Fenton氧化工艺处理DNT废水研究

DNT废水因其成分复杂、毒性大、难降解、对环境污染严重等特点,成为废水处理中的一个难题。本试验研究了难以生物降解DNT生产废水Fenton氧化处理效果,考查了各影响因子最佳工艺条件。结果表明,在pH值为2;FeSO4.7H2O投加量为200mg/L;H2O2投加量为2mL/L;反应时间为1h的条件下,Fenton氧化工艺COD去除率为47.76%,DNT去除率为87.37%左右。     

Fenton试剂-混凝法快速降解熄焦循环水中COD

以Fenton试剂氧化结合混凝法对焦化厂熄焦循环水COD进行快速去除实验,结果证明:当[Fe2+]/[H2O2]为1∶15,初始p H为3,30%H2O24.5 ml/100 ml废水时,反应90 min,COD去除率可达到90%,满足回用标准。但是,此时水的颜色较深,继续调节p H至7,加入Fe C13140 mg/L,PAM(聚丙烯酰胺)5 mg/L,搅拌5 min,静置30 min,COD去除率可达95.4%。Fenton-混凝对低浓度NH3-N几乎没有去除作用,CN-的去除率接近30%。整个处理过程中,有机物的种类和数量发生较大变化,Fenton氧化120 min后,混凝,污水基本接近无色,但仍含有单环芳香族化合物。     

多元催化氧化处理石化碱渣废水的研究

多元催化氧化技术实现了常温常压下有机物的氧化分解,催化氧化反应所产生的大量羟基自由基(·OH)具有极强的氧化能力,与不能或很难被生物降解的有机物都可以发生快速的链式反应,无选择地将高浓度难降解的有机物开环断链,氧化成简单的有机物、CO2和H2O。采用多元催化氧化装置处理石化碱渣废水,原水CODCr在4285~42,300mg/L之间,经催化氧化处理后,CODCr降至2000mg/L以下,出水水质稳定,为生化处理出水CODCr达标排放提供了可靠的技术保证。     

费通法治理糠醛废水的研究

利用Fe2+提高过氧化氢氧化能力的方法称为费通法,即Fe2+— H2O2法。使用费通法处理糠醛废水,可明显改善糠醛废水的可生化性。试验结果表明:当初始pH值小于3、Fe2+投加量为H2O2/Fe2+=6时,CODCr去除效果最好;双氧水投加量H2O2/CODCr值为0.5～2.0时,CODCr去除率可达到50%～75%,处理后废水的可生化性明显提高,BOD5/CODCr由0.15升至0.3以上。     

Fenton氧化处理微电解后制浆中段废水的研究

对微电解后废水初始pH、外加Fe2+、H2O2浓度、处理时间对色度及CODCr去除率的影响进行研究。实验结果表明随着pH的增加,色度和CODCr的去除率均呈现先增加后降低的趋势,在pH值等于4时,处理效果最好。外加Fe2+,H2O2和反应时间对废水CODCr和色度去除率的影响类似于pH的影响,获得的H2O2最佳投加量4 mL/L,FeSO4.7H2O为1.5g/L,最佳处理时间60min。在优化实验条件下,CODCr和色度的去除率稳定在80%和84%附近。     

Fenton试剂处理六氯苯废水的试验研究

研究了采用Fenton法处理六氯苯模拟废水的方法以及Fenton法处理六氯苯的影响因素。研究结果显示:在H2O2(30%)投加量为500mg/L,Fe2 投加量为1000mg/L,pH=2.5的条件下,经过4h的反应,废水中HCB去除率可达51.65%。     

油田稠油污水生物处理技术研究

针对稠油污水的特点,利用序批式生物反应器SBR对微生物进行了培养、驯化进而在稠油污水中生存、繁殖试验,并对其中的有机物进行了降解转化,生成稳定的CO2、H2O、NH3,利用该方法可以对稠油污水进行净化处理。试验结果表明,采用SBR工艺可使原水中CODCr从323 mg/L降至72 mg/L,去除率为77.7%;BOD从90 mg/L降至14.4 mg/L,去除率为84%;悬浮物从200 mg/L降至47 mg/L,去除率为76.5%。成功地解决了稠油污水的达标外排问题。     

