Mechanism study on SO2 poisoning of Fe x MnCe1-AC catalyst for low-temperature SCR

doi:10.11949/0438-1157.20190318

Abstract

Abstract:

A series of Fe _x MnCe₁-AC catalysts were prepared by ultrasonic-assisted impregnation method with activated carbon as carrier. The low-temperature NH₃-SCR denitrification activity of the catalysts was investigated, and the best activity catalyst was established. The effect of SO₂ on its denitration performance was also explored. The results showed that Fe_0.1MnCe₁-AC catalyst exhibited best denitration efficiency at low-temperature among prepared catalysts, the conversion rate of NO exceeded 90% with the temperature range from 120℃ to 220℃ (no SO₂). In addition, the catalyst could maintain NO conversion rate of approximately 77% under the atmosphere of 180℃ and SO₂ concentration of 429 mg/m³. The mechanism of SO₂ poisoning on the catalyst was characterized with BET, XRD, XPS, H₂-TPR NH₃-TPD, FT-IR and TGA. It was observed that SO₂ could form ammonium sulfate ( (NH₄)₂SO₄, (NH₄)₂SO₃), and MnSO₄ with NH₃ and the metal components in the catalyst, which changed the pore structure of the fresh catalyst and reduced the Br?nsted acid sites and Lewis acid sites on the catalyst surface. These variation made the inhibitory effect on the catalytic adsorption capacity of NH₃. Moreover, SO₂ also promoted a decrease in the number of Mn⁴⁺, Ce³⁺, Fe³⁺ and Fe³⁺—OH^- groups in the catalyst, and lessened the surface reducible species, thereby reducing the activity of the catalyst denitration.

Key words: selective catalytic reduction, activated carbon, catalyst, nitric oxide, sulfur dioxide, poisoning mechanism

摘要：

以活性炭为载体，通过超声辅助浸渍法制备了一系列Fe _x MnCe₁-AC催化剂，考察了该系列催化剂的低温NH₃-SCR脱硝活性，确立了活性最佳的催化剂，并探究了SO₂对其脱硝性能的影响。结果表明，Fe_0.1MnCe₁-AC催化剂低温脱硝活性最高，在120~220℃范围内NO的转化率均在90%以上（无SO₂）。此外，在180℃、SO₂浓度为429 mg/m³时，该催化剂仍能保持77%左右的脱硝率。通过BET、XRD、XPS、H₂-TPR、NH₃-TPD、FT-IR、TGA等表征手段对催化剂的SO₂中毒机理进行了分析。研究发现，SO₂能与NH₃及催化剂中金属组分生成硫酸铵盐((NH₄)₂SO₄、(NH₄)₂SO₃)、MnSO₄等物质，改变了原催化剂孔道结构并减少了催化剂表面Br?nsted和Lewis酸性位点，抑制了催化剂吸附NH₃的能力。更多地，SO₂促使催化剂中Mn⁴⁺、Ce³⁺、Fe³⁺和Fe³⁺—OH^-基团数量下降，表面可还原物质减少，从而降低了催化剂的脱硝活性。

关键词: 选择性催化还原, 活性炭, 催化剂, 氮氧化物, 二氧化硫, 中毒机理

CLC Number:

TQ 028.8

Xiaoxue CHEN, Min SONG, Fanyue MENG, Yuexing WEI. Mechanism study on SO₂ poisoning of Fe _x MnCe₁-AC catalyst for low-temperature SCR[J]. CIESC Journal, 2019, 70(8): 3000-3010.

陈潇雪, 宋敏, 孟凡跃, 卫月星. Fe _x MnCe₁-AC低温SCR催化剂SO₂中毒机理研究[J]. 化工学报, 2019, 70(8): 3000-3010.

Figures/Tables 12

Fig.1 Flow process diagram of equipment for evaluation of catalyst activity

Fig.2 Catalytic activity of different catalysts with variation of temperature

Fig.3 NO conversion of selected catalyst with presence of SO2

Fig.4 N2 adsorption-desorption isotherms and pore size distribution curves of catalysts

Table 1 BET specific surface area and pore characterization of fresh and poisoned catalyst

催化剂	比表面积/(m²/g)	孔容/(cm³/g)	微孔孔容/(cm³/g)	平均孔径/nm
Fe_0.1MnCe₁-AC	766.4	0.7641	0.1478	3.988
180℃-429 mg/m³SO₂	632.5	0.6636	0.1116	4.197
120℃-429 mg/m³SO₂	491.1	0.4985	0.0934	4.060
活性炭	953.5	1.137	0.2017	4.179

Fig.5 XRD patterns of fresh and poisoned catalyst

Fig.6 XPS of fresh and poisoned catalyst for Mn 2p, Fe 2p and Ce 3d

Table 2 Percentage of different valence states of relative catalytic atom

催化剂

Mn²⁺

Mn³⁺

Mn⁴⁺

Ce³⁺

Ce⁴⁺

Fe_0.1MnCe₁-AC

12.9%

(641.2 eV)

41%

(642.5 eV)

46.1%

(644.1 eV)

53.6%

46.4%

180℃-429 mg/m³ SO₂

7.4%

(641.2 eV)

48.5%

(642 eV)

44.1%

(644.2 eV)

38.4%

61.6%

120℃-429 mg/m³ SO₂

23.5%

(641.2 eV)

48.1%

(642.4 eV)

28.3%

(644.1 eV)

27.7%

72.3%

Fig.7 H2-TPR profiles of fresh and poisoned catalyst

Fig.8 NH3-TPD profiles of fresh and poisoned catalyst

Fig.9 FT-IR spectra of fresh and poisoned catalyst

Fig.10 TG/DTG curves of fresh and poisoned catalyst

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Mechanism study on SO₂ poisoning of Fe _x MnCe₁-AC catalyst for low-temperature SCR

Fe _x MnCe₁-AC低温SCR催化剂SO₂中毒机理研究

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