Fe2+/UV催化臭氧-曝气生物滤池降解腈纶废水研究

腈纶废水是一种难降解的有毒有机废水。本文采用Fe2+/UV催化臭氧-曝气生物滤池降解腈纶废水,探讨了臭氧浓度和紫外光辐射强度等影响因素对腈纶废水的COD去除效果的影响,并考察了紫外催化臭氧氧化单元和曝气生物滤池单元对COD去除的协同作用。结果表明,臭氧浓度对COD的去除率影响较大,臭氧浓度下降25%时,臭氧催化氧化和曝气生物滤池单元处理的COD去除率分别下降了12.53%和15.98%。紫外光强度对臭氧催化氧化单元的COD去除率影响较小,但对曝气生物滤池单元影响较大。臭氧催化氧化单元和曝气生物滤池单元COD去除率之比为1∶2,其协同作用使总出水COD值稳定在较低水平。     

絮凝-漂白粉催化氧化处理印染废水

采用絮凝-漂白粉催化氧化法,筛选出硫酸镁催化剂,提高难生化处理的印染废水对色度、COD的去除效果。实验结果表明,对COD_(Cr) 592 mg/L、色度625倍、pH 9.82、SS 150 mg/L的某印染废水,当废水p H为6时,投加Al_2(SO_4)_3·18H_2O 400 mg/L、聚丙烯酰胺(PAM)2 mg/L,催化剂硫酸镁80 mg/L,有效氯30%的漂白粉1.0 g/L,CODCr最终去除率达到88.2%,色度去除率98.4%,浊度去除率86.6%,出水pH为6,达到国家二级排放标准。催化氧化的脱色速率提高近一倍,结果对印染废水的处理研究和实际应用具有一定价值。     

湿式氧化工艺中颗粒Ru催化剂的活性和稳定性

分别采用传统成型法和新的成型法制备了一系列以CeO2为主要成分的载体,将贵金属Ru浸渍在这些载体上制备了不同的催化剂.对催化剂的比表面积和机械强度进行了表征,并通过湿式氧化乙酸的静态实验和湿式氧化苯酚的动态实验分别考察了催化剂的活性和稳定性.结果表明,Ru负载在采用新方法成型的载体上制得的催化剂具有更大的比表面积.向CeO2中掺杂Zr能增大载体的比表面积.新方法制备的催化剂Ru/ZrO2-CeO2催化湿式氧化乙酸具有良好的活性,化学需氧量(COD)去除率为98%.在110h的催化湿式氧化苯酚反应中,苯酚和COD的去除率维持在96%左右,反应过程中活性组分的溶出浓度很小,催化剂表面有少量的积炭,但积炭在300℃能够被完全氧化.因而催化剂具有较好的稳定性和工业应用可能性.     

Ru/ZrO2-CeO2催化剂催化湿式氧化乙酸和苯酚的研究

采用共沉淀法制备了ZrO2-CeO2颗粒载体,利用浸渍法制备了Ru/ZrO2-CeO2颗粒催化剂,采用BET、XRD、SEM、TEM等方法对其进行了结构表征,测定了其催化湿式氧化乙酸的活性,并以苯酚为模型物进行了动态试验.结果表明,Zr的添加抑制了CeO2晶粒的长大,增加了催化剂的抗热性能.当催化剂Zr、Ce摩尔比为1∶9,焙烧温度为300℃时催化剂活性最高,在200℃和4 MPa下,催化湿式氧化乙酸反应120 m in后,COD去除率可达99%.动态实验100 h内,苯酚与COD的去除率都保持在90%以上,催化剂具有很好的活性和稳定性.     

