Study of low temperature H2S removal on Ce-Cu-Al-O mixed metal oxide adsorbents

doi:10.16085/j.issn.1000-6613.2016.11.047

Abstract

Abstract: A series of Ce-Cu-Al-O mixed metal oxide adsorbents for deep removal of H₂S at low temperature was prepared by a co-precipitation method. Characterization methods such as XRD, N₂physical adsorption, SEM, XPS were used to analyze the samples before and after desulfurization. The influence of Ce content, calcination temperature, space velocity, adsorption temperature and impurity gas on the removal of H₂S was investigated. It was found that Ce-Cu-Al-O adsorbents were able to remove H₂S from CO₂ at 40℃and the adsorbent with 10% Ce (10Ce-Cu-Al-O) exhibited the highest breakthrough capacity of 94.1mg/g. The characterization results show that the addition of CeO₂ could effectively improve the dispersion of CuO, the BET surface areas and pore volumes of the adsorbents. A relatively high calcination temperature, high space velocity and balance gas CO₂will all inhibit the H₂S adsorption. The H₂S breakthrough capacity of 10Ce-Cu-Al-O increased with temperature and there was no COS impurities generated when the desulfurization temperature was not higher than 100℃. The characterization results of the used adsorbents showed that the aggregate components resulted in the decrease of the BET surface areas and pore volumes. In addition, the regeneration experiment indicated that a relatively low temperature of 100℃ can be applied to regenerate the used 10Ce-Cu-Al-O adsorbents in air.

Key words: mixed metal oxides, low temperature, hydrogen sulfide, adsorption, regeneration

摘要： 用共沉淀法制备了一系列Ce-Cu-Al-O复合金属氧化物吸附剂，用于低温下脱除CO₂气体中的微量H₂S。采用XRD、N₂物理吸附、SEM及XPS等手段对脱硫前后的吸附剂结构进行表征。研究了Ce含量、煅烧温度、气体空速、杂质气体及吸附温度对吸附剂脱除H₂S性能的影响。结果表明，Ce-Cu-Al-O系列吸附剂在40℃条件下可有效脱除CO₂气体中的H₂S，Ce含量为10%的吸附剂（10Ce-Cu-Al-O）具有最大H₂S穿透吸附量，为94.1mg/g。研究发现，引入CeO₂能有效改善CuO的分散性，提高吸附剂的比表面积和孔容。提高煅烧温度，较大空速均不利于吸附剂的脱硫效果；平衡气CO₂会抑制H₂S的吸附；吸附温度不高于100℃时，10Ce-Cu-Al-O的穿透吸附量随温度升高而增加且不会生成COS副产物。表征结果显示，硫化后吸附剂的组分团聚导致了比表面积和孔容降低。此外，失活后的脱硫剂可在100℃用空气再生。

关键词: 复合金属氧化物, 低温, 硫化氢, 吸附, 再生

CLC Number:

X701.3

LIU Dai, CHEN Shaoyun, HUANG Chunjie, FEI Xiaoyao, ZHANG Yongchun. Study of low temperature H₂S removal on Ce-Cu-Al-O mixed metal oxide adsorbents[J]. Chemical Industry and Engineering Progress, 2016, 35(11): 3701-3706.

刘岱, 陈绍云, 黄纯洁, 费潇瑶, 张永春. Ce-Cu-Al-O复合金属氧化物吸附剂低温脱除H₂S[J]. 化工进展, 2016, 35(11): 3701-3706.

