A core according to one aspect of the present disclosure is a core that is inserted into a space between a skin and a stringer in a step of integrally molding the skin and the stringer, the skin including fiber-reinforced resin, the stringer having a hat-shaped section that is open toward the skin. The core includes: a first die that extends along a longitudinal direction of the stringer and contacts the skin; a second die that extends along the longitudinal direction of the stringer, is adjacent to the first die, and contacts the skin; and a third die that extends along the longitudinal direction of the stringer, is located at an opposite side of the skin across the first die and the second die, and contacts both the first die and the second die.

The present invention relates to an injection moulding system for forming an oven liner, particularly of the type that is used with microwave ovens. Oven liners are of particular benefit when used inside microwave ovens. They improve hygiene as where food spills or spurts onto the oven liner rather than an interior of the microwave oven. An injection moulding system for forming an oven liner includes: a first mould tool which defines a cavity of length (L), width (W) and height (H), the first mould tool has a substantially rectangular end face with dimensions corresponding to the width (W) and height (H) of the cavity and has a hot feed located at a centroid of its end face; and a wedge collapsing tool is received in the cavity so as to contact and engage with an external periphery of the first mould tool at selected locations in order to define a volume into which hot material feed is injected, wherein the wedge collapsing tool comprises a first part and a second part in slidable contact one with another, and the width (W2) of the second part exceeds the width (W1) of the first part of the wedge collapsing tool by at least 0.1 mm so that a split line is formed on at least one side of an interior surface of the oven liner.

A method for forming a vehicle reinforcing member (26, 28, 30). The method includes conforming a planar body of fibre reinforced material (CFRM) (504), such as a sheet or unidirectional tape, to a shape of a shape defining member (506, 900). In effect, the shape defining member (506, 900) is a core that defines an internal volume of a closed cross-section portion of the vehicle reinforcing member (26, 28, 30). The CFRM material (504) comprises continuous fibres in a synthetic matrix. The method further includes bonding a first edge portion (510) of the CFRM body (504) to a second edge portion (512) of the CFRM body (504) thereby to form the closed cross-section portion of the vehicle reinforcing member (26, 28, 30). An apparatus (800) for implementing the method, and components (e.g. vehicle reinforcing members (26, 28, 30), vehicle seats (10) and so forth) formed using the method are also described.

A composite forming method includes manufacturing either one of a composite structure body and a dry preform having a hollow region, and pulling a core out of the hollow region. In the manufacturing, a rubber-made core having a tubular structure is disposed at a portion that forms the hollow region of either one of the composite structure body and the dry preform. The core has a thickness varied in a direction perpendicular to a longitudinal direction to be foldable inward at a thin portion. In the pulling, the core is folded inward with air being discharged from an inside of the core after either one of the composite structure body and the dry preform is manufactured.

A composite forming method includes manufacturing either one of a composite structure body and a dry preform having a hollow region, and pulling a core out of the hollow region. In the manufacturing, a rubber-made core having a tubular structure is disposed at a portion that forms the hollow region of either one of the composite structure body and the dry preform. The core has a thickness varied in a direction perpendicular to a longitudinal direction to be foldable inward at a thin portion. In the pulling, the core is folded inward with air being discharged from an inside of the core after either one of the composite structure body and the dry preform is manufactured.

A mold for producing atomizer nozzles, wherein a mouthpiece core mold part defines an inner wall of the mouthpiece, at least in the region of a transition between the mouthpiece and the flow chamber, and is of integral design, wherein the flow chamber core mold part has a substantially smooth surface and continuous contours in the region of the transition from the flow chamber to the mouthpiece, and wherein the mouthpiece core mold part is placed against the flow chamber core mold part at the transition between the flow chamber and the mouthpiece.

Methods and devices for manufacturing plastic preforms and plastic containers are provided. Methods of manufacturing a plastic preform having an inner undercut include forming a preform of plastic in amorphous state and inserting a plug within the mouth of the preform. The plug includes an upper plug member and an expandable element, the expandable element having an initial outer diameter in plan view with the plug in an initial condition and a deployed outer diameter in plan view with the plug in a deployed condition. Methods further include deploying the plug to the deployed condition with the expandable element positioned to engage a side wall proximate the inner undercut and crystallizing the plastic of the preform along the finish portion.

Methods and devices for manufacturing plastic preforms and plastic containers are provided. Methods of manufacturing a plastic preform having an inner undercut include forming a preform of plastic in amorphous state and inserting a plug within the mouth of the preform. The plug includes an upper plug member and an expandable element, the expandable element having an initial outer diameter in plan view with the plug in an initial condition and a deployed outer diameter in plan view with the plug in a deployed condition. Methods further include deploying the plug to the deployed condition with the expandable element positioned to engage a side wall proximate the inner undercut and crystallizing the plastic of the preform along the finish portion.

Techniques and assemblies are disclosed for a molding assembly to manufacture an article. The assembly includes a mold cavity block including a first molding surface. Received in the mold cavity block is a core that includes a second molding surface and an inner surface. The second molding surface and the first molding surface define a part cavity in which to manufacture the article. The inner surface is opposite the second molding surface and defines an internal cavity within the core. Received within the internal cavity and in contact with the inner surface therein is an insert. The insert includes at least one fluid channel within one or more external surfaces of the insert. The fluid within the fluid channel is to contact the inner surface to transfer thermal energy to the fluid from an article located within the part cavity via the second molding surface and the inner surface.

A blemish free surface is formed on the cavity side of a set of mold or die blocks, said set consisting of a core side and a cavity side, by use of a softer alloy on the core side as contrasted to the cavity side so that, during plastic injection molding, the core side will wear at the parting line in preference to the cavity side whereby erosion of the set occurs on the core side in preference to the cavity side leaving the cavity side erosion free.