树脂吸附法处理高浓度DSD酸氧化工序生产废水的研究

本文采用大孔吸附树脂固定床工艺处理DSD酸氧化工序生产废水。实验结果表明，ND804大孔吸附树脂对该废水具有良好的吸附－脱附效果，废水经ND804树脂吸附处理后，CODCr由14790mg/L降至1300mg/L左右，COD去除率约为91％，并可回收纯度达80％的DNS酸，废水在得到有效治理的同时实现了废物的资源化。     

催化氧化处理工业废气中高浓度甲醛

制备了用于温和条件下催化氧化去除工业废气中高浓度甲醛(HCHO)的1%Pt-4%CeO₂/AC催化剂. 将高浓度甲醛的催化氧化过程与双甘膦氧化制备草甘膦的反应过程集成在一起,使草甘膦合成过程中产生和排放出来的甲醛(100-300 mg/m³)在通过催化剂床层时被完全除去. 系统研究了温度、空速和甲醛含量对甲醛去除率的影响. 在气体空速(GHSV)低于20000 h^-1时废气中几乎所有的甲醛都被氧化,处理后的废气中的甲醛含量低于0.1 mg/m³,甲醛的转化率为99.1%-100%. 当GHSV为30000- h^-1,催化剂床层温度为12℃时,生产废气通过催化剂床层后的甲醛含量小于1.5 mg/m³,甲醛的转化率为97.56%-99.99%. 1%Pt-4%CeO₂/AC催化剂的中试试验结果表明,处理后最终尾气中甲醛含量小于10 mg/m³,有效地防止了甲醛对人们健康的危害,具有良好的产业化前景.     

二氧化钛粉体在纸厂废水处理中的应用

为了获得活性更高的催化剂来处理纸厂废水,本实验利用溶胶-凝胶法制备了TiO₂粉体,并对其进行了表征,最后将其应用于光催化氧化处理纸厂废水.实验结果表明,此粉体为锐钛型纳米颗粒;应用其作催化剂处理造纸废水可使废水COD和浊度的去除率分别达94%和97%,处理后废水达到排放标准,也使废水的色度得到很大程度的去除.     

ZrxCe1－xO2催化剂催化湿式氧化乙酸的活性研究

采用共沉淀法制备了Zr_xCe_1－xO₂催化剂, 利用BET, XRD和XPS对其进行了表征, 并研究了催化剂催化湿式氧化乙酸的活性. 结果表明: Zr和Ce摩尔比为1∶9的催化剂催化湿式氧化乙酸时具有最好的活性, 当乙酸溶液的初始化学需氧量(COD)为5000 mg/L, 反应温度为230 ℃, 压力为5 MPa时, 120 min后, COD的去除率为76% . 催化剂具有良好的活性是因为在CeO₂中加入Zr能够增大催化剂的比表面积和表面缺陷氧的含量, 并最终加快了HO₂•自由基的产生, 从而提高了催化剂的活性.     

“氧化·脱色·絮凝”协同法处理含吡啶酮废水

根据染料中间体吡啶-2-酮生产废水的特点,提出了利用“氧化、脱色和絮凝”三位一体的物化方法处理这种废水;探究了搅拌速度、絮凝反应时间、pH值、药剂用量、废水浓度和温度对COD去除率和脱色率的影响,得出了最佳工艺条件.研究结果表明,在常温下,两性聚丙烯酰胺NDPAM用量35 mg/L,氧化交联剂PDO用量0.55 mL/L,pH=5.7,搅拌速度80 r/m in,絮凝时间为15 m in和静止时间为30 m in的条件下,COD的去除率和脱色率均达到98%,处理后的废水达到了可生化的指标范围.并对处理成本和絮凝动力学机理进行了探讨.     

