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首页> 外文期刊>Environmental Science & Technology >DBP Formation in Hot and Cold Water Across a Simulated Distribution System: Effect of Incubation Time, Heating Time, pH, Chlorine Dose, and Incubation Temperature
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DBP Formation in Hot and Cold Water Across a Simulated Distribution System: Effect of Incubation Time, Heating Time, pH, Chlorine Dose, and Incubation Temperature

机译:整个模拟分配系统中冷热水中DBP的形成:温育时间,加热时间,pH,氯剂量和温育温度的影响

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摘要

This paper demonstrates that disinfection byproducts (DBP) concentration profiles in heated water were quite different from the DBP concentrations in the cold tap water. Chloroform concentrations in the heated water remained constant or even decreased slightly with increasing distribution system water age. The amount of dichloroacetic acid (DCAA) was much higher in the heated water than in the cold water; however, the maximum levels in heated water with different distribution system water ages did not differ substantially. The levels of trichloroacetic acid (TCAA) in the heated water were similar to the TCAA levels in the tap water, and a slight reduction was observed after the tap water was heated for 24 h. Regardless of water age, significant reductions of nonregulated DBPs were observed after the tap water was heated for 24 h. For tap water with lower water ages, there were significant increases in dichloroacetonitrile (DCAN), chloropicrin (CP), and 1,1-dichloropropane (1,1-DCP) after a short period of heating. Heating of the tap water with low pH led to a more significant increase of chloroform and a more significant short-term increase of DCAN. High pH accelerated the loss of the nonregulated DBPs in the heated water. The results indicated that as the chlorine doses increased, levels of chloroform and DCAA in the heated water increased significantly. However, for TCAA, the thermally induced increase in concentration was only notable for the chlorinated water with very high chlorine dose. Finally, heating may lead to higher DBP concentrations in chlorinated water with lower distribution system temperatures.
机译:本文证明,热水中消毒副产物(DBP)的浓度曲线与冷自来水中的DBP浓度有很大差异。随着分配系统水龄的增加,热水中的氯仿浓度保持恒定,甚至略有下降。热水中的二氯乙酸(DCAA)的量比冷水中的高得多。但是,在不同的分配系统水龄下,热水的最高含量没有显着差异。热水中的三氯乙酸(TCAA)含量与自来水中的TCAA含量相似,自来水加热24小时后观察到略有降低。无论水龄如何,自来水加热24小时后,未调节的DBP均显着减少。对于具有较低水龄的自来水,在短时间加热后,二氯乙腈(DCAN),氯吡啶(CP)和1,1-二氯丙烷(1,1-DCP)显着增加。低pH值的自来水的加热导致氯仿的显着增加和DCAN的短期显着增加。高pH值加速了热水中非调节DBP的损失。结果表明,随着氯剂量的增加,热水中的氯仿和DCAA含量显着增加。但是,对于TCAA,热诱导浓度的增加仅对于氯剂量非常高的氯化水才显着。最后,加热可能导致氯化钠水中的DBP浓度较高,而分配系统的温度较低。

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  • 来源
    《Environmental Science & Technology》 |2013年第20期|11584-11591|共8页
  • 作者

    Boning Liu; David A. Reckhow;

  • 作者单位

    Department of Civil and Environmental Engineering, University of Massachusetts, Amherst, Massachusetts 01003, United States;

    Department of Civil and Environmental Engineering, University of Massachusetts, Amherst, Massachusetts 01003, United States;

  • 收录信息 美国《科学引文索引》(SCI);美国《工程索引》(EI);美国《生物学医学文摘》(MEDLINE);美国《化学文摘》(CA);
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