TY - PAT
T1 - Chlorine Resistant Permeable Impermeable Nanocomposite (PINC) membranes for osmotic separations
AU - Lin, Jerry
AU - Lind, Mary
PY - 2011/9/28
Y1 - 2011/9/28
N2 - Water is crucial for human survival. Water is also a pivotal aspect of the global economy for its uses in agricultural irrigation, industrial processes, electricity production, and as drinking water. Continuous population growth limits the supply of freshwater. Because water conservation alone cannot resolve the problems of the shrinking water supply, production of fresh water from alternative sources such as reclaimed wastewater, brackish groundwater, and ocean water is imperative. Currently, osmotic processes are able to produce high quality water from these sources. However, with long-term use, osmotic membranes interact with biological material causing reduced overall performance and increased operating costs. In particular, osmotic membranes are vulnerable to degradation by chlorine exposure. Researchers at Arizona State University are developing a new type of osmotic membrane that resists degradation by chlorine. The membrane is composed of selectively permeable inorganic nanoparticles connected by a dense chlorine tolerant polymeric thin film. Potential Applications Desalination Plants Wastewater Treatment Plants Home-use Systems Benefits and Advantages Reduce Pre-treatment Costs: Because the membrane is chlorine resistant, there is no need for expensive pre-treatment processes such as de-chlorination. Extended Lifetime: Because the membranes will not be degraded by chlorine, it will last more than twice as long. Mechanical Strength & Flexibility: The polymeric thin film used has strong mechanical strength and flexibility. Download Original PDF For more information about the inventor(s) and their research, please see Dr. Mary Lind's directory webpage
AB - Water is crucial for human survival. Water is also a pivotal aspect of the global economy for its uses in agricultural irrigation, industrial processes, electricity production, and as drinking water. Continuous population growth limits the supply of freshwater. Because water conservation alone cannot resolve the problems of the shrinking water supply, production of fresh water from alternative sources such as reclaimed wastewater, brackish groundwater, and ocean water is imperative. Currently, osmotic processes are able to produce high quality water from these sources. However, with long-term use, osmotic membranes interact with biological material causing reduced overall performance and increased operating costs. In particular, osmotic membranes are vulnerable to degradation by chlorine exposure. Researchers at Arizona State University are developing a new type of osmotic membrane that resists degradation by chlorine. The membrane is composed of selectively permeable inorganic nanoparticles connected by a dense chlorine tolerant polymeric thin film. Potential Applications Desalination Plants Wastewater Treatment Plants Home-use Systems Benefits and Advantages Reduce Pre-treatment Costs: Because the membrane is chlorine resistant, there is no need for expensive pre-treatment processes such as de-chlorination. Extended Lifetime: Because the membranes will not be degraded by chlorine, it will last more than twice as long. Mechanical Strength & Flexibility: The polymeric thin film used has strong mechanical strength and flexibility. Download Original PDF For more information about the inventor(s) and their research, please see Dr. Mary Lind's directory webpage
M3 - Patent
ER -