An article, such as a hardfaced wearpart, includes a substrate, a sheet metal shell connected to the substrate to define a cavity between the surface of the substrate and the shell, and a composite material filling the cavity and forming a coating on at least a portion of the surface of the substrate, the composite material including a hard particulate material infiltrated with a metallic brazing material. The shell may be connected to the substrate by welding or brazing to the substrate, and may wear away during use. The shell and the substrate may be used as part of an assembly for producing the article, where the shell is used as a mold for forming the composite material by filling the shell with the hard particulate material and subsequently infiltrating with the brazing material.

Method for binding a bundle (5) of leaves (1) in a binding back (7), whereby the bundle (5) is placed in the binding back (7) with an edge (2) of the leaves (1) and fastened therein, characterised in that for the binding use is made of a bundle (5) of leaves (1) of which a strip (4) of each of the leaves (1) has been separately double folded beforehand along the same line to form a fold line (3) that extends parallel to and at a distance (A) from the aforementioned edge (2).

A consumable filament for use in an extrusion-based additive manufacturing system, where the consumable filament comprises a core portion of a first thermoplastic material, and a shell portion of a second thermoplastic material that is compositionally different from the first thermoplastic material, where the consumable filament is configured to be melted and extruded to form roads of a plurality of solidified layers of a three-dimensional object, and where the roads at least partially retain cross-sectional profiles corresponding to the core portion and the shell portion of the consumable filament.

The present application provides a flexible substrate and a fabricating method thereof. The present application has the advantages that the inorganic protrusions are embedded in the bottom portion of the second polymer layer, which can improve the adhesion between the second polymer layer (organic) material and the inorganic material, and effectively prevent delamination of the second polymer layer and the inorganic layer in sequential processes for fabricating devices such as display panels or during usages of devices such as display panels. The inorganic layer can effectively block water and oxygen from entering the intermediate layer of the substrate, thereby improving reliability of devices such as display panels.

A frame includes a metal plate, an adhesive film and a plastic border. The plastic border is wrapped around a periphery of the metal plate, the adhesive film is sandwiched between the plastic border and the metal plate. The disclosure also provides an electronic device having the frame and a method for manufacturing the frame.

A composite structure includes a stepped portion formed by laminating a plurality of plies with end surfaces thereof being shifted from each other. The composite structure includes a body portion which includes a first structure portion where a first ply is laminated on a top layer of the first structure portion, a second structure portion where a second ply is laminated on a top layer of the second structure portion, and the stepped portion disposed between the first structure portion and the second structure portion, the second ply being positioned at a distance from the first ply in a lamination direction, and a first cover ply which includes a covering portion covering the stepped portion, one end portion, and the other end portion and is formed so as to cover only a part of a surface of the first ply or a part of a surface of the second ply.

A reusable insulation wrap may include a multilayer insulation member having at least one stretchable layer adapted to resist moisture and sized to closely wrap around an article, at least one insulative layer adapted to accommodate deformation of the at least one stretchable layer, and at least one protective layer adapted to be abrasion and moisture resistant and prevent damage to at least one of the at least one stretchable layer and the at least one insulative layer. A releasable fastener may be configured to close the multilayer insulation member in releasable engagement around the article; whereby, the wrap may be configured to stretch around and fit snugly on the article.

A component-embedded resin substrate (1) includes a plurality of resin layers (2) made of a first resin and laminated on one another, and a component (3) arranged to be surrounded by each resin layer (2) in a first group (8) which is a group of two or more resin layers arranged successively in a thickness direction included in the plurality of resin layers (2). An auxiliary resin portion (9) made of a second resin different from the first resin is arranged to be in contact with and along at least one of surfaces of the component (3).

Disclosed are various embodiments of a structural reinforcement system. The system reinforces hollow cavities within various products to increase the structural rigidity of the product. The system generally includes a rigid carrier, a bonding material, and an insert. The rigid carrier provides the primary structural reinforcement within the cavity, and also serves as a substrate to carry the bonding material. The insert is provided to increase the structural rigidity of the reinforcement system.

A molded product includes a body including a flat part and a projection protruding from the flat part, a design member including a design surface, and an adhesive member sticking the design member to the body. The adhesive member includes a buffer portion formed by cutting off a part of the adhesive member at a position corresponding at least to the projection. Thus, the adhesive member negates differences in level on the body, allowing the design surface to be smooth.