The disclosure provides a method for forming a core layer for a plurality of information carrying cards, a resulting core layer, and a resulting information carrying card. A first portion of a crosslinkable polymer composition is dispensed onto the first thermoplastic layer. A second thermoplastic layer having a plurality of through-holes therein is then applied. A second portion of the crosslinkable polymer composition is dispensed into each through-hole. An inlay layer is placed over the polymer composition inside each through-hole. A third portion of the crosslinkable polymer composition is dispensed over each inlay layer. A third thermoplastic layer or a release film is placed over the third portion of the crosslinkable polymer composition to provide a layered structure. Each respective inlay layer is configured to be movable and/or self-center inside each through-hole in the presence of the crosslinkable polymer composition when the layered structure is pressed on a pressure.

The present invention discloses a spacer fabric structured garment, which comprises a garment body, a plurality of filling cavities arranged in the garment body, and spacer fabrics arranged in the filling cavities, wherein the spacer fabrics comprise a plurality of dragging units, and the dragging units comprise an upper surface layer, a lower surface layer and a dragging part connected to one side of the upper surface layer and the lower surface layer which are close to each other. The present invention has the advantage that the spacer fabrics can be used to prevent the filling materials in the filling cavities from piling up.

This disclosure relates to a composite textile that can be sustainable, as well as methods and systems for constructing the composite textile and recollecting and harvesting excess material (e.g., remnants). In at least some examples, a first pattern piece is cut from a first material layer, and a second pattern piece is cut from a second material layer. In addition, the first pattern piece can be separated from the first material layer, which can leave a first remnant, and the second pattern piece can be separated from the second material layer, which can leave a second remnant. Once separated, the first pattern piece can be stacked atop the second pattern piece, and the stacked pattern pieces can be entangled to form a composite pattern piece. The remnant associated with the first material layer can be separated from the remnant associated with the second material layer and reused.

A method of producing a laminated metal sheet for packaging applications and laminated metal sheet for packaging applications produced thereby.

A fiber-metal laminate having a honeycomb sandwich structure and a preparation method thereof are provided. Firstly, based on material reduction processing technology, a recessed polygonal structure is obtained according to a design trajectory, and an upper layer and a lower layer are closed to form a recessed honeycomb sandwich structure. Then, processed surfaces of the upper layer and the lower layer are chemically treated to passivate the processed surfaces, with the aim of increasing the adhesion between a fiber layer and the metal layers. Then, a viscous mixture is filled into the recessed structures of the metal layers to ensure the multifunctional characteristics and impact resistance of the fiber-metal laminate. Then, a fiber prepreg is laid between the upper layer and the lower layer to obtain a prefabricated fiber-metal laminate. Finally, the prefabricated fiber-metal laminate undergoes thermal curing treatment under pressure in a hot-pressing tank, thereby obtaining the fiber-metal laminate.

A rough board compositing process, comprising the following steps: S1: pre-treating raw materials; S2: pre-cutting materials; S3: performing first hot pressing fusion; S4: obtaining a faceplate layer core material after the hot pressing fusion; S5: cutting a demoulding cloth, a third resin layer, a supporting structure layer and a release film material; S6: stacking the materials one by one; S7: performing second hot pressing fusion to obtain a composite board; and S8: tearing off the demoulding cloth from the composite board to obtain a final product, a composite rough board. By the described process, a lightweight and durable composite rough board is obtained. The composite rough board is capable of effectively increasing striking resistance and prolonging service life. The composite fabric is suitable for covering beach rackets or pickleball rackets to improve durability and striking resistance.

In order to provide a manufacturing method of an elongated foam sheet capable of manufacturing the elongated foam sheet with highly-precise thickness without being limited by the material and thickness of foam material, a method of manufacturing an elongated foam sheet includes performing a slice process in which a foam sheet is created by slicing a foam block and a sheet pasting process in which a large number of foam sheets are arranged and pasted onto one side of an elongated base material sheet to manufacture the elongated foam sheet where the large number of foam sheets are lined up in a longitudinal direction of the base material sheet.

Systems for processing material, taping stations to apply tape to one or more rolls of material, and methods of processing material are disclosed. A system for processing material includes a winding station and a taping station. The winding station includes a winder to wrap material around a mandrel to produce one or more rolls of material. The taping station is arranged downstream of the winding station to receive the one or more rolls of material therefrom and apply tape to the one or more rolls of material.

A seat trim cover for an automotive seat is formed into a 3-dimensional shape by compression molding a laminated moldable foam in a 3-dimensional. The laminated moldable foam comprises at least a layer of cellular polyurethane foam compression moldable in a temperature range of about 220 F. to about 260 F. The 3-dimensional mold is heated to a temperature range of about 150 F. to about 320 F. The layer of cellular foam is adhered to a cover material layer and precut into a pre-laminated blank prior to molding into the 3-dimensional shape. Optionally, seat heaters or other components can be integrated with the laminated foam prior to compression molding the seat trim cover.