A method for manufacturing a cellular structure having first and second faces, rows of cells each alternatingly having first cells, which are open in the direction of the first face, second cells, which are open in the direction of the second face, and also third cells formed between each row of cells, each row of cells comprising first and second strips of material placed against one another. The first and second strips of material are shaped by bending. By contrast to plastic deformation, shaping by bending makes it possible to expand the choice of materials and thicknesses for the first and second strips of material. An advantageous cellular structure is thus obtained as well as an acoustic absorption coating comprising such a cellular structure.

A liner-label combination is provided for a tamper evident label. The combination includes a label substrate and a liner substrate. The label substrate includes label substrate die cuts that define a top portion, a middle portion, and a bottom portion for the label. The liner substrate includes liner substrate die cuts that correspond to the middle portion of the label. The top portion, middle portion, and bottom portion adapted to be separated from the liner substrate as a single label with a backside of the middle portion including the corresponding liner substrate defined by the liner substrate die cuts. The middle portion of the label adapted to cover an opening of an item and when removed from the opening, the middle portion separates from the top portion and the bottom portion along the label substrate die cuts providing evidence that the opening to the item was exposed.

A film laminating apparatus and an electrode sheet processing device are disclosed. The film laminating apparatus includes a frame, a conveying mechanism, a mounting plate, and a plurality of film laminating mechanisms, the plurality of film laminating mechanisms being mounted on the mounting plate; the conveying mechanism being mounted on the frame and being capable of conveying an electrode sheet in a first direction into the film laminating apparatus; and the mounting plate being mounted on the frame and forming an included angle with the first direction. The plurality of film laminating mechanisms are tilted or vertically arranged relative to the conveying direction of an electrode sheet. The space occupied by the plurality of film laminating mechanisms, the size of the film laminating apparatus, the volume of the film laminating apparatus, and the space occupied by the film laminating apparatus in the conveying direction of the electrode sheet is reduced.

A component assembly includes a core including a main body having a first surface and a second surface opposite from the first surface. One or more recessed cells are formed in each of the first surface and the second surface of the main body. The one or more recessed cells formed in the first surface extend toward the second surface. The one or more recessed cells formed in the second surface extend toward the first surface. A first layer is secured to the core at a first adhesive layer. A second layer is secured to the core at a second adhesive layer.

A tag is configured to be inserted into a product, the tag including a label portion having a first width and an insertion portion. The insertion portion extends from the label portion at a first end of the insertion portion. The insertion portion has a second width that is less than the first width. The insertion portion has a length terminating at an arrow-shaped head at an opposed second end of the insertion portion, the arrow-shaped head comprising a tip and a barb that extends laterally from an elongated wire. The elongated wire extends along the length of the insertion portion to at least a part of the label portion.

A method of manufacturing a backed cross-ply prepreg comprises cutting, using a cutting machine, a first continuous length of a unidirectional prepreg into first prepreg segments, each having an opposing pair of segment cut edges that are non-parallel to a lengthwise direction of the unidirectional prepreg. The method also includes picking up, using a pick-and-place system, the first prepreg segments off of the cutting machine, and placing the first prepreg segments in end-to-end relation onto a conveyor belt of an adhesion machine, and in an orientation such that the segment cut edges are generally parallel to a lengthwise direction of the conveyor belt. The method also includes feeding, using the conveyor belt, the first prepreg segments to an adhesion station of the adhesion machine, and adhering, using the adhesion station, the first prepreg segments to a continuous length of a backing material.

The problem of the present invention is to provide a substrate with high versatility, a method for producing the substrate, and a method for producing a unit cell using the substrate. The problem is solved by providing a substrate comprising a plurality of alkali metal azide spots on a substantially flat surface.

Described herein are methods of forming uncured sealant assemblies and also methods of forming seals between various parts using such assemblies. In some examples, an uncured sealant assembly comprises two protective layers and an uncured sealant layer, disposed in between. The uncured sealant assembly is stored and provided at a cure-inhibiting temperature, selected to minimize the curing rate of the uncured sealant layer. The size and the shape of the uncured sealant layer are specifically selected to ensure the complete coverage of the faying surfaces, filling of all gaps and voids between the faying surfaces, and controlling the shape and size of uncured sealant squeeze out between the faying surfaces. In some examples, the size and shape of the uncured sealant layer maybe be specifically selected to have no uncured sealant squeeze out between parts.

A method for fabricating a sheet structure from paper and/or paperboard material, which provides a thickness dimension ordinarily associated with corrugated paperboard material. The sheet structure is constructed from a first planar linerboard sheet and a second non-planar linerboard sheet, wherein a plurality of projections are cut and folded from the second linerboard sheet and are adhesively coupled to the first linerboard sheet, such that portions of the projections define a standoff between the first and second linerboard sheets.

Provided is a method of manufacturing plate-like members whereby shape defects in the plate-like members can be prevented to increase production yield and a laminate for use in the method of manufacturing plate-like members. A method of manufacturing a plurality of plate-like members by breaking a base material 11 for plate-like members into segments includes the steps of: preparing a base material 11 for plate-like members having a first principal surface 11a and a second principal surface 11b opposed to each other; forming a breaking groove 12a, 13a in the first principal surface 11a of the base material 11 for plate-like members; bonding a support film 14 to the second principal surface 11b of the base material 11 for plate-like members; bonding an adhesive film 17 to the first principal surface 11a of the base material 11 for plate-like members to cover the first principal surface 11a of the base material 11; and breaking the base material 11 for plate-like members into segments along the breaking groove 12a, 13a by pressing, through the support film 14 and with the adhesive film 17 bonded to the base material 11 for plate-like members, a region of the base material 11 for plate-like members where the breaking groove 12a, 13a is formed.