Preparation and ozonation performance of multicomponent supported catalysts

doi:10.19965/j.cnki.iwt.2021-0386

Abstract

Abstract:

In order to solve the problems of low efficiency and easy loss of the ozone catalyst，the FeO _x -CuO _x -MnO _x /activated carbon-montmorillonite ozone catalyst was prepared by the roasting method. The prepared ozone catalyst was characterized by scanning electron microscopy（SEM），X-ray energy spectrum analysis（EDS） and other methods，and the catalyst was applied to the experiment of advanced treatment of landfill leachate by ozone catalytic oxidation. The effects of the compound ratio of powdered activated carbon and montmorillonite in the ozone catalyst carrier，the molar ratio of active components Fe²⁺，Cu²⁺，Mn²⁺，the compound ratio of carrier to active component，the calcination temperature and time，on the performance of the catalyst were respectively investigated. The results showed the prepared ozone catalyst had a clear pore structure，and the active components Fe²⁺，Cu²⁺，and Mn²⁺ had high loading rates and uniform distribution under the condition of mass ratio of powdered activated carbon to montmorillonite in the carrier component 1∶1，the molar ratio of active components Fe²⁺，Cu²⁺，and Mn²⁺ 3∶1∶1，and the mass ratio of carrier to active component 4∶1，the calcination temperature 600 ℃ and the calcination time was 60 minutes. When the landfill leachate was deeply treated，the dosage of ozone catalyst was 5 g/L，the dosing amount of ozone was 100 mg/L，the COD removal rate of landfill leachate reached 67.46%，and it had a high catalytic efficiency. After repeated use of the ozone catalyst，the Performance remained stable.

Key words: FeO _x -CuO _x -MnO _x, activated carbon, montmorillonite, ozone catalytic oxidation

摘要：

为了解决臭氧催化剂效率低、易流失等问题，采用焙烧法制备FeO _x -CuO _x -MnO _x /活性炭-蒙脱土臭氧催化剂。通过扫描电子显微镜（SEM）、X射线能谱分析（EDS）等方法对所制备臭氧催化剂进行表征，并将该催化剂应用于臭氧催化氧化深度处理垃圾渗滤液实验。分别考察了臭氧催化剂载体中粉末活性炭与蒙脱土质量比、活性组分Fe²⁺、Cu²⁺、Mn²⁺物质的量比、载体与活性组分的质量比、焙烧温度与时间等因素对催化剂性能的影响。结果表明，当载体组分中粉末活性炭与蒙脱土质量比为1∶1，活性组分Fe²⁺、Cu²⁺、Mn²⁺物质的量比为3∶1∶1，载体与活性组分质量比为4∶1，焙烧温度为600 ℃，焙烧时间为60 min时，所制备臭氧催化剂孔道结构清晰，活性组分Fe²⁺、Cu²⁺、Mn²⁺负载率高且分布均匀；在深度处理垃圾渗滤液时，臭氧催化剂投加量为5 g/L，臭氧投加量为100 mg/L，垃圾渗滤液COD去除率达到67.46%，有较高的催化效率，且臭氧催化剂经过多次重复使用后，催化性能仍保持稳定。

关键词: FeO _x -CuO _x -MnO _x, 活性炭, 蒙脱土, 臭氧催化氧化

CLC Number:

X703.1

Zhenbang LI, Huan ZHANG, Quanyong WANG, Jinyu PENG. Preparation and ozonation performance of multicomponent supported catalysts[J]. Industrial Water Treatment, 2022, 42(1): 148-153.

李振邦, 张欢, 王全勇, 彭锦玉. 多元负载型催化剂的制备及臭氧催化氧化性能[J]. 工业水处理, 2022, 42(1): 148-153.

