A magnetic field propulsion unit includes a magnetic field generating device with multiple conductive lines conduct a current to generate a magnetic field; a contact breaker arrangement individually transitions each of the multiple conductive lines from a conductive state to a non-conductive state; an energy supply unit provides the magnetic field generating device with electrical energy; and a control unit controls the energy supply unit so that energy supply to each individual conductive line is controlled and control the contact breaker arrangement. The multiple conductive lines are arranged along a longitudinal axis. The control unit supplies a first conductive line with electrical energy so that a first magnetic field surrounding the first conductive line is generated, transitions the first conductive line to a non-conductive state, and supplies a second conductive line with electrical energy so that a second magnetic field is generated.

An electrical machine (10) for an electrically operable axle of a motor vehicle, having a shaft (12) with an axis of rotation (D), at least one bearing (14), wherein the shaft is rotatably mounted via the at least one bearing, at least one end shield (16), and at least one bearing ring (18), which is arranged coaxially with the axis of rotation (D). The at least one bearing is connected to the end shield via the bearing ring, and the bearing ring has at least one longitudinal recess (20a, 20b) on the outside for fluid evacuation. An electrically operated axle for a motor vehicle having the electrical machine is also provided.

A power conversion apparatus connected to three or more voltage units, includes three or more power conversion circuits connected to respective units of the three or more voltage units; and a multiport transformer connected to the three or more power conversion circuits at mutually different ports, in which at least one voltage unit of the three or more voltage units is an electrical load.

A vehicle is provided that includes a basic structure; and coupled to the basic structure, a plurality of power sources, a propulsion system and power distribution circuitry. The propulsion system includes a plurality of electric motors configured to power a plurality of propulsors to generate propulsive forces that cause the vehicle to move. The power distribution circuitry is configured to deliver direct current electric power from the plurality of power sources to the plurality of electric motors. The power distribution circuitry electrically couples the plurality of power sources to the plurality of electric motors in an interleaved topology in which electric motors of the plurality of electric motors are alternately, electrically coupled to power sources of the plurality of power sources. Each of the electric motors in the interleaved topology is electrically coupled to a different one of the power sources than immediately adjacent ones of the electric motors.

A vehicle is provided that includes a basic structure; and coupled to the basic structure, a plurality of power sources, a propulsion system and power distribution circuitry. The propulsion system includes a plurality of electric motors configured to power a plurality of propulsors to generate propulsive forces that cause the vehicle to move. The power distribution circuitry is configured to deliver direct current electric power from the plurality of power sources to the plurality of electric motors. The power distribution circuitry electrically couples the plurality of power sources to the plurality of electric motors in an interleaved topology in which electric motors of the plurality of electric motors are alternately, electrically coupled to power sources of the plurality of power sources. Each of the electric motors in the interleaved topology is electrically coupled to a different one of the power sources than immediately adjacent ones of the electric motors.

Provided is a semiconductor device including: a laminated substrate in which a circuit layer, an insulating layer, and a metal layer are sequentially laminated. A slit is formed in the circuit layer. A recess recessed from one surface side facing the insulating layer toward the other surface side is formed in the metal layer. The recess of the metal layer has a relaxation portion at least partially overlapping the slit of the circuit layer in a planar view.

A power conversion apparatus connected to three or more voltage units, includes three or more power conversion circuits connected to respective units of the three or more voltage units; and a multiport transformer connected to the three or more power conversion circuits at mutually different ports, in which at least one voltage unit of the three or more voltage units is an electrical load.

The present invention relates to a power supply device for supplying power, from a battery provided at an electric vehicle, to various types of components, the power supply device enabling current sensing to be performed so as to confirm that an electric vehicle charging facility and an electric vehicle are connected to each other through a connector, and reducing electro-magnetic interference (EMI) noise. The objective of the power supply device of the present invention is to: provide a stable voltage to electric vehicle application components; and reduce the EMI noise according to battery charging, self-switching of the power supply device and the like.

The present invention relates to a power supply device for supplying power, from a battery provided at an electric vehicle, to various types of components, the power supply device enabling current sensing to be performed so as to confirm that an electric vehicle charging facility and an electric vehicle are connected to each other through a connector, and reducing electro-magnetic interference (EMI) noise. The objective of the power supply device of the present invention is to: provide a stable voltage to electric vehicle application components; and reduce the EMI noise according to battery charging, self-switching of the power supply device and the like.

An electric power distribution system includes a first path through which electric power is supplied to a main load; a second path through which electric power is supplied to the backup load; a third path that connects a second DC/DC converter and a first battery; a fourth path that connects the first battery and the first DC/DC converter in parallel to the main load; and a control unit that controls an output voltage of the second DC/DC converter according to an assumed output capacity derived from travel route information of a navigation system mounted on the vehicle. The assumed output capacity is a capacity that is able to supply electric power used for a driven load in the backup load, and is set to be lower than a threshold battery capacity that is lower than in a fully charged state of the second battery.