Disclosed is a water purification device based on filter cartridge anti-counterfeiting identification, comprising a filter cartridge assembly (1), a booster pump (2) and a membrane filter assembly (3); a water inlet and a water outlet of the filter cartridge assembly (1) are connected respectively to a water supply pipe and the booster pump (2), the water outlet of the booster pump is connected to a water inlet of the membrane filter assembly (3). The filter cartridge assembly (1) and the membrane filter assembly (3) are respectively provided with an identification chip to be identified and paired with an identifier installed on the water purification device; the booster pump (2) is connected to the identifier; the identifier transmits a signal to propel the booster pump (2) to work only after the identification chips are identified and paired with the identifier.

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.

A water purifier includes a hot water tank for receiving and heating received water by induction heating, a water outlet portion that is at least partially exposed to an outside of the water purifier for discharging hot water, a hot water line that is connected to the water outlet portion to communicate the hot water from the hot water tank to the water outlet portion, a hot water outlet valve that is located at the hot water line and that opens or closes the hot water line based on a control command, a connector that includes a hot water inlet connected to a water outlet pipe of the hot water tank and a hot water outlet connected to the hot water line, and a temperature sensor that is connected to the connector and that is configured to measure a temperature of the hot water that passes through the connector.

The present invention teaches a design of apparatus using which microspheres of customizable uni-sizes may be produced through a greatly simplified process. The apparatus consists a microsphere-forming unit, a microsphere rinsing unit, and a sterile hood that isolate the other two unit within a sterilized cover. The microsphere-forming unit enables the processed of microsphere formation, solidification and collection simultaneously. The sterile hood allow the microsphere producing operation be carried out within a glove box, preventing direct contact of operator with the sterilized materials of the microspheres. The apparatus has also a refrigerator wherein the microsphere collector and final product storage are placed for extracting the solvent of microsphere-forming materials and stabilizing the final product, respectively.

According to one embodiment of the present invention, a control method for a water purifier comprises the steps of: filtering inflowing water so as to generate purified water; extracting the generated purified water; measuring the flow rate of the purified water extracted per unit time; flushing a filter part by using purified water generated in the filter part, when the extraction of the purified water is complete; and draining the flushed water to the outside through a residential water outlet of the filter part, wherein, in the purified water generation step, discharging of residential water generated in the purified water generation step is blocked according to the accumulated flow rate during a one-time extraction of the purified water, calculated on the basis of the flow rate of the purified water.

Provide herein are a control arrangement and method for evaluating the integrity of a forward osmosis (FO) membrane of a FO device in a dialysis solution generation apparatus. The FO-membrane separates a feed side and a draw side of the FO device. The FO-device comprises a feed inlet port and a feed outlet port in fluid communication with the feed side, and a draw inlet port and a draw outlet port in fluid communication with the draw side. The method comprises providing a flow of feed solution at the feed side via the feed inlet port and providing a flow of draw solution at the draw side via the draw inlet port, with an osmotic pressure at the draw side that is higher than an osmotic pressure at the feed side. Water is extracted from the feed side to the draw side to dilute the draw solution.

A desalination system that is deployable in a body of water having a surface and a seafloor and which includes a vessel structure that is capable of travel in water, a reverse osmosis system disposed within an internal space of the vessel structure and a tank connected to the reverse osmosis system, the tank configured to receive filtered water from the reverse osmosis system. A positioning system is provided for controlling the travel of the vessel structure, and a ballast system is configured to control the buoyancy of the vessel structure. A controller is operably associated with the positioning system and the ballast system to control the position of the vessel below the surface of the body of water.

A fluid filtration assembly includes a filter housing having a first end for fluid connection with a fluid storage vessel. A filter cartridge is disposable within the filter housing, and a plunger pump is coupled at a second end of the filter housing. The plunger pump includes a housing having a rigid portion and a flexible portion. The flexible portion has a plunger-engaging portion for coupling to the plunger of an actuator. The flexible portion selectively movable with respect to the rigid portion via the actuator. The filter cartridge can be a hollow fiber filter. The plunger pump can be configured to induce alternating tangential flow in at least a portion of the assembly. The fluid filtration assembly can be provided as a disposable single-use arrangement.

Systems and methods for removing carbon monoxide from whole blood are provided. In one configuration, an extracorporeal phototherapy system includes an oxygenator and a light source configured to output light and arranged to emit the light output by the light source onto at least one surface of the oxygenator. The oxygenator includes a plurality of membrane layers each having a plurality of microporous hollow fiber membranes. The plurality of microporous hollow fiber membranes each include an external surface and an internal channel. Each of the plurality of membrane layers may be rotationally offset with respect to an adjacent layer. The oxygenator further includes a gas inlet port in fluid communication with a first end of the internal channels, a gas outlet port in fluid communication a second end of the internal channels, a blood inlet port, and a blood outlet port.

A membrane separation type activated sludge treatment method according to an aspect of the present invention includes a step of performing biological treatment on waste water and a step of performing membrane separation on water having been treated in the biological treatment step. The membrane separation step employs a plurality of filtration modules including a plurality of hollow fiber membranes arranged adjacent to one another and oriented in one direction and a pair of holding members fixing both ends of the plurality of hollow fiber membranes, and a plurality of cleaning modules supplying air bubbles from beneath the filtration modules. An amount of treated water sucked by the filtration modules and an amount of air bubbles supplied by the cleaning modules are varied in response to variations in an inflow rate of the waste water in the biological treatment step.