References

[1] 陈绍云,张永春,王新平. 过渡金属盐改性HZSM-5 氧化吸附深度脱除CO2 中的NO[J]. 化工学报,2012,63(11):3700-3706.
[2] 任文玲,陈绍云,张永春,等. Zn/SBA-15 介孔吸附剂的制备及脱附低浓度H2S 性能[J]. 化工进展,2011,30(10):2304-2309.
[3] 肖永厚,王树东,袁权. 浸渍活性炭脱除硫化氢研究进展[J]. 化工进展,2006,25(9):1025-1030.
[4] 李芬,张杰,姜安玺,等. 低温脱硫剂的研究进展[J]. 化工进展, 2007,26(4):519-525.
[5] WANG L F,YANG R T. New nanostructured sorbents for desulfurization of natural gas[J]. Front. Chem. Sci. Eng.,2014,8(1):8-19.
[6] SKRZYPSKI J,BEZVERKHYY I, HEINTZ O, et al. Low temperature H2S removal with metal-doped nanostructure ZnO sorbents:study of the origin of enhanced reactivity in Cu containing materials[J]. Ind. Eng. Chem. Res.,2011,50:5714-5722.
[7] POLYCHRONOPOULOU K,FIERRO J L G,EFSTATHIOU A M. Novel Zn-Ti-based mixed metal oxides for low-temperature adsorption of H2S from industrial gas streams[J]. Applied Catalysis B Environmental,2005,57(2):125-137.
[8] WANG X X, MA X L, XU X, et al. Mesoporous-molecular-sieve-supported polymer sorbents for removing H2S from hydrogen gas streams[J]. Topics in Catalysis, 2008,49(1):108-117.
[9] DAVYDOV A,CHUANG K T,SANGER A R. Mechanism of H2S oxidation by ferric oxide and hydroxide surfaces[J]. Journal of Physical Chemistry B,1998,102(24):4745-4752.
[10] KIM K,JEON S K,VO C,et al. Removal of hydrogen sulfide from a steam-hydrogasifier product gas by zinc oxide sorbent[J]. Ind. Eng. Chem. Res.,2007,46(18):5848-5854.
[11] GARCES H F,GALINDO H M,GARCES L J,et al. Low temperature H2S dry-desulfurization with zinc oxide[J]. Microporous & Mesoporous Materials,2010,127(3):190-197.
[12] LIU D,CHEN S,FEI X,et al. Regenerable CuO-based adsorbents for low temperature desulfurization application[J]. Ind. Eng. Chem. Res., 2015,54(14):3556-3562.
[13] POLYCHRONOPOULOU K,GALISTEO F C,GRANADOS M L, et al. Novel Fe-Mn-Zn-Ti-O mixed-metal oxides for the low-temperature removal of H2S from gas streams in the presence of H2,CO2,and H2O[J]. Journal of Catalysis,2005,236(2):205-220.
[14] JIANG D H,SU L H,MA L,et al. Cu-Zn-Al mixed metal oxides derived from hydroxycarbonate precursors for H2S removal at low temperature[J]. Applied Surface Science,2010,256(10):3216-3223.
[15] PATRICK V,GAVALAS G R,FLYTZANI-STEPHANOPHOULOS M,et al. High-temperature sulfidation-regeneration of CuO-Al2O3 sorbents[J]. Ind. Eng. Chem. Res.,1989,28(7):940-947.
[16] 李芬,姜安玺,邵纯红,等. 铈对纳米氧化锌室温脱硫剂结构及性能的影响[J]. 稀有金属材料与工程,2006,35(s2):347-350.
[17] LI Z,FLYTZANI-STEPHANOPOULOS M. Cu-Cr-O and Cu-Ce-O regenerable oxide sorbents for hot gas desulfurization[J]. Ind. Eng. Chem. Res. 1997,36(1):187-196.
[18] GERVASINI A,MANZOLI M,MARTRA G,et al. Dependence of copper species on the nature of the support for dispersed CuO catalysts[J]. Journal of Physical Chemistry B,2006,110(15): 7851-61.
[19] ZHANG F M,LIU B S,ZHANG Y,et al. Highly stable and regenerable Mn-based/SBA-15 sorbents for desulfurization of hot coal gas[J]. Journal of Hazardous Materials,2012,233/234:219-227.
[20] YANG H,SOTHEN R,CAHELA D R,et al. Breakthrough characteristics of reformate desulfurization using ZnO sorbents for logistic fuel cell power systems[J]. Ind. Eng. Chem. Res.,2008,47 (24):10064-10070.

