Disclosed herein is a gas separation section for separating a first gas from one or more other gasses in a separation device, the gas separation section comprising: a first membrane that is substantially planar; a second membrane that is substantially planar; a first substrate that has a first surface and a second surface, wherein the second surface of the first substrate is on an opposite side of the first substrate than the first surface of the first substrate; a second substrate that has a first surface and a second surface, wherein the second surface of the second substrate is on an opposite side of the second substrate than the first surface of the second substrate; and a mesh that is arranged between the second surface of the first substrate and the second surface of the second substrate; wherein: the first substrate and the second substrate are sintered plates; the first membrane is on the first surface of the first substrate; the second membrane is on the first surface of the second substrate; the first and second membranes are both permeable by at least a first gas and not permeable by one or more other gasses; the thickness of the first membrane in a direction orthogonal to the plane of the first membrane is less than 10 micrometres; and the thickness of the second membrane in a direction orthogonal to the plane of the second membrane is less than 10 micrometres. Embodiments provide an improved gas separation device over known techniques. Advantages of the separation device according to embodiment include improved performance, easy implementation, a modular design and a scalable design.

A concentration membrane for use in concentrating biological particles, including: a hydrophilic composite porous membrane including: a porous substrate; and a hydrophilic resin with which at least one main surface and inner surfaces of pores of the porous substrate are coated, the hydrophilic composite porous membrane having a ratio t/x of a membrane thickness t (m) to an average pore diameter x (m), as measured with a perm porometer, of from 50 to 630. A concentration device 10 for biological particles 50 including: a housing 20 having an inlet 21 and an outlet 22, in which, due to a differential pressure between the inlet 21 and the outlet 22, a liquid to be treated 40 containing biological particles 50 and water is injected from the inlet 21 and discharged from the outlet 22; a concentration membrane 30 provided to separate the inlet 21 and the outlet 22 from each other in the housing 20, the concentration membrane 30 being a hydrophilic porous membrane onto which the biological particles 50 are not adsorbed, the concentration membrane 30 allowing an effluent 42, which is a liquid having a concentration that is a concentration of the biological particles 50 subtracted from a concentration of the liquid to be treated 40, to permeate from a surface on a side of the inlet 21 to a surface on a side of the outlet 22; and a concentration space portion 24 which is a space on an upstream side of the concentration membrane 30 in the housing 20 and stores a concentrated liquid 41 which is a liquid having a concentration that is a concentration of the biological particles 50 added to a concentration of the liquid to be treated 40 by the concentration membrane 30.

Embodiments relate generally to a filter (110), for example, for attachment onto a gas detector device or a gas sensor, and attempt to improve the efficiency and service life of the filter (110). Embodiments typically comprise a dustproof membrane (114) and a waterproof membrane (113). Some embodiments may also comprise a splash-proof cap (130) and/or features to reduce negative pressure on the filter (110).

Disclosed herein is a gas separation section for separating a first gas from one or more other gasses in a separation device, the gas separation section comprising: a first membrane that is substantially planar; a second membrane that is substantially planar; a first substrate that has a first surface and a second surface, wherein the second surface of the first substrate is on an opposite side of the first substrate than the first surface of the first substrate; a second substrate that has a first surface and a second surface, wherein the second surface of the second substrate is on an opposite side of the second substrate than the first surface of the second substrate; and a mesh that is arranged between the second surface of the first substrate and the second surface of the second substrate; wherein: the first substrate and the second substrate are sintered plates; the first membrane is on the first surface of the first substrate; the second membrane is on the first surface of the second substrate; the first and second membranes are both permeable by at least a first gas and not permeable by one or more other gasses; the thickness of the first membrane in a direction orthogonal to the plane of the first membrane is less than 10 micrometres; and the thickness of the second membrane in a direction orthogonal to the plane of the second membrane is less than 10 micrometres. Embodiments provide an improved gas separation device over known techniques. Advantages of the separation device according to embodiments include improved performance, easy implementation, a modular design and a scalable design.

The present invention relates to a method for concentrating extracellular vesicles in a fluid sample, and specifically, a method for concentrating extracellular vesicles with high efficiency within a short period of time, by using a filter with a pore size of 20 nm to 100 nm and controlling the composition of the fluid sample and the usage of an elution buffer. The method of the present invention for concentrating extracellular vesicles can simplify the process of concentration, reduce the time of concentration, and concentrate extracellular vesicles with high efficiency. That is, the method of the present invention can reduce time and cost for a concentration process and increase concentration efficiency compared to conventional concentration methods, and is thus an economical concentration method suitable for extracellular vesicles.

A system for treatment of a polluted effluent includes an outer chamber and a computerized control system. The system is configured to treat an effluent/catalyst mixture that includes the polluted effluent in admixture with a purification slurry. The slurry includes particles of one or more catalysts and/or organoclays. The treatment of the effluent/catalyst mixture is carried out by contact between the particles of the catalysts and/or organoclays and the polluted effluent to mineralize or degrade pollutants in the polluted effluent.

Tangential flow filtration systems utilizing flexible bags for permeate collection are provided.

A hollow fiber membrane module that increases a ratio of a membrane area contributing to membrane separation effect. On an inner wall surface of a case 100, at least one flow-straightening projection 130 and at least one flow-disturbing projection 140 are provided. The flow-straightening projection 130 projects toward an outer circumferential surface of a hollow fiber membrane bundle 300 to secure a gap between the inner wall surface of the case 100 and the hollow fiber membrane bundle 300 and extends from one end side toward the other end side of the case 100 and straightens a flow of fluid. The flow-disturbing projection 140 extends along a circumferential direction of the case 100 and disturbs the flow of the fluid.

Stack assembly comprising a hollow external housing having a central axis, the external housing extending from a first end to a second end and enclosing a housing space, and a membrane stack comprising a plurality of membranes, wherein the membrane slack is positionable inside the external housing and a number of side plates extending substantially parallel to the central axis, wherein each side plate of the number of side plates is associated with a side of the membrane stack and extending along the associated side and a number of sealing connectors that extend substantially parallel to the central axis and adjacent with an inner surface of the external housing, wherein each sealing connector of the number of sealing connectors is configured to connect two side plates to each other, wherein the sealing connectors and the side plates cooperate to form an enclosing structure, and wherein, in use of the stack assembly, the enclosing structure encloses the membrane stack. The invention also relates to a method for assembling a stack assembly and a method for generating energy or performing an electrodialysis process.

A sheet-shaped hollow fiber membrane module includes a casing having a flat shape, the casing including a supply port and a discharge port, and a plurality of hollow fiber membranes accommodated inside the casing. The casing includes a plurality of the supply ports on one main surface of the casing and a plurality of the discharge ports on the other main surface of the casing, at least one of the plurality of the supply ports is closable, and at least one of the plurality of the discharge ports is closable. Each of the plurality of hollow fiber membranes includes a first opening at one end of the hollow fiber membrane and a second opening at the other end of the hollow fiber membrane, and the first opening and the second opening communicate with an outside of the casing and do not communicate with an inside of the casing.