光催化-臭氧氧化降解H酸的研究

采用光催化一臭氧氧化技术（催化膜／UV／O3）降解H酸。研究结果表明，光催化与臭氧氧化相结合具有明显的协同作用。实验进一步讨论了臭氧投加量、废水初始pH值和H酸初始浓度对光催化一臭氧氧化降解H酸的影响。降解后的H酸，萘环结构被破坏，可生化性提高。     

氧化铈/活性炭催化臭氧氧化技术去除水中邻苯二甲酸二甲酯

用浸渍法在活性炭(AC)上负载氧化铈(CeO2)制备催化刺CeO2/AC催化臭氧氧化去除邻苯二甲酸二甲酯(DMP),考察了臭氧投加量,DMP初始浓度和溶液初始pH的影响.结果表明,CeO2/AC催化臭氧氧化去除DMP的最佳臭氧投加量为50mg/h,DMP初始浓度和溶液初始pH对CeO2/AC催化臭氧氧化DMP过程都有一定的影响.在DMP初始质量浓度为30 mg/L、溶液初始pH为5、臭氧投加量为50 mg/h、反应60 min时,CeO2/AC的加入(1.5g/L)有利于催化臭氧氧化DMP过程中总有机碳(TOC)的去除,TOC去除率由AC催化臭氧氧化的48%提高到68%.而单独臭氧氧化过程中的TOC去除率仅22%;且单独臭氧氧化与AC、CeO2/AC催化臭氧氧化DMP的矿化过程均符合二级反应动力学方程,CeO2/AC催化臭氧氧化DMP时TOC降解的二级反应动力学常数为0.0015L/(mg·min),分别是AC催化臭氧氧化的2.5倍和单独臭氧氧化的7.5倍.     

光催化臭氧氧化法在废水处理中的研究进展

光催化臭氧氧化法作为一种有效的废水处理技术,对难降解的有机废水,具有良好的降解功效。文中分析了UV/O3/Fe2＋、UV/O3/Fe3＋和UV/O3/H2O2体系的反应机理,介绍了光催化臭氧氧化法在废水处理中的应用情况,指出了光催化臭氧氧化法存在的问题和展望。     

臭氧催化氧化降解苯胺的机理

对臭氧单独氧化和臭氧催化氧化下的苯胺降解效率进行了比较,并通过液质联机分析了氧化过程中产物变化情况。实验结果表明,催化剂MnO2-CuO-CeO2/沸石的添加能有效地提高臭氧氧化苯胺的降解率,当苯胺初始浓度为200mg/L,反应20 min后,苯胺的去除率由原来的75%提高到89%;通过LC-MS分析,臭氧催化氧化苯胺降解过程中代谢产物依次为对亚胺醌、对苯醌、马来酸和草酸,并由此推断出了臭氧催化氧化降解苯胺的途径。     

催化臭氧氧化降解糖蜜酒精废水的研究

以SnO2为催化剂,研究糖蜜酒精废水在臭氧条件下的氧化降解反应,为糖蜜酒精废水的治理提供一种新的处理方法.研究表明,SnO2加速了臭氧氧化反应,使糖蜜酒精废水的氧化降解加快.影响糖蜜酒精废水氧化降解的主要因素有臭氧流量、废水的初始pH和催化剂用量等.加大臭氧流量及增加催化剂用量,均有利于糖蜜酒精废水的降解.适宜的反应条件是:糖蜜酒精废水的稀释倍数为10倍,臭氧流量为130 mg/h,催化剂用量为2.500 g/L,废水的初始pH为4.25,温度为30 ℃.在该条件下反应60 min,废水的脱色率为60.2%,COD去除率为44.5%.动力学分析表明,单独臭氧氧化降解糖蜜酒精废水和SnO2催化臭氧氧化降解糖蜜酒精废水均为拟一级反应.     

臭氧/Mn2+催化降解水溶液中的2,4-二氯苯氧乙酸

以Mn2 为催化剂与臭氧联合降解除草剂2,4-二氯苯氧乙酸(2,4-D).考察了反应温度、pH、2,4-D初始浓度和臭氧气体流量等因素对2,4-D降解效果的影响.pH对2,4-D降解效果影响很大,当pH=2.0、反应5 min时,2,4-D的去除率达99.8%;当pH=10.1、反应20min时,2,4-D的去除率仅为50.0%.反应温度升高、臭氧气体流量增加、2,4-D初始浓度降低均有助于2,4-D降解速率的提高.单独臭氧氧化2,4-D的表观反应速率常数为0.170 min-1;催化臭氧氧化2,4-D的表观反应速率常数为0.295min-1,是单独臭氧氧化的1.74倍.2,4-D的Mn2 催化臭氧反应遵循拟一级反应动力学方程.     

