An electric motor, in particular a radiator fan motor of a motor vehicle, has a stator which is fitted with a rotating-field winding, and a rotor which is mounted such that it can rotate in relation to the stator. A converter electronics system is provided, wherein a number of contact elements for insulation-free or enamel-insulated connection contacts of at least one component of the converter electronics system and/or for enamel-insulated winding ends of the rotating-field winding are mounted on a printed circuit board. The contact elements are in the form of clamping contacts or insulation-displacement terminal contacts.

An electric motor, in particular a radiator fan motor of a motor vehicle, has a stator which is fitted with a rotating-field winding, and a rotor which is mounted such that it can rotate in relation to the stator. A converter electronics system is provided, wherein a number of contact elements for insulation-free or enamel-insulated connection contacts of at least one component of the converter electronics system and/or for enamel-insulated winding ends of the rotating-field winding are mounted on a printed circuit board. The contact elements are in the form of clamping contacts or insulation-displacement terminal contacts.

Connectors for connecting light emitting diode (LED) strip light to power are disclosed. The connectors include a housing with a first opening sized to accept an LED strip light and a second opening for a power cord or electrical leads. The openings open into an interior cavity with an internal vertical barrier to separate power and ground leads. Gripping structures proximate to the first opening retain the strip light. A gasket or gaskets within the connector seal the connector from the elements. The second opening may carry a strain relief molded to the power cord. Additionally, an adapter or nipple may be provided to connect the connector to conduit.

An electric motor, in particular a radiator fan motor of a motor vehicle, has a stator which is fitted with a rotating-field winding, and a rotor which is mounted such that it can rotate in relation to the stator. A converter electronics system is provided, wherein a number of contact elements for insulation-free or enamel-insulated connection contacts of at least one component of the converter electronics system and/or for enamel-insulated winding ends of the rotating-field winding are mounted on a printed circuit board. The contact elements are in the form of clamping contacts or insulation-displacement terminal contacts.

An assembly includes a housing, a flat cable, a first wire, a second wire, a first terminal, a second terminal, and a divider. The flat cable may be disposed at least partially in the housing and may include a first exposed conductor portion and a second exposed conductor portion. The first wire and the second wire may be disposed partially in the housing. The first terminal and the second terminal may be disposed in the housing. The first terminal may be connected to the first exposed conductor portion and the first wire such that the first exposed conductor portion is electrically connected to the first wire. The second terminal may be connected to the second exposed conductor portion and the second wire such that the second exposed conductor portion is electrically connected to the second wire. The divider may be disposed between the first terminal and the second terminal.

A bus connection wire forward soldering structure includes a circuit board, a flat cable and a fixing member, and the circuit board has a solder area, a docking area, first and second surfaces and an outgoing line direction. The solder area is disposed on the first surface, the flat cable includes a solder terminal, first and second attaching sections, a folding section and a main body section, the solder terminal faces the docking area and is electrically connected to the solder area, the folding section is connected between the first and second attaching sections, the main body section extends along the outgoing line direction, the fixing member covers the solder terminal, the folding section, the first and second attaching sections, the fixing member has a notch defined corresponding to the second surface and located at junction of the second attaching section and the main body section junction.

A bus connection wire forward soldering structure includes a circuit board, a flat cable and a fixing member, and the circuit board has a solder area, a docking area, first and second surfaces and an outgoing line direction. The solder area is disposed on the first surface, the flat cable includes a solder terminal, first and second attaching sections, a folding section and a main body section, the solder terminal faces the docking area and is electrically connected to the solder area, the folding section is connected between the first and second attaching sections, the main body section extends along the outgoing line direction, the fixing member covers the solder terminal, the folding section, the first and second attaching sections, the fixing member has a notch defined corresponding to the second surface and located at junction of the second attaching section and the main body section junction.

A method is for connecting a flexible organic electronic device to an electrical wire, the method includes: providing a flexible electronic device, providing an electrical wire, providing a contact including at least one conductor comprising a contact face, the contact face defining a contact surface, incision of the encapsulating barrier film defining an incision surface, the incision surface having a maximum dimension and a minimum dimension, the maximum dimension of the incision surface being smaller than the maximum dimension of the contact surface, and assembling the conductor and the conductive strip through the incision to ensure an electronic conduction between the conductor and the electrode.

Provided is a flexible printed wiring board including: a base film which is an insulating layer; a first conductor layer; a second conductor layer; and a through-hole, in which the first conductor layer is provided on one surface of the base film, the second conductor layer is provided on the other surface of the base film, and the through-hole is provided so as to penetrate the base film and electrically connect the first conductor layer and the second conductor layer to each other, and the second conductor layer has a solderable region.

Provided is a flexible printed wiring board including: a base film which is an insulating layer; a first conductor layer; a second conductor layer; and a through-hole, in which the first conductor layer is provided on one surface of the base film, the second conductor layer is provided on the other surface of the base film, and the through-hole is provided so as to penetrate the base film and electrically connect the first conductor layer and the second conductor layer to each other, and the second conductor layer has a solderable region.