An induction motor includes a motor shaft, a rotor, and a rotor conductor bar. In some embodiments described herein, the rotor has a first axial side and a second axial side, and is non-rotatably secured to the motor shaft. The rotor includes a rotor core having an interior surface defining a slot extending from the first axial side to the second axial side. The rotor conductor bar is disposed in the slot. The rotor conductor bar and the slot cooperate to define a channel configured to transfer a fluid through the rotor core from the first axial side to the second axial side while directly contacting the rotor conductor bar.

An induction motor includes a motor shaft, a rotor, and a rotor conductor bar. In some embodiments described herein, the rotor has a first axial side and a second axial side, and is non-rotatably secured to the motor shaft. The rotor includes a rotor core having an interior surface defining a slot extending from the first axial side to the second axial side. The rotor conductor bar is disposed in the slot. The rotor conductor bar and the slot cooperate to define a channel configured to transfer a fluid through the rotor core from the first axial side to the second axial side while directly contacting the rotor conductor bar.

A motor is disclosed. The motor includes a stator with a stator coil to generate a periodic unidirectional field current flowing through the stator coil and a rotor. An air gap is disposed between the stator and the rotor. The rotor has at least one rotor ring, a portion of the rotor ring is disposed in the air gap. Due to the unidirectional magnetic field, a periodic electric current is induced in the rotor ring. The electric current flowing through the portion of the rotor ring disposed in the air gap flows in a first direction to rotate the rotor relative to the stator.

A motor is disclosed. The motor includes a stator with a stator coil to generate a periodic unidirectional field current flowing through the stator coil and a rotor. An air gap is disposed between the stator and the rotor. The rotor has at least one rotor ring, a portion of the rotor ring is disposed in the air gap. Due to the unidirectional magnetic field, a periodic electric current is induced in the rotor ring. The electric current flowing through the portion of the rotor ring disposed in the air gap flows in a first direction to rotate the rotor relative to the stator.

A motor vehicle drive train assembly includes an axial flux induction motor including a stator, a first rotor and a second rotor. The stator, the first rotor and the second rotor are concentric with a motor center axis. The first rotor is axially spaced from a first axial side of the stator by a first air gap and the second rotor is axially spaced from a second axial side of the stator by a second air gap. The axial flux induction motor is configured such that the first rotor is rotatable about the motor center axis by the stator at a first rotational speed to drive a first drive shaft non-rotatably connected to the first rotor while the second rotor is rotatable about the motor center axis by the stator at a second rotational speed that is greater than the first rotational speed to drive a second drive shaft non-rotatably connected to the second rotor.

A motor vehicle drive train assembly includes an axial flux induction motor including a stator, a first rotor and a second rotor. The stator, the first rotor and the second rotor are concentric with a motor center axis. The first rotor is axially spaced from a first axial side of the stator by a first air gap and the second rotor is axially spaced from a second axial side of the stator by a second air gap. The axial flux induction motor is configured such that the first rotor is rotatable about the motor center axis by the stator at a first rotational speed to drive a first drive shaft non-rotatably connected to the first rotor while the second rotor is rotatable about the motor center axis by the stator at a second rotational speed that is greater than the first rotational speed to drive a second drive shaft non-rotatably connected to the second rotor.

An electric drive system includes an energy storage system (ESS), a power conversion system, and an alternating current (AC) traction system. The ESS provides or receives electric power. The ESS includes a first energy storage unit and a second energy storage unit. The power conversion system is electrically coupled to the ESS for converting an input power to an output power. The AC traction system is electrically coupled to the power conversion system for converting the output power of the power conversion system to mechanical torques. The AC traction system includes a first AC drive device and a second AC drive device. An energy management system (EMS) is in electrical communication with the ESS, the AC traction system, and the power conversion system for providing control signals.

An electric drive system includes an energy storage system (ESS), a power conversion system, and an alternating current (AC) traction system. The ESS provides or receives electric power. The ESS includes a first energy storage unit and a second energy storage unit. The power conversion system is electrically coupled to the ESS for converting an input power to an output power. The AC traction system is electrically coupled to the power conversion system for converting the output power of the power conversion system to mechanical torques. The AC traction system includes a first AC drive device and a second AC drive device. An energy management system (EMS) is in electrical communication with the ESS, the AC traction system, and the power conversion system for providing control signals.

Systems and methods for electric motor, where the stator core has one or more stator core sections, each of which is a single-piece unit formed of soft magnetic composite (SMC) material, and where the stator core sections are positioned end-to-end with seals at each end to form a plurality of stator slots, where each of the stator slots extends through each of the stator core sections and is in fluid communication with the others to form a sealed stator chamber. The sealed stator chamber may have an expansion chamber to allow expansion and contraction of dielectric fluid in the stator chamber while maintaining separation of the dielectric oil from lubricating oil which is within the motor but external to the stator chamber. The sealed stator chamber can prevent well fluids that leak into the motor from reaching the stator windings and degrading their insulation.

Systems and methods for electric motor, where the stator core has one or more stator core sections, each of which is a single-piece unit formed of soft magnetic composite (SMC) material, and where the stator core sections are positioned end-to-end with seals at each end to form a plurality of stator slots, where each of the stator slots extends through each of the stator core sections and is in fluid communication with the others to form a sealed stator chamber. The sealed stator chamber may have an expansion chamber to allow expansion and contraction of dielectric fluid in the stator chamber while maintaining separation of the dielectric oil from lubricating oil which is within the motor but external to the stator chamber. The sealed stator chamber can prevent well fluids that leak into the motor from reaching the stator windings and degrading their insulation.