臭氧-二氧化钛光催化技术脱除硫化氢

在连续性反应器内以臭氧-光催化技术氧化硫化氢,证实了臭氧对光催化脱除硫化氢有促进作用,探讨了可能存在的主要基元反应和二氧化钛失活的原因,考察了反应温度、臭氧含量、硫化氢初始体积分数等因素对臭氧-光催化技术脱除硫化氢的影响。结果表明,臭氧在光催化作用下快速分解为活性氧离子或自由基,硫化氢在臭氧和光催化联合作用下快速氧化为二氧化硫,最终转化为硫酸;硫酸在二氧化钛表面的沉积使其催化活性降低,导致硫化氢和二氧化硫的转化率逐渐下降。研究还发现,当硫化氢的初始体积分数为100×10-6时,臭氧和硫化氢的最佳摩尔比约为2∶1;臭氧-光催化脱除硫化氢的最佳温度为70℃左右;降低硫化氢的初始体积分数可大幅度降低二氧化硫的选择性。     

臭氧光催化降解水中甲醛的研究

研究比较了3种光化学方法对水中低浓度甲醛的降解效果,考察了初始pH值、甲醛浓度和臭氧投加速率等因素对臭氧光催化(TiO_2/UV/O_3)降解甲醛的影响。结果表明,紫外臭氧(UV/O_3)、光催化(TiO_2/UV)和TiO_2/UV/O_3对甲醛的降解均符合表观一级反应动力学,TiO_2/UV/O_3降解甲醛的一级表观速率常数大于TiO_2/UV与UV/O_3之和,说明臭氧、光催化有明显的协同作用。pH值对臭氧光催化降解甲醛的速率几乎没有影响;甲醛初始浓度增加,表观反应速率常数下降,但甲醛的绝对去除量仍随初始浓度的增加而显著增加;臭氧投加速率增加,降解速率增加。甲醛降解的主要中间产物为甲酸,但甲酸在臭氧光催化反应过程中也快速降解而被矿化,说明臭氧光催化是一种能安全有效去除甲醛的方法。     

活性炭-臭氧体系处理含氰废水的作用机理

针对活性炭催化臭氧化降解低质量浓度含氰废水体系,研究了活性炭吸附、催化作用在催化臭氧化体系中的作用,提出了吸附-催化臭氧化协同作用机理。在活性炭-臭氧体系中,活性炭吸附CN-的能力很弱,活性炭在反应体系中主要起了吸附、催化臭氧的作用。活性炭-臭氧体系降解CN-的过程是臭氧直接氧化、活性炭吸附臭氧与活性炭催化臭氧产生.OH自由基间接氧化三者共同作用的结果。     

非均相催化臭氧氧化深度处理炼油废水

采用非均相催化剂催化臭氧氧化处理炼油废水,考察了催化剂负载率、p H、催化剂投加量和臭氧投加量及反应时间对处理效果的影响。结果表明,组合工艺最佳工艺条件为:催化剂负载率2.1%、p H 9、催化剂投量80 g/L、臭氧投量8.1 mg/L、反应时间60 min,COD、石油类、NH3-N、硫化物和SS去除率分别为91.3%、92.7%、80.5%、34.5%和59%。处理炼油废水过程中组合工艺存在明显协同效应,协同因子为1.47。中间臭氧氧化和催化臭氧氧化在最优工艺条件下对炼油废水COD的降解均符合准一级动力学规律。基于叔丁醇的实验结果,结合降解动力学可以推测,降解炼油废水过程中非均相催化剂催化臭氧产生高活性羟基自由基是降解效率提高的主导因素。     

紫外光助臭氧化处理活性艳红K-2BP废水研究

以 30 0W高压汞灯为光源 ,研究了紫外光联合臭氧化、单纯臭氧氧化及单纯紫外光照处理 4 0 0mg/L的活性艳红K 2BP废水的可行性。结果表明 :光催化臭氧化可加速有机物的矿化。在同样时间条件下 ,三者氧化能力由大至小为 :UV/O3 >单独O3 >单独UV。运用TOC、紫外 可见光谱 (UV Vis)、毛细管电泳 (CE)等分析技术初步探讨了紫外光催化臭氧化活性艳红K 2BP溶液的降解效果及降解机理。     

Wastewater disinfection alternatives: chlorine, ozone, peracetic acid, and UV light.

