A device which is configured for controlling a vehicle drive (40) for traction of a vehicle has a drive control apparatus and a monitoring apparatus. In order to ensure a high degree of safety when using the vehicle drive during rapid deceleration of the vehicle, the monitoring apparatus provides a traction release control signal value to the drive control apparatus, under the effect of which the drive control apparatus is enabled to control the vehicle drive, if, in addition to a traction release request signal value due to a rapid deceleration request and an additional traction lock request signal value due to a traction lock request, an additional traction release request signal value due to a traction release condition has effect on the monitoring apparatus. There is also described a vehicle with such a device and to a method for controlling a vehicle drive for traction of a vehicle.

A braking arrangement for decelerating a heavy duty vehicle, the arrangement including a control unit, at least one electric machine arranged for regenerative braking, an electrical energy absorption device, an eddy current braking device, and a power distribution network arranged to connect the electric machine to the energy absorption device and to the eddy current braking device, wherein the control unit is configured to distribute regenerated electrical power from the electric machine between the energy absorption device and the eddy current braking device by the power distribution network in dependence of a target deceleration value of the heavy duty vehicle.

A braking arrangement for decelerating a heavy duty vehicle, the arrangement including a control unit, at least one electric machine arranged for regenerative braking, an electrical energy absorption device, an eddy current braking device, and a power distribution network arranged to connect the electric machine to the energy absorption device and to the eddy current braking device, wherein the control unit is configured to distribute regenerated electrical power from the electric machine between the energy absorption device and the eddy current braking device by the power distribution network in dependence of a target deceleration value of the heavy duty vehicle.

A mobile mining machine includes a plurality of traction elements, a plurality of motors, a power source in electrical communication with the plurality of motors, and an energy storage system in electrical communication with the plurality of motors and the power source. Each of the motors is coupled to an associated one of the plurality of traction elements. Each of the motors is driven by the associated traction element in a first mode, and drives the associated traction element in a second mode. The energy storage system includes a shaft, a rotor secured to the shaft, a stator extending around the rotor, and a flywheel coupled to the shaft for rotation therewith. In the first mode, rotation of the motors causes rotation of the flywheel to store kinetic energy. In the second mode, rotation of the rotor and the flywheel discharges kinetic energy to drive the motors.

A mobile mining machine includes a plurality of traction elements, a plurality of motors, a power source in electrical communication with the plurality of motors, and an energy storage system in electrical communication with the plurality of motors and the power source. Each of the motors is coupled to an associated one of the plurality of traction elements. Each of the motors is driven by the associated traction element in a first mode, and drives the associated traction element in a second mode. The energy storage system includes a shaft, a rotor secured to the shaft, a stator extending around the rotor, and a flywheel coupled to the shaft for rotation therewith. In the first mode, rotation of the motors causes rotation of the flywheel to store kinetic energy. In the second mode, rotation of the rotor and the flywheel discharges kinetic energy to drive the motors.

A system and method of managing power for an electric motor drive system is provided, where at least two electric motor drives are connected to a common power bus, each of the electric motor drives connected to at least one electric motor. A voltage of the common power bus is monitored, and upon the voltage of the common power bus exceeding a prescribed threshold voltage it is determined which of the at least two electric motor drives is operating in a mode other than a regeneration mode. The electric motor drive operating in a mode other than a regeneration mode is commanded to drive the connected motor into a load to dissipate the regenerated energy.

In order to enable safe deceleration of a transport unit of a long-stator linear motor, wherein in a normal mode a plurality of drive coils of the long-stator linear motor are energized in such a way that a magnetic field coupled to a transport unit is moved along a direction of motion in order to move the transport unit along the direction of motion, according to the invention a switching to a controlled short-circuit mode is performed during the braking operation of the transport unit, in which at least some of the drive coils are short-circuited at least over a first time interval in said mode.

A system comprising resistive circuit legs coupled with and disposed between (a) a converter that converts electric current for a motor of a powered system and (b) a source of electric current for powering the motor, each of the circuit legs including a braking resistor coupled with the converter, a contactor coupled with the braking resistor such that the braking resistor is between the converter and the contactor, and a semiconductor switch coupled with the contactor such that the contactor is between the semiconductor switch and the braking resistor, where, during a regenerative braking mode of operation of the powered system, the regenerated energy from the motor is conducted to the braking resistor and dissipated as heat.

A system comprising resistive circuit legs coupled with and disposed between (a) a converter that converts electric current for a motor of a powered system and (b) a source of electric current for powering the motor, each of the circuit legs including a braking resistor coupled with the converter, a contactor coupled with the braking resistor such that the braking resistor is between the converter and the contactor, and a semiconductor switch coupled with the contactor such that the contactor is between the semiconductor switch and the braking resistor, where, during a regenerative braking mode of operation of the powered system, the regenerated energy from the motor is conducted to the braking resistor and dissipated as heat.

A vehicle control device for decelerating by the regenerative braking of a motor connected to a drive shaft of a drive wheel calculates a torque command value for suppressing a vibration component of the drive shaft by feeding back a torsional angular velocity of the drive shaft to a desired torque that determines the power of the motor and controls the operation of the motor on the basis of the torque command value. The control device estimates a dead zone section, in which the torque of the motor in the vehicle is not transmitted to the drive shaft, on the basis of the desired torque and limits the torque command value in the case where the vehicle is in the dead zone section.