二氧化氯催化氧化处理直接大红染料

研究了ClO2化学氧化体系和ClO2催化氧化体系。实验结果表明:单用ClO2化学氧化处理COD为3 400mg/L的直接大红染料配制废水时,最佳反应pH值为1,氧化剂ClO2经济用量为400 mg/L废水,反应时间为10 min,COD去除率可达85.9%,氧化指数(COD削减量∶ClO2投加量)=7。当ClO2与自制催化剂所组成的催化氧化体系用于对直接大红染料配制废水的处理时,最佳反应pH值为2左右,氧化剂ClO2经济用量为600 mg/L废水,反应时间为6 min,COD去除率可达96.6%,氧化指数=6。结果表明,ClO2催化氧化法是一种新型高效的处理难降解废水的技术,有着广阔的应用前景。     

Na_2CO_3/H_2O_2“稳定”的CO_2的型体研究(Ⅱ)——“稳定性二氧化氯”溶液的UV吸收光谱、纸层析特性、微观结构和离子色谱分析

本文对以稳定剂H_2O_2和Na_2CO_3与ClO_2制备的所谓"稳定性二氧化氯"溶液的UV吸收光谱、纸层析特性、微观结构及离子色谱进行了分析,并与纯NaClO_2及ClO_2溶液做了对比.结果表明,“稳定性二氧化氯” 与NaClO_2在UV吸收光谱、层析比移值、微观结构、离子色谱这几方面都具有很好或极其相似的一致性 表明“稳定性二氧化氮’与NaClO_2溶液中氯氧化物存在型体的一致性.因此,认为“稳定性二氧化氯“溶液中ClO_2是以亚氯酸盐ClO_2~-的型体存在的.     

罗丹明染料荧光猝灭法分别测定痕量二氧化氯和亚氯酸根

在碱性条件下,ClO2氧化罗丹明染料发生荧光猝灭可选择性地测定ClO2的含量,而ClO2-不干扰测定;在酸性条件下可测量ClO2与ClO2-共同产生的荧光猝灭强度,利用差减法可求出ClO2-的含量.对于罗丹明S,罗丹明G,罗丹明B及丁基罗丹明B四体系,ClO2浓度分别在0.00840-0.53μg·ml-1,0.0930-3.15μg·ml-1,0.215-2.610μg·ml-1及0.0825-1.096μg·ml-1范围内,与四体系的荧光猝灭强度呈线性关系;亚氯酸根浓度分别在0.00950-0.711μg·ml-1,0.0940-2.36μg·ml-1,0.473-4.73μg·ml-1及0.473-2.36μg·ml-1范围内,与四体系的荧光猝灭强度呈线性关系.另外,选择罗丹明S荧光猝灭法分别测定了饮用水中ClO2及ClO2-,获得了满意的结果.     

二氧化氯消毒前后污水毒性的变化及消毒条件的影响

采用发光细菌试验和umu试验,分别考察了二氧化氯投加量和反应时间对污水二氧化氯消毒后急性毒性和遗传毒性变化的影响.结果表明,随着二氧化氯消毒剂投加量的增加,消毒后水样的急性毒性不断增大,但遗传毒性逐渐减小后趋于稳定.随着反应时间的延长,二氧化氯的消耗量不断增大,消毒后水样的急性毒性先增大后减小,遗传毒性逐渐减小后趋于稳定.由于消毒条件对污水急性毒性和遗传毒性有着不同的影响,说明污水中产生急性毒性和产生遗传毒性的物质不同,对于某一种污水,通过控制消毒条件可以使消毒后污水的急性毒性和遗传毒性都较低.     

大亚湾核电站余氯排放对邻近海域环境的影响

对大亚湾核电站冷却水排放口及邻近海域海水中余氯污染状况进行了调查，结果表明：余氯的含量为〈０．０１～０．０４ｍｇ．Ｌ＾－１，各季节平均水平为０．０１～０．０２ｍｇ．Ｌ＾－１，冬季较高。余氯在海水中的形态为化合态。选择若干养殖经济动物进行了余氯毒性胁迫试验。以０．５为安全因子，余氯胁迫作用时间不超过３０ｍｉｎ时，游离斜 氯对平鲷、黑鲷仔鱼的安全容许浓度约为０．１０ｍｇ．Ｌ＾－１，对斑节对虾幼苗为０．     

二氧化氯销毁氰化物的应用研究

在弱碱性条件下,二氧化氯消毒剂将氰化物氧化成无毒的氰酸盐(OCN-)、二氧化碳和氮气.研究了影响二氧化氯销毁氰化物的几种因素:pH在8～11的范围内,不影响二氧化氯对氰化物的销毁率;在所试验的反应温度(0～40℃)内,温度对反应速率表现出有限的影响;二氧化氯与氰离子的最佳质量比为2:1;当氰离子最高使用浓度小于0.5 g/L时,废水中氰离子浓度达一级以上的排放标准.     