Disinfection tests were carried out at pilot scale to compare the disinfection efficiency of ozone, sodium hypochlorite (NaOCl), peracetic acid (PAA), and UV irradiation. Total coliforms, fecal coliforms, and Escherichia coli were monitored as reference microorganisms. Total heterotrophic bacteria (THB) were also enumerated by cytometry. At similar doses, NaOCl was more effective than PAA, and its action was less affected by contact time. The results obtained by ozonation were comparable for total coliforms, fecal coliforms, and E. coli. On the contrary, some differences among the three indicators were observed for NaOCl, PAA, and UV. Differences increased with increasing values of the disinfectant concentration times contact time (C x t) and were probably the result of different initial counts, as total coliforms include fecal coliforms, which include E. coli. The UV irradiation lead to complete E. coli removals, even at low doses (10 to 20 mJ/cm2). Total heterotrophic bacteria appeared to be too wide a group to be a good disinfection indicator; no correlation was found among THB inactivation, dose, and contact time.     

Comparison of the degradation of p-hydroxybenzoic acid in aqueous solution by several oxidation processes

A comparative study is made of 12 methods of chemical oxidation applied to degrading p-hydroxybenzoic acid in aqueous solution. The oxidation processes tested were: UV, O3, UV/TiO2, O3/Fe2+, O3/H2O2, O3/UV, UV/H2O2, H2O2/Fe2+, H2O2/Fe2+/O3, UV/H2O2/O3, H2O2/Fe2+/UV and O3/UV/H2O2/Fe2+. The 12 processes were ranked by reactivity. In a kinetic study, the overall kinetic rate constant was split up into three components: direct oxidation by UV irradiation (photolysis), direct oxidation by ozone (ozonation), and oxidation by free radicals (mainly OH*).     

Enhancement of ozone oxidation and its associated processes in the presence of surfactant: degradation of atrazine

In this study, the degradation of atrazine (ATZ) by ozone (O3) oxidation and its associated processes (i.e. UV, UV/O3) in the presence and absence of surfactant was investigated and compared. A non-ionic surfactant, Brij 35, was selected. It was found that the presence of a low concentration of surfactant could improve the removal of ATZ by increasing the dissolution of ozone and the indirect generation of hydroxyl radicals. The saturated ozone level and the reaction rate constants were increased with increasing the concentration of surfactant and then decreased at higher surfactant doses at pH level of 2.5. A similar trend was observed at pH level of 7.0 in the presence of bicarbonate ion, because it is capable of deactivating the hydroxyl radicals generating at higher pH level. However, when the radical reactions become dominant in the ozonation (at pH 7.0 without bicarbonate), the saturated ozone level was higher than that with bicarbonate and the kinetic rate constants were increased first and levelled off with increasing of the dose of surfactant. Through the examining of a proposed unit performance index, the low concentration of surfactant is surely beneficial to the ozonation process. Besides, the direct photolysis and photo-assisted ozonation were compared to the ozonation. A significant enhancement on the decay rate of ATZ was resulted exclusively by adding the surfactant. An enhancement index for quantifying the improvement of the various processes was developed.     

Photo-Fenton-assisted ozonation of p-Coumaric acid in aqueous solution

The degradation of p-Coumaric acid present in olive oil mill wastewater was investigated as a pretreatment stage to obtain more easily biodegradable molecules, with lower toxicity that facilitates subsequent anaerobic digestion. Thus, photo-Fenton-assisted ozonation has been studied and compared with ozonation at alkaline pH and conventional single ultraviolet (UV) and acid ozonation treatments. In the combined process, the overall kinetic rate constant was split into various components: direct oxidation by UV light, direct oxidation by ozone and oxidation by hydroxyl radicals. Molecular and/or radical ozone reaction was studied by conducting the reaction in the presence and absence of tert-butylalcohol at pHs 2, 7 and 9. Ozone oxidation rate increases with pH or by the addition of Fenton reagent and/or UV radiation due to generation of hydroxyl radicals, *OH. Hydrogen peroxide and ferrous ion play a double role during oxidation since at low concentrations they act as initiators of hydroxyl radicals but at high concentrations they act as radical scavengers. Finally, the additional levels of degradation by formation of hydroxyl radicals have been quantified in comparison to the conventional single processes and an equation is proposed for the reaction rate as a function of studied operating variables.     

