Effects of phosphate-based corrosion inhibitors on disinfectant stability and HAA/NDMA formation when in contact with copper, iron and lead .

摘要

This research examined the impacts of water quality, phosphate-based corrosion inhibitors and pipe wall exposure on free chlorine (HOCl)/chloramine (NH2Cl) degradation and haloacetic acid (HAA)/ N-nitrosodimethylamine (NDMA) formation in simulated distribution system water mains and household plumbing at bench-scale and pilot scale.;In bench-scale bottle tests, the reactivity of fresh/pre-corroded pipe materials with HOCl/NH2Cl in decreasing order was: ductile iron, copper, lead. The addition of phosphate-based corrosion inhibitors generally increased HOCl/NH2Cl degradation for fresh iron coupons, but decreased HOCl/NH2Cl decay only for fresh copper coupons. Generally, these corrosion inhibitors did not impact HAA formation.;Copper corrosion products, including Cu(II), Cu2O, CuO and Cu2(OH)2CO3, catalyzed HAA and NDMA formation. For HAAs, copper catalysis increased with increasing pH from 6.6 to 8.6 and/or increasing concentrations of these copper corrosion products. Interactions of copper with natural organic matter (NOM), likely by complexation, and the subsequent increase in the reactivity of NOM were proposed to be the primary reason for the increased HAA formation. NDMA formation increased with increasing Cu(II) concentrations, DMA concentrations, alkalinity and hardness but was inhibited by the presence of NOM. The transformation of NH2Cl to dichloramine (NHCl2) and complexation of copper with DMA were proposed to be involved in elevating the formation of NDMA at pH 7.0.;Finally, in pilot-scale modified pipe loop tests, copper catalysis of NDMA formation was confirmed, especially under laminar flow conditions, and iron was shown to possibly catalyze NDMA formation under turbulent conditions. Orthophosphate increased the catalytic effects of iron but decreased copper catalysis on NDMA formation by either modifying the properties of the iron-associated suspended particles or reducing the dissolved metal concentrations. Orthophosphate increased chloramine decay when in contact with iron, likely by promoting nitrite formation, but orthophosphate decreased chloramine decay for copper and lead by reducing the availability of metal corrosion products.