To provide a blood treatment filter device capable of efficiently utilizing a blood treatment filter. A blood treatment filter device 20 has a filter sheet 26 through which a specific component among components forming blood is harder to pass than other components and a spacer sheet 27 through which the specific component is easier to pass than through the filter sheet 26. The filter sheet 26 has filter through-holes 39 disposed at intervals. The filter sheet 26 and the spacer sheet 27 are spirally wound in an overlapped state. The filter device 20 has seals 31 sealing both end portions in the longitudinal direction of a wound body 25 formed by the filter sheet 26 and the spacer sheet 27 which are spirally wound in a fluid-tight manner. The outer peripheral surface of the wound body 25 is formed by the filter sheet 26.

A flushable filter system is configured to purify a contaminated liquid containing substances that degrade filter performance and includes a filter cartridge including semi-permeable hollow fiber membrane that separates the filter cartridge into an upstream compartment and a downstream compartment. The system includes a flush port in communication with the upstream compartment of the filter cartridge for periodically discharging accumulated particulates and contaminates from an upstream side of the semi-permeable hollow fiber membrane. A device is provided to reduce mechanical stress imposed on the semi-permeable hollow fiber membrane during operation of the flushable filter system resulting in maintenance of integrity of the semi-permeable hollow fiber membrane during extended use and cyclic operation of the filter cartridge. The device is configured to dampen any fluid pressure spike that is observed within the flushable filter system during operation thereof.

A method and a system for improving mixing of content in a container 3 provided in a filter system 1, said method comprising providing a mixing loop 13 parallel to a recirculation flow path 11 of the filter system 1.

Provided is a fuel cell membrane humidifier in which humidification efficiency is improved by preventing differential pressure loss in a humidification module. The fuel cell membrane humidifier performs moisture exchange between a first fluid and a second fluid and includes a mid-case, a second fluid inlet through which the second fluid is introduced into the mid-case, a second fluid outlet through which the second fluid is discharged to outside, a partition wall configured to divide an inner space of the mid-case into a first space and a second space, and at least one cartridge located in the mid-case and configured to accommodate a plurality of hollow fiber membranes therein. A cross-sectional area of the second fluid inlet is equal to or greater than a total area of windows constituting a first mesh hole unit and arranged in a mesh shape in the at least one cartridge for fluid communication with the first space.

Disclosed is a fuel cell membrane humidifier which may improve humidification efficiency by preventing a differential pressure loss in a humidification module. A disclosed fuel cell membrane humidifier performs moisture exchange between a first fluid and a second fluid and includes a mid-case, a second fluid inlet configured to introduce the second fluid into the mid-case, a second fluid outlet configured to discharge the second fluid to outside, and at least one cartridge arranged in the mid-case and accommodating a plurality of hollow fiber membranes. A cross-sectional area of the second fluid inlet is formed to be greater than or equal to an inner cross-sectional area of the at least one cartridge excluding a cross-sectional area occupied by the plurality of hollow fiber membranes accommodated in the at least one cartridge.

The present invention relates to a fuel cell system capable of adjusting a bypass flow rate, which can automatically adjust the bypass flow rate according to the temperature of dry gas flowing from a blower. A fuel cell system capable of adjusting a bypass flow rate according to one embodiment of the present invention comprises: a blower for supplying dry gas through a supply flow path; a dry gas inlet for supplying at least a portion of the dry gas supplied from the blower to a membrane humidifier; a bypass flow path for supplying at least a portion of the dry gas supplied from the blower to a fuel cell stack by bypassing the membrane humidifier; and a bypass flow rate adjustment part formed in the bypass flow path and for adjusting the degree of opening of the bypass flow path according to the temperature of the dry gas flowing from the blower.

The present invention relates to a fuel cell membrane humidifier capable of preventing a decrease in humidification efficiency, caused by a pressure difference between the inside and outside of the membrane humidifier. The fuel cell membrane humidifier according to an embodiment of the present invention comprises: a middle case which has a module insertion unit; a cap case; a hollow fiber membrane module which is inserted into the module insertion unit; and an active pressure buffer unit which is formed between the middle case and the module insertion unit and which, according to the output condition of a fuel cell, prevents expansion of the module insertion unit due to the pressure difference between the inside and outside of the middle case or eliminates the pressure difference.

A membrane filtration system, in particular for reverse osmosis, includes a plurality of stages. Each stage has at least one pump and one filter membrane. The stages are hydraulically interconnected in sequence by connecting lines. The system also includes a bypass line for each stage for diverting liquid flow around the stage. At least one bypass valve blocks the respective bypass line in the closed state. The system further includes a control and regulating unit that can actuate the respective bypass valve.

A hollow fiber membrane module includes: an inner case; an outer case that covers the inner case from an outer periphery side with a space left therebetween; at least one bypass pipe that connects to the inner case in the space between the inner case and the outer case; and a plurality of hollow fiber membranes that are provided in the space, the inner case including, on an upstream side, an introduction portion that establishes communication between inside and outside, the outer case including, on a downstream side, a discharge portion that establishes communication between the inside and the outside, the inner case including, on the downstream side, at least one bypass port that penetrates through the inner case between the inside and the outside, the bypass pipe communicating with the bypass port and being capable of forming a fluid path that connects the bypass port and the discharge portion.

Ultrapure water supply apparatuses, substrate processing systems, and substrate processing methods are provided. An ultrapure water supply apparatus includes: a first supply device that produces first ultrapure water; a second supply device that produces second ultrapure water; a first reserved supply device that provides the second supply device with a portion of fluid in the first supply device; and a second reserved supply device that provides the first supply device with a portion of fluid in the second supply device. The first supply device includes a first front-side filtering part, a first rear-side filtering part, and a first connection part. The second supply device includes a second front-side filtering part, a second rear-side filtering part, and a second connection part. Each of the first and second reserved supply devices connects the first connection part and the second connection part to each other.