An accelerator device includes a stepping member that receives a stepping by a driver, a case attachable to a vehicle body, an internal movable mechanism housed in the case, and a rotation angle detector. The internal movable mechanism includes a shaft that rotates in respond to a stepping to the stepping member, and the rotation angle detector outputs a signal corresponding to a rotation angle of the shaft via a plurality of terminals. Output ends of the plurality of terminals are arranged in an arrangement different from a line arrangement when being viewed from an output side of the plurality of terminals.

A method for producing a molded article by injection molding may include using a heat-curable 1K polyurethane (PU) composition, as well as the molded articles obtained using said method.

The invention relates to a method for producing a cable, comprising both a molding tool with a cavity and with at least one first opening, and a line, said line consisting of at least one wire and a sheath surrounding the at least one wire. According to the invention, the line is inserted into the cavity and is guided out of the cavity via at least the first opening. A molding compound is injected into the cavity of the molding tool in a pressurized manner, wherein the line is pressed onto a seal surface of the cavity by means of the pressure of the molding compound, and the line closes the cavity at the seal surface.

An injection mold for molding an electrical connector assembly which includes a plurality of terminals, a clamping component located above the plurality of the terminals, and a base body fastened to the plurality of the terminals and the clamping component. The injection mold includes a lower mold and an upper mold. The lower mold has a plurality of lower terminal grooves. Lower portions of the plurality of the terminals are placed in the plurality of the lower terminal grooves. The clamping component is placed on the lower mold. The upper mold is engaged with and mounted on the lower mold. A molding cavity is formed between the upper mold and the lower mold. The upper mold has a plurality of upper terminal grooves. Upper portions of the plurality of the terminals are placed in the plurality of the upper terminal grooves.

A mat seal for an electrical connector includes a plurality of through-holes extending in a through-hole direction through the mat seal, a grid of a first material having a plurality of grid meshes, the grid is arranged with the through-holes extending through the grid meshes, a first material layer of a second material disposed on a first side of the grid, and a second material layer of a third material disposed on a second side of the grid opposite the first side. The first material of the grid has a greater compression modulus than the second material of the first material layer and the third material of the second material layer.

A connector includes an insulating housing that is fixed to a casing of a first device at a communication part through which an opening of the casing of the first device and as opening of a casing of a second device communicate with each other, a conductor unit including a plurality of conductors arranged in a row and an insulating holding body integrally molded with the conductors, and a sealing member that seals between the conductor unit and the housing. Each of the conductors includes a plate-shaped body. The holding body includes a fitting part fitted to the housing, a plurality of covering parts each extending from the fitting part along the body and individually surrounding the body, and a connecting part connecting the adjacent covering parts at a position separated from the fitting part.

A method can be applied for manufacturing an electrical connector on an end portion of a multi-wire electrical cable whose wires are surrounded annularly in cross section in the end portion by an outer conductor. The outer conductor is partially radially compressed toward the wires by at least one die, and is also partially provided with an overmold in an injection mold. In the method, after the outer conductor is deformed, the die is positioned on the outer conductor in such a way that the die partially bounds a mold cavity to be filled with a plasticized molding compound to form the overmold. At least one mold part of the injection mold is moved toward the outer conductor and the mold part is positioned in a vicinity of the outer conductor so to further bound the mold cavity.

A method for overmolding at least one line (40) comprises the steps: receiving the at least one line (40) in an opening (14) of a sealing element (10), wherein the opening (34) of the sealing element (10) is substantially complementary in shape to a peripheral geometry of the at least one line (40); mounting the sealing element (10) on a mold (30); overmolding the at least one line (40) received in the sealing element in a region (42) that is adjacent to the sealing element (10) and delimited by the sealing element (10); and removing from the mold (30) the sealing element (10) and the at least one line (40) received therein and overmolded in a region.

A fuse assembly including a fuse connected to two busbars, an injection molded base and an injection molded cover. The busbars are powder-coating with a powder-based adhesive or adhesion promoter, then cured in an oven. The busbars are then placed in the cavity image of an injection molding apparatus. Plastic is heated to a liquid form and injected into the cavity image. The resulting injection molded base is resistant to both dust and water, protecting the fuse inside.

A cable assembly is provided comprising a collar adjacent to a cable transition member, the cable transition member having a first longitudinal axis x.sup.1, the collar having a second longitudinal axis x.sup.2. The cable transition member provides for a cable to extend by approximately 90 degrees from the first axis x.sup.1 of the cable transition member, a connector body having a non-circular outer diameter, wherein the collar is disposed between the connector body and the cable transition member so that the first axis x.sup.1 and the second axis x.sup.2 are aligned and the collar secures the cable transition member in a predetermined angular orientation z with respect to the connector body. The angular orientation z of the cable transition member with respect to the connector body is other than 90, 180, 270 or 360 degrees with respect to the first axis x.sup.1.