臭氧－生物活性炭工艺处理化工污水中试研究

针对兰州石化公司污水处理厂二级生化处理出水可生化性较低,色度比较高的问题,通过采用臭氧-生物活性炭工艺(O3-BAC)对污水处理厂二沉池出水进行深度处理,分析了该工艺对CODCr、氨氮、色度的处理效果。结果表明:处理后出水CODCr为26.7mg/L,氨氮为0.18mg/L,色度约5倍,效果良好。     

复合絮凝剂Al2(SO4)3+PAM处理生活污水中CODCr和浊度的实验研究

研究絮凝剂硫酸铝Al2(SO4)3与助凝剂聚丙烯酰胺(PAM)联合处理生活污水的效果。研究表明:Al2(SO4)3与PAM联用比单独用Al2(SO4)3处理生活污水效果更好;Al2(SO4)3 PAM对生活污水CODCr和浊度具有良好的去除能力;当投加1:1的50mg/L的Al2(SO4)3 0.5mg/L的PAM,调节水体pH=7时,处理效果最理想,CODCr去除率可达95.8%,浊度去除率可达97.5%。为复合絮凝剂Al2(SO4)3 PAM处理生活污水的应用提供了有价值的参考依据。     

Fenton及电-Fenton处理难降解有机废水技术

Fenton法与电-Fenton法属于高级氧化技术(Advanced Oxidation Technologjes,AOTs),是由H2O2与催化剂Fe2 所构成的氧化体系.在Fenton体系中,H2O2在Fe2 的催化剂作用下,能产生两种活泼的氢氧自由基(HO2·和·OH),从而引发和传播自由基链反应,加快有机物和还原性物质的氧化.本文简要介绍了Fenton法与电-Fenton反应的机理和应用在催化氧化难降解废水领域中的处理技术及研究进展.     

低渗透油田压裂废水处理技术实验研究

通过低渗透油田压裂废水处理系列实验,研究了降黏预处理-Fe/C微电解-絮凝处理技术,有效地降低了废水的COD,考察H2O2、pH、Fe/C比例、Fe/C加量、Ca(OH)2加量及反应时间等影响因素。结果表明此实验的优化工艺条件为:H2O2加量0.5%、pH为1、Fe/C比例1∶1、Fe/C加量5g/L、Ca(OH)2加量3g/L、反应时间120min。     

Degradation of a commercial textile biocide with advanced oxidation processes and ozone

