A method for producing a foam-molded product uses a producing apparatus including a plasticizing cylinder. The plasticizing cylinder has a plasticization zone, a starvation zone, and an introducing port which is formed in the plasticizing cylinder and via which a physical foaming agent is introduced into the starvation zone. The method includes: plasticizing and melting a thermoplastic resin into a molten resin in the plasticization zone; introducing a pressurized fluid containing the physical foaming agent having a fixed pressure into the starvation zone; allowing the molten resin to be in the starved state in the starvation zone; bringing the molten resin in the starved state into contact with the pressurized fluid having the fixed pressure in the starvation zone; and molding the molten resin into the foam-molded product. At least one pressure boosting part is provided in the starvation zone.

A liquid introduction apparatus for introducing liquid into a product includes a platform, a cabinet on the platform for receiving the product, a cover transfer mechanism on the platform and adjacent to the cabinet, and an introduction mechanism. The cover transfer mechanism moves a cover to seal the cabinet. The introduction mechanism includes an introduction nozzle extending through the cover, and the introduction nozzle is configured to connect to the product in the cabinet and introduce liquid into the product when the cabinet has a vacuum environment. An adhesive dispensing apparatus and a liquid introduction method are also disclosed.

Provided is a method for producing an injection molded article for obtaining an injection molded article by injection molding a copolymer using an injection molding machine and a mold having a hot runner, wherein the copolymer is a copolymer containing tetrafluoroethylene unit and a fluoroalkyl vinyl ether unit, and the number of functional groups of the copolymer is 100 or less per 10.sup.6 main-chain carbon atoms.

An injection molding apparatus includes a mold, an injection device, a porous structure, and a gas-driven unit. The mold has a mold cavity. The injection device is adapted to inject a material into the mold cavity so that the material is formed into a forming article. The porous structure is disposed on an inner surface of the mold cavity and corresponds to a non-appearance surface of the forming article. The gas-driven unit is connected to the mold and is adapted to drive a gas to flow into or flow out of the mold cavity through the porous structure. In addition, an injection molding method is also provided.

An injection molding machine with an injection system and a clamping system. The injection system may include a removable injection module defining a portion of the material flow path. The injection module may include all of parts that come in contact with the material between the material source and the mold. The injection module may include a valve arrangement movable between a fill position to load the injection module with material and an inject position to eject material from the injection module into the mold. The actuators for the injection module may be supported on the machine rather than the injection module. The clamping system may include a platen linear actuator to open and close the mold, and a hydraulic clamping system to apply clamping force to the closed mold. The hydraulic clamping system may include a free-float valve manifold assembly that selectively places the hydraulic cylinders in free-float mode.

A gardening glove consisting of a glove liner defining a plurality of fingers, a thumb, and a palm is provided. The glove liner is placed on a first glove mandrel and received inside an injection mold configured to inject hot liquid PVC material on the glove liner's palm, fingers, and thumb, creating patterns of raised nodules that facilitate digging, for example.

A fiber-orientation system for a fiber-reinforced thermoplastic is provided. In various embodiments, the system includes a first tool, and a second tool that, in combination with the first tool, defines a gap therebetween configured to define a flow path for a fiber-reinforced thermoplastic melt during an injection molding. A plurality of electrodes are disposed in the first tool. The electrodes have exposed ends disposed in or along the flow path such that the electrodes are configured to, when energized, orient fibers within the thermoplastic melt. This provides a localized, controllable modification of the orientation of the fibers within the melt.

A housing assembly includes a housing, a printed circuit board (PCB) contained in a housing, and a cup-shaped cap having an interior and a flange portion. A tall component extending from the PCB is covered by the cap such that the tall component is disposed in the interior of the cap and the flange portion of the cap engages the PCB. A vacuum is applied and while maintaining the vacuum, an encapsulant is introduced into the housing to a level so as to cover the PCB and certain other components not the relatively taller component(s). When the vacuum is released, a pressure differential between the environmental pressure and the vacuum remaining in the cap interior forces encapsulant into the cap interior to a level higher than that outside of the cap. A multi-level height potting process is achieved.

A method for molding a part includes forming a mold having a part cavity and an associated electromagnet, placing resin in the part cavity, the resin including a ferromagnetic pigment, energizing the electromagnet and moving the ferromagnetic pigment towards an A-surface area of the part, and curing the resin with the ferromagnetic pigment concentrated at the A-surface area of the part. The A-surface of the part is free of flow marks and dark spots. Also, the ferromagnetic pigment is introduced into the resin before the resin is placed in the part cavity, or in the alternative, the ferromagnetic pigment is introduced into the resin after the resin is placed in the part cavity.

A cleaning system for use with a filter is described herein. The cleaning system includes a housing including a main enclosure defining an interior sized to receive the filter, a collection vessel coupled in communication with the housing, and a nozzle configured to direct a stream of air towards the filter to dislodge particles from the filter. A pneumatic suction device is coupled in communication with the collection vessel, wherein the pneumatic suction device is configured to draw the particles dislodged from the filter towards the collection vessel.