吸附增效低温等离子体法去除甲苯废气的研究

采用150Hz中频高压交流电源作为低温等离子体发生源,选用典型的微孔γ-Al2O3球形颗粒吸附剂(以下简称γ-Al2O3)作为等离子体反应器填充材料,协同低温等离子体法催化降解甲苯废气。考察了在不同条件下,γ-Al2O3的甲苯吸脱附效果和吸附增效低温等离子体法的甲苯去除效果。结果表明,甲苯降解反应主要发生在γ-Al2O3的表面,甲苯的去除率在一定的浓度范围内与γ-Al2O3表面吸附的甲苯量成正比关系;填充γ-Al2O3有利于提高甲苯去除率及等离子体反应器能量利用率;γ-Al2O3对臭氧的降解表现出一定的促进作用。     

零价铁复合有机膨润土处理染料废水的研究

针对目前印染废水处理现状及膨润土在水处理中回收困难等问题，提出将零价铁复合到有机膨润土中制成零价铁复合有机膨润土(ZVI-OB)，以达到高效吸附并降解污染物的目的。以染料废水(Orange II) 作为研究对象，考察了废水中染料的初始浓度、pH以及吸附时间对ZVI-OB去除染料效率的影响，并研究了吸附后降解过程中时间和pH对污染物降解的影响以及降解前后膨润土层结构的变化。研究结果表明，ZVI-OB相对于CTMAB改性的有机膨润土而言，其吸附量有所降低，但ZVI-OB在吸附污染物之后能有效降解有机物。ZVI-OB在饱和吸附Orange II后经催化氧化，总有机碳含量降低为原来的19%，可以重复利用。     

树脂固载纳米铁对偶氮染料直接湖蓝5B的脱色性能研究

以FeSO4和NaBH4水溶液为前驱溶剂,以聚苯乙烯型阳离子交换树脂为载体,制备了树脂固载的纳米铁,室温下用于对偶氮染料直接湖蓝5B水溶液进行脱色研究。研究结果发现,脱色反应遵循准一级反应动力学,在初始pH为3~10的范围内,反应进行14 m in时,50 mg/L的染料溶液脱色率均能达到83%以上。固载的纳米铁材料可多次重复利用,溶液中释放的铁离子浓度不超过0.1 mg/L。     

废弃轮胎制备中孔炭吸附材料工艺及性能研究

为了解决废弃轮胎造成的资源浪费和环境污染的问题,对以废弃轮胎橡胶为碳的前驱体原料,制备具有高吸附性能中孔炭材料工艺进行了系统的研究。通过XRD、扫描电镜以及比表面积分析,对制备的中孔炭微观结构和性能进行表征,讨论了炭化温度、碱炭比,以及活化温度和活化时间等工艺条件对制备中孔炭的产率、结构和性能的影响。结果表明,通过改变工艺条件制备的中孔炭的孔径分布可以在2~80 nm范围内进行调控。在500℃炭化温度,碱炭比为4∶1,900℃活化1 h的工艺条件下,制备的中孔炭的比表面积为473 m2/g,对甲基橙的最大吸附量达到254 mg/g。     

超声-Fenton高级氧化降解染料工业废水的研究

采用超声与Fenton高级氧化技术联合处理染料废水,取得了满意的效果。同时考察了初始浓度、初始pH值、超声时间、超声频率、超声功率、H2O2和FeSO4初始浓度等因素对其COD去除效果的影响,当超声波频率为45 kHz,功率为200 W,初始pH值为2.63,超声时间为150 min,H2O2浓度为60 mmol/L,FeSO4浓度为12 mmol/L时,染料废水COD去除率达到91.8%。     

高压脉冲放电等离子体处理活性红X-3B染料废水

采用高压脉冲放电等离子体技术对活性红X-3B染料废水进行处理,考察了废水电导率、脉冲电压、脉冲频率、针板间距以及曝气量对处理效果的影响。实验结果表明,当废水电导率为200μS/cm、脉冲电压为34kV、脉冲频率为60Hz、针板间距为15mm、曝气量为12L/h、处理时间为60m in时,活性红X-3B染料废水脱色率能达到98.6%。     

