A filter member including a cylinder part extending in one direction, a filter hollow part which is formed inside the cylinder part to pass through along the one direction and allows the inside of the cylinder part to be in communication along the one direction, and a filtering part disposed to surround the cylinder part from radially outside and configured to filter raw water flowing through the filter hollow part.

A filtration device (1, 1) has a housing (2, 2) with an inlet (3, 3) to supply fluid to be filtered and an outlet (4, 4) to discharge filtered permeate. A filter module (5, 5) is between the inlet and outlet and has membrane layers (9, 9) connected to the housing (2, 2) in a fluid-tight manner. An inflow channel (11, 11) is at the inlet side (3, 3) and an outflow channel (12, 12) is at the outlet side (4, 4). A compressible and flow-permeable intermediate layer (10, 10) is arranged between at least two membrane layers (9, 9). The intermediate layer (10, 10) is made of a nonwoven material with: a thickness corresponding to 20 to 200% of the thickness of the membrane layers (9, 9), a basis weight of 10 to 150 g/m.sup.2, and an air flow rate therethrough of 150 to 5000 L/(m.sup.2 * s).

A spiral membrane element that can reduce the dimension increase in the length direction is provided. Also, a method for producing a spiral membrane element is provided having a step of forming a fiber reinforced resin layer having a reinforcing fiber layer and a strengthening fiber layer. The spiral membrane element is provided with a cylindrical wound body in which a separation membrane, a feed-side channel material, and a permeate-side channel material in a laminated state are wound in a spiral form around a center tube having a hole, and a sealing part for preventing feed-side fluid and permeate-side fluid from being mixed with each other, wherein a fiber reinforced resin layer having a reinforcing fiber layer and a strengthening fiber layer enclosed and buried with the same resin is provided on an outer circumferential side of the cylindrical wound body.

A process for separating a feed gas comprising polar and non-polar gases into a gas mixture enriched in polar gas(es) and a gas mixture depleted in polar gas(es), the process comprising passing the feed gas through a gas separation unit comprising at least two gas-separation modules in order of increasing selectivity for the polar gas(es), wherein the feed gas entering the gas separation unit comprises more than 35 mol % and up to 90 mol % of polar gas(es).

The system and method of the present application improves the efficiency of systems utilizing spiral membranes but can also be applied to systems using other types of membranes. The membrane vessels and membranes are configured in a vertical orientation and a clear path is provided for the removal of product and cleaning chemicals on the retentate and permeate sides of the membrane with hide or no dilution.

A separation membrane module 100 of the present invention includes: a container 10; a degassing membrane element 20 that is disposed inside the container 10; and a separation membrane element 60 that is disposed inside the container 10, is located upstream or downstream of the degassing membrane element 20 in a flow direction of a liquid to be treated, and filters the liquid. The separation membrane element 60 is for example, an NF membrane element or an RO membrane element.

An electrodialysis cell includes a housing defining an internal chamber, a core positioned within the internal chamber, a first electrode positioned in the internal chamber adjacent the housing, a second electrode coupled to the core and spaced from the first electrode, and a membrane assembly positioned between the first and second electrodes in a spiral wound configuration. The housing includes an inlet end for receiving a feed fluid and an outlet end in fluid communication with the inlet end. The membrane assembly includes a plurality of ion exchange membranes spaced from each other to define a plurality of fluid channels between the inlet and outlet ends.

The present disclosure generally relates to a method of manufacturing a spiral sheet product via an additive manufacturing process, the method comprising: obtaining an electronic file representing a geometry of the spiral sheet product; and controlling an additive manufacturing apparatus to manufacture, via the additive manufacturing process, the spiral sheet product according to the geometry specified in the electronic file. The geometry of the spiral sheet product comprises: a geometric model of a spiral body revolving around a longitudinal axis, the spiral body comprising spiral sections repeating along the longitudinal axis; each spiral section comprising unit cells repeating along a spiral length of the spiral section; and each unit cell comprising a geometric pattern, such that the repetitive geometric pattern functionalizes the spiral sheet product that is arrangeable into a flat sheet product that is larger than a build chamber of the additive manufacturing apparatus.

Printed spacer membrane elements offer the unique advantage of applying any pattern on the membrane surface to act as the feed spacer material. This is in contrast to conventional feed spacer mesh material that is uniform in thickness and density throughout the mesh. More open feed spaces can be utilized but may also result in higher stress concentration, and where the spacer material comes in contact with the opposing membrane leaf. This patent presents concepts for reducing the damage on membrane leaves by increasing the concentration of the print pattern near the center tube where the stress concentration on the membrane leaves is greatest, orienting the membrane sheets prior to rolling to minimize damage from slippage during rolling, moving the fold away from the first features to minimize leaks at the insertion point.

A process for preparing a semi-permeable membrane includes providing an aqueous phase comprising a polyfunctional amine monomer, covering a surface of a porous support membrane with the aqueous phase, applying an organic phase comprising a polyfunctional acyl halide monomer, a phosphorous containing compound and a co-solvent, and allowing the polyfunctional amine monomer and the polyfunctional acyl halide monomer to perform an interfacial polymerization reaction to form a polyamide thin film composite layer. The presence of the co-solvent together with the phosphorous compound in the organic phase potentiates the effect of the phosphorous compound so that the water flux is increased without substantially sacrificing the salt rejection.