An encapsulated anchor includes an anchor core and an encapsulation. The encapsulation is molded onto the anchor core. The anchor core includes one or more detents which correspond with one or more keys of an encapsulating mold. The detents engage one or more of the keys such that the anchor core is aligned properly in the encapsulating mold.

A mold for insert molding, which houses an electronic unit including a first circuit portion and a second circuit portion protruding from the first circuit portion, is prepared. The mold includes an upper wall surface facing an upper surface of the second circuit portion and side wall surfaces facing side surfaces of the second circuit portion. The flow resistance of a resin flowing through a space between each side surface of the second circuit portion and the corresponding side wall surface is lower than that of the resin flowing through a space between the upper surface of the second circuit portion and the upper wall surface. Then, the electronic unit is placed in the mold. Then, the resin is injected into the mold in which the electronic unit has been placed. Thus, the electronic unit and the housing in which the electronic unit is housed are integrated with each other.

A lacrosse head pocket includes a plug unit having first and second plugs disposed on a cross lace. The plugs are overmolded by first and/or second runners constructed from a polymeric material so that the plugs are joined with the first and/or second runners. The cross lace extends outwardly from the plug and the overmolded first and/or second runners. Some plug units can have cross laces that cross one another, while other plug units might not include cross laces that cross one another. A method is also provided including: forming a first plug on a first cross lace, placing the first plug in a mold, overmolding a first runner over at least a portion of the plug so the plug and first runner are joined, and optionally overmolding a second plug joined with the cross lace with a second runner or the same first runner.

A resin member with a gas permeable member (8) includes a resin member having at least one gas hole (20h) extending therethrough between a front surface (8a) and a back surface (8b), and a sheet-like gas permeable member (50) covering the gas hole. An outer circumferential portion (50p) of the gas permeable member is embedded in the resin member. The resin member further includes first recesses (22) disposed around the gas hole, depressed from at least one of the front surface and back surfaces, and allowing at least a portion of the gas permeable member to be visible in a front-back direction, and second recesses (24) disposed externally of an outer peripheral edge (50e) of the gas permeable member and depressed from at least one of the front surface and the back surface and through which the gas permeable member is invisible in the front-back direction.

The protective cover having a cup shape is mounted to an outer ring of a bearing so as to seal an inward-side end portion of the bearing. A protective cover includes: a disc part made of a synthetic resin; and a sensor holder part that is made of the synthetic resin and protrudes inward from the disc part. The disc part is provided with a separation wall which separates the magnetic encoder and the magnetic sensor from each other. The separation wall has a surface facing the magnetic encoder and a surface facing the magnetic sensor, and one of the surfaces has a mark of a gas drainage pin of an injection molding die.

A vehicle component (1, 17, 31, 46, 55, 62) for a motor vehicle, with a structural component (7, 16, 30) and with a casing (2, 18, 32, 38, 56, 57, 79). The structural component (7, 16, 30) is at least partially or completely overmolded and/or embedded by casting in order to form the casing (2, 18, 32, 38, 56, 57, 79). To avoid any interruption of the casing (2, 18, 32, 38, 56, 57, 79) and/or interruption of corrosion protection in the area of the holding point (8), a holding point covering (12, 15, 39, 36, 45, 54, 61) is arranged at a holding point (8) for holding the structural component (7, 16, 30) in an injection-molding die and/or a casting mold.

The present invention produces a reliable composite material structure having high rigidity and strength. A production device is for producing a composite material structure which is formed of continuous fiber laminate plates and a resin, and which includes a tabular panel part and a rib part for reinforcing the panel part, the production device being provided with a mold which includes a first mold and a second mold and in which a space is formed. The first mold includes first mold recesses which form space corresponding to the rib part. The second mold includes a second mold recess which forms a space corresponding to the panel part. In the first mold recesses, insert pins for supporting the continuous fiber laminate plates are provided so as to be placed at a predetermined position in the first mold recesses.

A holding portion having a diameter larger than that of a cavity is formed in communication with the cavity, in an area of a two-part type mold, the area including a portion corresponding to an annular groove. Subsequently, an insert member formed in a cylindrical shape and provided with, on an outer circumferential surface, the annular groove having no step in a groove surface is fitted to the holding portion, and then the mold is closed. On an inner circumferential surface of the insert member, a surface treatment layer having a surface roughness rougher than those of other portions of the insert member is formed. Molten resin is injected into the cavity; thereafter, an assist material is injected into the cavity to mold the resin into a desired pipe body. Then, the insert member and the pipe body are integrated along with curing of the resin.

A system and method for making an anti-scatter grid device is provided. The method may include providing a mold including one or more orientation structures arranged in first positions. The method may also include placing a plurality of plates including a first material into at least one of the orientation structures, and injecting a second material into a first cavity in the mold formed by the plurality of plates and the orientation structures. The method may further include separating the plurality of plates and the hardened second material from the mold to generate a first module.

A system and method for making an anti-scatter grid device is provided. The method may include providing a mold including one or more orientation structures arranged in first positions. The method may also include placing a plurality of plates including a first material into at least one of the orientation structures, and injecting a second material into a first cavity in the mold formed by the plurality of plates and the orientation structures. The method may further include separating the plurality of plates and the hardened second material from the mold to generate a first module.