ACF电极电解处理含NaCl结晶紫染料废水的研究

以吸附结晶紫达到饱和的活性炭纤维为阳极,在NaCl介质中对初始浓度为100 mg/L的结晶紫染料废水进行了电解脱色处理。实验考察了NaCl浓度、pH值和电流密度等对溶液脱色率的影响,测定了电解时溶液中生成的游离氯浓度及不同电解时间后溶液的紫外-可见吸收光谱曲线,并对不同电解时间后溶液的归一化吸光度比值进行了计算。结果发现,溶液中所产生的游离氯的浓度随电解时间的增加快速上升,20 min时就几乎达到了最大值;在活性氯的作用下,结晶紫分子中的大π共轭体系被破坏,溶液迅速脱色;电解液中所含的NaCl浓度、电解液的pH值和电流密度等都对脱色率有影响;在一定实验条件下,初始浓度为100 mg/L的结晶紫染料废水在电解60 min后脱色率可高达99.3%。     

粉煤灰负载铁离子催化氧化活性黄染料废水

以粉煤灰为载体,制备铁/粉煤灰负载型催化剂,并利用该催化剂催化H2O2氧化降解活性黄染料废水,探讨了H2O2投加量、催化剂投加量、染料初始浓度和初始pH值等因素对染料废水COD去除率和脱色率的影响。结果表明,当染料废水COD初始浓度为200 mg/L,初始pH值为1.7,投加0.5 g/100 mL催化剂及加入1.0 mL浓度为1.13 mol/L的H2O2溶液时,处理效果最好,此时染料废水的COD去除率和脱色率分别达到63%和99%,并且废水的可生化性得到很大的提高。利用该负载催化剂能够有效地减少活性黄染料废水中Fe3+的残留量。     

UASB反应器降解活性染料废水的特性

中温（35±1）℃条件下，采用上流式厌氧污泥床（upflowanaerobicsludgebed，简称UASB）反应器处理了含蒽醌类-活性艳蓝（c．I．ReactiveBlue5，简称K—GR）或偶氮类-活性艳红（C．I．ReactiveRed20，简称KD-8B；C．I．ReactiveRed2，简称X-3B）模拟染料废水，重点研究了回流比对染料脱色率和COD去除率的影响，在最佳回流比的条件下，探讨HRT（hydraulicretentiontime）对脱色的影响和不同结构染料的脱色效果，并初步分析了脱色机理。结果表明，适宜的回流比有利于提高系统的脱色率；控制回流比和HRT分别为2和24h，当模拟废水中染料的浓度为100mg／L时，COD去除率和脱色率分别为90％～96％和85％～92％；蒽醌和偶氮类染料的脱色是通过偶氮键和葸醌共轭结构的断裂来实现的。     

Effect of tracer dyes on initial deposits and persistence of bacillus thuringiensis subsp. kurstaki toxin after application of two commercial formulations onto spruce trees

Abstract

The effect of two tracer dyes [Erio Acid Red (EAR) and Acid Black 48 (AB‐48)] on initial deposits and persistence of Bacillus thuringiensis subsp. kurstaki (Btk) toxin (delta‐endotoxin) was studied after spraying two commercial formulations, Foray® 48B and Foray® 76B, over potted white spruce [Picea glauca (Moench) Voss] seedlings, at a dosage rate of 30 billion international units (BIU) per ha. Spray was applied using a spinning disc atomizer calibrated to deliver droplet sizes similar to those utilized in ultra‐low‐volume (ULV) treatments in operational insect control programs. The sprayed seedlings were left outdoors at the Sault Ste. Marie laboratory for 18 days under natural conditions of sunlight, wind and rainfall. Initial deposits and persistence of delta‐endotoxin protein in spruce foliage were determined by immunoassay [enzyme linked immunosorbent assay (ELISA)] quantification of the delta‐endotoxin. The total protein (inactive plus active) and delta‐endotoxin (active protein) concentrations in the two formulations were determined by a gravimetric procedure and by ELISA respectively.

The initial deposit levels of the toxin on foliage were not markedly affected by the addition of either of the two tracer dyes, and showed only a narrow range of 1521 to 1625 ng/g foliage (fresh weight) for Foray 48B, and 1789 to 2056 ng/g for Foray 76B. However, the persistence of the toxin was significantly influenced by the presence of the dyes. The toxin persisted in foliage only for 7 d post‐spray When the EAR dye was added to Foray 48B, compared to 10 d when no dye was added. The average half‐life (DT₅₀) of disappearance was 17.4 h for Foray 48B with EAR, and 20.9 h when no dye was present. In contrast, the situation was reversed in Foray 76B, since the duration of persistence was 10 d when EAR was added to Foray 76B, compared to 7 d when no dye was added. The average DT₅₀ was 27.9 h for Foray 76B with EAR, and 22.2 h without the dye. Persistence was the longest (14 d) when the AB‐48 dye was added to Foray 76B, and the DT₅₀ was 44.9 h.