常温常压湿式催化氧化染料废水的Mo-Cu-Fe-O新型复合催化材料

染料广泛应用于纺织厂、皮革厂以及染发等各个领域.染料废水具有成分复杂、浓度高、色度大和生物难降解等特性,因此传统的处理方法难以将其完全降解.高级氧化技术已成为国内外广泛应用的染料废水处理技术之一,特别是湿式催化氧化(CWAO)技术.然而,CWAO工艺中反应往往需要高温(通常为200-280℃)和高压(通常为2-9 MPa),制约了其广泛应用.因此,人们致力于研发具有高催化活性的催化剂,通过改变反应历程和降低反应的活化能,使反应在常温常压条件下进行.本课题组曾采用钼酸盐浸渍于Zn/Al LDHs溶液中成功制备了Mo/Zn-Al LDHs催化剂,该催化剂能在常温常压下湿式催化氧化降解阳离子红GTL有机废水.Mo/Zn-Al LDHs催化剂中Mo作为主催化成分,Zn-Al LDHs作为载体.Cu-Fe LDHs本身作为一种催化剂,与Mo相结合能有效提高催化剂的活性及稳定性,因此本文采用浸渍法制备了Mo-Cu-Fe-O新型复合催化材料,采用X射线衍射、氢气程序升温还原、循环伏安法和氧气程序升温脱附等表征手段研究了Mo-Cu-Fe-O材料的结构及氧化还原特性.以阳离子红GTL、结晶紫和酸性红为染料废水代表,研究了常温常压下Mo-Cu-Fe-O催化降解染料废水的催化活性.结果表明,在中性条件下Mo-Cu-Fe-O对阳离子型染料废水具有良好的催化活性.循环使用七次后该样品对阳离子红GTL和酸性红的脱色率分别达到91.5%和92.8%,然而对酸性红阴离子型染料废水基本无催化活性.在常温常压CWAO过程中产生的羟基自由基能有效降解阳离子GTL废水,其废水毒性随着反应的进行逐渐减小.     

ZnFe0.25Al1.75O4催化剂在苯酚催化湿式氧化中的活性和稳定性

利用溶胶-凝胶法制备了ZnFe0.25Al1.75O4尖晶石复合氧化物催化剂,并将其用于苯酚催化湿式氧化反应.结果表明,这种催化剂对苯酚降解有较好的催化活性和稳定性.连续反应5次后,苯酚转化率为100%,COD去除率为88.7%.反应过程中,铁离子的溶出量先增加后减小,最终的出水金属离子浓度很低.第5次反应后的出水铁离子浓度为2.15 mg/L,锌离子浓度为1.53 mg/L.     

Fe-Mn-Cu-Ce/Al2O3 as an efficient catalyst for catalytic ozonation of bio-treated coking wastewater: Characteristics,efficiency, and mechanism

It is important to develop a catalyst that has high catalytic activity and can improve the degradation efficiency of refractory organic pollutants in the catalytic ozonation process. In this study, Fe-Mn-Cu-Ce/Al₂O₃ was synthesised via impregnation calcination for catalytic ozonation of bio-treated coking wastewater. The physical and chemical characteristics of the catalysts were analysed using X-ray diffraction (XRD), X-ray fluorescence spectrometry (XRF), X-ray photoelectron spectroscopy (XPS), scanning electron microscopy (SEM), and Brunauer–Emmett–Teller nitrogen adsorption–desorption methods. The effects of catalyst dosage, pH, and reflux ratio on the degradation efficiency of wastewater were examined in laboratory-scale experiments. The chemical oxygen demand (COD) removal rate of bio-treated coking wastewater was estimated to be 52.76 % under optimal conditions. The experiments on the catalytic mechanism demonstrated that the surface hydroxyl formed by the Lewis acid sites on the surface of the catalyst can react with ozone as the active site forming the active oxygen (·OH, ·O₂^–, and ¹O₂), thereby efficiently degrading the organic pollutants in coking wastewater. Furthermore, a pilot-scale experiment on the catalytic ozonation of bio-treated coking wastewater was carried out using an Fe-Mn-Cu-Ce/Al₂O₃ catalyst, while the effects of the initial pollutant concentration, ozone concentration, and gas flow on the COD removal rate were studied on a pilot scale. It was found that the COD removal rate of the wastewater was ～ 60 % under optimal parameters. After the treatment, the wastewater steadily reached the coking wastewater discharge standard (COD < 80 mg/L), while the operating cost of catalytic ozonation reached ～ 0.032$/m³, thereby paving the way toward economic engineering applications. The COD degradation kinetics in the bio-treated coking wastewater followed pseudo-second-order kinetics. Three-dimensional fluorescence and gas chromatography–mass spectrometry revealed that macromolecular organic pollutants in the bio-treated coking wastewater were greatly degraded. In summary, Fe-Mn-Cu-Ce/Al₂O₃ exhibited good reusability, high catalytic activity, and low cost and has a wide application prospect in the treatment of coking wastewater.     

