DRINKING WATER TREATMENT RESOURCES
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Small municipalities and industrial sites face constant pressure: deliver safe, stable water with limited resources and tight deadlines. Traditional on-site construction can stretch project schedules by months and introduce quality and cost risks. By shifting much of the fabrication off-site, these risks are dramatically reduced.
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Ion exchange resin is a reliable, high-capacity solution for municipal PFAS treatment, demonstrating zero detectable PFAS after processing 82 million gallons of water. The technology offers a significantly smaller footprint and superior volumetric capacity compared to GAC. Read the full case study to review performance data and strategic impacts.
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Real-time sensing is replacing traditional sampling to deliver essential water quality insights. Overcoming challenges like sensor biofouling and data management is the critical next step in ensuring future water resource protection.
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Meeting modern water reuse goals requires moving past legacy disinfection. Advances in UV technology now provide chemical-free, reliable pathogen inactivation for even high-flow, open-channel tertiary treatment.
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How Edison vs. Tesla shapes today's approach to sustainable water systems.
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Ozone is a vital pre-treatment for PFAS mitigation. It oxidizes precursors and co-contaminants, significantly extending the service life of downstream GAC and membrane systems.
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Nanobubble physics enable higher ozone stability and mass transfer efficiency in water. Discover how the negative surface charge of these microstructures improves localized oxidation and penetration into difficult matrices.
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Ozone and UV-AOP each offer powerful contaminant removal for drinking water, wastewater, and reuse applications. Their unique strengths—and potential synergy—help utilities meet diverse treatment goals efficiently.