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References 16

1	周敏，孙文全，陆曦，等. 臭氧化技术在垃圾渗滤液深度处理中的应用研究［J］. 工业安全与环保，2015，41（2）：10-12. doi:10.3969/j.issn.1001-425X.2015.02.004
	ZHOU Min， SUN Wenquan， LU Xi，et al. Application of ozone oxidation in advanced treatment of landfill leachate［J］. Industrial Safety and Environmental Protection，2015，41（2）：10-12. doi:10.3969/j.issn.1001-425X.2015.02.004
2	钟璟，韩光鲁，陈群，等. 高盐有机废水处理技术研究新进展［J］. 化工进展，2012，31（4）：920-926.
	ZHONG Jing， HAN Guanglu， CHEN Qun，et al. Recent developments in treatment technology for highly saline organic wastewater［J］. Chemical Industry and Engineering Progress，2012，31（4）：920-926.
3	张楚. 高盐有机废水生物处理技术研究进展［J］.河北农业科学，2009，13（9）：78-80. doi:10.3969/j.issn.1088-1631.2009.09.032
	ZHANG Chu. Research progress on biological treatment technology of organic wastewater with high salinity［J］. Journal of Hebei Agricultural Sciences，2009，13（9）：78-80. doi:10.3969/j.issn.1088-1631.2009.09.032
4	汪星志，汪晓军，王蓓蓓，等. 含锰氧化物的陶粒催化臭氧氧化苯甲酸废水［J］. 环境工程学报，2016，10（7）：3653-3656. doi:10.12030/j.cjee.201502006
	WANG Xingzhi， WANG Xiaojun， WANG Beibei，et al. Catalytic ozonation of benzoic acid wastewater by ceramsite containing manganese oxide［J］. Journal of Environmental Engineering，2016，10（7）：3653-3656. doi:10.12030/j.cjee.201502006
5	LIU Yang， LI Xiaosong， SHI Chuan，et al. Ozone catalytic oxidation of adsorbed benzene over AgMnHZSM-5 catalysts at room temperature［J］. Catalysis Science & Technology，2014，4（8）：2589-2598. doi:10.1039/c3cy01102j
6	WANG He， LIN Xiaozi， HUNG Yuanxin，et al. Two advanced oxidation pathways of modified iron⁃shavings participation in ozonation［J］. Separation and Purification Technology，2020，244：116838. doi:10.1016/j.seppur.2020.116838
7	PEREIRA M F R， ORFAO J J M， FARIA P C C. Ozone decomposition in water catalyzed by activated carbon：Influence of chemical and textural properties［J］. Ind. Eng. Chem. Res.，2006，45（8）：2715-2721. doi:10.1021/ie060056n
8	范举红. 活性炭催化臭氧氧化垃圾渗滤液生物处理出水的研究［D］. 北京：清华大学，2016.
	FAN Junhong. Study on biological treatment of landfill leachate by ozonation catalyzed by cyclic activated carbon journal of environmental engineering［D］. Beijing： Tsinghua University，2016.
9	REY A， FARALDOS M， CASAS J A，et al. Catalytic wet peroxide oxidation of phenol over FeAC catalysts：Influence of iron precursor and activated carbon surface［J］. Applied Catalysis B Environmental，2009，86（1/2）：69-77. doi:10.1016/j.apcatb.2008.07.023
10	李民，陈炜鸣，蒋国斌，等. Fe-Ce/GAC催化臭氧降解高浓度腐殖酸废水［J］. 环境科学学报，2017，37（9）：3409-3418. doi:10.13671/j.hjkxxb.2017.0126
	LI Min， CHEN Yiming， JIANG Guobin，et al. Ozonation treatment of high humic acid wastewater catalized by Fe-Ce/GAC［J］. Acta Scientiae Circumstantiae，2017，37（9）：3409-3418. doi:10.13671/j.hjkxxb.2017.0126
11	KASPRZYK⁃HORDERN B， ZIOEK M， NAWROCKI J， et al. Catalytic ozonation and methods of enhancing molecular ozone reactions in water treatment［J］. Applied Catalysis B Environmental，2003，46（4）：639-669. doi:10.1016/s0926-3373(03)00326-6
12	GHORBAN A， FATEME S， MOH A，et al. Catalytic ozonation of pentachlorophenol in aqueous solutions using granular activated carbon［J］. Applied Water Science，2017，7（1）：393-400. doi:10.1007/s13201-014-0254-y
13	张耀辉. Fe₂O₃-TiO₂-MnO₂/Al₂O₃催化臭氧化催化剂的制备及表征［J］. 中国环境科学，2016，36（10）：3003-3009. doi:10.3969/j.issn.1000-6923.2016.10.023
	ZHANG Yaohui. Preparation and characterization of Fe₂O₃-TiO₂-MnO₂/Al₂O₃ catalysts［J］. China Environmental Science，2016，36（10）：3003-3009. doi:10.3969/j.issn.1000-6923.2016.10.023
14	王振东，刘东方，李文姣，等. 金属氧化物膨润土催化剂臭氧催化处理高盐废水［J］. 水处理技术，2019，45（1）：85-88. doi:10.16796/j.cnki.1000-3770.2019.01.018
	WANG Zhendong， LIU Dong， LI Wenjiao，et al.Fang high salinity wastewater treatment by catalytic ozonation with catalyst metal oxide/bentonite［J］. Technology of Water Treatment，2019，45（1）：85-88. doi:10.16796/j.cnki.1000-3770.2019.01.018
15	杨文玲，郜子兴，吴赳，等. CuO-Fe₂O₃/γ-Al₂O₃/H₂O₂/O₃催化氧化深度处理制药二级生化出水［J］. 化工进展，2018，37（6）：2399-2405. doi:10.16085/j.issn.1000-6613.2017-1466
	YANG Wenling， GAO Zixing， WU Jiu，et al. Advanced treatment of secondary biochemical effluent by CuO-Fe₂O₃/γ-Al₂O₃/H₂O₂/O₃ ［J］.Progress in Chemical Industry，2018，37（6）：2399-2405. doi:10.16085/j.issn.1000-6613.2017-1466
16	JIANG Liying， ZHANG Lu， CHEN Jianmeng，et al. Degradation of 17β-estradiol in aqueous solution by ozonation in the presence of manganese（Ⅱ） and oxalic acid［J］. Environmental Technology，2013，34（1/2/3/4）：131-138. doi:10.1080/09593330.2012.689358

