A method for manufacturing waterproof and breathable shoes is provided. The method includes subjecting shoe sole materials to plastication and mixing, followed by cutting into pieces to be mold to form a shoe sole; stacking a knitted fabric as an outer layer, a polyurethane layer as a middle layer, and a knitted fabric as an inner layer sequentially into a mold for hot-pressing and shaping to form a shoe upper; and bonding the shoe upper to the shoe sole with an adhesive glue so as to form a shoe. The shoe is made flexible and light as the shoe upper is made up of two layers of knitted fabric bonded to a polyurethane layer. Moreover, the middle layer of the shoe upper includes a wavy structure, which is stretchable and helps improve waterproofness and breathability of the shoe upper.

According to various embodiments, a method of forming an image on a fabric and the resulting fabric is disclosed. The method includes providing a printable media including a carrier layer having a first surface comprising a first area and a second surface opposite the first surface. The method includes providing a fabric layer having a third surface and a fourth surface opposite the third surface, the third surface includes a second area. The fabric layer is secured to the carrier layer by the adhesive bonding a first portion of the fourth surface to the first surface. The method includes applying a toner to a first portion of the third surface of the fabric layer. The toner includes antimicrobial nanoparticles on an outer surface of the toner. The method includes fusing the toner to the first portion of the third surface of the fabric layer.

A mask assembly having antimicrobial properties is provided. The mask is preferably worn on a user's face and it comprises a material layer, preferably a polyester fabric, and an applied emulsion or combination of chemical components (a silver containing stabilized solution and a phosphorescent compound). The combination provides enhanced antimicrobial properties in the mask via the silver containing stabilized solution and the phosphorescent compound, which emits a controlled field around the mask of microbe destroying UV-C radiation, preferably in the 200-290 nm wavelength range. The emulsion may be applied to other surfaces wherever antimicrobial properties are desired.

Provided are materials that include one or more cycloaliphatic polyamides integrated into or coated onto one or more structural fibers such as polyethylene fibers, aramid-fibers, glass fibers or carbon fibers. The resulting materials may be incorporated into composite articles suitable for use as protective equipment or structural layers.

Provided are materials that include one or more cycloaliphatic polyamides integrated into or coated onto one or more structural fibers such as polyethylene fibers, aramid-fibers, glass fibers or carbon fibers. The resulting materials may be incorporated into composite articles suitable for use as protective equipment or structural layers.

A method for manufacturing a closed porous composite material includes 1) preparing a mixture that has 30 to 70 parts by weight of water-dispersed resin, 10 to 300 parts by weight of unexpanded thermal expansion microspheres, and 100 to 550 parts by weight of water, and stirring the mixture thoroughly; 2) preparing a carrier; 3) coating the carrier with the mixture acquired in step 1; 4) heating the carrier so that the unexpanded thermal expansion microspheres expand; and 5) repeating steps 3 and 4 multiple times to acquire a closed porous composite material. The closed porous composite material has a large number of closed cavities and polymer walls separating the closed cavities. The closed cavity is 20 μm to 800 μm in size. The ratio of a total volume of the closed cavities to a total volume of the polymer walls is greater than 16.

A multiaxial fabric resin base material includes a multiaxial fabric base material laminate impregnated with a thermosetting resin (B), the multiaxial fabric base material laminate including fiber bundle sheets layered at different angles, the fiber bundle sheets including unidirectionally aligned fiber bundles stitched with stitching yarns composed of a thermoplastic resin (A), the multiaxial fabric base material laminate being penetrated in the thickness direction by other bodies of the stitching yarns, and being stitched with the other bodies of the stitching yarns such that the yarns reciprocate at predetermined intervals along the longitudinal direction, the thermoplastic resin (A) constituting the stitching yarns having a softening point, the softening point being higher than the resin impregnation temperature of the thermosetting resin (B).

A multiaxial fabric resin base material includes a multiaxial fabric base material laminate impregnated with a thermosetting resin (B), the multiaxial fabric base material laminate including fiber bundle sheets layered at different angles, the fiber bundle sheets including unidirectionally aligned fiber bundles stitched with stitching yarns composed of a thermoplastic resin (A), the multiaxial fabric base material laminate being penetrated in the thickness direction by other bodies of the stitching yarns, and being stitched with the other bodies of the stitching yarns such that the yarns reciprocate at predetermined intervals along the longitudinal direction, the thermoplastic resin (A) constituting the stitching yarns having a softening point, the softening point being higher than the resin impregnation temperature of the thermosetting resin (B).

A printable fabric can include a blockout fabric and from 1 gsm to 6 gsm of a discontinuous crosslinked polymer network on an outermost surface of the blockout fabric. The blockout fabric can include an inner fabric layer having a first side and a second side, wherein the inner fabric layer includes from 80 wt % to 100 wt % dark fibers; a first outer fabric layer attached to the first side and including from 80 wt % to 100 wt % light fibers; and a second outer fabric layer attached to the second side and including from 80 wt % to 100 wt % light fibers.

A method for manufacturing waterproof and breathable shoes includes manufacturing of a shoe sole, manufacturing of a shoe upper, and bonding of the shoe upper and the sole. The specific steps are as follows: S1: manufacturing of a shoe sole: subjecting shoe sole materials to plastication and mixing using an open mill, cutting into pieces according to set requirements, and compression molding to obtain the shoe sole; S2 manufacturing of a shoe upper: stacking a knitted fabric as an outer layer (1), a polyurethane (PUR) layer, and a knitted fabric as an inner layer (3) sequentially into a molding die in a nested fashion, and hot-pressing and shaping; and S3: bonding of the shoe upper and sole: bonding the shoe upper and sole for the waterproof and breathable shoes with an adhesive glue according to a size.