Parameter optimization of jet aeration in catalytic ozonation system and analysis of stage oxidation of phenol

doi:10.16085/j.issn.1000-6613.2022-1266

Chemical Industry and Engineering Progress ›› 2023, Vol. 42 ›› Issue (5): 2717-2723.DOI: 10.16085/j.issn.1000-6613.2022-1266

• Resources and environmental engineering • Previous Articles Next Articles

Parameter optimization of jet aeration in catalytic ozonation system and analysis of stage oxidation of phenol

ZHU Hao¹^,²(), LIU Hanfei¹, GAO Yuan¹, BAI Rongrong¹, NI Songbo¹, HUANG Yiping¹, LI Qingtong³, LI Xiaodong³, HAN Weiqing²

^1.China Construction Industrial & Energy Engineering Group Co. , Ltd. , Nanjing 210046, Jiangsu, China
^2.School of Environmental and Biological Engineering, Nanjing University of Science and Technology, Nanjing 210094, Jiangsu, China
^3.China Construction Xinjiang Installation Engineering Co. , Ltd. , Urumqi 830092, Xinjiang, China

Received:2022-07-05 Revised:2022-08-30 Online:2023-06-02 Published:2023-05-10
Contact: ZHU Hao

催化臭氧化体系射流曝气系统参数优化及苯酚阶段氧化分析

朱昊¹^,²(), 刘汉飞¹, 高源¹, 白蓉蓉¹, 倪嵩波¹, 黄益平¹, 李庆同³, 李小东³, 韩卫清²

^1.中建安装集团有限公司，江苏南京 210046
^2.南京理工大学环境与生物工程学院，江苏南京 210094
^3.中建新疆安装工程有限公司，新疆乌鲁木齐 830092

通讯作者: 朱昊
作者简介:朱昊（1992—），男，博士，研究方向为化工废水处理及资源化利用。E-mail：zhu-hao@cscec.com。
基金资助:
中建安装2020年度科技研发计划(AZ-2020-05);中国建筑股份有限公司2022年度科技研发课题(CSCEC-2022-Q-60);中建安装2022年度科技研发计划(CSCEC-PT-007-04)

Abstract

Abstract:

As a typical phenolic compound, phenol showed the characteristics of high content and wide range of toxicity in phenol-containing wastewater. Mastering effective method of phenol treatment will provide technical support for the efficient treatment of phenol-containing wastewater. By analyzing the catalytic performance of five ozone catalysts, type A catalyst was selected as the preferred catalyst in ozone jet aeration system. The key operating parameters of the system were optimized. The results showed that the jet aeration system based on type A catalyst presented the good pollutants removal performance with an average COD removal efficiency of 56.7% when the circulating water velocity, wastewater pH and initial concentration of pollutant were 1400L/h, 8 and 148mg/L, respectively. The stage oxidation of phenol at different time nodes was investigated using three-dimensional fluorescence spectra, GC-MS and aerobic respiratory inhibition rate as evaluation indexes. By comprehensive analysis of the evaluation indexes, it was found that E_x/E_m was (300~350nm)/(420~460nm) region in the three-dimensional fluorescence spectrum might be an indicator of high removal efficiency and low aerobic respiratory inhibition at the reaction time of 60min.

Key words: ozone, catalyst, wastewater, optimization, stage oxidation

摘要：

作为酚类化合物的典型，苯酚在含酚废水中含量高、毒性范围大，掌握水中苯酚的有效处理方法将为含酚废水的高效处理提供技术支撑。本文通过分析5种臭氧催化剂的催化性能，选择A型催化剂作为臭氧射流曝气系统的优选催化剂。优化了系统关键运行参数，结果表明，当循环水流速、废水pH和污染物初始浓度分别为1400L/h、8和148mg/L时，基于A型催化剂的射流曝气系统对污染物具有良好的去除效果，此时废水COD平均去除率为56.7%。以不同时间节点废水的三维荧光光谱、GC-MS和好氧呼吸抑制率作为评价指标，考察了苯酚的阶段氧化进程。综合分析各评价指标，发现当反应时间为60min时，废水三维荧光光谱对应的荧光区域E_x/E_m为(300~350nm)/(420~460nm)可能是苯酚在臭氧高级氧化过程高效率降解、低好氧呼吸抑制的指示因子。

关键词: 臭氧, 催化剂, 废水, 优化, 阶段氧化

CLC Number:

TU992.3

ZHU Hao, LIU Hanfei, GAO Yuan, BAI Rongrong, NI Songbo, HUANG Yiping, LI Qingtong, LI Xiaodong, HAN Weiqing. Parameter optimization of jet aeration in catalytic ozonation system and analysis of stage oxidation of phenol[J]. Chemical Industry and Engineering Progress, 2023, 42(5): 2717-2723.

朱昊, 刘汉飞, 高源, 白蓉蓉, 倪嵩波, 黄益平, 李庆同, 李小东, 韩卫清. 催化臭氧化体系射流曝气系统参数优化及苯酚阶段氧化分析[J]. 化工进展, 2023, 42(5): 2717-2723.

