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Air Chem Systems has provided a solution for the treatment of solvent-contaminated water in California using composites and resins which provide solvent resistance to a water cleansing system.
When the San Gabriel Valley Water District (SGVWD) discovered solvent-contaminated water in the Baldwin Park-Covina area of Southern California, officials turned to U.S. Filter/Westates Carbon, of Santa Fe Springs, CA. to supply all the equipment for the stage 1 treatment system. U.S. Filter/Westates Carbon in turn came to Air Chem Systems to supply all the equipment prior to installation of the carbon units.
Air Chem’s solution is a stripper system that uses four composite towers, composite fans with sound enclosures, heaters and interconnecting duct dampers and stacks. The resin used to manufacture the composite towers is Vipel K022C, a flame-retardant bisphenol A epoxy vinyl ester from AOC.
Because of the resin’s resistance to solvents, it is also used for the ductwork, stacks, and fan blades of the water cleansing system at Congressman David Dreier Water Treatment Facility in Baldwin Park. In addition, the resin also meets specifications calling for a Class 1 flame and smoke rating per ASTM E 84. The rating is achieved with 1.5% antimony trioxide synergist.
“Composite made with Vipel K022C resin offers excellent corrosion resistance and will easily outlast aluminium, which SGVWD was previously specifying for this type of application,” says Bob Leisz, Sales Manager for Air Chem Systems. “The composite is also a much lower thermal conductor than aluminium, so it is easier to control the process.”
Leisz adds, “With Vipel K022C, we get very good processing characteristics for both filament winding and open moulding operations. When we need technical support, the AOC Corrosion Team is very helpful and responsive.”
1,1-DCE, 1,2-DCE benzene, toluene and other solvents in the region’s water supplies are attributed to waste discarded by aerospace companies before more stringent environmental standards were established. Funding for the clean-up is provided by the U.S. Environmental Protection Agency’s Superfund for reclaiming sites affected by hazardous waste.
The treatment process starts when 7,500 gallons (28,390 litres) of water per minute are recovered from six wells. Water coming into the main header is split into four streams, one for each of the four scrubbers. As the influent water is injected into the towers, a high speed, high capacity fan pulls fresh filtered air through the towers to strip out the solvents from the influent water. The contaminated fumes are then pushed into and through the carbon filters supplied by US Filter/Westates Carbon.
The solvent fumes are adsorbed by the carbon units and remaining contaminates in the effluent water are removed in a process that involves hydrogen peroxide and UV light. At the end of the system is potable water with no detectable amounts of contamination.
The cylindrical structure for each tower was filament wound of glass fibre roving impregnated with the Vipel K022C vinyl ester. Each tower is approximately 30 feet (9.1 meters) tall and 10 feet (1 meter) in diameter. To ensure superior corrosion resistance throughout the system, Vipel K022C was used with fibre glass mat to open mould tower end caps, air movement ductwork and fan blades.
“This San Gabriel Valley Water District plant is a showcase of how composites can help improve people’s lives,” comments Emilio Oramas, “To ensure the performance of these showcase projects, Vipel K022C has become the new-generation ‘work horse’ material for equipment that must resist highly corrosive conditions and require a Class 1 flame rating.”
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