An electronic component including a component main body and a plurality of lead terminals is inserted and accommodated in a housing member, the lead terminals are brought into contact with a plurality of terminal fittings held in the housing member. The lead terminals are formed such that at least one of the number of lead terminals on each side surface before and after the reversing, a distance between the contact portion and the side surface of the component main body facing the contact portion, and a width dimension in a direction perpendicular to the extending direction of the contact portion differs, when the component main body is rotated at 180 degrees to reverse the positions of the pair of opposite side surfaces of the component main body. Accordingly, it is possible to prevent improper assembly of an electronic component.

A magnetic latching relay includes a base having a receiving chamber with a first sidewall extending in a longitudinal direction and a second sidewall extending in a transverse direction, and connected with the first sidewall; a coil assembly in the receiving chamber in the transverse direction and having a first end adjacent to the first sidewall; and a fixing frame on the base. The fixing frame has a first side close to the coil assembly, and is in sealed contact with the first end of the coil assembly, and a side of the fixing frame facing the first sidewall is in sealed contact with the first sidewall, forming a first glue dispensing port surrounded by the first sidewall, the second sidewall, the first end of the coil assembly, and the fixing frame.

An electronic device where molten solder does not come into contact with a sealant so as not to destroy a sealing function. An electronic device is provided with: an insulating base mounted on a printed circuit board; a common planar terminal provided so as to extend from an outer side surface to a bottom surface edge of the insulating base, and cause electrical continuity between the outer side surface and the bottom surface edge of the insulating base; a cover fitted to the insulating base and covering the common planar terminal; and a sealant sealing a gap between the outer side surface of the insulating base and an inner circumferential surface of the cover. A solder pool is formed in a position surrounded by the printed circuit board and the common planar terminal at the bottom surface edge of the insulating base.

Provided is a solenoid switch of a motor including a solenoid case, a solenoid having at least one control terminal for connection to at least one external control cable, two power terminals for connection to external power cables, two stationary serrated electrical contacts mounted within the solenoid case, where each serrated electrical contact is electrically connected to a corresponding one of the power terminals, two movable electrical contacts coupled to the solenoid and electrically connected to windings of the motor, where each movable electrical contact corresponds to one of the two serrated electrical contacts, and is movable by applied force of the solenoid. In response to a control signal received by the at least one control terminal, the solenoid is energized and moves the two movable electrical contacts to mate with the corresponding two serrated electrical contacts resulting in an electrical connection between the power cables and the motor windings.

The inventive assembly comprises a hyperfrequency component of the surface-mounted component type including at least one first hyperfrequency transmission line, as well as a printed circuit board including at least one second hyperfrequency transmission line able to be put in contact with the first hyperfrequency transmission line. The component comprises an enclosure with a face in contact with the printed circuit board, which includes at least one cavity for confining a hyperfrequency signal, delimited by conductive surfaces of the enclosure, and by a conductive zone of the second hyperfrequency transmission line.

An electromagnetic contactor capable of coupling either one of an alternating current (AC) electromagnet or a direct current (DC) electromagnet with an identical contact support is provided. The electromagnetic contactor includes an electromagnet including either one of the AC electromagnet (12AC) including a movable core or the DC electromagnet (12DC) including an armature, and a contact support (36) configured to hold plural movable contacts in alignment to be coupled with and driven by the electromagnet. The contact support includes a coupling portion (40) including a movable core contact portion (41), coupling spring edge accommodation portions (46), and armature contact portions (51) arranged on opposite sides with respect to the movable core contact portion of the coupling spring edge accommodation portion. The AC electromagnet (12AC) includes an AC electromagnet coupling spring (56) and the DC electromagnet (12DC) includes a DC electromagnet coupling spring (161).

A novel-structure electromagnetic relay containing a permanent magnet. At least three pairs of leading-out rods penetrate through a rectangular base, two pairs of leading-out rods are connected with the lower ends of four static spring plates respectively, an iron core and a coil framework are arranged at a diagonal position on the upper surface of the base, winding connectors of coils are connected with the other pair of leading-out rods respectively, the static spring plates are arranged at the other diagonal position on the upper surface of the base, a support is arranged at the top end of the coil framework, a pole face, a yoke and the permanent magnet are installed on the support, an armature, movable spring plates, the pole face and the yoke are located and connected through a middle shaft, and a sealing casing is covered outside the relay.

A system may be configured to replace a manual service disconnect (MSD). Some embodiments may: provide a set of batteries that include an MSD; remove the MSD; and install a contactor at the MSD. The replacement may be performed via substantially similar housing previously used by the MSD.

A power relay for a vehicle is disclosed. The power relay has a housing formed by a connector base and a housing can set thereon, two connection bolts being inserted into the connector base for contacting a load circuit. The power relay further has a coil subassembly arranged in the housing and containing a solenoid coil and an armature. The armature is coupled by a force-transmission member to a contact bridge and can shift in the housing, under the effect of a magnetic field generated by the solenoid coil, in such a way that the contact bridge can be reversibly moved between a closing position, in which the contact bridge bridges the connection bolts in an electro conducting manner, and an opening position, in which the contact bridge is not in contact with the connection bolts. The housing can is configured as an injection-molded component made of plastic.

An electrical assembly may include a bus bar assembly, a sensor assembly, including a circuit board connected to the bus bar assembly, and a sensor, a bracket connected to the bus bar assembly, and a cooling member connected to the bracket. A method of assembling an electrical assembly may include connecting a shunt resistor with a bus bar assembly, connecting a circuit board with the bus bar assembly, connecting the bus bar assembly with the bracket, disposing the cooling member on or about the bracket, and/or connecting the cooling member with the bracket.