催化剂	元素	理论质量分数/%	质量分数/%	理论原子分数/%	原子分数/%
活性炭	Mn	—	—	—	—
	Fe	—	3.35	—	1.04
	Cu	—	—	—	—
活性炭+蒙脱土	Mn	—	0.94	—	0.38
	Fe	—	4.17	—	1.33
	Cu	—	0.37	—	0.13
FeO _x -CuO _x -MnO _x /活性炭-蒙脱土	Mn	4.94	4.85	2.19	2.15
	Fe	16.17	16.15	6.80	6.79
	Cu	4.37	4.06	1.65	1.53

催化剂	元素	理论质量分数/%	质量分数/%	理论原子分数/%	原子分数/%
活性炭	Mn	—	—	—	—
	Fe	—	3.35	—	1.04
	Cu	—	—	—	—
活性炭+蒙脱土	Mn	—	0.94	—	0.38
	Fe	—	4.17	—	1.33
	Cu	—	0.37	—	0.13
FeO _x -CuO _x -MnO _x /活性炭-蒙脱土	Mn	4.94	4.85	2.19	2.15
	Fe	16.17	16.15	6.80	6.79
	Cu	4.37	4.06	1.65	1.53

焙烧时间/min	进水COD/（mg·L^-1）	出水COD/（mg·L^-1）	COD 去除率/%	备注
20	—	—	—	催化剂粉末化
40	630	265	57.94	强度一般
60	630	205	67.46	坚硬
80	630	220	65.08	坚硬
100	—	—	—	催化剂粉末化

焙烧时间/min	进水COD/（mg·L^-1）	出水COD/（mg·L^-1）	COD 去除率/%	备注
20	—	—	—	催化剂粉末化
40	630	265	57.94	强度一般
60	630	205	67.46	坚硬
80	630	220	65.08	坚硬
100	—	—	—	催化剂粉末化

使用次数/次	COD去除率/%
1	67.46
5	65.64
10	65.53
15	65.50

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