A cover (5) of an electronic device has side walls (8) and a ceiling wall (9), and is molded by injection molding using a mold. The ceiling wall (9) has a flat plate shape. Disk-shaped thick portions (21) that locally protrude inward so as to be relatively thicker than an adjacent normal portion of the ceiling wall (9) are provided at a plurality of positions of the ceiling wall (9) corresponding to respective positions of ejection by ejection pins (25). Although a circular dent (22) is formed at a middle of the thick portion (21) due to the thick portion (21) being pressed by a tip of the ejection pin (25), even at this dent (22) portion, a thickness equal to or greater than that of the normal portion of the ceiling wall (9) is secured.

Disclosed is an injection mold. The injection mold includes a mold set having n molds (n is a natural number of 2) defining a cavity for injection molding a green body, and at least one ejector provided on at least one of the n molds to separate an injection-molded part from the mold set. The ejector is provided with a first heater capable of heating the mold set to a first temperature.

An improved injection mold for forming an injection molded component. The injection mold includes a main cavity block and a main core block that are moveable with respect to one another. The main cavity block has a cavity block mating face that includes a first mold surface and the main core block has a core block mating face that includes a second mold surface. A plurality of induction heating coils extend within the main cavity block and a plurality of gas inlet channels extend through the main core block. The second mold surface includes a plurality ridges that cooperatively form a continuous gas flow path that is disposed in fluid communication with the plurality of as inlet channels. The continuous gas flow path follows a serpentine shape to provide even and uninterrupted gas flow across the second mold surface.

A mold apparatus includes first and second mold plates that constitute a cassette mold, a first base mold, a base intermediate mold for loading the first mold plate, a second base mold for loading the second mold plate, a base intermediate mold driving device for positioning and fixing the base intermediate mold at any position between the first and second base molds, and a controller for performing control to position and fix the base intermediate mold so that the first mold plate and the first base mold are in contact with each other when a molded product is taken out.

An injection mold that has an injector mold plate with a first injector mold plate face and an opposite second injector mold plate face, an ejector mold plate having a first ejector mold plate face and an opposite second ejector mold plate face, with the first injector mold plate face faces the first ejector mold plate face, at least one tempering medium channel connecting a tempering medium inlet of the injection mold to a tempering medium outlet of the injection mold, wherein the at least one tempering medium channel traverses an area of at least one of the second injector mold plate face and/or the second ejector mold plate face and defines a free opening in the respective mold plate face along at least a length of the at least one tempering medium channel.

An electrical connector is used to electrically connect a chip module to a circuit board. The electrical connector has an insulating body, provided with multiple accommodating holes vertically penetrating through the insulating body. An upper surface of the insulating body protrudes upward to form a protruding block located between adjacent ones of the accommodating holes to support the chip module. The protruding block has a first ejector pin surface. The insulating body has a second ejector pin surface adjacent to the protruding block. The first ejector pin surface and the second ejector pin surface are provided for an ejector pin on a mold to push thereon so as to push the insulating body out of the mold. Multiple terminals are correspondingly accommodated in the accommodating holes to be electrically connected to the chip module.

Provided is an injection molding apparatus for a worm wheel, in which the worm wheel is not only integrally manufactured by an injection mold method, but a gear teeth structure of a gear forming unit is also manufactured as an injection mold without a hobbing operation, and the structure of the injection molding apparatus is also improved so that worm wheel products can be easily taken out from the injection mold. The injection molding apparatus includes: a boss injection mold; a product injection mold having a movable side core, a fixed side core, and a worm gear tooth-shaped core; and a take-out unit for taking out a worm wheel product formed with a worm gear by the product injection mold, wherein the take-out unit includes: a plurality of take-out pins; a take-out plate; and a guide unit guiding rotation of the worm gear tooth-shaped core.

A die casting machine includes a plurality of ejector pins capable of advancing and retracting together with respect to the internal portion of a die; an electric motor capable of driving the plurality of ejector pins; a position sensor capable of detecting the positions of the plurality of ejector pins; a force sensor capable of detecting the pressure which is given to the molding material inside the die by the plurality of ejector pins; a display device capable of displaying images, and a control device controlling the electric motor and display device. The control device includes a drive control part which controls the electric motor so as to generate a driving force making the plurality of ejector pins advance to the inside of the die after the start of injection and before die opening, and a display control part which controls the display device so as to display the position detected by a position sensor and the pressure detected by a force sensor along a common time axis.

A method of forming a thin-walled skin includes coating at least one side of a mold cavity of a molding tool, evacuating air from the mold cavity, and filling the mold cavity with a molten polymeric resin. Among other optional variations of the disclosed method, an inert gas is injected into the molten polymeric resin simultaneously with the step of filling the mold cavity with a molten polymeric resin. As a result, high quality, large, thin-walled skins are produced by the teachings of the present disclosure.

Provided is a method of manufacturing a resin retainer having two annular sections. A fixed-side cavity forming mold has a first axial mold surface that is in contact with an axial end surface of a first annular section of the annular sections of a resin retainer having two annular sections, and a first protruding portion protruding from the first axial mold surface. A movable-side cavity forming mold has a second axial mold surface that is in contact with an axial end surface of a second annular section of the annular sections of the resin retainer, and a second protruding portion protruding from the second axial mold surface. A slide core sliding step is performed in which slide cores are slid toward an outer diameter and pocket-forming protruding portions of the slide cores are extracted from a pocket of the retainer, and then a mold opening step is performed in which the movable-side cavity forming mold is opened relative to the fixed-side cavity forming mold.