原水氨氮含量对氯投加量的影响研究

通过对某水厂一段时期内原水氨氮含量及氯投加量进行调查研究,进一步讨论了原水氨氮含量对氯投加量的影响,并从工艺流程和氯的投加方式两方面对引起变化的原因进行了分析。

氯胺投加量及氯氮比对生成卤乙腈的影响

以两种原水中常见的含氮有机物酪氨酸和绿麦隆为前体物,研究了氯胺消毒时,氯胺投加量及氯氮比(Cl/N)的变化对消毒副产物卤乙腈(HANs)生成量的影响。结论表明:采用氯胺消毒时,HANs及其各组分含量随氯胺投加量的增大出现先增后减的变化趋势,当氯胺浓度为10 mg/L时HANs总量最大。在中性条件下,控制氯氮比(Cl/N)为4/1时HANs总量最大。结合不同条件下HANs的生成情况,应控制氯氮比在3/1~3.5/1内,以提高消毒效果。

Coagulation behavior of polyaluminum chloride: Effects of pH and coagulant dosage

Coagulation mechanisms of polyaluminum chloride(PACl) at various dosages were studied using a conventional jar test at different final and initial pH values during treating kaolin suspension. The optimal final pH and dosages for PACl were obtained based on residual turbidity and zeta potential of flocs. The coagulation zones at various PACl dosages and solution p H values were developed and compared with those of alum. It is found that the optimal mechanism under acidic condition is charge neutralization, while alkaline condition will facilitate the coagulation of PACl. Both charge neutralization coagulation and sweep coagulation can achieve high coagulation efficiency under the alkaline condition ranging from final p H 7.0 to 10.0. Stabilization, charge neutralization destabilization, restabilization and sweep zones occur successively with increasing PACl dosages with the final p H values fixed at 7.0 and 8.0, but restabilization zone disappears at final p H 10.0. When the final p H is not controlled and consequently decreases with increasing PACl dosage, no typical sweep zone can be observed and the coagulant efficiency decreases at high PACl dosage. It seems that the final pH is more meaningful than the initial p H for coagulation. Charge neutralization coagulation efficiency is dominated by zeta potential of flocs and PACl precipitates. The charge neutralization and sweep coagulation zones of PACl are broader in the ranges of coagulant dosage and p H than those of alum. The results are helpful for us to treat water and wastewater using PACl and to understand the coagulation process of PACl.

LED-紫外线/氯高级氧化降解苯妥英钠特性

发光二极管(light emitting diode,LED)作为新型紫外线光源,其与活性氯联用的LED-紫外线/氯高级氧化技术可协同高效降解抗惊厥药微量污染物苯妥英钠(phenytoin sodium,PHT)。LED-紫外线剂量为0. 82 J/cm2时,LED-紫外线/氯高级氧化对水中的PHT去除率到62%,远高于单独氯化和单独LED-紫外线处理的加和。降解动力学研究发现:LED-紫外线/氯高级氧化降解PHT符合准一级反应动力学。280 nm LED作为光源的LED-紫外线/氯相比310 nm LED-紫外线/氯有更好的PHT去除效果。与LED-紫外线/H2O2和LED-紫外线/过硫酸盐相比,氧化剂(氯、H2O2和过硫酸盐)浓度为0. 282 mmol/L时,LED-紫外线/氯高级氧化降解PHT的准一级反应动力学常数(0. 096 min-1)远高于LED-紫外线/H2O2和LED-紫外线/过硫酸盐,分别是其3. 7倍和3. 0倍。优化氯投加量发现,LED-紫外线/氯高级氧化在较低氯投加量(10 mg/L)条件下即可高效降解PHT。对PHT毒性变化研究发现,氯化作用降解PHT过程中,可生成具有急性毒性的中间产物,且持续累积。LED-紫外线/氯高级氧化降解PHT在较低紫外线剂量(0. 08 J/cm2)下生成了具有急性毒性的中间产物,随着紫外线剂量增加至0. 41 J/cm2,毒性中间产物被有效去除。

以管壁生物膜为前体物的DBPs生成特性和毒性评估

针对球墨铸铁管、钢管和聚乙烯(PE)管3种常见给水管材,探究管壁生物膜在氯化作用下生成典型含碳消毒副产物(C-DBPs)和含氮消毒副产物(N-DBPs)的潜能,考察消毒剂投加量对消毒副产物(DBPs)产生的影响,进一步评估管壁生物膜作为DBPs前体物潜在的毒理学危害。结果表明,与主体水相比,管壁生物膜的DBPs生成潜能(DBPFP)更具优势。氯投加量对不同管材生物膜生成C-DBPs和N-DBPs的影响规律有所区别。随着投氯量的增加,三卤甲烷(THMs)和卤乙酸(HAAs)生成量均持续增大;球墨铸铁管生物膜的N-DBPs生成量先增大后减小;钢管和PE管生物膜的二氯乙腈(DCAN)和二氯乙酰胺(DCAcAm)生成量呈现先上升后下降的趋势,三氯硝基甲烷(TCNM)生成量保持增大的趋势。毒性评估结果表明,在较高投氯量下,生物膜的毒性生成潜能更高;但持续增加投氯量,毒性生成潜能有所下降或增势减缓。相比C-DBPs,N-DBPs在生物膜毒性生成潜能上占据更高贡献率,降低生物膜细胞毒性风险的关键是控制DCAN和HAAs,规避遗传毒性风险的核心是防控TCNM的生成。