Abstract: A load management system for managing loads in a power distribution grid. The load management system includes a control unit and at least two current transformers, which are each connected to the control unit by a signal cable. A first current transformer of the at least two current transformers is arranged in the power distribution grid such that the first current transformer is suitable for measuring a current level that is dominant in a grid connecting line of the power distribution grid, which grid connecting line is connected to a power supply company. A second current transformer of the at least two current transformers is arranged in the power distribution grid such that the second current transformer is suitable for measuring the current level that is dominant in a power line of the power distribution grid, which power line feeds at least one charging station of the power distribution grid.

Abstract: A method is provided for operating a bidirectional charger (1) for DC charging of electric vehicles. The charger (10) has a charging terminal (11) for connecting an electrically driven vehicle and at least one power electronics unit (12) for providing defined charging current and defined charging voltage at the charging terminal (11). The power electronics unit (12) is subjected to a self-test voltage of at least the maximum charging voltage of the charger (10) at defined time intervals for a defined time for performing a self-test when there is no vehicle at the charging terminal (11). A check then is performed to ascertain whether a short circuit or defect is formed at the power electronics unit (12). The charging terminal (11) is enabled for charging a vehicle if no short circuit is found and the charging terminal is blocked for charging a vehicle when a short circuit is established.

Abstract: A dehumidifier means includes: an electrothermal converter element; and a collecting container, arranged beneath the electrothermal converter element, for collecting condensate forming thereon, the collecting container having a drain through which the condensate from the collecting container is dischargeable out of the dehumidifier means. In an embodiment, the dehumidifier means includes a support plate on which a holding frame is arranged. The electrothermal converter element is inserted into the holding frame.

Abstract: A charging station for an electric or hybrid vehicle includes at least one battery bank, a charging/discharging electronics system, at least one connection to a vehicle charging port, and an air conditioning device for heating and cooling at least one battery bank. The air conditioning device includes a refrigerant circuit for conducting a refrigerant and a coolant circuit for conducting a coolant. A control unit of the air conditioning device is configured for establishing a thermal short circuit of the coolant circuit between a heat reservoir and a cold reservoir and operating a motor of a compressor of the refrigerant circuit for as long as it takes for the waste heat of the motor fluidically connected to a space surrounding the battery bank to effectuate a temperature increase in the space to or above a predefined value.

Abstract: A method for charging a traction battery of a vehicle at a stationary charging column includes having the vehicle charging controller register a charging process to the charging column charging controller with a high voltage value of the traction battery as a requested maximum charging voltage. The charging column charging controller then performs an insulation test at an insulation test voltage that corresponds to the requested maximum charging voltage or to the maximum charging column voltage when the latter is lower than the requested maximum charging voltage. The insulation test voltage is measured by a vehicle voltmeter. If the measured insulation test voltage corresponds to the lower voltage value, the vehicle charging controller registers a charging process to the charging column charging controller with the low voltage value as new requested charging voltage and sets the charging voltage adapter to a charging column voltage corresponding to the low voltage value.

Abstract: A method charges a traction battery (42) with a stationary charging column (20). The method includes registering a charging process by the vehicle charging controller (50) to the charging column charging controller (22) with a low voltage value (U1) as a requested charging voltage (UR). The method then controls an insulation test carried out by the charging-column-side insulation tester (26). The method reports the maximum charging column voltage (UL) to the vehicle charging controller (50), and if the reported maximum charging column voltage (UL) corresponds to a high voltage value (U2) higher than the low voltage value (U1): registering a charging process by the vehicle charging controller (50) to the charging column charging controller (22) with the high voltage value (U2) as a requested charging voltage (UR) and setting the charging voltage adapter (44) to a charging voltage (UL) corresponding to the high voltage value (U2).

Abstract: An expansion module (1) for a charging point has a DC measuring device (3) configured, when installed in the charging point, to carry out a current and voltage measurement on the DC charging lines of the charging point. An evaluation unit (2) is coupled to the DC measuring device (3) and calculates an amount of energy drawn based on the current and voltage measurement carried out by the DC measuring device (3). A display unit (4) is coupled to the evaluation unit (2) or is integrated therein. The evaluation unit (2) further has a switch-off interface (5) to provide a switch-off signal at the switch-off interface (5) if, on the basis of the current and/or voltage measurement carried out by the DC measuring device (3), it is determined that an overcurrent or short circuit is present. A charging point equipped with the expansion module (1) also is provided.

Abstract: A charging station for electric automobiles having a variable number of power electronics modules and a variable number of charging connections electrically connected to the power electronics modules.

Abstract: A cooling tank installation (10) for a liquid cooling of a charging station for electrically powered motor vehicles includes at least one reservoir (12, 14) for receiving an environmentally hazardous cooling medium. The reservoir (12, 14) is inserted in a retention vessel (16) for retaining a quantity of leakage from the reservoir (12, 14), and a receiving volume for receiving the entire liquid volume of the reservoir (12, 14) is formed between the reservoir (12, 14) and the retention vessel (16). The retention vessel (16) is inserted in an outer vessel (20) that provides support with respect to earth loads. An absorption body (24) is provided in the outer vessel (20) between the retention vessel (16) and the outer vessel (20) in the direction of gravity for absorbing moisture, and a moisture sensor detects moisture of the absorption body (24).

