A fiber reinforced resin hollow molded body 30 in which a resin-integrated fiber sheet is used. The resin-integrated fiber sheet includes unidirectional continuous fibers that are spread fibers of a continuous fiber group and arrayed unidirectionally in parallel, and thermoplastic resin that is present at least on a surface of the unidirectional continuous fibers. In the hollow molded body, in a state where the resin-integrated fiber sheet or a plurality of the resin-integrated fiber sheets 30 are stacked, the resin-integrated fiber sheet or the plurality of resin-integrated fiber sheets are wound to produce a wound body having an overlapping portion. The thermoplastic resin is impregnated in the unidirectional continuous fibers. The resin-integrated fiber sheet or the plurality of resin-integrated fiber sheets are consolidated.

A multi-layer panel product for use as structural sheathing. The panel product comprises a base manufactured-wood structural panel, such as OSB or plywood, with a factory-applied foam layer affixed to the exterior or outward-facing surface. The foam layer provides thermal resistance as an insulation layer. The foam layer also may act as an air and bulk water barrier. The foam layer may be expanded polystyrene (XPS) foam sheets.

A probe cleaning sheet and a manufacturing method thereof are provided. The manufacturing method includes material preparing step, first printing step, first baking step, first cooling step, second printing step, second baking step, and second cooling step. The probe cleaning sheet includes a silicone glass fiber cloth layer and an abrasive layer set printed on one side of the silicone glass fiber cloth layer. The silicone glass fiber cloth layer includes a plurality of glass fibers and silicone, the silicone is coated on the surface of the glass fibers and in the gap between the glass fibers. The abrasive layer set includes a high-density abrasive layer printed on one side of the silicone glass fiber cloth layer and a low-density abrasive layer printed on the top surface of the high-density abrasive layer and is opposite to the silicone glass fiber cloth layer.

The invention relates to a method and a device for producing laminated cores (2) from laminations (1), in which an adhesive medium is applied as at least one adhesive point (22) to the top of the surface of a sheet metal insulation (21) of a sheet metal strip (5), which is guided horizontally with respect to the direction of gravity, by means of an application unit (35) via an application head (32). Advantages for the structure and function result from the fact that the adhesive medium is transferred as at least one adhesive point (22) to the surface of the sheet metal insulation (21) of the sheet metal strip (5) or a lamination (1) cut from this strip without movable components in the application head (32), the application head (32) being moved perpendicularly relative to the surface of the sheet metal strip (5) in order to transfer the adhesive medium in the form of the at least one adhesive point (22).

[Problem] To provide a cover bonding product fabrication method with which it is possible to perform complex sewing such as zigzag stitching, double stitching, and embroidery with a pattern sewing machine via automated operation, regardless of the size of a curved surface of the cover bonding product. [Solution] According to the present invention, a method for determining a sewing pattern on a base material includes: (1) an analysis step for measuring and analyzing an expansion rate of a cover when the cover is vacuum-formed on the base material; (2) a specifying step for specifying, on the basis of the measured expansion rate, a range where the expansion rate is 130% or lower; and (3) a sewing pattern determination step for determining a sewing pattern in the range where the expansion rate is 130% or lower.

A composite component includes an outer skin that is formed from a thermoplastic polyurethane (TPU) elastomer, within a thermoforming mold, into a desired shape, a mesh reinforcement layer formed from a blend of TPU and polyester fibers and attached to an inner surface of the outer skin, and a padding that is formed from a TPU foam and applied to the inner surface of the outer skin and comprising one of liquid TPU foam that is poured within the desired shape of the outer skin, a plurality of gas-filled TPU beads that are melted to one another at points of contact of outer surfaces of adjacent beads, or one of TPU foam that is molded to a desired shape, or TPU foam that is cut in the desired shape from a bulk piece of TPU foam.

A film laying apparatus and laying method are provided. The apparatus includes a panel conveying mechanism and a film laying mechanism arranged above the panel conveying mechanism. The film laying mechanism includes a first driving member, a first supporting plate driven by the first driving member to move horizontally, a film feeding unit and a cutting unit arranged on the first supporting plate, and a tail end pressing unit that presses tightly a tail end of a film on the surface of a panel, and the cutting unit is located on a film output side of the film feeding unit.

The present application relates to a laminating machine, including a first heating device, a first sheet material device, a second sheet material device, and a first combining device, the first combining device includes a heating mechanism and a rolling mechanism. A first sheet material, a first material strip, and a second sheet material are heated and pressed by the heating mechanism and the rolling mechanism, compared with a combination method of a PET film and an oven, it is not necessary to set arrange the PET film, cost of the PET film, arranging a PET film unwinding mechanism, and arranging a PET film winding mechanism is reduced, and occupied space is reduced, manufacturing cost is reduced, and there is no need to set up a longer oven, which improves combination efficiency and production efficiency, and further saves space and reduces device cost.

A stack has first and second faces and multiple LOEs that each has two parallel major surfaces and a first plurality of parallel internal facets oblique to the major surfaces. A first block has third and fourth faces and a second plurality of parallel internal facets. The first block and the stack are bonded such that the second face joins the third face and the first and second facets are non-parallel, forming a second block. The second block is cut at a plane passing through the first face, forming a first structure having an interfacing surface. A third block has fifth and sixth faces and a plurality of parallel internal reflectors. The third block and the first structure are bonded such that fifth face joins the interfacing surface and the internal reflectors are non-parallel to all the facets, forming a second structure. Compound LOEs are sliced-out from the second structure.

The presently disclosed subject matter generally relates to recyclable insulation material for shipping containers, groceries bags, etc., machines for making the recyclable insulation material, and methods for the making the recyclable insulation material. In one aspect, an insulation product may include a first layer and a first continuous paper sheet formed into a first plurality of flexible loops disposed on and attached to the first layer and defining a first plurality of air channels that extend in a direction that is substantially perpendicular with a machine direction of the insulation product. A take up factor of the first continuous paper sheet to the first layer may be greater than 1:1.