An ostomy pouch assembly (1) comprises a receptacle (2) for receiving material from a stoma of a person, and a mounting plate (4) for securing the receptacle to a person's body. The mounting plate includes a first layer (10) with an outer surface that is configured to be bonded to a person's skin and an inner surface. An intermediate layer (12) is located between the inner surface of the first layer (10) and the receptacle (2). A stress displacement or bonding layer (16) is located between the intermediate layer (12) and the receptacle (2) for bonding the mounting plate (4) to the receptacle (2). The region of bonding securement between the bonding layer (16) and the intermediate layer (12) has a first peripheral edge (20), and the region of bonding securement between the bonding layer and the receptacle has a second peripheral edge (26) that is located inwardly of the first peripheral edge (20).

A method for thermally joining thermoplastic fiber composite components, including jointly covering thermoplastic fiber composite components to be joined, at least in the region of a joining zone, with a pressurization arrangement, which is flexible, at least in some section or sections, and extensive pressurization of thermoplastic fiber composite components to be joined by the pressurization arrangement, with the result that the fiber composite components are pressed against one another, at least in the joining zone. The fiber composite components are welded in the joining zone during pressurization. The pressurization is maintained by the pressurization arrangement until the joining zone solidifies. A cover is also disclosed, in particular a mold or diaphragm, for a pressurization device for thermally joining thermoplastic fiber composite components, and an apparatus for thermally joining thermoplastic fiber composite components.

The present invention relates to a hose line (1) for transporting abrasive media with an electrically conductive reinforcing element (5) running in or on the hose wall (2) and extending in the hose direction (6), wherein an insert (7) made of electrically conducting material is at least partially embedded in the hose wall (2) and extends in the hose direction (6) at a distance from the reinforcing element (5).

Disclosed is a method for setting-up and adjusting a system including a conveying table, as well as a first and a second module. Also disclosed is a system, a first and a second module and a conveying table for transporting hollow bodies, including: at least two transfer wheels having an upstream-end transfer wheel and a downstream-end transfer wheel; and a rigid common chassis which rotatably supports all the transfer wheels via individual a rotational guide. Also disclosed is adjustment of the various transport elements with respect to one another because the setting-up of a system for the mass production of containers is an operation that requires precision so that the hollow bodies can circulate smoothly through the system.

A method is provided for forming a thermoplastic structure. During this method, a substrate is provided. The substrate includes a substrate thermoplastic and a plurality of substrate fibers disposed within the substrate thermoplastic. The substrate fibers are arranged in a substrate pattern. A first layer is deposited on the substrate using an automated fiber placement device. The first layer includes a first layer thermoplastic and a plurality of first layer fibers disposed within the first layer thermoplastic. The first layer fibers are arranged in a first layer pattern that is different than the substrate pattern. A blank is stamped into the thermoplastic structure. The blank includes the substrate and the first layer where the first layer thermoplastic is consolidated with the substrate thermoplastic.

An apparatus for internal heating of end portions of pipes made of thermoplastic material having a central axis including a heating element, designed to be inserted at least partially inside an end portion of a pipe made of thermoplastic material for heating an inner cylindrical surface of the portion, the heating element including an infra-red radiation unit designed to face at least partially the inner cylindrical surface.

The invention relates to a method for welding a polyolefin plastic and a plastic using a primer, said primer containing at least one maleic anhydride containing polymer and at least one polyester. The invention also relates to correspondingly bonded products.

There is provided a structural member configured to be disposed in an internal space of a fuel tank and support a wall of the fuel tank. The structural member has an axial direction along a direction in which the wall is to be supported, and a radial direction perpendicular to the axial direction. The structural member includes a gas introduction path which is formed to be exposed at a tip end of the structural member and penetrate an inside of the structural member along the axial direction, a first gap which is formed to be concaved in the radial direction to communicate with the gas introduction path through a first hole, and a second hole which is formed to communicate with the gas introduction path at a position more distant from the tip end than the first hole along the axial direction.

A process for manufacturing a water soluble product including the steps of: providing a water soluble fibrous first ply; providing a water soluble fibrous second ply formed on a surface other than the first ply, wherein the second ply is separate from the first ply; superposing the first ply and the second ply; and joining a first portion of the first ply to a second portion of the second ply to form the water soluble product.

The present disclosure generally relates to thermoplastic truss structures and methods of forming the same. The truss structures are formed using thermoplastic materials, such as fiber reinforced thermoplastic resins, and facilitate directional load support based on the shape of the truss structure. In one example, multiple two-dimensional patterns of fiber reinforced thermoplastic resin are disposed on one another in a saw tooth pattern, sinusoidal pattern, or other repeating pattern, and adhered to one another in selective locations. The two dimensional patterns may then be expanded in a third dimension to form a three-dimensional, cross-linked truss structure. The three-dimensional, cross-linked truss structure may then be heated or otherwise treated to maintain the three-dimensional shape.