A dual actuated power pack (300) comprises a battery (104) and first (101) and second (102) electric motors, as well as a power generator (103). The first electric motor (101) is powered by the battery (104) and the second electric motor (102) by a grid (106). The first and second electric motors (101, 102) are mechanically coupled (108) with each other so that when said second electric motor (102) is powered, said second electric motor (102) actuates (109) said power generator (103) and said first electric motor (101) at the same time, whereupon the first electric motor (101) functions as a hi-power battery charger and recharge the battery (104) when said second electric motor (102) actuates (109) the power generator (103). When the second electric motor is not used, the first electric motor (101) is powered (104, 105), and the power generator (103) is actuated (108) by said first electric motor (101).

To provide a system of low cost and low loss capable of the supply of electric power according to characteristics of each of a plurality of motors from a single battery. A power supply system for a vehicle of the present invention includes: a high-voltage battery; a first inverter which connects with the high-voltage battery; a motor described later which connects with the first inverter; a high-voltage DCDC converter which is connected to the high-voltage battery and steps down the voltage of the high-voltage battery; a second inverter which connects with the high-voltage battery; and a motor described later which connects with the second inverter.

To provide a system of low cost and low loss capable of the supply of electric power according to characteristics of each of a plurality of motors from a single battery. A power supply system for a vehicle of the present invention includes: a high-voltage battery; a first inverter which connects with the high-voltage battery; a motor described later which connects with the first inverter; a high-voltage DCDC converter which is connected to the high-voltage battery and steps down the voltage of the high-voltage battery; a second inverter which connects with the high-voltage battery; and a motor described later which connects with the second inverter.

A dual motor system includes a first motor providing a lower speed range and a second motor providing a higher speed range, wherein the motors are coaxially arranged and aligned on and drive a common shaft, and a motor control system controlling the speed of the first motor and engaging the second motor as needed. The first motor is a variable speed motor providing a lower two-thirds of a full speed range, and the second motor is an induction motor providing the upper one-third in the form of one or more discrete fixed speeds. The system may include a transformer including a first winding tap which provides a first higher speed, and a second winding tap which provides a second higher speed. The system may also include a flow control system for automatically controlling the speed of the motors for particular applications, such as flow control in a pool.

Embodiments disclosed herein include a first motor having a high gear ratio, a second motor having a low gear ratio, and a drive shaft, the first and second motors being connected to a load via the drift shaft. The motor system is arranged to at least one of electrically and mechanically disconnect the first motor when a speed of the first motor reaches a threshold speed such that the first motor does not act as a generator and consume mechanical power. In some embodiments, the first motor is a torque booster and the second motor is a high speed motor. The first motor may be electrically disconnected via one or more relays, couplers, and additional switching semiconductors. The first motor may be mechanically disconnected via a clutch.

Embodiments disclosed herein include a first motor having a high gear ratio, a second motor having a low gear ratio, and a drive shaft, the first and second motors being connected to a load via the drift shaft. The motor system is arranged to at least one of electrically and mechanically disconnect the first motor when a speed of the first motor reaches a threshold speed such that the first motor does not act as a generator and consume mechanical power. In some embodiments, the first motor is a torque booster and the second motor is a high speed motor. The first motor may be electrically disconnected via one or more relays, couplers, and additional switching semiconductors. The first motor may be mechanically disconnected via a clutch.

A drive system has a main electric drive and an auxiliary electric drive. A frequency converter controls a torque of the auxiliary drive. A planetary gear has a ring gear, a sun gear, a planet gear and a planet gear carrier. The ring gear is coupled to the main drive, the sun gear is coupled to an output shaft and the planet gear carrier is coupled to the auxiliary drive. A clutch path is disposed between the planet gear carrier and the input shaft. A controller operates the drive system in a first range with the clutch closed and the switching apparatus open, or in a second range with the clutch open and the switching apparatus closed. The controller is adapted to superelevate the torque of the auxiliary drive during a transition between the first and second ranges beyond the torque that the auxiliary drive is able to provide permanently.

A sensor unit includes a bus bar and a magneto-electric conversion device. The bus bar connects a plurality of switch elements constituting a part of a power conversion circuit and a motor. The magneto-electric conversion device is disposed to face a middle portion of the bus bar across a clearance in a predetermined direction to detect a magnetic field caused by an electric current flowing through the bus bar, to thereby detects the electric current. The bus bar includes a first end and a second end. The first end of the bus bar is connected to one of a switch terminal extending from the switch elements and a motor terminal extending from the motor, and the second end of the bus bas is connected to the other of the switch terminal and the motor terminal.

In a method for operating a system with drives, which are mechanically coupled to one another, and with a higher-level computer, which is connected to the drives with the aid of a data-bus connection, and a system, a respective actual torque value is determined in each drive and transmitted to the higher-level computer, in particular using a data-bus connection. The higher-level computer determines for each drive a setpoint torque value allocated to this drive, the higher-level computer has controllers, and one of the controllers is allocated, in particular biuniquely, to each drive. The controller allocated to the respective drive controls the actual torque value of the respective drive to the setpoint torque value of the respective drive by determining a setpoint speed value allocated to the respective drive as the control value and transmits it to the respective drive, in particular with the aid of a data-bus connection. The respective drive has a controller in each case, to which the respective actual speed value, determined in the drive, of an electric motor of the drive is supplied and which controls this actual speed value to the respective setpoint speed value transmitted by the higher-level computer by setting the motor voltage or the motor current of the electric motor of the respective drive.

In a method for operating a system with drives, which are mechanically coupled to one another, and with a higher-level computer, which is connected to the drives with the aid of a data-bus connection, and a system, a respective actual torque value is determined in each drive and transmitted to the higher-level computer, in particular using a data-bus connection. The higher-level computer determines for each drive a setpoint torque value allocated to this drive, the higher-level computer has controllers, and one of the controllers is allocated, in particular biuniquely, to each drive. The controller allocated to the respective drive controls the actual torque value of the respective drive to the setpoint torque value of the respective drive by determining a setpoint speed value allocated to the respective drive as the control value and transmits it to the respective drive, in particular with the aid of a data-bus connection. The respective drive has a controller in each case, to which the respective actual speed value, determined in the drive, of an electric motor of the drive is supplied and which controls this actual speed value to the respective setpoint speed value transmitted by the higher-level computer by setting the motor voltage or the motor current of the electric motor of the respective drive.