新型生物电Fenton法降解偶氮染料:铁复合碳毡阴极研究

传统电Fenton反应通过电化学方法产生H2O2,需外加电源,能耗大,成本高。基于MFC持续产电并可驱动阴极电Fenton系统运行的特点,本研究以铁复合碳毡为阴极电极,构建了微生物燃料电池驱动的生物电Fenton系统,探讨了铁复合碳毡及阴极pH对偶氮染料(金橙I号)脱色的影响。结果发现,铁复合碳毡脱色效果均好于普通碳毡。当pH为3时,4 h后Fe@Fe2O3/CF阴极脱色率达91.7%,明显高于α-FeOOH/CF和FeAlSi/CF的83.4%和69.9%。扫描电镜发现,Fe@Fe2O3以微粒状结构附着于碳毡表面,比表面积增大,可能是Fe@Fe2O3/CF脱色性能改善的主要原因。研究表明,低pH有利于生物电Fenton反应的进行。当pH由3.0提高至5.0时,Fe@Fe2O3/CF阴极脱色率降低至47.1%。阴极室染料脱色与阳极室废水TOC削减呈线性相关,说明阳极生物氧化是驱动阴极生物电Fenton反应的原动力。本研究提供了一种能自我维持、无需外源电力的生物电Fenton系统,为印染废水脱色提供了崭新的途径。

O_2-Fenton试剂处理对氨基苯磺酸废水的探讨

利用由O2和Fenton试剂组成的类Fenton系统处理对氨基苯磺酸废水,取得了很好的降解效果。当FeSO4(10g／L)投加量为1.2mL、H2O2(3％)投加量为3mL时,COD去除率可达到70％。

青神县工业开发区污水处理厂设计与调试运行

青神县工业开发区污水处理厂进水水质复杂,难降解有机物含量较高且可生化性低,出水执行《四川省岷江、沱江流域污染物排放标准》(DB 51/2311—2016)。为使出水达到高标准排放,设计采用“水解酸化池+A^(2)/O/AMBR+Fenton流化床氧化系统+紫外消毒”处理工艺,设计规模为3×10^(4)m^(3)/d。介绍了该工程设计进出水水质指标、主要构筑物参数、工艺设计特点等。经过调试运行后,出水COD为32~39 mg/L,出水NH3-N为0.11~0.19 mg/L,出水TN为10.4~14.4 mg/L,出水TP为0.11~0.18 mg/L。Fenton氧化系统对NH3-N去除效果显著,但对污水中TN基本无影响,Fenton流化床系统的应用实现了化学降解有机物以及化学除磷。稳定运行5个月的出水水质可稳定达标排放。经测算,该工程合计运行成本(药剂费、电费、人工费)为1.491元/m^(3)。

化工综合废水处理研究进展

化工开发区的大量出现,使得成分复杂,含有难降解、有毒有机物的综合化工废水的处理成为亟待解决的问题,国内外对于化工废水的处理方法研究多针对含有某种或某类特定污染物的废水,而对化工综合废水处理的研究还不够。本文对现有综合化工废水的处理方法进行简要介绍,从而为化工园区废水处理提供思路。

Distinct synergetic effects in the ozone enhanced photocatalytic degradation of phenol and oxalic acid with Fe^(3+)/TiO_2 catalyst

In this work. phenol and oxalic acid （OA） degradation in an ozone and photocatalysis integrated process was intensively conducted with Fe3 ＋/TiO2 catalyst. The ferrioxalate complex formed between Fe3＋ and oxalate accelerated the removal of OA in the ozonation, photolysis and photocatalytic ozonation process, for its high reactivity with ozone and UV. Phenol was degraded in ozonation and photolysis with limited TOC removal rates, but much higher TOC removal was achieved in photocatalytic ozonation due to the generation of-OH. The sequence of UV light and ozone in the sequential process also influences the TOC removal, and ozone is very powerful to oxidize intermediates catechol and hydroquinone to maleic acid. Fenton or photo-Fenton reactions only played a small part in Fe3＋/TiO2 catalyzed processes, because Fe＋ was greatly reduced but not regenerated in many cases. The synergetic effect was found to be highly related with the property of the target pollutants. Fe3 ＋/TiO2 catalyzed system showed the highest ability to destroy organics, but the TiO2 catalyzed system showed little higher synergy.