One aspect is an overmolded hinge device having a first and a second shaft, each having first and second ends. A first friction element is mounted on the first shaft. A first molded housing is at least partially enclosing the first shaft and a second molded housing is at least partially enclosing the second shaft. A first molded outer link is at least partially enclosing each of the first and second shafts and a second molded outer link is at least partially enclosing each of the first and second shafts. One of the first molded housing and the first molded outer link enclose the first friction element

A one-piece cast component having at least one integrated attachment part is disclosed. The component includes at least one pin which is rigidly connected to an attachment part; a housing at least partially enclosing the pin in a contactless manner; the pin being arranged in the axial direction between two axial connecting webs and being rigidly connected via the latter to the housing; the pin being arranged in the radial direction between a plurality of radial connecting webs and being rigidly connected via the latter to the housing; wherein the connecting webs are dimensioned in such a way that only the latter break at respective predetermined breaking points when pivoting the attachment part for the first time relative to the housing, whereafter the attachment part, together with the pin, is mounted so as to be pivotable with respect to the housing. The regions of the connecting webs that remain on the housing after the breaking operation prevent the pin from being removed from the housing. The disclosure further relates to a method for producing such a cast component having an integrated attachment part.

A structural component for a floor assembly of a vehicle. The structural component is formed integrally and includes at least one hinge element and a base part. The base part is configured to support the structural component on the vehicle when the structural component is installed in the vehicle. The at least one hinge element includes at least one flap element which is connected at least in regions to the base part and is configured to be pivoted relative to the base part and, in an end position, to at least partially enclose at least one predetermined construction space of the vehicle. The at least one flap element is furthermore configured in order, in the end position, to abut or to engage in a form-fitting manner against or on respective vehicle elements delimiting the at least one construction space of the vehicle.

A mould for forming a collapsible container from an expandable material, the container comprising, at least a base and two pairs of a side walls extending at right angles from opposing sides of the base, the mould comprising: a first mould member and a second mould member movable with respect to each other between an open and a closed moulding position to define a mould cavity; and a plurality of anvils mounted on a rear surface of at least one of the first mould member and/or second mould member, each anvil being movable so as to be extended into the mould cavity so as to form one or more hinges in the expandable material at predetermined locations within the mould cavity; wherein the mould cavity defined by the first mould member and the second mould member is a three-dimensional representation of an inside-out configuration of the assembled container.

A hinged component comprising a polyethylene composition having a molecular weight distribution M.sub.w/M.sub.n, of from 2.0 to 7.0; a density of at least 0.949 g/cm.sup.3; a melt index, I.sub.2 of from greater than 10.0 g/10 min to 20.0 g/10 min, a Z-average molecular weight M.sub.Z, of less than 300,000; and a melt flow ratio I.sub.21/I.sub.2, of from 24 to 38; where the hinged component has an average hinge life of more than 4100 cycles.

There is described a method of creating a hinge in a body of expandable material, said body being substantially flat and having at least two planar regions connected by said hinge to facilitate folding of the planar regions about said hinge, comprising: expanding said expandable material to form said body; creating a region of excess expandable material in said body adjacent said hinge; and compressing said region of excess expandable material into the hinge of said body after the expandable material has fused to create a hinge having a concentrated volume of expanded material when compared to said at least two planar regions of said body.

A stretch blow-molded plastic container, including a container body, one longitudinal end of which is closed by a container bottom and to whose other longitudinal end is connected a shoulder section; and a container neck, which connects to the shoulder section, the shoulder section having at least two hinge-like areas that run in a circumferential direction, and which areas are arranged at a distance (a) from one another and in each case have a wall thickness (v, w) that is reduced compared to the adjoining areas, the stretch blow-molded plastic container having a total stretching ratio of greater than 11 for a longitudinal stretching ratio of 2.5 to 3.5.

A foamed plastic foldable container has a first wall, a pair of mutually facing second walls hingedly coupled to the first wall, a pair of mutually facing third walls hingedly coupled to the first wall, and a closing wall defined by at least one panel hingedly coupled to one of the second walls.

A portable information handling system presents visual images with a flexible display disposed over separate housing portions rotationally coupled by a set of hinges having an opening defined between them. A multi-segmented support couples to the hinges in the opening to dispose a planar surface proximate the flexible display and extend plural parallel members up from the planar support between the hinges, the plural parallel members separating in response to rotation from a flat to a curved orientation.

A method of forming and assembling a foldable plastic utility enclosure using molds to form sides of the enclosure, preferably using glass fiber-reinforced thermoplastic composite. The molds are constructed to form a central hole in hinge members which are formed on ends of the sides. The central hole of the hinge member is molded with two molding parts, wherein one or both of the molding parts have a solid central portion that forms the central hole. The sides are removed from the molds after curing and the sides are assembled to form the utility enclosure while the sides are still hot from the molding process. Hinge pins are inserted into the central holes of the hinge members to form hinges and to prevent the sides from warping during cooling. Assembling the sides and inserting hinge pins to form the utility enclosure is completed within approximately 10 minutes after removing the sides from the molds.