The present invention relates to a textile material-based porous water splitting catalyst and a preparation method therefor, and the textile material-based porous water splitting catalyst according to the present invention comprises: a porous textile support (10) formed by the inter-crossing of a plurality of fibers (11); binding layers (20) formed on the surface of the fibers (11); conductive layers (30) comprising nanoparticle layers (31), which comprise metal nanoparticles and are formed on the binding layers (20), and monomolecular layers (33), which comprise a monomolecular material containing an amine group (NH2) and are formed on the nanoparticle layers (31); and catalyst layers (40) which comprises a catalytic metal, and which is formed on the conductive layers (30) by the electroplating of the catalytic metal.

The present invention relates to a textile material-based porous water splitting catalyst and a preparation method therefor, and the textile material-based porous water splitting catalyst according to the present invention comprises: a porous textile support (10) formed by the inter-crossing of a plurality of fibers (11); binding layers (20) formed on the surface of the fibers (11); conductive layers (30) comprising nanoparticle layers (31), which comprise metal nanoparticles and are formed on the binding layers (20), and monomolecular layers (33), which comprise a monomolecular material containing an amine group (NH2) and are formed on the nanoparticle layers (31); and catalyst layers (40) which comprises a catalytic metal, and which is formed on the conductive layers (30) by the electroplating of the catalytic metal.

Described herein are apparatuses and methods for dyeing garments. An exemplary apparatus comprises a dye injection system configured to dispense concentrated liquid dye; a dyeing machine comprising a dyeing chamber configured for dyeing at least one garment in a dyebath; and a controller in communication with the dye injection system and the dyeing machine, wherein the controller is configured: to receive at least one garment parameter corresponding to the at least one garment; based at least in part on the at least one received garment parameter, cause the dye injection system to dispense a volume of concentrated liquid dye containing an amount of dyestuff that can be substantially absorbed by the at least one garment; and cause the dyeing machine to execute a dye cycle such that substantially all of the dyestuff in the dispensed concentrated liquid dye is absorbed by the at least one garment within the dyeing chamber.

A textile structure including one or more layers of warp yarns interwoven with one or more layers of weft yarns, a durable thermoregulating coating, and a binder that chemically bonds the durable thermoregulating coating to the textile structure. The warp yarns and/or weft yarns include polyester yarns. A method for manufacturing a textile structure includes weaving one or more layers of warp yarns with one or more layers or weft yarns to form a woven textile structure, brushing the textile structure at least two times, applying a binder to the textile structure, and applying a durable thermoregulating coating to the textile structure such that the binder chemically bonds the durable thermoregulating coating to the textile structure. The method may also include heat setting and curing the textile structure to fix the durable thermoregulating coating permanently onto the textile structure.

A textile structure including one or more layers of warp yarns interwoven with one or more layers of weft yarns, a durable thermoregulating coating, and a binder that chemically bonds the durable thermoregulating coating to the textile structure. The warp yarns and/or weft yarns include polyester yarns. A method for manufacturing a textile structure includes weaving one or more layers of warp yarns with one or more layers or weft yarns to form a woven textile structure, brushing the textile structure at least two times, applying a binder to the textile structure, and applying a durable thermoregulating coating to the textile structure such that the binder chemically bonds the durable thermoregulating coating to the textile structure. The method may also include heat setting and curing the textile structure to fix the durable thermoregulating coating permanently onto the textile structure.

A system can include a heatset steam tunnel extending along a longitudinal axis. The heatset steam tunnel can have an inlet/outlet structure, the inlet/outlet structure extending along a horizontal axis that is perpendicular to the longitudinal axis and a vertical axis that is perpendicular to the horizontal axis and the longitudinal axis. An operator space positioned adjacent the inlet/outlet structure of the heatset steam tunnel. A guard can at least partially covering the inlet/outlet structure. The guard can comprise a transparent window material. The guard can be configured to direct steam from the inlet/outlet structure of the heatset steam tunnel away from the operator space while permitting viewing into the inlet/outlet structure from the operator space.

A system can include a heatset steam tunnel extending along a longitudinal axis. The heatset steam tunnel can have an inlet/outlet structure, the inlet/outlet structure extending along a horizontal axis that is perpendicular to the longitudinal axis and a vertical axis that is perpendicular to the horizontal axis and the longitudinal axis. An operator space positioned adjacent the inlet/outlet structure of the heatset steam tunnel. A guard can at least partially covering the inlet/outlet structure. The guard can comprise a transparent window material. The guard can be configured to direct steam from the inlet/outlet structure of the heatset steam tunnel away from the operator space while permitting viewing into the inlet/outlet structure from the operator space.

The present invention discloses a braided silk scaffold with adjustable mechanical and degradation properties, and a preparation method and use thereof, belonging to the field of three-dimensional scaffold materials for tendon/ligament repair. The preparation method includes braiding at least one silk strand to form a silk core; placing 1-6 bundles of silk cores in a braiding machine, and braiding at least one layer of silk cladding on the surface of the silk cores to form a silk base frame; removing sericin from the silk base frame; soaking the silk base frame in a collagen solution with a concentration of 3-20 mg/ml, and cross-linking the silk base frame in a vacuum thermal cross-linking machine to obtain the silk scaffold. The braided silk scaffold with adjustable mechanical and degradation properties according to the present invention has good mechanical properties and biocompatibility.

A functional resin material is manufactured by the following reagents including a polyol, a polyamine, a first cross-linking agent, a second cross-linking agent, and a nanocellulose. Each of the first cross-linking agent and the second cross-linking agent includes an isocyanate block. The nanocellulose includes a repeating unit represented by formula (1),

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A functional resin material is manufactured by the following reagents including a polyol, a polyamine, a first cross-linking agent, a second cross-linking agent, and a nanocellulose. Each of the first cross-linking agent and the second cross-linking agent includes an isocyanate block. The nanocellulose includes a repeating unit represented by formula (1),

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