kinetics investigation on iron-based oxygen carrier aided oxy-fuel combustion of anthracite char [J]. CIESC Journal, 2022, 73(1): 384-392.
[13]	Tingting WANG, Xi ZENG, Zhennan HAN, Fang WANG, Peng WU, Guangwen XU. Reaction characteristics and kinetics of biomass char-steam gasification in micro-fluidized bed reaction analyzer [J]. CIESC Journal, 2022, 73(1): 294-307.
[14]	Xujie CHEN, Xilei LYU, Huanhuan SHI, Liping ZHENG, Xiwen WEI, Penghui TIAN, Yuxi JIANG, Xiuyang LYU. Study on cyclodehydration of hexaric acids to 2,5- furandicarboxylic acid catalyzed with HBr-MgBr₂ [J]. CIESC Journal, 2021, 72(9): 4658-4664.
[15]	Tiantian PING, Xin YIN, Yu DONG, Shufeng SHEN. Research progress on reaction kinetics of CO₂ with amines in nonaqueous solvents [J]. CIESC Journal, 2021, 72(8): 3968-3983.

Study on SO₃ formation characteristics of a typical vanadium titanium SCR catalyst

一种典型钒钛系SCR催化剂SO₃生成特性研究

RichHTML

PDF (PC)

Knowledge

Abstract

Cite this article

share this article

Figures/Tables 15

References 30

Related Articles 15

Recommended Articles

Metrics

Comments