Disclosed herein is a filter having a housing having first and second end surfaces and interior and exterior surfaces, a membrane disposed within the tubular housing, a first end cap sealed to the first end surface of the tubular housing and the first end surface of the membrane; a second end cap sealed to the second end surface of the tubular housing and the second end surface of the membrane; and a fluid channel formed in the interior surface of the housing in a helical pattern. The helical pattern has a helical pitch in an axial direction of the housing of less than or equal to about 60 mm.

The present invention relates to a cartridge for a fuel cell humidifier, and a fuel cell humidifier, the cartridge comprising: an inner case having both ends opened; a hollow fiber membrane bundle received in the inner case; an inner inlet and an inner outlet formed on the inner case so as to be spaced along a first axial direction; a first potting layer for fixing one end of the hollow fiber membrane bundle at one end of the inner case; and a second potting layer for fixing the other end of the hollow fiber membrane bundle at the other end of the inner case, wherein the packing density is 0.405 to 0.625 inclusive, the packing density being based on, with respect to a second axial direction perpendicular to the first axial direction, the potting cross-section of the inside of the one end of the inner case where the first potting layer is potted, and the membrane cross-section of the hollow fiber membrane bundle.

The present invention relates to: a cartridge for a fuel cell humidifier for humidifying dry gas supplied from the outside by using wet gas discharged from a fuel cell stack; and a fuel cell humidifier, the cartridge comprising: an inner case having an opening at the end thereof, and having a plurality of hollow fiber membranes contained therein; and a first gas inlet and a first gas outlet formed to be spaced from each other in a first axial direction in the inner case, wherein: the inner case comprises a first segment having the hollow fiber membranes contained therein, a second segment spaced from the first segment on the basis of a second axial direction that is vertical with respect to the first axial direction, and a third segment positioned between the first segment and the second segment on the basis of the second axial direction; and the average thickness of the third segment is thinner than each of the average thickness of the first segment and the average thickness of the second segment.

In some embodiments thereof, the present invention describes TFF (Tangential Flow Filtration) filtration devices that utilize tubular membranes for the separation of cells and particles. These devices encompass several innovative features, including the use of membrane tubes with either circular or non-circular cross-sections. These tubes are closely surrounded by both tube housing and filter housing to regulate the pressure of the liquid exiting the filter housing. Additionally, the membrane tubes may feature internal cores within their lumens and/or structures along their inner walls. These internal features serve to regulate flow patterns and pressures within the tubes. One notable aspect of this invention is the inclusion of features on the tube housing or tube core that effectively regulate pressure resistance and feed flow patterns. These features lead to a reduction in the required recirculation rate and contribute to improved transmembrane pressure profiles, making these membrane filters highly effective for cell retention in cell culture and other applications. The patent also introduces various filter designs that incorporate tubular membranes into TFF filtration devices to achieve multiple goals, including a more consistent TMP (Transmembrane Pressure) profile for efficient separation, reduced recirculation rates to generate adequate shear rates, higher packing densities of membrane surface areas within the same filter design, and enhanced manufacturability and recyclability of the filters. Overall, this invention represents a significant advancement in the field of TFF filtration, offering innovative solutions for a wide range of applications in the separation of cells and particles.

A method of activating and dewatering sludge through application of acoustic pressure shock waves to wastewater.

A method of treating fluids, including for recovery of water apart from impurities or undesired matter, utilizes application of shock waves to the fluids.

A process for producing nitrogen-rich air by feeding high temperature air at 150? C. or more to an air separation membrane module is described. After being placed at 175? C. for two hours, the air separation module exhibits a shape-retention ratio of 95% or more in one embodiment. The nitrogen-rich air can be fed to a fuel tank for an aircraft, for example.

A reverse osmosis filter assembly for fluid filtration having a push-activated lock and release mechanism. A push filter design activates a floating key lock upon insertion and extraction, where the filter key may be used simultaneously as a lock and as an identifier for particular filter attributes. The filter base may be situated inline, and in fluid communication, with the raw water ingress, permeate egress, and reject water egress. The reverse osmosis filter housing assembly may be attached to, and removed from, the filter base by a push-actuated release. Upon insertion, the filter key shifts the filter lock longitudinally to receive interlocking segments. Upon extraction, the same axial push shifts the filter lock further to align the interlocking fingers within gaps that allow for easy extraction. The specific key lock design allows a user to identify and match certain filter configurations received by the mechanical support, and reject other filter configurations.

The present invention is directed toward a dialysis unit that is modular and portable, with improved functionality. In one embodiment, the dialysis system comprises a top unit that is detachably affixed to a base that comprises a reservoir for fluid storage. Among numerous other features, the portable, modular dialysis system of the present invention has improved power door locking, zoned leak detection, fluid handling, and mechanical design features that enable improved modularity.

The present invention relates to portable filtration units including filter components mated with retentate and permeate flow channels wherein particle containing solutions are introduced into the portable filtration units and contacted with the filter components for filtration thereby producing a retentate outflow and a permeate outflow for capture of desired end product.