A control system includes a current sensor and one or more processors. The current sensor is configured to be disposed onboard a vehicle and to monitor a measured current conducted into a resistor leg of the vehicle. The resistor leg has a braking chopper and one or more resistive elements, and is connected with a traction bus of the vehicle. The one or more processors are configured to receive the measured current from the current sensor and, in response to the measured current differing from an expected current through the resistor leg, the one or more processors are configured to generate a control signal configured to one or more of increase an engine speed of an engine of the vehicle, increase cooling to the one or more resistive elements of the resistor leg, restrict movement of the vehicle, or schedule maintenance for the resistor leg.

A control system includes a current sensor and one or more processors. The current sensor is configured to be disposed onboard a vehicle and to monitor a measured current conducted into a resistor leg of the vehicle. The resistor leg has a braking chopper and one or more resistive elements, and is connected with a traction bus of the vehicle. The one or more processors are configured to receive the measured current from the current sensor and, in response to the measured current differing from an expected current through the resistor leg, the one or more processors are configured to generate a control signal configured to one or more of increase an engine speed of an engine of the vehicle, increase cooling to the one or more resistive elements of the resistor leg, restrict movement of the vehicle, or schedule maintenance for the resistor leg.

A method for operating a motor vehicle, including an electric machine and a coupling device, which, in a first coupling state, couples the electric machine to a drivetrain and, in a second coupling state, decouples the electric machine from the drivetrain, wherein the method includes the following steps: a) registering an item of coupling information, which specifies whether the coupling device is in the first or second coupling state, b) analyzing a recuperation condition, the fulfillment of which is dependent on the coupling information, wherein the recuperation condition is fulfilled or can only be fulfilled if the coupling device is in the second coupling state, and c) braking the electric machine by operating the electric machine as a generator if the recuperation condition is fulfilled.

A method for operating a motor vehicle, including an electric machine and a coupling device, which, in a first coupling state, couples the electric machine to a drivetrain and, in a second coupling state, decouples the electric machine from the drivetrain, wherein the method includes the following steps: a) registering an item of coupling information, which specifies whether the coupling device is in the first or second coupling state, b) analyzing a recuperation condition, the fulfillment of which is dependent on the coupling information, wherein the recuperation condition is fulfilled or can only be fulfilled if the coupling device is in the second coupling state, and c) braking the electric machine by operating the electric machine as a generator if the recuperation condition is fulfilled.

A method for controlling an electronically slip-controllable power braking system, an electronically slip-controllable power braking system, and an electronic control unit of an electronically slip-controllable power braking system. The power braking system has a friction braking device, a generator braking device, and an electronic control unit for controlling the braking devices adapted to need. The friction braking device includes an electronically activatable brake pressure generator including a displacer which is actuatable by an activatable drive unit and conveys pressure medium to a wheel brake of the power braking system. After a change of the power braking system from generating a generator braking torque to generating a friction braking torque, the activation of the drive unit of the displacer is carried out by the electronic control unit in such a way that a velocity of the actuated displacer changes strictly monotonously.

A system includes a phase break input unit, one or more vehicle location detectors, and one or more processors. The phase break input unit is configured to obtain phase break location information indicating a location of a phase break along a route to be traversed by a vehicle. The one or more vehicle location detectors are configured to obtain vehicle location information indicating at least one of location of the vehicle or movement of the vehicle. The one or more processors are configured to determine an estimated arrival time of the vehicle at the phase break using the phase brake location information and the vehicle location information, and send a phase break control signal to a control system of the vehicle responsive to the estimated arrival time satisfying a threshold.

A voltage supply device includes at least one intermediate circuit that has at least one intermediate circuit capacitor, at least one power converter, wherein the power converter is connected to the connections of the intermediate circuit such that the power converter can be supplied with electrical energy from the intermediate circuit capacitor, and includes at least one braking chopper that is connected to the connections of the intermediate circuit capacitor such that electrical energy from the intermediate circuit capacitor can be converted into thermal energy by the braking chopper, where the power converter is equipped with at least one semiconductor switch that is clocked at a higher rate, in particular based on SiC, while the braking chopper is equipped with at least one semiconductor switch that is clocked at a lower rate, in particular based on Si.

A vehicle having wheels for riding the vehicle over a carrier such as a road or rails, said vehicle having a battery and a generator connected thereto, said generator being arranged to generate electrical power for charging said battery, said generator being further mechanically connected to at least one of said wheels such that said wheel drives the rotor of said generator, characterized in that said generator is an asynchronous generator or a permanent magnet generator, wherein an AC/DC inverter/charger is connected between said generator and said battery for regulating the current and the voltage of the charging power to said battery.

A method for controlling the regenerative braking torque of a vehicle having a data processing unit for detecting a first information representing a deceleration request of the vehicle, detecting a second information representing a speed of the vehicle, and a first moving member of the vehicle and a second moving member of the vehicle. The method includes determining temperatures of different braking components on different axles, as well as the state of a battery module and a traction and regenerative braking module. The method also includes determining a regenerative braking power dynamic distribution ratio between the first and second axles. A regenerative braking torque is provided to one of the modules.

A power system including at least one electrical machine, plurality of doubly fed induction machines (DFIMs), a plurality of first power converters, and a speed regulation unit is presented. The electrical machine includes a mechanical input end and at least one of a first stator winding terminal and a first rotor winding terminal. Each DFIM includes a second stator winding terminal, a second rotor winding terminal, and a mechanical output end. At least one of the first stator winding terminal and the first rotor winding terminal is coupled to one of first power converters and the second rotor winding terminal of each DFIM is coupled to one of the first power converters. The speed regulation unit is coupled to at least one of the mechanical input end and the mechanical output end.