SMX degradation by ozonation and UV radiation: a kinetic study

The rate constants of sulfamethoxazole (SMX) degradation by ozonation and UV₂₅₄ radiation were investigated under various parameters including influent ozone gas concentration, initial SMX concentration, UV light intensity, ionic strength, water quality in terms of varying anions (bicarbonate, sulfate and nitrate), humic acid (HA) and pH. The results indicated that the removal of SMX by ozonation and UV₂₅₄ radiation fitted well to a pseudo first-order kinetic model and the rate constants were in the range of (0.9-9.8) × 10⁻³ and (1.7-18.9) × 10⁻³ s⁻¹, respectively. The second-order rate constants of SMX with ozone (k_O3), under varying operational parameters, were also determined and varied in the range of (0.60-3.38) ± 0.13 × 10⁵ M⁻¹ s⁻¹. In addition, SMX degradation through UV pretreatment followed by ozonation in the presence of HA was proved to be an effective method which can remove SMX with a low ozone dose. The results suggested that ozonation of SMX was more affected by concentration of influent ozone gas, alkalinity, and HA, while incident UV light intensity, pH, and HA were the dominant factors influencing UV degradation of SMX.     

Photocatalytic ozonation of terephthalic acid: a by-product-oriented decomposition study

Terephthalic acid (TA) is considered as a refractory model compound. For this reason, the TA degradation usually requires a prolonged reaction time to achieve mineralization. In this study, vanadium oxide (V_xO_y) supported on titanium oxide (TiO₂) served as a photocatalyst in the ozonation of the TA with light-emitting diodes (LEDs), having a bandwidth centered at 452 nm. The modified catalyst (V_xO_y/TiO₂) in combination with ozone and LEDs improved the TA degradation and its by-products. The results obtained by this system were compared with photolysis, single ozonation, catalytic ozonation, and photocatalytic ozonation of V_xO_y/TiO₂ with UV lamp. The LED-based photocatalytic ozonation showed almost the same decomposition efficiency of the TA, but it was better in comparison with the use of UV lamp. The oxalic acid accumulation, as the final product of the TA decomposition, was directly influenced by either the presence of V_xO_y or/and the LED irradiation. Several by-products formed during the TA degradation, such as muconic, fumaric, and oxalic acids, were identified. Besides, two unidentified by-products were completely removed during the observed time (60 min). It was proposed that the TA elimination in the presence of V_xO_y/TiO₂ as catalyst was carried out by the combination of different mechanisms: molecular ozone reaction, indirect mechanism conducted by ·OH, and the surface complex formation.     

原位臭氧氧化污泥减量工艺的运行效能

采用ASBR/SBR原位臭氧污泥减量工艺,重点研究了原位臭氧氧化对SBR段污泥产率和出水水质的影响。两个相同的ASBR/SBR组合工艺同时运行,每隔3个周期向臭氧投加组SBR的曝气阶段原位间歇投加臭氧,臭氧投加量为0.027 g O3/g MLSS,连续运行40 d;对照组不投加臭氧作为对比。结果表明,原位臭氧氧化实现污泥减量约43.9%,臭氧投加组SBR段平均污泥产率系数为0.1447 g SS/g SCOD,而对照组为0.2580 g SS/g SCOD,投加组没有惰性污泥的累积,并且污泥沉淀性能得到改善。原位臭氧氧化对出水水质影响不大,投加组与对照组相比,臭氧投加3周期后的出水COD、NH4+-N、TN和TP平均值分别为47.8、0.76、14.1和6.4 mg/L,去除率分别下降了4%、2%、3%和7.7%,其中COD、NH4+-N和TN均能达到《城镇污水处理厂污染物排放标准》(GB18918-2002)一级A标准。     

Degradation of gas-phase propylene glycol monomethyl ether acetate by ultraviolet/ozone process: A kinetic study

A pilot-scale plug-flow reactor was built to investigate its performance in treating airborne propylene glycol monomethyl ether acetate (PGMEA) via ozonation, ultraviolet (UV) photolysis and UV/O3 technologies. Governing factors, such as the initial molar ratio of ozone (O3) to PG-MEA, UV volumetric electric power input, and moisture content in the influent airstream, were investigated. A 1-L batch reactor was used to investigate some photodegradation characteristics of PGMEA in advance. Experiments were conducted at a fixed influent PGMEA concentration of approximately 50 ppm and an ambient temperature of 26 degrees C. A gas space time of 85 sec in the plug-flow reactor was kept for either ozonation or photolysis reaction, whereas a gas space time of 170 sec was used for the UV/O3 degradation. Results show that an initial molar ratio of O3 to PGMEA of >2.91 and an UV volumetric electric input power of 0.294 W/L(-1) sufficed to obtain PGMEA decompositions of >90% by UV/O3. Kinetic analyses indicate that all types of PGMEA decomposition are pseudo-first order with respect to its concentration. Moisture content (relative humidity = 15-99%) and UV volumetric electric input power (0.147 and 0.294 W/L(-1)) were major factors that strongly affect the PGMEA degradation rate.