Boccelli Dominic L, Tryby Michael E, Uber James G, Summers R Scott
Department of Civil and Environmental Engineering, Carnegie Mellon University, Porter Hall 119, Pittsburgh, PA 15213, USA.
Water Res. 2003 Jun;37(11):2654-66. doi: 10.1016/S0043-1354(03)00067-8.
Chlorine is typically used within drinking water distribution systems to maintain a disinfectant residual and minimize biological regrowth. Typical distribution system models describe the loss of disinfectant due to reactions within the water matrix as first order with respect to chlorine concentration, with the reactants in excess. Recent work, however, has investigated relatively simple dynamic models that include a second, hypothetical reactive species. This work extends these latter models to account for discontinuities associated with rechlorination events, such as those caused by booster chlorination and by mixing at distribution system junction nodes. Mathematical arguments show that the reactive species model will always represent chlorine decay better than, or as well as, a first-order model, under single dose or rechlorination conditions; this result is confirmed by experiments on five different natural waters, and is further shown that the reactive species model can be significantly better under some rechlorination conditions. Trihalomethane (THM) formation was also monitored, and results show that a linear relationship between total THM (TTHM) formation and chlorine demand is appropriate under both single dose and rechlorination conditions. This linear relationship was estimated using the modeled chlorine demand from a calibrated reactive species model, and using the measured chlorine demand, both of which adequately represented the TTHM formation.
在饮用水分配系统中,通常使用氯来维持消毒剂余量并尽量减少生物再生长。典型的分配系统模型将由于水基质中的反应导致的消毒剂损失描述为相对于氯浓度呈一级反应,反应物过量。然而,最近的研究探讨了相对简单的动态模型,该模型包含第二种假设的反应性物质。这项工作扩展了后一种模型,以考虑与再氯化事件相关的不连续性,例如由增压氯化和分配系统节点处的混合所引起的不连续性。数学论证表明,在单剂量或再氯化条件下,反应性物质模型总是比一级模型能更好地或同样好地表示氯的衰减;这一结果在对五种不同天然水的实验中得到了证实,并且进一步表明,在某些再氯化条件下,反应性物质模型可能会明显更好。还监测了三卤甲烷(THM)的形成,结果表明,在单剂量和再氯化条件下,总三卤甲烷(TTHM)形成与氯需求之间的线性关系都是合适的。这种线性关系是使用来自校准的反应性物质模型的模拟氯需求以及使用测量的氯需求来估计的,这两者都充分代表了TTHM的形成。