Secondary effects of anion exchange on chloride, sulfate, and lead release: Systems approach to corrosion control

Water treatment processes can cause secondary changes in water chemistry that alter finished water quality including chloride, sulfate, natural organic matter (NOM), and metal release. Hence, the goal of this research was to provide an improved understanding of the chloride-to-sulfate mass ratio (CSMR) with regards to chloride and sulfate variations at full-scale water treatment plants and corrosion potential under simulated premise plumbing conditions. Laboratory corrosion studies were conducted using Pb–Sn solder/Cu tubing galvanic cells exposed to model waters with low (approx. 5 mg/L Cl− and 10 mg/L SO42–) and high (approx. 50 mg/L Cl− and 100 mg/L SO42–) concentrations of chloride and sulfate at a constant CSMR of ∼0.5. The role of NOM during corrosion was also evaluated by changing the type of organic material. In addition, full-scale sampling was conducted to quantify the raw water variability of chloride, sulfate, and NOM concentrations and the changes to these parameters from magnetic ion exchange treatment. Test conditions with higher concentrations of chloride and sulfate released significantly more lead than the lower chloride and sulfate test waters. In addition, the source of NOM was a key factor in the amount of lead released with the model organic compounds yielding significantly less lead release than aquatic NOM.

Figure optionsDownload high-quality image (225 K)Download as PowerPoint slideHighlights
► Effect of concentrations at constant CSMR investigated.
► Higher absolute concentrations of chloride and sulfate yielded greater lead release.
► Presence and type of organic matter impacted lead and copper release.
► MIEX treatment increased chloride, decreased sulfate, and increased the CSMR.
► Systems framework needed to address and understand all aspects of corrosion control.