Abstract: A method is provided for operating a vehicle-external charging device (1) for charging an electric or hybrid vehicle. The method checks an electrical connection of an insulation monitor (3) between a contactor (4) of the charging device (1) and a charging cable (5) of the charging device (1) when the contactor (4) is in a closed switching state and also uses the insulation monitor to check an electrical insulation of the charging cable (5) when the contactor (4) is in an open switching state. A charging device (1) also is provided.

Abstract: A method is provided for carrying out a charging process of a vehicle-external charging apparatus (1) for charging a vehicle (2), in particular an electric or hybrid vehicle. The method includes using a current measuring instrument (3) of the charging apparatus (1) to measure a charging current. The method then includes closing a first contactor (4) of the charging apparatus (1) and a second contactor (5) of the vehicle (2) for a time period that is measured by the current measuring instrument (3). A charging apparatus (1) for performing the method also is provided.

Abstract: A method charges a traction battery (42) with a stationary charging column (20). The method includes registering a charging process by the vehicle charging controller (50) to the charging column charging controller (22) with a low voltage value (U1) as a requested charging voltage (UR). The method then controls an insulation test carried out by the charging-column-side insulation tester (26). The method reports the maximum charging column voltage (UL) to the vehicle charging controller (50), and if the reported maximum charging column voltage (UL) corresponds to a high voltage value (U2) higher than the low voltage value (U1): registering a charging process by the vehicle charging controller (50) to the charging column charging controller (22) with the high voltage value (U2) as a requested charging voltage (UR) and setting the charging voltage adapter (44) to a charging voltage (UL) corresponding to the high voltage value (U2).

Abstract: A method for charging a traction battery of a vehicle at a stationary charging column includes having the vehicle charging controller register a charging process to the charging column charging controller with a high voltage value of the traction battery as a requested maximum charging voltage. The charging column charging controller then performs an insulation test at an insulation test voltage that corresponds to the requested maximum charging voltage or to the maximum charging column voltage when the latter is lower than the requested maximum charging voltage. The insulation test voltage is measured by a vehicle voltmeter. If the measured insulation test voltage corresponds to the lower voltage value, the vehicle charging controller registers a charging process to the charging column charging controller with the low voltage value as new requested charging voltage and sets the charging voltage adapter to a charging column voltage corresponding to the low voltage value.

Abstract: A motor vehicle charging cable for DC voltage charging of an electrical energy store of a motor vehicle has a cable sheath that encloses conductors, such as first and second cooling-fluid-cooled electrical conductor for first and second DC voltage phases, a ground conductor or equipotential bonding conductor and/or at least one control conductor. Shaped elements are arranged between the cable sheath and the conductors at positions of the motor vehicle charging cable that are fixed in mounts. The shaped elements guide, clamp and restrict a relative movement between the conductors. The cable sheath restricts a relative movement between the conductors between those positions at which the motor vehicle charging cable is fixed in mounts.

Abstract: A device for charging at least one battery has an electronics module and at least one charging pillar with a charging point. The electronics module has at least one power electronics unit having an AC/DC converter and a DC/DC converter, wherein the electronics module and the at least one charging pillar are spatially separate from one another.

Abstract: A charging system for charging an electric vehicle is provided. The charging system includes a charging station, at least one charging connector, which is able to be coupled to the electric vehicle in order to charge same, a buffer storage device for storing energy, power electronics that are configured to provide the energy from the buffer storage device and/or from a mains connection to the charging station at the at least one charging connector, and a coolant reservoir in which a coolant for cooling the power electronics is stored.

Abstract: A method for determining a maximum storage capacity of an energy store, in particular as a drive battery of a vehicle with an electrical drive, including the steps of determining a state of charge of the energy store of the vehicle, charging the energy store until it reaches its maximum amount of charge, completely discharging the energy store using a separate energy storage unit for receiving the charge of the energy store, wherein an amount of charge transferred from the energy store to the energy storage unit is captured, and outputting the transferred amount of charge upon complete discharging of the energy store as the maximum capacity of the energy store.

Abstract: A dehumidifier means includes: an electrothermal converter element; and a collecting container, arranged beneath the electrothermal converter element, for collecting condensate forming thereon, the collecting container having a drain through which the condensate from the collecting container is dischargeable out of the dehumidifier means. In an embodiment, the dehumidifier means includes a support plate on which a holding frame is arranged. The electrothermal converter element is inserted into the holding frame.

Abstract: A cooling system for a charging column system for charging electrically driveable motor vehicles, has an inlet collecting line for the supply of a cooling medium, an outlet collecting line for the discharge of the heated cooling medium, and multiple cooling lines which are each able to be thermally coupled to an associated charging column to be cooled that serves for charging the electrically driveable motor vehicle and which serve for cooling the charging column, in particular a charging cable of a charging point and/or power electronics of the charging column. The cooling lines are fluidically connected to the inlet collecting line and to the outlet collecting line so as to be connected in parallel with respect to one another. The connection in parallel of the charging columns for the cooling allows an equal cooling power to be set for each charging column to be cooled.

Abstract: A method for charging sequence control of a power electronics system, in which a charging power is provided by the power electronics system, in which a charging unit, which is operated by a user and which transfers the charging power to a battery, is controlled by a charging control system. A communication exchange is carried out at least between a control device of the power electronics system and the charging control system, in which a plurality of charging process states are predetermined, in which sequences between the charging process states are stored in a program sequence plan and in which the program sequence plan is used for charging sequence control of the power electronics system. For the event of a fault the charging process states “Not ready to charge” and “Fault in charging process” are predetermined.