ZHAOMeng,WANGPan-xin,NINGChao,et al.Internal Circulating Fluidized Bed-Ozone Catalytic Oxidation Process for Treatment of Petrochemical Secondary Effluent[J].China Water & Wastewater,2023,39(1):26-33.
内循环流化床-臭氧催化氧化处理石化废水二级出水
- Title:
- Internal Circulating Fluidized Bed-Ozone Catalytic Oxidation Process for Treatment of Petrochemical Secondary Effluent
- Keywords:
- internal circulating fluidized bed; ozone catalytic oxidation; petrochemical wastewater; adsorption; three-dimensional fluorescence spectrum
- 摘要:
- 采用内循环流化床-臭氧催化氧化工艺深度处理石化废水二级出水,通过单因素实验确定了该工艺的最佳运行条件,并在该条件下对臭氧催化氧化流化床与固定床工艺进行了效果对比。结果表明,流化床工艺能够更高效地降解石化废水中的有机物,在催化剂投加量为40 g/L、臭氧投加量为75 mg/(L·h)、反应时间为1 h的条件下,流化床工艺的TOC去除率为46.47%,臭氧利用率为68%,固定床工艺的TOC去除率为21.73%,臭氧利用率为39.8%;达到相同TOC去除效果时,流化床工艺所需催化剂投加量仅为固定床工艺的1/10。流化床催化剂1 h内可以吸附石化废水中30.23%的TOC,相同投量的固定床催化剂对TOC的吸附效果不明显。重复实验结果表明,臭氧催化氧化是流化床工艺去除污染物的主要途径。三维荧光光谱和UV254分析显示,相同条件下流化床工艺将臭氧转化为活性自由基的能力强于固定床工艺。内循环流化床-臭氧催化氧化工艺可大量减少催化剂使用量,提高臭氧利用率,降低废水处理成本,且效果稳定。
- Abstract:
- An internal circulating fluidized bed-ozone catalytic oxidation process was used to treat the secondary effluent of petrochemical wastewater. The optimal operating conditions of the process were determined by single-factor experiments, and the effects of the ozone catalytic oxidation fluidized bed process were compared with the fixed bed process under the optimal operation conditions. The results showed that the fluidized bed process could more effectively degrade organic matter in petrochemical wastewater. Under the conditions of 40 g/L of catalyst dosage, 75 mg/(L·h) of ozone dosage and 1 h of reaction time, the TOC removal rate of the fluidized bed process was 46.47% and ozone utilization rate was 68%, while the corresponding values for the fixed bed process were only 21.73% and 39.8%, respectively. The catalyst dosage required to achieve the same TOC removal effect in fluidized bed process was only 1/10 of that in fixed bed process. The fluidized bed catalyst could adsorb 30.23% of TOC in the petrochemical wastewater within 1 h, and the fixed bed catalyst with the same dosage had no obvious adsorption effect on the TOC in the wastewater. Repeated experimental results indicated that ozone catalytic oxidation was the main way to remove pollutants by fluidized bed process. The results of three-dimensional fluorescence spectrum and UV254 analysis indicated that under the same conditions, the fluidized bed process had a stronger ability to catalyze ozone into active radicals than that of fixed bed process. The internal circulating fluidized bed-ozone catalytic oxidation process can substantially reduce the amount of catalyst, improve the ozone utilization efficiency, reduce the cost of wastewater treatment, and the treatment effect is stable.
相似文献/References:
[1]李一龙,包宇,邸文正,等.高排放标准下分段进水多级AO+MBR工艺的设计[J].中国给水排水,2022,38(4):76.
LIYi-long,BAOYu,DIWen-zheng,et al.Design of Step-feed Multi-stage AO+MBR Process under High Discharge Standard[J].China Water & Wastewater,2022,38(1):76.
[2]王建兴,吕恺祺,郭中伟,等.银定庄污水厂深度处理工艺选择及运行实效[J].中国给水排水,2022,38(10):125.
WANGJian-xing,LüKai-qi,GUOZhong-wei,et al.Advanced Treatment Process Selection and Operation Effect of Baoding Yindingzhuang WWTP[J].China Water & Wastewater,2022,38(1):125.
[3]周国标,吕银忠,郑望,等.工业园区污水厂出水提至地表水Ⅴ类标准改造工程[J].中国给水排水,2022,38(18):87.
ZHOUGuo-biao,LüYin-zhong,ZHENG Wang,et al.Retrofitting Project of an Industrial Park WWTP to Meet Level Ⅴ Surface Water Standard[J].China Water & Wastewater,2022,38(1):87.
[4]曾明,郭庆贺,徐贵达,等.化工园区综合污水厂的工程改造及运行分析[J].中国给水排水,2022,38(18):101.
ZENGMing,GUOQing-he,XUGui?da,et al.Reconstruction and Operation Analysis of WWTP in a Chemical Industry Park[J].China Water & Wastewater,2022,38(1):101.
[5]张方方,刘骁智,张波.A2O+MBR+臭氧催化氧化用于化工园区污水厂升级改造[J].中国给水排水,2022,38(20):61.
ZHANGFang-fang,LIUXiao-zhi,ZHANGBo.Application of A2O/MBR/Catalytic Ozonation in Upgrading and Reconstruction of Wastewater Treatment Plant in Chemical Industrial Park[J].China Water & Wastewater,2022,38(1):61.
[6]张永森,夏文辉,董文博,等.MBBR+臭氧催化氧化用于工业区污水厂提标扩建[J].中国给水排水,2022,38(22):107.
ZHANGYong-sen,XIAWen-hui,DONGWen-bo,et al.Application of MBBR and Ozone Catalytic Oxidation in Upgrading and Expansion of an Industrial Park WWTP[J].China Water & Wastewater,2022,38(1):107.
[7]杨祝平.长流程四级处理工艺用于准Ⅳ类排放标准大型污水厂[J].中国给水排水,2022,38(24):58.
YANGZhu-ping.Application of Four-stage Treatment Long Process in a Large-scale Municipal Wastewater Treatment Plant to Meet Quasi Class Ⅳ Discharge Standard[J].China Water & Wastewater,2022,38(1):58.
[8]沈方方,刘永泽,马军,等.非均相催化剂催化臭氧产生·OH性能评价体系构建[J].中国给水排水,2023,39(13):25.
SHENFang?fang,LIUYong?ze,MAJun,et al.Development and Application of Evaluation Method for Hydroxyl Radical Formation during Heterogeneous Catalytic Ozonation[J].China Water & Wastewater,2023,39(1):25.
[9]柯水洲,李书平,马晶伟,等.三维电解-A/O-臭氧工艺处理垃圾填埋场后期渗滤液[J].中国给水排水,2023,39(23):1.
KEShui-zhou,LIShu-ping,MAJing-wei,et al.Three-dimensional Electrolysis-A/O-Ozone Process for Treatment of the Leachate in the Later Stage of Landfill[J].China Water & Wastewater,2023,39(1):1.
[10]程明涛,张万里.气浮+臭氧催化氧化用于工业园区污水厂提标改造[J].中国给水排水,2023,39(24):134.
CHENGMing-tao,ZHANGWan-li.Application of Dissolved Air Flotation and Ozone Catalytic Oxidation Process in the Upgrading and Reconstruction of a WWTP in an Industrial Park[J].China Water & Wastewater,2023,39(1):134.