A safety circuit arrangement is provided for an electrical drive unit, wherein the electrical drive unit includes a traction battery, an intermediate circuit capacitance connected in parallel to the traction battery, and an electric machine which can be supplied with electrical power by the traction battery. The electric machine has a plurality of phases which can be connected to the traction battery via a controllable inverter having a plurality of switch elements. The safety circuit arrangement includes: a discharge circuit which is designed to take a predeterminable discharge current from the intermediate circuit capacitance in the activated operational state of the discharge circuit, a short-circuit control circuit which is designed to short-circuit at least some of the phases of the electric machine by controlling some of the switch elements in the activated operational state of the short-circuit control circuit, a supply voltage circuit which is designed to provide a supply voltage on the basis of input voltage delivered to the supply voltage circuit, an intermediate circuit voltage applied to the intermediate circuit capacitor being delivered as input voltage, and an activating element which is designed to close an activation path when a switch-on condition is present in order to activate the discharge circuit and the short-circuit control circuit by providing the supply voltage.

In a flying object, a PCU has a plurality of operation modes in which an engine and/or a motor generator is used as a driving source for a pusher propeller. In accordance with the state of the flying object, the PCU controls the engine, a first clutch, the motor generator, and a second clutch in one of the operation modes.

A vehicle power supply control apparatus controls (i) storage of electricity generated by an alternator powered by an internal combustion engine of a vehicle and (ii) main and auxiliary power supplies that supply stored electricity to a load. The apparatus includes a first switch, a second switch, a controller and a switching circuit. The first switch is provided between the main power supply and the alternator. The second switch is provided between the auxiliary power supply and the alternator. The controller controls a connection state of the first switch and a connection state of the second switch based on a state of the vehicle. The switching circuit turns on the first switch and/or the second switch in a case where a first voltage of the main power supply is smaller than a second voltage of the auxiliary power supply by a threshold value or greater.

A method is provided for transmitting measured data from cells of a battery system, having a plurality of individual cells, to a control device, comprising the steps of identifying a first individual cell for which measured data are to be furnished at a first measured-data quality; identifying at least one further individual cell or which measured data are to be furnished at a second measured-data quality; the first measured-data quality being higher than the second measured-data quality; identifying the first-quality measured data; identifying the second-quality measured data; transferring the first-quality measured data to a control device using a data connection; and transferring the second-quality measured data after the first-quality measured data have been transferred.

The invention relates to a work machine, in particular in the form of a dump truck or truck, having a diesel electric traction drive, wherein at least one alternator is or can be driven by at least one internal combustion engine of the work machine. In accordance with the invention, the current generation can also be reliably interruptible with a running internal combustion engine by interruption of the excitation circuit by means of a breaker switch.

A flexible charger network includes one or more chargers, each coupled to a processor, and is configured to perform the following operations: at power-up, a charger announces its presence to the network, and requests and awaits an acknowledgement by the network; and, if no acknowledgement is received from the network, that charger assumes a role of master of the network; or, if a response is received from the network, that charger acknowledges an existing master and assumes the role of slave within the network.

An apparatus includes at least one energy source and a drive system coupled to the at least one energy source. The drive system converts electrical power received from the at least one energy source and provides converted electrical power for driving at least one load. The drive system includes a first converter, a second converter, and a first switch module coupled to outputs of the first and second converters. When the apparatus is operating under a first mode, the first switch module is switched to assume a first state to allow a first output electrical power provided from the first converter and a second output electrical power provided from the second converter to be combined for driving a first load with the combined output electrical power.

A power system for a marine ship includes a plurality of protection zones, wherein at least two protection zones are coupled to each other via at least one bus-tie converter. Each of the protection zones includes a plurality of direct current (DC) buses; wherein DC buses which do not have same DC voltage are coupled to each other via at least one DC to DC converter. Furthermore, at least one energy source is coupled to at least one DC bus via a power electronic converter.

A mobility device that can accommodate speed sensitive steering, adaptive speed control, a wide weight range of users, an abrupt change in weight, traction control, active stabilization that can affect the acceleration range of the mobility device and minimize back falls, and enhanced redundancy that can affect the reliability and safety of the mobility device.

A fail-safe method and apparatus for high voltage parts in a hybrid vehicle is provided. In the fail-safe method, it is determined whether or not a high voltage main relay is turned off. Here, when the high voltage main relay is turned off, a voltage is charged into a direct current (DC) link using a counter electromotive force generated in a motor generator linked with a revolution of an engine. Voltage control is performed such that the voltage of the DC link is uniformly maintained using an inverter for the motor generator.