二氧化氯的发生技术

本文对国内外ＣｌＯ２的发生技术进行了综合评述，详尽地介绍了作者自行研制的ＣｌＯ２发生技术和装置，认为我国推广应用ＣｌＯ２消毒处理饮用水的时机已经成熟。     

Acute and Chronic Toxicity of Chlorine Dioxide (ClO2) and Chlorite (ClO2ˉ) to Rainbow Trout (Oncorhynchus mykiss) (4 pp)

Goal, Scope and Background Chlorite (ClO2ˉ) is a primary decomposition product when chlorine dioxide (ClO2) is added during water treatment; therefore the toxic effects of both compounds on aquatic organisms are possible. Limited data are available concerning their toxicity to fish. The aim of this study was to investigate sensitivity of rainbow trout to acute and chronic toxicity of chlorine dioxide and chlorite, and to estimate the Maximum-Acceptable-Toxicant-Concentration (MATC) of those compounds in fish. Methods The acute and chronic toxicity of chlorine dioxide and chlorite to larval and adult rainbow trout was investigated in 96-hour to 20-day laboratory exposures evaluating the wide range spectrum of biological indices under semi-static conditions. Results and Discussion Median lethal concentration (96-hour LC50) values derived from the tests were: 2.2 mg/l for larvae; 8.3 mg/l for adult fish and 20-day LC50 for larvae was 1.6 mg/l of chlorine dioxide, respectively. Chlorite was found to be from 48 to 18 times less acutely toxic to larvae and adult fish, correspondingly. Both chemical compounds induced similar toxic effects in rainbow trout larvae during chronic tests (they affected cardio-respiratory and growth parameters), but chlorine dioxide had a higher toxic potency than chlorite. A significant decrease in the heart rate and respiration frequency of larvae was established. However, within an increase in exposure duration recovery of cardio-respiratory responses was seen to have occurred in larvae exposed to chlorite. Meanwhile, in larvae exposed to chlorine dioxide, a significant decrease in cardio-respiratory responses remained during all 20-day chronic bioassays. Chlorine dioxide also more strongly affected growth parameters of rainbow trout larvae at much lower test concentrations. Decreased rate of yolk-sack resorption occurred only in the tests with chlorine dioxide. Conclusions Maximum-Acceptable-Toxicant-Concentration (MATC) of 0.21 mg/l for chlorine dioxide and of 3.3 mg/l for chlorite to fish was derived from chronic tests based on the most sensitive parameter of rainbow trout larvae (growth rate). According to substance toxicity classification accepted for Lithuanian inland waters, chlorine dioxide and chlorite can be referred to substances of \moderate\ toxicity to fish. Recommendations and Outlook Due to its very reactive nature, chlorine dioxide is rapidly (in a few hours) reduced to chlorite, which is persistent also as a biocide but 16 times less toxic to fish, according to MATC. Therefore, it is much more likely that fish will be exposed to chlorite than to chlorine dioxide in natural waters. Presently accepted, the Maximum-Permitted-Concentration of total residual chlorine (TRC) in waste-water discharging into receiving waters is 0.6 mg/l. If this requirement will not be exceeded, it is unlikely that fish would be exposed to lethal or even to sublethal concentrations of chlorine dioxide or chlorite. Furthermore, chlorine dioxide does not generate toxic nitrogenous (chloramines) or carcinogenic organic residuals (trihalomethanes). All these properties make chlorine dioxide a more promising biocide than chlorine.     

ClO2杀灭拟柱孢藻过程中毒素释放行为与释放机理

试验考察了二氧化氯(ClO_2)杀灭拟柱孢藻过程中不同条件下柱孢藻毒素(CYN)随时间的释放规律,对释放量与时间数据进行曲线方程拟合,并以透射电镜观察不同反应时间拟柱孢藻细胞形态,对柱孢藻毒素的释放机理进行分析。结果表明,反应初期5 min内CYN释放率随时间延长快速提高,随后增长缓慢,30 min后趋于稳定。ClO_2投加量影响了CYN释放速率,1.0 mg/L ClO_2投加量时CYN释放率要高于0.5 mg/L和0.7 mg/L时,但在反应2 h后不同ClO_2投加量的CYN释放率趋于接近。拟柱孢藻初始浓度对CYN释放率的影响不明显。CYN释放率在酸性条件下高于中性和碱性条件。随反应温度升高,CYN释放率逐渐升高。各种反应条件下CYN释放量与反应时间的关系可以用曲线方程来表示。藻细胞形态随反应时间延长发生变化。ClO_2投加量增大,藻细胞结构的破坏程度加剧。在反应初期CYN释放是通过扩散作用而并非由细胞壁的破裂而致。     

umu试验研究饮用水氯和氯胺消毒过程中遗传毒性的变化以及消毒条件的影响

采用umu遗传毒性测试方法考察了消毒剂投加量、反应时间和消毒剂氯氮比对某饮用水厂臭氧-生物活性炭出水加氯或氯胺消毒前后遗传毒性的影响.结果表明,炭后水具有一定的遗传毒性(20～70 ng/L),加氯或氯胺消毒后遗传毒性增加.反应时间为24 h,在相同投加量下氯消毒遗传毒性(40～95 ng/L)高于氯胺消毒遗传毒性(20～40 ng/L);当氯初始投加量从0 mg/L增加到10 mg/L时,炭后水的遗传毒性先迅速增加,在0.5～1 mg左右达到极大值,然后再降低,在3～5 mg左右达到极小值后缓慢上升,但是氯胺消毒后水样遗传毒性变化规律不如氯消毒的明显.当投加量为3 mg/L时,随着反应时间从0 h延长至72 h,无论是氯消毒还是氯胺消毒,炭后水遗传毒性均是先迅速增加,在2 h时达到极大值后再下降,在18 h左右达到极小值然后缓慢上升,而且任意反应时间内,氯胺消毒的遗传毒性(20～62 ng/L)均小于氯消毒(83～120 ng/L).本试验还研究了消毒剂氯氮比对炭后水氯消毒后遗传毒性的影响.在本试验条件下,从遗传毒性的角度看,对于饮用水消毒氯胺比氯更安全,而且2种消毒方式的遗传毒性的变化规律均不同于总HAAs的变化规律.