A composite material forming device includes a pressurizing unit, heating unit, a movement mechanism, and a control unit. The device processes a composite material in which reinforced fibers have been impregnated with a thermosetting resin from a softened state or semi-cured state into a cured state while forming the composite material into a prescribed size and prescribed shape. The pressurizing unit applies pressure to a prescribed region of the composite material. The heating unit applies a magnetic field to the prescribed region of the composite material to which pressure has been applied by the pressurizing unit, thereby heating a prescribed region of the composite material. The movement mechanism causes the pressurization region and heating region to synchronously move by simultaneously changing the position of a first member relative to the composite material and the position of the heating unit relative to the composite material.

A vehicle interior material manufacturing apparatus includes a preheater for preheating a raw fabric, a mover for moving the preheated raw fabric and including a stretching jig movable back and forth, a first mold into which the preheated raw fabric is inserted by the mover, a second mold having an at least partially corresponding shape to the first mold, and an injection resin introduced into the second mold, wherein the first mold includes: a base member on which an embossed pattern to be transferred to the preheated raw fabric is formed, a vacuum hole through which the preheated raw fabric is adsorbed onto the base member, and a spring core protruding from the base member and contacting at least a portion of the preheated raw fabric inserted into the first mold.

A vehicle interior material manufacturing apparatus includes a preheater for preheating a raw fabric, a mover for moving the preheated raw fabric and including a stretching jig movable back and forth, a first mold into which the preheated raw fabric is inserted by the mover, a second mold having an at least partially corresponding shape to the first mold, and an injection resin introduced into the second mold, wherein the first mold includes: a base member on which an embossed pattern to be transferred to the preheated raw fabric is formed, a vacuum hole through which the preheated raw fabric is adsorbed onto the base member, and a spring core protruding from the base member and contacting at least a portion of the preheated raw fabric inserted into the first mold.

A system and method to dispense, mix, and inject liquids and force them into a vented investment pattern mold cavity comprises a source of raw materials in fluid communication with an injection unit for metering and delivering the raw materials. A mixing and injection head receives and mixes the metered raw materials. A movable molding cart upon which an investment pattern mold is mounted is disposed adjacent the injection unit and proximate the mixing and injection head. The movable molding cart includes a fill cup that may be engaged by the mixing and injection head. A displaceable gating tray provides fluid communication with the fill cup and a sprue aligned with an investment port on a lower portion of the investment pattern mold. The system also includes a digital computer control by which the injection process may be controlled.

A method and apparatus for curing a composite workpiece to form a part. In one illustrative embodiment, an apparatus may comprise an object, a portable structure, and a heating system. The object may have a shape selected for a part. The portable structure may comprise a retaining structure configured to hold the object. The retaining structure may have a first side and a second side. The heating system may be configured to cover the object at the first side of the retaining structure and the second side of the retaining structure. The heating system may be further configured to generate heat for use in curing a workpiece placed over the object to form the part.

A method and apparatus for curing a composite workpiece to form a part. In one illustrative embodiment, an apparatus may comprise an object, a portable structure, and a heating system. The object may have a shape selected for a part. The portable structure may comprise a retaining structure configured to hold the object. The retaining structure may have a first side and a second side. The heating system may be configured to cover the object at the first side of the retaining structure and the second side of the retaining structure. The heating system may be further configured to generate heat for use in curing a workpiece placed over the object to form the part.

A method of manufacturing a composite molded body includes a first step of introducing an FRP base material into a mold via a slit part provided in the mold, and inserting the FRP base material along a mold cavity; and a second step of injecting a molten thermoplastic resin composition A into the mold cavity to form the FRP base material into a three-dimensional shape and integrate the injected thermoplastic resin composition A and the FRP base material. The method makes it possible to easily and accurately mold a composite molded body of which a desired portion is efficiently and accurately reinforced in the same mold.

A cooler including a container comprising a linear low-density polyethylene and a glow-in-the-dark additive, a lid comprising the linear low-density polyethylene and the glow-in-the-dark additive and coupleable to the container, each of the container and the lid including an insulation layer, and the glow-in-the-dark additive emitting light when exposed to an external electromagnetic radiation source. A method includes rotomolding a cooler comprising a linear low-density polyethylene polymer and a glow-in-the-dark additive. A method of using a cooler comprising a linear low-density polyethylene polymer and a glow-in-the-dark additive includes exposing the cooler to an external electromagnetic radiation source and removing the cooler from the source, and illuminating the surrounding area with the cooler.

A cooler including a container comprising a linear low-density polyethylene and a glow-in-the-dark additive, a lid comprising the linear low-density polyethylene and the glow-in-the-dark additive and coupleable to the container, each of the container and the lid including an insulation layer, and the glow-in-the-dark additive emitting light when exposed to an external electromagnetic radiation source. A method includes rotomolding a cooler comprising a linear low-density polyethylene polymer and a glow-in-the-dark additive. A method of using a cooler comprising a linear low-density polyethylene polymer and a glow-in-the-dark additive includes exposing the cooler to an external electromagnetic radiation source and removing the cooler from the source, and illuminating the surrounding area with the cooler.

A sliding mechanism includes a slider movable along a predetermined direction, an interlock member, an inner holder, and an outer holder. The interlock member is movable in a first direction in engagement with the slider. The interlock member, the inner holder, and the outer holder each include guiding sections to guiding the slider along the predetermined direction. The outer holder includes a guiding section guiding the inner holder along the first direction, and the inner holder can move in such a way that the inner holder is displaced relative to the outer holder.