A method of operating a membrane is provided. The membrane comprises: a porous layer; a first electrically conductive layer located on a first side of the porous layer; and a second electrically conductive layer located on a second side of the porous layer. When an electric voltage is applied between the first and second electrically conductive layer across the porous layer, the membrane prevents moisture intrusion from a first surface of the membrane towards a second surface of the membrane. The method comprises applying an electric voltage between the first and second electrically conductive layer across the porous layer to prevent moisture intrusion from the first surface of the membrane towards the second surface of the membrane when it is desired to prevent moisture intrusion from the first surface towards the second surface. A membrane system for performing the method is also provided.

This disclosure relates to an apparatus and method for analyzing an influence variable on membrane fouling of a seawater desalination system, wherein influence variables other than variables having a low degree of influence, among variables affecting the membrane, are selected, and the influence thereof on membrane fouling is used to derive an equation. The apparatus includes a variable storage unit configured to store variables affecting membrane fouling of a seawater desalination system, a dominant variable selection unit configured to select at least one dominant variable among the variables through at least one algorithm, and an equation derivation unit configured to derive a specific equation based on a correlation between the selected dominant variable and the membrane fouling.

A hollow fiber membrane bundle configured to be used in an artificial lung and comprised of integrated hollow fiber membranes 31 has hollow portions through which a fluid passes. The hollow fiber membrane bundle is shaped as a cylinder body. In addition, the hollow fiber membrane 31 is tilted with respect to a central axis O of the cylinder body, is wound around the central axis O of the cylinder body, and satisfies the following conditions. An inner diameter d.sub.1 of the hollow fiber membrane 31 is equal to or smaller than 150 m, a tilt angle with respect to the central axis O of the cylinder body of the hollow fiber membrane 31 is equal to or smaller than 60, and a ratio D.sub.1/L of an outer diameter D.sub.1 of the cylinder body to a length L of the cylinder body is equal to or greater than 0.4.

A conditioning system for a filter module is disclosed. The conditioning system may generally include an inlet, a heat exchanger, a magnetically levitated pump, a channel provided to bypass the heat exchanger, a controller, an outlet, and a base. The system may have components lined with corrosion-resistant materials. A method of conditioning a filter module is also disclosed. The method may generally include measuring TOC in a source of ultrapure water, heating the ultrapure water, rinsing a filter module with the heated water, flushing the filter module with ambient temperature water, and repeating the rinsing with heated water and flushing with ambient temperature water. A method of facilitating conditioning of the filter module is also disclosed. The method may generally include providing a portable filter module conditioning system and providing instructions for installation or use.

The present invention relates to a computer-readable recording medium having recorded thereon a clogging location determination program for a separation membrane module, in which, in order to determine a clogging location of a separation membrane module in a fresh water generation system for obtaining treated water by filtrating water to be treated by a separation membrane module having a separation membrane, a computer is caused to function as a clogging location determination means for determining a clogging location of the separation membrane module from a resistance in a lower part of the separation membrane module, a filtration resistance of a hollow-fiber membrane, and a resistance in an upper part of the separation membrane module.

The invention relates to a method and a system for controlling a membrane separation unit of an aqueous liquid effluent treatment plant comprising a system for injecting at least one chemical compound into the effluent to be treated. The method and the system allow regulating at least one parameter selected from an amount of chemical compound(s) to be added and a conversion rate in order to avoid clogging and/or precipitation of ionic species in the retentate. This regulation uses optimum setpoint values determined according to one or more parameter(s) characteristic of the retentate and not of the water to be treated. Thus, an accurate regulation of the amount of chemical compound(s) to be added and/or of the conversion rate of the membrane separation unit at an optimum value allowing at the same time avoiding clogging and/or precipitation of the species likely to precipitate and minimising the operating costs is achieved.

Methods and system for real-time monitoring and control of an ultrafiltration/diafiltration (UF/DF) conditioned pool in a UF/DF recovery tank are disclosed. In various embodiments, a UF/DF pool is received at a recovery tank for conditioning or dilution by a buffer. Inline Raman measurements of the conditioned UF/DF pool may be performed and provided to a trained machine learning model as input. The machine learning model can then predict product quality attributes of the UF/DF conditioned pool, examples of said product quality attributes including protein concentration and osmolality of the conditioned UF/DF pool.

The present invention concerns an electronic safety system for an RO device which is configured to be used with at least one dialysis device (e.g., a hemodialysis or a peritoneal dialysis device). The system comprises the RO device, which is configured for the production of ultrapure water and which includes a sensor unit for collecting sensor data and whereby the RO device comprises an electronic data interface in order to send the sensor data collected by the sensor unit; and it also comprises an analysis unit which is configured to analyze a water sample with regards to safety requirements and for example with regard to contamination and to generate result data whereby the analysis unit also includes an analysis interface in order to send the generated result data in electronic form; and a network for the data exchange between the medical entities, for example between the RO device and the analysis unit.

An apparatus, comprising: a membrane; a membrane holder including an output, wherein the membrane holder is operable to hold the membrane and the membrane holder has three or more ports, and a permeate attachment coupled to the output of the membrane. The apparatus may further comprise a flow meter coupled to an output of a first pump, wherein the flow meter is disposed between the pump and the membrane holder.

A system and method retrieves liquid stream data associated with a first liquid stream that includes a set of chemical compounds. and a set of parameters. The system also retrieves reference data that is associated with a reference liquid stream, and includes a set of reference parameters. The system compares at least a first parameter of the set of liquid-stream parameters with a corresponding reference parameter of the set of reference parameters. The system also controls an output of the first liquid stream based on the comparison of parameters.