The occurrence of significant amounts of biocidal finishing agents in the environment as a consequence of intensive textile finishing activities has become a subject of major public health concern and scientific interest only recently. In the present study, the treatment efficiency of selected, well-known advanced oxidation processes (Fenton, Photo-Fenton, TiO(2)/UV-A, TiO(2)/UV-A/H(2)O(2)) and ozone was compared for the degradation and detoxification of a commercial textile biocide formulation containing a 2,4,4'-trichloro-2'-hydroxydiphenyl ether as the active ingredient. The aqueous biocide solution was prepared to mimic typical effluent originating from the antimicrobial finishing operation (BOD(5,o) < or =5 mg/L; COD(o)=200 mg/L; DOC(o) (dissolved organic carbon)=58 mg/L; AOX(o) (adsorbable organic halogens)=48 mg/L; LC(50,o) (lethal concentration causing 50% death or immobilization in Daphnia magna)=8% v/v). Ozonation experiments were conducted at different ozone doses (500-900 mg/h) and initial pH (7-12) to assess the effect of ozonation on degradation (COD, DOC removal), dearomatization (UV(280) and UV(254) abatement), dechlorination (AOX removal) and detoxification (changes in LC(50)). For the Fenton experiments, the effect of varying ferrous iron catalyst concentrations and UV-A light irradiation (the Photo-Fenton process) was examined. In the heterogenous photocatalytic experiments, Degussa P25-type TiO(2) was used as the catalyst and the effect of reaction pH (3, 7 and 12) and H(2)O(2) addition on the photocatalytic treatment efficiency was examined. Although in the photochemical (i.e. Photo-Fenton, TiO(2)/UV-A and TiO(2)/UV-A/H(2)O(2)) experiments appreciably higher COD and DOC removal efficiencies were obtained, ozonation appeared to be equally effective to achieve dearomatization (UV(280) abatement) at all studied reaction pH. During ozonation of the textile biocide effluent, AOX abatement proceeded significantly faster than dearomatization and was complete after 20 min ozonation (267 mg O(3)). On the other hand, for complete detoxification, ozonation had to be continued for at least 30 min (corresponding to 400mg O(3)). Effective AOX and acute toxicity removal was also obtained after heterogeneous photocatalytic treatment (TiO(2)/UV-A and TiO(2)/UV-A/H(2)O(2)). The Fenton-based treatment experiments and particularly the dark Fenton reaction resulted in relatively poor degradation, dearomatization, AOX and acute toxicity removals.     

Influence of pyrene combination state in soils on its treatment efficiency by Fenton oxidation

Interactions of hydrophobic organic compounds (HOCs) with soil organic matter (SOM) determine their combination state in soils, and therefore strongly influence their mobility, bioavailability, and chemical reactivity. Contact time (aging) of an HOC in soil also strongly influences its combination state and environmental fate. We studied Fenton oxidation of pyrene in three different soils to reveal the influences of SOM, contact time, and combination state on the efficiency of vigorous chemical reactions. Pyrene degradation efficiency depended strongly on the dose of oxidant (H(2)O(2)) and catalyst (Fe(2+)); the greatest degradation was achieved at an oxidant to catalyst molar ratio of 10:1. Pyrene degradation differed among the three soils, ranging from 65.4% to 88.9%. Pyrene degradation efficiency decreased with increasing SOM content, and the aromatic carbon content in SOM was the key parameter. We hypothesize that pyrene molecules that combine with the compact net structure of aromatic SOM are less accessible to Fenton oxidation. Furthermore, pyrene degradation efficiency decreased considerably after aged for 30 days, but further aging to 60 and 180 days did not significantly change degradation efficiency. The Fenton oxidation efficiency of pyrene in both unaged and aged soils was greater than the corresponding desorption rate during the same period, perhaps because Fenton reaction can make pyrene more accessible to the oxidant through the enhancement of HOCs' desorption by generating reductant species or by destroying SOM through oxidation.     

高铁酸钾氧化去除弱碱性地下水中低浓度石油类污染物实验研究

研究一般地下水弱碱性水溶液中,高铁酸钾对低浓度石油烃类污染物的氧化去除率。采用0#柴油模拟石油类污染物试验水样,氧化反应在200mL烧杯中模拟完全混合状态完成。实验分析浓度分别为5.02mg/L、2.05mg/L、1.01mg/L和0.52mg/L 4个水样石油类污染物氧化去除率。实验研究显示,石油类污染浓度与高铁酸钾浓度分别按1∶1、1∶2和1∶3投加进行配比,最大氧化去除率97.51%,平均氧化去除率89.46%,氧化反应结束时间为25T。采用乙酸等效计算的导致溶液p H降低小分子有机酸累积量较小;在高铁酸钾过量条件下,石油类污染物氧化反应近似为一级反应。     

高氯低COD废水中COD的测定

以某污水厂的高氯低COD生化出水为研究对象,探讨了硫酸汞加入量、K2Cr2O7溶液浓度、反应酸度、取水样量等参数对COD测定的影响,探讨消除该厂Cl-干扰最简单有效方法,结果表明:控制硫酸汞与氯离子比为15∶1(质量比)、K2Cr2O7浓度为0.18 mol/L、水样稀释0.75倍、Ag2SO4-H2SO4加入量为28mL,皆可有效减少氯离子的干扰。该方法相对氯气校正法,操作简单、准确可靠。     

