Abstract: A manifold is provided for supporting a power module assembly with a plurality of power modules. The manifold includes a first manifold section. The first face of the first manifold section is configured to receive the first power module, and the second face of the first manifold section defines a first cavity with a first baseplate thermally coupled to the first power module. The first face of the second manifold section is configured to receive the second power module, and the second face of the second manifold section defines a second cavity with a second baseplate thermally coupled to the second power module. The second face of the first manifold section and the second face of the second manifold section are coupled together such that the first cavity and the second cavity form a coolant channel. The first cavity is at least partially staggered with respect to second cavity.

Abstract: A filter for an automotive electrical system includes a substrate having first and second conductive members. First and second input terminals are mounted to the substrate. The first input terminal is electrically connected to the first conductive member, and the second input terminal is electrically connected to the second conductive member. A plurality of capacitors are mounted to the substrate. Each of the capacitors is electrically connected to at least one of the first and second conductive members. First and second power connectors are mounted to the substrate. The first power connector is electrically connected to the first conductive member, and the second power connector is electrically connected to the second conductive member. A common mode choke is coupled to the substrate and arranged such that the common mode choke extends around at least a portion of the substrate and the first and second conductive members.

Abstract: A connector assembly is provided for coupling an electric motor to a power source, wherein the power source comprises a first conductive member. The connector assembly comprises a non-conductive member having an inner channel configured to receive at least a portion of the first conductive member, a second conductive member slidably disposed within the inner channel, coupled to the electric motor, and configured to be coupled to, and to receive a force having a first direction from, the first conductive member, and a spring member, retained between the non-conductive member and the second conductive member and configured to resist movement of the second conductive member in the first direction.

Abstract: A vehicular power inverter connector assembly is provided. The assembly includes a housing, a plurality of first engagement formations on the housing shaped to mate with a plurality of inverter engagement formations on a vehicular power inverter, a plurality of second engagement formations on the housing shaped to mate with a plurality motor engagement formations on a vehicular motor, and a plurality of current sensors connected to the housing and configured to detect current flowing between the vehicular power inverter and the vehicular motor.

Abstract: An inverter assembly for a vehicle includes a housing, a first inverter, and a second inverter. The housing comprises a plurality of walls. The plurality of walls form an inlet for cooling fluid to enter the housing, an outlet for the cooling fluid to exit the housing, and a channel, and a channel for the cooling fluid to flow therebetween. The first inverter is disposed within the housing proximate the channel, and is configured to be cooled by the cooling fluid flowing through the channel. The second inverter is also disposed within the housing proximate the channel, and is also configured to be cooled by the cooling fluid flowing through the channel.

Abstract: A busbar assembly for an inverter module has a power module, a capacitor module with at least one capacitor, and a battery all interconnected by a busbar. The busbar includes a base busbar portion that is electrically coupled to the battery and a branch busbar portion that extends from the base busbar to the power module and that electrically connects to the capacitor module at points located between the base node and the power module.

Abstract: Systems and/or methods are provided for an inverter power module with distributed support for direct substrate cooling. An inverter module comprises a power electronic substrate. A first support frame is adapted to house the power electronic substrate and has a first region adapted to allow direct cooling of the power electronic substrate. A gasket is interposed between the power electronic substrate and the first support frame. The gasket is configured to provide a seal between the first region and the power electronic substrate. A second support frame is adapted to house the power electronic substrate and joined to the first support frame to form the seal.

Abstract: Systems and apparatus are provided for capacitor segments for use in a vehicle. A capacitor segment comprises an inner conductor configured to receive a first potential and having a generally L-shaped longitudinal cross-section. An outer conductor is configured to receive a second potential, and is electrically insulated from the inner conductor. The outer conductor comprises a first section having a generally L-shaped longitudinal cross-section aligned with the inner conductor, and a second section coupled to the first section and having a generally L-shaped lateral cross-section. The second section and the inner conductor define an inner region. A capacitor is located in the inner region and coupled to the inner conductor and the second section. The capacitor segment is configured such that current flows through the capacitor in a first direction, and current flows through the second section in a second direction that generally opposes the first direction.

Abstract: An inverter assembly includes a housing and a substrate disposed in the housing. The substrate includes at least a first conductive layer patterned to include an alternating current (AC) path and a direct current (DC) path. A plurality of inverter switches is mounted on the substrate and electrically coupled to the AC path and the DC path.