Industrial indigo dyeing wastewater purification: Effective COD removal with peroxi-AC electrocoagulation system

Direct current (DC) electrocoagulation has obvious decolorization effect on indigo dyeing wastewater produced in actual production, while the removal rate of chemical oxygen demand (COD) was less than 40%, accompanied by serious electrode corrosion and high energy consumption. In order to enhance the COD removal rate, reduce the electrode loss and power consumption, a peroxi-alternating current (AC) electrocoagulation (EC) system was constructed. With COD as the main evaluation index, the effects of power type, electrode combination and process parameters on COD removal rate and decolorization rate were focused on and explored, as well as revealing the degradation mechanism of COD. The results showed that AC electrocoagulation enhanced the floc adsorption capacity by improving the floc structure, and the COD removal rate after treatment was 51.19%. The coupled system of peroxi-AC electrocoagulation further removed sulfite and residual dyes in the wastewater, and the COD removal and decolorization rate of the treated wastewater reached 78.09% and 98.47%, respectively. In addition, the specific energy consumption analysis of COD removal showed that the coupled system was far less energetic than the DC electrocoagulation process, with only 30% of its energy consumption. The uniform corrosion of the electrode under the action of AC weakened the passivation, which reduced the electrode loss and power consumption by 22.73% and 43.75%, respectively. Results from the present work indicated that the peroxi-AC EC system could be an effective method for reducing the concentration of COD in indigo dyeing wastewater.     

Removal of COD,aromaticity and color of a pretreated chemical producing industrial wastewater: a comparison between adsorption,ozonation, and advanced oxidation processes

A wide range of products are produced in the chemical producing industry such as textile dyes, chemicals, printing dyes and chemicals, paper chemicals, electrostatic powder dyes, and optical brighteners. The aim of this study is to investigate the treatability of chemical oxygen demand (COD), aromaticity, and color in the wastewater of this sector, where highly complex chemicals are used. Most of the studies in the literature are related to the treatment of synthetically prepared dyed wastewater. This study is important as it is carried out with real wastewater and gives results of many treatment methods. In the study, COD, UV-vis absorbance, and color values were attempted to be removed from the wastewater of a chemical producing industry that was pretreated by coagulation-flocculation. The COD value of the pretreated wastewater discharged to the central treatment system was restricted as 1000 mg/L. Pretreated wastewater characterization is as follows: COD: 2117 mg/L, UV-vis absorbance values at; 254 nm: 9.91, 280 nm: 8.65, 341 nm: 12.77, 436 nm: 5.01, 525 nm: 2.24, and 620 nm: 1.59. In the study, adsorption, ozonation, and advanced oxidation processes (Fenton and persulfate oxidation) were used to remove COD and UV-vis absorbance values (aromaticity, organics, and color). The method by which the best removal efficiency was obtained for all parameters was the adsorption process using powdered activated carbon (PAC). The equilibrium PAC dose was found as 6 g/L. At this adsorbent dose, the removal efficiencies of UV-vis absorbance values were all around 99% and the efficiency of COD removal was 77%. The Langmuir isotherm constants were found to be q_max= 30.4 mg/g and K_L = 487.9 (L/mg). The COD concentration at this adsorbent dose was 486 mg/L and wastewater was suitable for discharge to the central wastewater treatment plant in that region.     

Degradation of p-aminophenol wastewater using Ti-Si-Sn-Sb/GAC particle electrodes in a three-dimensional electrochemical oxidation reactor

In this study, Ti-Si-Sn-Sb/GAC particle electrodes were prepared by sol–gel method. The particle electrodes were characterized by SEM, XRD, EDX, and BET then used to carry out three-dimensional (3D) electrocatalytic oxidation degradation on simulated refractory p-aminophenol (PAP) wastewater. The effects of initial pH, cell voltage, aeration flow rate and initial PAP concentration on degradation experiments were investigated. Under the optimal conditions, the PAP and COD removal rates were 89.45% and 75.17% respectively. In addition, the possible degradation mechanism of PAP was further investigated by UV–Vis and HPLC. Finally, it was found that the Ti-Si-Sn-Sb/GAC particle electrodes with high catalytic activity and excellent stability could significantly improve the PAP wastewater removal efficiency.     

