The present disclosure relates to an inflatable structure transformable between a deflated state and an inflated state. The inflatable structure comprises a drop stitch fabric having a first layer and a second layer tethered by drop stitches. The inflatable structure is provided with one or more folding lines defining the inflatable structure into two or more interconnected chambers, the one or more folding lines comprising coupling means coupling the first layer to the second layer. Dimensions of the one or more folding lines and/or coupling means are adapted to enable the inflatable structure to in both the deflated state and the inflated state be foldable along the one or more folding lines. The disclosure also relates to a method for manufacturing a foldable inflatable structure in accordance with the foregoing.

A method is provided for forming a flexible fire-resistant and thermal resistant sheet product. Such a method comprises securing a first insulation material sheet to a first cover sheet to form a first sheet product portion including a perimeter; securing a second insulation material sheet to a second cover sheet to form a second sheet product portion including a perimeter; and securing the first sheet product portion to the second sheet product portion, at least about the perimeters thereof and such that the first insulation material sheet is disposed adjacent to the second insulation material sheet, to form the sheet product. An associated apparatus is also provided.

A process for fabricating a three-dimensional, multi-layered fabric product with a moisture barrier is provided. A partially seamed inner lining fabric assembly having at least a two-dimensional shape is laminated with a membrane barrier film having flaps left un-laminated to cover at least one seam. The inner lining fabric assembly is further seamed and flaps of the of the membrane barrier film overlapped into contact with each other and sealed to provide a continuous moisture barrier. A process for fabricating a stretchable section of a garment with a moisture barrier is also provided. At least a section of a garment is formed from fibers arranged in a pattern having a direction of stretch in one direction and a three-dimensional surface texture such that a portion of the fibers protrude above another portion of the fibers. The stretchable section is stretched in the direction of stretch. Segments of a membrane barrier film are adhered to an outer edge of the protruding portion of the fibers while the section is stretched in the direction of stretch, leaving intermediate segments of the barrier film free from adherence to the section. In this way, the intermediate segments of the membrane barrier film include slack that folds up to form ruches when the section is in a relaxed state.

A method for manufacturing (S) a subassembly (3) for a tire (4) comprising the following substeps: providing an assembly comprising a supporting structure (14) comprising supporting filamentary elements linking a first structure (10) of filamentary elements and a second structure (12) of filamentary elements, aligning (S1) the first structure (10) and the second structure (12), securely fixing (S4) the first structure (10) onto the second structure (12) using a securing element (18), and cutting (S5) the assembly (1) along the securing element (18) so as to separate said securing element (18) from the rest of the assembly (1) and to obtain at least one subassembly (3) without securing element (18).

An article of footwear includes an upper formed of a base layer, a reinforcement layer, and an auxetic structure coupled to the reinforcement layer. The base layer includes an elastic material and is elastically deformable between a resting configuration and a stretched configuration. The base layer is configured to be stretched to a predetermined amount. The inelastic reinforcement layer is coupled to the base layer. The reinforcement layer is configured to delimit the stretch amount of the base layer when the base layer is in the stretched configuration.

An article of footwear includes at least one panel comprised of a composite material. The composite material includes a plurality of layers that are secured together according to a predetermined embroidery stitching pattern. The panel includes a first layer having a maximum elongation in a length direction of the article of footwear, and a second layer having a maximum elongation in a width direction of the article of footwear. The composite material also includes additional layers coupled to the first layer and the second layer.

The invention relates to a belt (1) as a continuous traction means, in particular for conveyor belts of agricultural machines, in particular baling presses, comprising at least one fabric layer (2) embedded, at least in certain regions, in a polymer layer (3), in particular rubber layer, whereby end regions (1a, 1b) of the belt (1) lie flat on top of one another in an overlap region (4) and are connected to each other for creating a continuous belt (1) reinforced by the fabric layer (2).

According to the invention, it is provided that the end regions (1a, 1b) of the belt (1) are connected to each other by at least one thread (7) forming a seam (9), whereby, to that end, said at least one thread (7) penetrates the end regions (1a, 1b) of the belt (1) in a seam region (6) in several stitches (8), whereby the fabric layer (2) of the belt (1) is embedded in the polymer layer (3) at least across said seam region (6), and the thread (7) is embedded in transition regions (20) between the stitches (8) into the polymer layer (3) in such a manner shallowly at a depth of penetration (T) that the thread (7) runs below surfaces (10a, 10b) of the belt (1).

The present invention relates to a fastening structure of a composite material structure, and more particularly, to a composite material stitching structure reinforced with z-direction fiber which improves strength in a lamination direction of a relatively weak composite material structure, for a composite material structure, in which composite materials are laminated and bonded.

Multi-layered fabric laminates, such as, for example, those used as filler cloths and/or in manufacturing mattress foundations, are described along with methods of making and/using the same.

The present invention provides a mop cleaning cloth and a method for manufacturing the same. The mop cleaning cloth comprises, sequentially from bottom to top, a base cloth layer, a water-absorption layer and a dirt removal layer. The dirt removal layer is formed by high terry fabrics and low terry fabrics. The ratio of the terry height of the high terry fabrics to the terry height of the low terry fabrics is 1.1-5:1. The high terry fabrics have a terry height of 2-20 mm and low terry fabrics have a terry height of 1-10 mm. The water-absorption layer is formed by a water-absorption fabric made from water-absorption fibers. The base cloth layer is formed by a terry fabric. The manufacturing method is simple, and the mop cleaning cloth is easy to manufacture and has the advantages of being small in resistance, high in water absorptivity and dirt collection and removal capacity, and the like.