A light system including: (a) a first light region configured to provide a first light function; (b) a second light region configured to provide a second light function that is different from the first light function; (c) a blocker located between the first light region and the second light region so that when the first light function is activated, light from the first light region is prevented from passing to the second light region by the blocker and when the second light function is activated, light from the second light region is prevented from passing to the first light region by the blocker; (d) a textured surface in the first light region, the second light region, or both; and (e) a texture shutoff located between the textured surface in the first light region, the second light region, or both and located between the textured surface and the blocker so that the texture surface prevents material of the first light region, the second light region, the blocker, or a combination thereof from forming flash on an outside of the light system; wherein the blocker prevents light from only extending through the texture shutoff; and wherein the first light function and the second light function provide the light to a location around a vehicle that comprises the light system.

The purpose of the present invention is to make it possible to shorten the time required for a burr removal step and make it difficult for the burrs to detach from a sheet member in a step for removing the burrs together with the sheet member. For removal, by making the burrs to adhere to a pliable sheet member such as paper or nonwoven fabric that has been incorporated beforehand in the molding die and stripping the sheet member from the molding die, the burrs are removed together with the sheet member. The present invention is characterized in that in order to make it difficult for the burrs to detach from the sheet member during the stripping, a radiused shape with an arc-shaped cross-section is formed by the molding die on the areas surrounding the sections where the burrs adhere to the sheet member.

A rechargeable battery includes a battery case, a cover that closes an open end of the battery case, and a power collection terminal arranged on the cover to supply power from a power generating element to an external terminal. The power collection terminal extends through a gasket arranged on a lower surface of the cover, an insulator arranged on an upper surface of the cover, and the external terminal arranged on an upper surface of the insulator. An annular sealing member is held between the lower surface of the cover and the gasket. The insulator is a resin-molded component. The insulator includes a through hole defined by an inner wall that includes a lower open end, an upper open end, and a central portion. At least one of the lower open end and the upper open end has a larger diameter than the central portion.

There is provided a method for manufacturing a molded member having a hollow part. The method comprises a step for molding the hollow part by extracting a first piece, a second piece, a third piece and a fourth piece of a mold in four different directions. The second piece has an elongated shape in its extracting direction, the second piece and the fourth piece have extracting directions substantially opposed to each other, and at the molding, each of the first piece, the second piece, the third piece and the fourth piece abuts on at least one of the first piece, the second piece, the third piece and the fourth piece.

An electronic module has a rear surface-exposed conductor 10, 20, 30 having a rear surface-exposed part 12, 22, 32 whose rear surface is exposed; an electronic element 15, 25 provided on a front surface of the rear surface-exposed conductor 10, 20, 30; and a connector 60 configure to connect the rear surface-exposed conductor 10, 20, 30 and the electronic element 15, 25 or two rear surface-exposed conductors 10, 20, 30 each other. A groove 150 is provided on the front surface of the rear surface-exposed conductor 10, 20, 30. The sealing part 90 is provided with a press hole or a press impression 110, 120, 130 used to press the rear surface-exposed conductor 10, 20, 30. In an in-plane direction, a center portion of the press hole or the press impression 110, 120, 130 is provided on the side opposite to the connector 60 or the electronic element 15, 25 with respect to the groove 150.

A resin filling method for a magnet embedded core includes: a fixing step of sandwiching the laminated iron core at axial ends thereof between a first mold and a second mold provided to face each other; and a resin injecting step of injecting a resin into the magnet insertion hole from a resin injecting portion provided in the first mold or the second mold, wherein in the resin injecting step, an end portion of the resin injecting portion is inserted into the magnet insertion hole beyond an axial end surface of the permanent magnet inserted in the magnet insertion hole.

An electronic module has a rear surface-exposed conductor 10, 20, 30 having a rear surface-exposed part 12, 22, 32 whose rear surface is exposed; an electronic element 15, 25 provided on a front surface of the rear surface-exposed conductor 10, 20, 30; and a connector 60 configure to connect the rear surface-exposed conductor 10, 20, 30 and the electronic element 15, 25 or two rear surface-exposed conductors 10, 20, 30 each other. A groove 150 is provided on the front surface of the rear surface-exposed conductor 10, 20, 30. The sealing part 90 is provided with a press hole or a press impression 110, 120, 130 used to press the rear surface-exposed conductor 10, 20, 30. In an in-plane direction, a center portion of the press hole or the press impression 110, 120, 130 is provided on the side opposite to the connector 60 or the electronic element 15, 25 with respect to the groove 150.

The purpose of the present invention is to make it possible to shorten the time required for a burr removal step and make it difficult for the burrs to detach from a sheet member in a step for removing the burrs together with the sheet member. For removal, by making the burrs to adhere to a pliable sheet member such as paper or nonwoven fabric that has been incorporated beforehand in the molding die and stripping the sheet member from the molding die, the burrs are removed together with the sheet member. The present invention is characterized in that in order to make it difficult for the burrs to detach from the sheet member during the stripping, a radiused shape with an arc-shaped cross-section is formed by the molding die on the areas surrounding the sections where the burrs adhere to the sheet member.

The present disclosure relates generally to seal rings useful in oil-lubricated systems such as automobile transmissions, torque converters and automatic clutches. In one embodiment, the disclosure provides an injection molded seal ring comprising a circular ring body extending between a first end and a second end engageable with the first end, the circular ring body including an inner circumferential face; an outer circumferential face; a first lateral face; a second lateral face opposing the first lateral face; a recess formed in the outer circumferential face, the recess not extending to both the first lateral edge and the second lateral edge of the outer circumferential face; and an injection molding gate vestige disposed in the recess, the injection molding gate vestige not extending beyond the outer circumferential face.

A biocompatible and/or food-safe tube assembly (1) is used to connect at least three tube connectors (A, B, C). A first tube section (2) serves to connect two (A, B) of the at least three tube connectors (A, B, C). A sec-ond tube section (3) opens into the first tube section (2) via an orifice (4) in a casing wall (5) of the first tube section (2). An orifice sealing body (8) delimits the orifice (4) to the inner lumen of the first tube section (2) and to the inner lumen of the second tube section (3). The first tube sec-tion 2 and the second tube section 3 are molded onto the orifice sealing body 8. A core (10) is used for this purpose. The result is a biocompatible and/or food-safe tube assembly that avoids manufacturing problems.