UV/Fenton法处理高浓度香料废水的试验研究

研究了UV/Fenton法处理高浓度废水的新技术以及有关影响因素。试验:pH在2－4，COD／H2O2＝1：1.5,Fe^2 浓度为1.7g／L的条件下，反应时间90min，COD去除率可达99.6%。     

芬顿法和湿式过氧化氢氧化法处理醇酮模拟水的研究

以醇酮模拟水为研究对象,系统考察了芬顿法和湿式过氧化氢氧化法主要因素的影响规律,其中包括H2O2加量、pH值、Fe2+加量、反应时间等。通过单因素实验分别得到较优的反应条件。在较优条件下,芬顿法使醇酮模拟水的COD去除率达到73.40%,B/C由原来的0.15提高至0.30;湿式过氧化氢氧化法使醇酮模拟水的COD去除率达到73.12%,B/C提高到0.36。两种处理方法较大的提高了醇酮模拟水的可生化性,为后续的深度处理创造了条件。     

车载巡回式UV／Fenton装置处理小城镇垃圾渗滤液

为了研究车载巡回处理装置对小城镇垃圾渗滤液的处理效果,采用自制的UV-Fenton试验装置研究了pH值、FeSO_4剂量、反应时间等因素对处理效果的影响,结果表明:最佳pH值为4.0,进水中COD为825 mg/L时,FeSO_4和H_2O_2的投加量分别为0.008 mol/L和0.08 mol/L,此时COD去除率72.22%,出水COD为216 mg/L;随着FeSO_4投加量缓慢增加到一定程度后转而下降,FeSO_4最佳投加量为0.008 mol/L;不同H_2O_2和Fe~(2+)配比对COD去除效果具有影响,(10:1)时为最佳配比。经过氨吹脱和混凝沉淀预处理的渗滤液采用UV/Fenton处理工艺,出水中COD可以达到《生活垃圾填埋场污染控制标准》(GB 16889-1997)中二级标准。     

Treatment of IGCC power station effluents by physico-chemical and advanced oxidation processes

The aim of this work was to improve the quality of aqueous effluents coming from the Gasification Unit in an Integrated Gasification Combined Cycle (IGCC) Thermoelectric Power Station, with the purpose of fulfilling the future more demanding normative. To this end, an integral wastewater treatment including coagulation, flocculation, neutralization, photocatalytic oxidation, and ion-exchange has been studied. A final scheme has been proposed to remove pollutants. All the parameters of the treated wastewater are below pouring specifications. In the first stage, the wastewater was treated with CaCl2 (optimal dose=11 g CaCl2/g F-) as coagulant and a commercial anionic polyelectrolyte (optimal dose=0.02 g/g F-) as flocculant to remove fluoride ions (99%) and suspended solids (92%). The water was then neutralized, improving the degree of transmission of ultraviolet light, allowing the faster photo-degradation of pollutants. The photochemical study included different systems (H2O2, UV/H2O2, Fenton, Fenton-like, UV/Fenton, UV/Fenton-like and UV/H2O2/O2). In the Fenton-like system, the influence of two parameters (initial concentration of H2O2 and amount of Cu(II)) on the degradation of cyanide and formate (taken as the reference of the process) was studied. Experimental results were fit using neural networks (NNs). Results showed that the photocatalytic process was effective for total cyanide destruction after 60 min, while 180 min was needed to remove 80% of formates. However, a more simple system with UV/H2O2/O2 yields similar results and is preferred for industrial application due to fewer complications. Finally, an ion-exchange process with Amberlite IRA-420 was proposed to remove the excess of chlorides added as a consequence of the initial coagulation process.