Many municipal and industrial wastewater producers have constant challenges meeting heavy metals limits set by the EPA in drinking water consumed by public communities. Furthermore, chemical manufacturers and agricultural industries discharge harmful chemicals like microplastics and polyfluoroalkyl hydrocarbons (PFA’s), are common organic pollutants found in public drinking water reservoirs. Recent research studies show that microplastic and PFA waste pollutants may cause long-term health related issues such as prostate cancer, liver, and kidney diseases.
Current EPA mandatory action levels for lead and arsenic in drinking water is 15 ppb and 10 ppb, respectively. In spite of these EPA mandates, there are still many municipalities around the country whose drinking water supply exceeds EPA action limits for heavy metals. Under the new EPA Safe Water Drinking Act (2023), target goals for lead and arsenic levels in drinking water will be 0 ppb and 3 ppb, respectively. These new limits are necessary because lead and arsenic are toxic metals that can accumulate over time in the human body and there is no known safe limit that humans can tolerate without the possibility of long-term harmful biological effects.
Most municipal water treating systems rely on standard industrial coagulation, sedimentation, filtration, and bio remediation technologies to purify process waters that may be used for human consumption or as effluent discharge back into the natural environment. Process purification and separation systems are used for a variety of applications, such as protecting down stream equipment, treatment or recycling of brine streams,removal of contaminants, concentration of products, recovery of valuable by-products, product purification and potable water generation, among other uses. The costs of water purification/separation systems range in varying costs depending upon the flow rates as needed. Conventional purification/separation process system uses some combination micro-filtration, ultra-filtration, reverse osmosis, and ion-exchange resin technology. Although the use of these purification/separation water treating technologies are effective in removing bacteria, amines, chlorine, and chloramines down below EPA target levels, such treatment methods are not sufficiently effective for the reduction of heavy metals, microplastics, and PFAH’s below EPA action levels. Many heavy metals can be found in natural waters in the form of inorganic metal compounds like organic lead compounds. Some metal-inorganic and metal-organic compounds are highly soluble in water and thus it is difficult for water purification systems producers to meet EPA target limits.
Unlike conventional water and wastewater treating processes, SIE Technologies LLC utilizes its PUCFP-CDS method and process to make water safe for human consumption or as desirable discharge effluents back into the natural environment. The SIE Technologies LLC PUCFP-CDS technology is a network of innovative separation technologies that will produce potable drinking water that meets or exceeds current and future EPA target goals for heavy metals, harmful organics, and perfluoroalkyls hydrocarbons in drinking water.
The SIE Technologies LLC innovation technology and process is capable of removing harmful inorganic heavy metals such as but not limited to mercury, lead, cobalt, cadmium,vanadium, chromium, mercury, and arsenic all which have been found at different levels to be present-in industrial wastewater discharge and in many cases even public drinking water reservoirs, often times at concentration levels that have been determined to be significantly dangerous to health of the public if consumed. The PUCFP-CDS technology will help municipalities and industrial wastewater producers to meet the new EPA target goals for toxic metal levels for drinking water or wastewater discharge.
The SIE Technologies LLC PUCFP-CDS technology and process is capable of removing harmful organic substances from water streams and other water resources (ponds, lakes, streams, rivers, etc. Organic pollutants such as benzene, acrylamides, chlorobenzene, dichloroethylene, chloramines, chlorine, chlorine dioxide,dioxin, di(ethyl-hexyl) phthalate, ethylene dibromide, perfluoroalkyl hydrocarbons, microplastics, as well as ammonia, nitrates, sulfates, total dissolves solids, and microorganisms
SIE Technologies LLC: We Green Thumb Innovation
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