Figures/Tables 6

References 17

1	邹艳霞. 含酚废水治理技术现状及展望[J]. 化工管理, 2021(26): 33-34.
	ZOU Yanxia. Status and prospect of phenol-containing wastewater treatment technology[J]. Chemical Enterprise Management, 2021(26): 33-34.
2	强喆林, 王玲, 吴迪, 等. 含酚废水处理技术研究进展[J]. 当代化工, 2021, 50(9): 2206-2210.
	QIANG Zhelin, WANG Ling, WU Di, et al. Research progress of phenolic wastewater treatment technology[J]. Contemporary Chemical Industry, 2021, 50(9): 2206-2210.
3	蒋博龙, 史顺杰, 蒋海林, 等. 金属有机框架材料吸附处理苯酚污水机理研究进展[J]. 化工进展, 2021, 40(8): 4525-4539.
	JIANG Bolong, SHI Shunjie, JIANG Hailin, et al. Research progress in phenol adsorption mechanism over metal-organic framework from wastewater[J]. Chemical Industry and Engineering Progress, 2021, 40(8): 4525-4539.
4	熊威. 活性炭及其负载铁锰催化臭氧氧化苯酚的研究[D]. 北京: 中国地质大学(北京), 2019.
	XIONG Wei. Research on ozonation catalyzed by activated carbon and iron/manganese supported on activated carbon for treatment of phenol[D]. Beijing: China University of Geosciences, 2019.
5	GE Mingliang, WANG Xubin, DU Mingyi, et al. Adsorption analyses of phenol from aqueous solutions using magadiite modified with organo-functional groups: Kinetic and equilibrium studies[J]. Materials, 2018, 12(1): 96.
6	ADEEL Mister, XU Yubo, REN Longfei, et al. Improvement of phenol separation and biodegradation from saline wastewater in extractive membrane bioreactor (EMBR)[J]. Bioresource Technology Reports, 2022, 17: 100897.
7	BAO Q, HUI K S, DUH J G. Promoting catalytic ozonation of phenol over graphene through nitrogenation and Co₃O₄ compositing[J]. Journal of Environmental Sciences, 2016, 50: 38-48.
8	庄海峰. 催化臭氧化-生物组合工艺深度处理煤制气废水效能的研究[D]. 哈尔滨: 哈尔滨工业大学, 2015.
	ZHUANG Haifeng. Research on efficiency of advanced treatment of coal gasification wastewater by catalytic ozonation integrated with biological process[D]. Harbin: Harbin Institute of Technology, 2015.
9	洪浩峰, 潘湛昌, 许磊, 等. 臭氧催化氧化处理苯酚废水研究[J]. 环境科学与技术, 2010, 33(S1): 301-304.
	HONG Haofeng, PAN Zhanchang, XU Lei, et al. Degradation of aqueous phenol by catalytic ozonation[J]. Environmental Science & Technology, 2010, 33(S1): 301-304.
10	石岩, 邓淑仪, 许丹宇, 等. 臭氧催化氧化法处理含酚废水的研究进展[J]. 环境工程, 2015, 33(3): 17-20.
	SHI Yan, DENG Shuyi, XU Danyu, et al. Research progress of phenolic wastewater treatment by catalytic ozonation[J]. Environmental Engineering, 2015, 33(3): 17-20.
11	王吉坤, 李阳, 陈贵锋, 等. 臭氧催化氧化降解煤化工生化进水有机物的实验及机理[J]. 化工进展, 2021, 40(10): 5837-5844.
	WANG Jikun, LI Yang, CHEN Guifeng, et al. Experimental and mechanism studies on degradation of the organics in biochemical influent of coal chemical industry by ozone catalytic oxidation[J]. Chemical Industry and Engineering Progress, 2021, 40(10): 5837-5844.
12	JOTHINATHAN Lakshmi, HU Jiangyong. Kinetic evaluation of graphene oxide based heterogenous catalytic ozonation for the removal of ibuprofen[J]. Water Research, 2018, 134: 63-73.
13	董山山. 可见光催化与生物氧化直接耦合工艺强化处理苯酚废水研究[D]. 长春: 吉林大学, 2016.
	DONG Shanshan. Intimately coupled system of visible-light-responsive photocatalysis and biodegradation for enhancing phenol wastewater treatment[D]. Changchun: Jilin University, 2016.
14	王宏伟, 王天来, 齐岩, 等. 臭氧催化氧化工艺中pH值对催化剂活性的影响研究[J]. 化工科技, 2017, 25(5)：53-56.
	WANG Hongwei, WANG Tianlai, QI Yan, et al. Effect of pH value on catalytic activity in catalytic ozonation process[J]. Science & Technology In Chemical Industry, 2017, 25(5)：53-56.
15	LI Pu, MIAO Rui, WANG Pei, et al. Bi-metal oxide-modified flat-sheet ceramic membranes for catalytic ozonation of organic pollutants in wastewater treatment[J]. Chemical Engineering Journal, 2021, 426: 131263.
16	汪淑婷, 魏建建, 马雪柔, 等. 臭氧高级氧化含酚类废水出水的急性生物毒性和荧光光谱特征分析[J]. 环境工程, 2021, 39(11): 69-76.
	WANG Shuting, WEI Jianjian, MA Xuerou, et al. Changes of acute toxicity and fluorescence spectrum properties of phenol wastewater treated by ozone advanced oxidation[J]. Environmental Engineering, 2021, 39(11): 69-76.
17	CHEN W, WESTERHOFF P, LEENHEER J A, et al. Fluorescence excitation-emission matrix regional integration to quantify spectra for dissolved organic matter[J]. Environmental Science & Technology, 2003, 37(24): 5701-5710.

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Parameter optimization of jet aeration in catalytic ozonation system and analysis of stage oxidation of phenol

催化臭氧化体系射流曝气系统参数优化及苯酚阶段氧化分析

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