An injection mold (100) including a core plate assembly (200), a cavity plate assembly (400) and a stripper plate assembly (300) arranged between the core and cavity plate assemblies (200, 400). The mold (100) includes a plurality of mold stacks (MS) with a molding configuration, in which the mold stacks (MS) are closed to define molding cavities. A gap (G) is provided between the core plate (210) and the stripper plate (310) when the mold (100) is in the molding configuration, such that a clamping load (CL) applied to urge the core plate (210) toward the cavity plate (410) is directed substantially entirely through the mold stacks (MS).

A molding tool for forming a non-pneumatic tire includes a wheel portion cavity, a tread ring portion cavity, and a plurality of spoke cavities extending between the wheel portion cavity and the tread ring portion cavity. At least a subset spoke cavities within the plurality of spoke cavities include at least one of a non-uniform thickness, a non-uniform width, and a non-uniform surface. Also, the molding tool can include a conformal thermal control channel, e.g., a conformal cooling channel and/or a conformal heating channel, proximate to at least one mold cavity.

A molded resin component includes a first surface on which a convex portion is formed, and a second surface opposite to the first surface. The convex portion includes a molding mark formed by a valve pin of a manufacturing apparatus that manufactured the molded resin component. A shape of at least a portion of a leading-end surface of the valve pin is not transferred into the molding mark.

A mold apparatus including a mold, a cooling flow path, and a sensing module is provided. The mold has a cavity. The sensing module is adapted to sense at least one of a temperature and a pressure in the cavity. The sensing module is surrounded by the cooling flow path.

An injection molding device includes a stationary mold provided with a first gate opening, and a second gate opening, a movable mold configured to be mold-clamped against the stationary mold, a first hot runner configured to inject a first molding material in a cavity compartmented by the stationary mold and the movable mold, via the first gate opening, a second hot runner configured to inject a second molding material in the cavity via the second gate opening, and a cooler configured to cool the stationary mold. An end surface of the stationary mold opposed to the movable mold has a first region located between the first gate opening and the second gate opening, and a second region different from the first region. The cooler is configured so that a cooling performance with respect to the first region becomes higher than a cooling performance with respect to the second region.

Embodiments of the innovation relate to a seal plug which includes a plug body having a first sealing portion and a second sealing portion; the first sealing portion having a first sealing portion diameter and defining a radial channel having a first shoulder and a second shoulder, the radial channel having a radial channel diameter that is smaller than the first sealing portion diameter; a set of threads disposed about an outer periphery of the second sealing portion, the set of threads defining a major diameter and a minor diameter; and an o-ring disposed within the radial channel defined by the first sealing portion and between the first shoulder and the second shoulder, the o-ring having an outer diameter that is smaller than the minor diameter of the set of threads of the second sealing portion.

A method of making an electrically conductive and weatherproof enclosure includes mixing and melting an electrically conductive material, a latex rubber material, and a polycarbonate material to produce a weatherproof material mixture, blending carbon black with polyethylene to produce an electrically conductive additive, positioning an injection mold of the enclosure in fluid communication with an exit end of a heating barrel, injecting the weatherproof material mixture into an entry end of the heating barrel, introducing the electrically conductive additive through a lateral port of the heating barrel proximate to the exit end to partially mix with the weatherproof material mixture to produce an injection mixture, and injecting the injection mixture into the injection mold to produce the electrically conductive and weatherproof enclosure.

A rotating apparatus includes a rotary plate for mounting a tool part, a rotary shaft connected to the rotary plate, a rotary feedthrough including a stator, and a rotor connected to the rotary shaft for feeding through at least two media to the rotary plate. The rotor has a first rotor part for feeding through a first medium and a second rotor part for feeding through a second medium, and the first and the second rotor parts are thermally separated from each other. A first media routing for the first medium is in the form of a hose and/or pipe for the first medium from the first rotor part past the connecting part to the rotary plate. A connecting part is non-rotatably connected to the second rotor part and the rotary shaft. The hose and/or pipe extends from the first rotor part.

Embodiments of the innovation relate to a seal plug which includes a plug body having a first sealing portion and a second sealing portion, an o-ring disposed about an outer periphery of the first sealing portion, and a set of threads disposed about an outer periphery of the second sealing portion. The second sealing portion defines a tool engagement portion.

An injection mold (100) including a core plate assembly (200), a cavity plate assembly (400) and a stripper plate assembly (300) arranged between the core and cavity plate assemblies (200, 400). The mold (100) includes a plurality of mold stacks (MS) with a molding configuration, in which the mold stacks (MS) are closed to define molding cavities. A gap (G) is provided between the core plate (210) and the stripper plate (310) when the mold (100) is in the molding configuration, such that a clamping load (CL) applied to urge the core plate (210) toward the cavity plate (410) is directed substantially entirely through the mold stacks (MS).