Study of low temperature H₂S removal on Ce-Cu-Al-O mixed metal oxide adsorbents

Ce-Cu-Al-O复合金属氧化物吸附剂低温脱除H₂S

PDF (PC)

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 15

Recommended Articles

Metrics

Comments

[1]	CUI Shoucheng, XU Hongbo, PENG Nan. Simulation analysis of two MOFs materials for O₂/He adsorption separation [J]. Chemical Industry and Engineering Progress, 2023, 42(S1): 382-390.
[2]	CHEN Chongming, CHEN Qiu, GONG Yunqian, CHE Kai, YU Jinxing, SUN Nannan. Research progresses on zeolite-based CO₂ adsorbents [J]. Chemical Industry and Engineering Progress, 2023, 42(S1): 411-419.
[3]	XU Chunshu, YAO Qingda, LIANG Yongxian, ZHOU Hualong. Research progress on functionalization strategies of covalent organic frame materials and its adsorption properties for Hg(Ⅱ) and Cr(Ⅵ) [J]. Chemical Industry and Engineering Progress, 2023, 42(S1): 461-478.
[4]	GU Yongzheng, ZHANG Yongsheng. Dynamic behavior and kinetic model of Hg⁰ adsorption by HBr-modified fly ash [J]. Chemical Industry and Engineering Progress, 2023, 42(S1): 498-509.
[5]	GUO Qiang, ZHAO Wenkai, XIAO Yonghou. Numerical simulation of enhancing fluid perturbation to improve separation of dimethyl sulfide/nitrogen via pressure swing adsorption [J]. Chemical Industry and Engineering Progress, 2023, 42(S1): 64-72.
[6]	WANG Shengyan, DENG Shuai, ZHAO Ruikai. Research progress on carbon dioxide capture technology based on electric swing adsorption [J]. Chemical Industry and Engineering Progress, 2023, 42(S1): 233-245.
[7]	LUO Cheng, FAN Xiaoyong, ZHU Yonghong, TIAN Feng, CUI Louwei, DU Chongpeng, WANG Feili, LI Dong, ZHENG Hua’an. CFD simulation of liquid distribution in different distributors in medium-low temperature coal tar hydrogenation reactor [J]. Chemical Industry and Engineering Progress, 2023, 42(9): 4538-4549.
[8]	GE Yafen, SUN Yu, XIAO Peng, LIU Qi, LIU Bo, SUN Chengying, GONG Yanjun. Research progress of zeolite for VOCs removal [J]. Chemical Industry and Engineering Progress, 2023, 42(9): 4716-4730.
[9]	YANG Ying, HOU Haojie, HUANG Rui, CUI Yu, WANG Bing, LIU Jian, BAO Weiren, CHANG Liping, WANG Jiancheng, HAN Lina. Coal tar phenol-based carbon nanosphere prepared by Stöber method for adsorption of CO₂ [J]. Chemical Industry and Engineering Progress, 2023, 42(9): 5011-5018.
[10]	ZHANG Zhen, LI Dan, CHEN Chen, WU Jinglan, YING Hanjie, QIAO Hao. Separation and purification of salivary acids with adsorption resin [J]. Chemical Industry and Engineering Progress, 2023, 42(8): 4153-4158.
[11]	JIANG Jing, CHEN Xiaoyu, ZHANG Ruiyan, SHENG Guangyao. Research progress of manganese-loaded biochar preparation and its application in environmental remediation [J]. Chemical Industry and Engineering Progress, 2023, 42(8): 4385-4397.
[12]	YU Jingwen, SONG Luna, LIU Yanchao, LYU Ruidong, WU Mengmeng, FENG Yu, LI Zhong, MI Jie. An indole-bearing hypercrosslinked polymer In-HCP for iodine adsorption from water [J]. Chemical Industry and Engineering Progress, 2023, 42(7): 3674-3683.
[13]	LI Yanling, ZHUO Zhen, CHI Liang, CHEN Xi, SUN Tanglei, LIU Peng, LEI Tingzhou. Research progress on preparation and application of nitrogen-doped biochar [J]. Chemical Industry and Engineering Progress, 2023, 42(7): 3720-3735.
[14]	YU Shan, DUAN Yuangang, ZHANG Yixin, TANG Chun, FU Mengyao, HUANG Jinyuan, ZHOU Ying. Research progress of catalysts for two-step hydrogen sulfide decomposition to produce hydrogen and sulfur [J]. Chemical Industry and Engineering Progress, 2023, 42(7): 3780-3790.
[15]	BAI Yadi, DENG Shuai, ZHAO Ruikai, ZHAO Li, YANG Yingxia. Exploration on standardized test scheme and experimental performance of temperature swing adsorption carbon capture unit [J]. Chemical Industry and Engineering Progress, 2023, 42(7): 3834-3846.