Abstract: An interface assembly for an inverter of a vehicle includes an interface, a plurality of busbars, a communication medium, and a clip. The interface is for communicating with one or more vehicle systems outside of the interface assembly. The plurality of busbars are configured to receive and transport electric current. The communication medium is electrically coupled between the plurality of busbars and the interface. The communication medium is configured to provide information to the interface based at least in part on the electric current transported by the plurality of busbars. The clip assembly is electrically coupled between the plurality of busbars and the communication medium.

Abstract: An assembly for transporting electric current in a vehicle includes a connector and a sensor package. The connector comprises a plurality of prongs. The plurality of prongs are configured to receive and transport electric current. The sensor package is electrically coupled to the connector, and comprises a plurality of sensors. Each of the plurality of sensors is electrically coupled to a different one of the plurality of prongs, and is configured to determine a measure of electric current thereof.

Abstract: An inverter assembly includes a housing and a substrate disposed in the housing. The substrate includes at least a first conductive layer patterned to include an alternating current (AC) path and a direct current (DC) path. A plurality of inverter switches is mounted on the substrate and electrically coupled to the AC path and the DC path.

Abstract: A bus bar and a related electrical assembly for an electric traction system of a vehicle are provided. The bus bar includes an electrically conductive body configured for coupling to an electrical device high current node, the electrically conductive body comprising a circuit board mounting end, and a plurality of electrically conductive fingers extending from the circuit board mounting end. The fingers are configured to accommodate soldering to at least one conductive trace of a circuit board.

Abstract: A filter assembly is provided which includes a Faraday cage interface. Electrical noise is filtered by the Faraday cage interface. The Faraday cage interface is configured to prevent passage of electromagnetic waves.

Abstract: An assembly for transporting electric current in a vehicle includes a connector and a sensor package. The connector comprises a plurality of prongs. The plurality of prongs are configured to receive and transport electric current. The sensor package is electrically coupled to the connector, and comprises a plurality of sensors. Each of the plurality of sensors is electrically coupled to a different one of the plurality of prongs, and is configured to determine a measure of electric current thereof.

Abstract: An interface assembly for an inverter of a vehicle includes an interface, a plurality of busbars, a communication medium, and a clip. The interface is for communicating with one or more vehicle systems outside of the interface assembly. The plurality of busbars are configured to receive and transport electric current. The communication medium is electrically coupled between the plurality of busbars and the interface. The communication medium is configured to provide information to the interface based at least in part on the electric current transported by the plurality of busbars. The clip assembly is electrically coupled between the plurality of busbars and the communication medium.

Abstract: An electric current connector assembly for a vehicle includes a first connector and a second connector. The first connector comprises a first end portion of a first busbar and a first end portion of a second busbar. The second connector is electrically coupled to the first connector. The second connector comprises a second end portion of the first busbar and a second end portion of the second busbar.

Abstract: An inverter assembly for a vehicle includes a housing, a first inverter, and a second inverter. The housing comprises a plurality of walls. The plurality of walls form an inlet for cooling fluid to enter the housing, an outlet for the cooling fluid to exit the housing, and a channel, and a channel for the cooling fluid to flow therebetween. The first inverter is disposed within the housing proximate the channel, and is configured to be cooled by the cooling fluid flowing through the channel. The second inverter is also disposed within the housing proximate the channel, and is also configured to be cooled by the cooling fluid flowing through the channel.

Abstract: A high current interconnection system is provided which can be configured to couple a motor to an inverter. A high current interconnection system comprises a bus bar, a motor winding coupled to the bus bar, and a thermal interface. The motor winding is configured to receive a current. The thermal interface can be coupled to at least one of the motor winding or the bus bar. The thermal interface is configured to reduce a temperature of the motor winding or bus bar which the thermal interface is coupled to.

Abstract: An electrical system as described herein is suitable for use in an electric or hybrid vehicle. The electrical system includes electrical devices, such as power transistors, coupled to an electrically and thermally conductive bus bar. The respective nodes of the electrical devices are coupled to the bus bar such that the bus bar carries a combined signal generated by the electrical devices. The bus bar is also thermally coupled to a conduction heat transfer system, such as a liquid cooled cold plate. Thus, the bus bar functions as both an electrical conduit and a conduction-based heat sink for the electrical system.