Method for producing a seat for a vehicle, the bottom and the foam obtained by molding in a double mold by the following subsequent steps: gluing: in which a robot moves the molded product in front of a glue nozzle; activation: in which the robot transfers the molded product into a heating station, activating the glue; loading: in which a user arranges the cover in a loading station; superimposition: in which the cover is transferred into a superimposition station; simultaneously, a second robot grasps the molded product and moves it into the superimposition station; pressing: in which a plurality of grippers press the edge of the cover against the edge of the bottom, causing irreversible gluing between the bottom and cover, forming the seat; moving-away: in which the second robot grasps the seat from the superimposition station and places it on a conveyor belt to move it away.

A method for producing parts from polymer in a mould comprising first and second mould portions that can be moved relative to each other, comprising: closing (202) the mould in order to form a first injection cavity connected to an injection device by the first mould portion, injecting (204) material into the first injection cavity in order to form a first part, moving (206) one of the mould portions relative to the other, the first part remaining connected to the second mould portion, closing (208) the mould to form: a second injection cavity connected to the injection device by the first mould portion, and a first solidification cavity in which the first part is disposed, injecting (210) material into the second injection cavity to form a second part and simultaneously solidifying the first part disposed in the first solidification cavity.

A syringe includes a barrel having a proximal end, a distal end, and a sidewall extending substantially circumferentially between the proximal end and the distal end along a longitudinal axis. The barrel is formed from an injection molding process including aligning a mold die defining an internal shape of the barrel in a molding cavity defining an external shape of the barrel, the molding cavity defined by first and second mold sections. Each mold section includes at least one gate adapted to control the flow of a molding material into the molding cavity. The gates of each mold section are opened to permit the first and second melt streams of molding material to fill the molding cavity surrounding the mold die, where the molding material takes the shape of the molding cavity.

This disclosure provides an injection molding system for use with a material, the system comprising: a heated barrel; a member mounted in the barrel for melting the material and for ejecting molten material; a pair of mold plates, one of the pair being operatively coupled to the barrel in use, the other of the pair being movable relative to other plate for movement between a closed position and an open position, characterized in that the barrel is defined by a nested part and a protruding part, the nested part having an external end which is disposed exteriorly of the one of the pair of mold plates and an internal end which, in use, is disposed interiorly of the one of the pair of mold plates and engaged therewith, the protruding part, in use, extending to the nested part and being releasably coupled thereto in end-to-end communicating relation.

A system comprises a fully automated fabrication cell (20) for forming overmolded oral care implements. The cell (20) includes a cluster of process stations (21) including injection molding machines operable to first form oral care implement preforms and then overmold the preforms with an overlay to create fully formed oral care implement bodies. In one example, the overlay may be a flexible elastomeric or rubber material while the preform may comprise a more rigid plastic material. Transfer of the preforms and bodies between the process stations (21) is fully automated and performed by a computer-operated robot (40) having a jointed articulated arm. A grasping tool (60) disposed on an end of the arm (42) releasably engages and transports a plurality of preforms and/or bodies simultaneously. The tool provides two different methods for engaging and holding the toothbrush skeletons/bodies. A programmable controller (130) automatically controls the robotic arm (42)'s operation and movement.

To produce first and second light control panels 11, a molded preform 22 made from a transparent resin, which includes triangle-cross-section grooves 15 (each having an inclined surface 14 and a vertical surface 23) and triangle-cross-section protruded strips 16 (formed by the grooves 15 next to each other) respectively arranged in parallel on a front side of a transparent plate material 12, is produced by press-molding, injection-molding, or roll-molding, and mirror surfaces 13 are selectively formed only on the vertical surfaces 23 of the grooves 15. The first and second light control panels 11 each having a group of band-like light-reflective surfaces standing upright and spaced in parallel are overlapped such that the groups of band-like light-reflective surfaces are crossed in a plan view. Thereby providing a stereoscopic-image-forming device and its producing method enabling to easily produce the first and second light control panels 11 and obtain clearer stereoscopic images.

The invention relates to a dispenser container consisting of an outer container and an inner container for receiving a fluid, wherein the outer container and the inner container are formed from blow-moulded plastics, which do not form an integral connection with one another, and wherein a first plastic from which the inner container is formed has a higher elasticity than a second plastic from which the outer container is formed, such that the inner container is deformable, and wherein the outer container has at least one pressure compensation opening for pressure compensation in the region between the outer container and the inner container, wherein the inner container has a first outlet region and the outer container has a second outlet region, wherein the first outlet region can be shifted relative to the second outlet region in an outlet direction.

A device (6) for producing injection-molded parts (1) is provided, with the device device (6) having at least one cooling device (9) in which pre-molded parts (4) are cooled before the injection-molding of a further material component (3). A method is also provided with improvements in the technical field of the production of injection-molded parts (1), in particular of brushes or toothbrush bodies.

A vehicle part includes an injection molded main body having a front side and a rear side with a three dimensional form on the rear side, a metallized coating on one or more portions of the three dimensional form on the rear side of the injection molded main body, and a backing layer overmolded on the rear side of the injection molded main body, the three dimensional form, and the metallized coating.

A cooling device for cooling a plurality of preforms or tubular containers, preferably exiting from a rotary injection molding apparatus, the device comprisinga first longitudinal support member (7) defining a longitudinal axis Y and having a first longitudinal surface (2) and a second longitudinal surface (3) opposite to the first longitudinal surface; a plurality of cooling tubes (4), each adapted to receive a respective preform to be cooled, said cooling tubes being arranged on said first longitudinal surface (2) in sequence along the longitudinal axis Y and each cooling tube defining a perpendicular axis thereof with respect to said longitudinal axis Y; at least one first connection pin (5) protruding from said second longitudinal surface (3) for a quick coupling to a second longitudinal support member (14), preferably adapted to be arranged on a rotary cooling apparatus.