ZrxCe1－xO2催化剂催化湿式氧化乙酸的活性研究

采用共沉淀法制备了Zr_xCe_1－xO₂催化剂, 利用BET, XRD和XPS对其进行了表征, 并研究了催化剂催化湿式氧化乙酸的活性. 结果表明: Zr和Ce摩尔比为1∶9的催化剂催化湿式氧化乙酸时具有最好的活性, 当乙酸溶液的初始化学需氧量(COD)为5000 mg/L, 反应温度为230 ℃, 压力为5 MPa时, 120 min后, COD的去除率为76% . 催化剂具有良好的活性是因为在CeO₂中加入Zr能够增大催化剂的比表面积和表面缺陷氧的含量, 并最终加快了HO₂•自由基的产生, 从而提高了催化剂的活性.     

Optimization of multiple parameters for treatment of coking wastewater using Fenton oxidation

Present study deals with the treatment of coking wastewater (CWW) using Fenton oxidation process for the degradation of pollutants containing chemical oxygen demand (COD), phenol and cyanide. The experiments were performed in batch mode to study the effect of operating parameters like initial pH (pH_i), temperature (T), oxidant H₂O₂ amount, catalyst mass loading (Cw) and treatment time (t_R). The response surface methodology (RSM) gave optimum value of pH, H₂O₂, Cw and t_R as 3, 0.3 M, 1.85 g/L (0.0266 M) and 1.52 h. At this optimum operating condition maximum 84.66% COD, 88.46% phenol and 79.34% cyanide reduction were achieved from initial value of COD (COD_i) = 2810.0 mg/L, phenol_i = 283.0 mg/L and cyanide_i = 18.88 mg/L. Results reflect that Fenton oxidation is an effective process for the reduction of pollutants present in CWW. The CWW treated by Fenton oxidation having average value COD = 590.0 mg/L, phenol = 39.49 mg/L and cyanide = 5.2 mg/L was further treated by adsorption process as second stage treatment, and these values were reached to COD = 199.0 mg/L, phenol = 0.0 mg/L and cyanide = 2.36 mg/L. The response surface methodology (RSM) was used for the designing and optimization of the experiments. Analysis of variance (ANOVA) suggested the high regression coefficient R² = 0.999 and 0.993 for COD and phenol removal respectively. The two stage treated CWW can be recycled and reused in same industry for various purpose.     

活性炭催化氧化预处理PTA废水

研究了活性炭催化氧化预处理精对苯二甲酸(PTA)废水的工艺。实验结果表明,活性炭投加量为16g/L,曝气2h,最佳pH值为4,在此催化氧化的条件效果最佳,对COD的去除率可达64%,活性炭通过碱再生可重复使用。此外,色谱分析的结果证明,对苯二甲酸,苯甲酸,甲基苯甲酸都有不同程度的降解,对苯二甲酸被部分氧化成苯甲酸,使得处理后的废水可生化性好。成本核算表明,活性炭催化氧化是一种PTA废水的高效廉价预处理技术。     

Preparation of Al2O3-supported nano-Cu2O catalysts for the oxidative treatment of industrial wastewater

Cuprous oxide (Cu₂O) nanoparticles supported on Al₂O₃ prepared using two different methods (hereafter referred to as catalyst I and II, respectively) were characterized by XRD and TEM. The catalytic activities of catalyst I and II during the treatment of industrial wastewater were then investigated. Specifically, the progress of the catalytic oxidation of industrial wastewater was observed by monitoring the time-dependent change in the chemical oxygen demand (COD) of industrial wastewater when the catalysts were applied. The results indicated that the catalytic activity of catalyst II was greater than that of catalyst I. Furthermore, under optimal conditions the COD removal efficiency was 94.59%. Finally, the mechanism by which the oxidative degradation of the industrial wastewater occurred could be explained based on a hydroxyl radical mechanism.