Abstract: A charging station system for an electric vehicle includes two plugs, each configured to allow an electric vehicle to be charged by supplying it with direct current, two conductors, each one associated with a plug, and two groups of power modules, each one associated with a plug and capable of converting a current originating from an electric network into direct current delivered to the associated plug. A diagnostic method of the charging station system includes a connection step, aimed at connecting the two plugs together so as to form a loop including the two plugs, the two conductors and the two groups of power modules; a testing step, involving transmitting an electric quantity flowing between the two plugs, in the loop, and measuring operating states of at least some of the elements of the loop in response to this electric quantity; and an analysis step involving diagnosing the elements based on operating state measurements.

Abstract: A charging device, including a housing, a power module, a temperature sensor, a humidity sensor and a controller; the temperature sensor and the humidity sensor are respectively configured to collect a real-time temperature and a real-time relative humidity in an interior of the housing and provide the real-time temperature and real-time relative humidity to the controller; the controller compares the real-time temperature with a threshold temperature and the controller compares the real-time relative humidity with a threshold humidity; upon one of following conditions being met, the controller sets the power module to a heating dew-removal mode, the conditions includes: the real-time temperature is less than or equal to the threshold temperature and greater than 0 degree; the real-time relative humidity is greater than or equal to the threshold humidity; in the heating dew-removal mode. The present disclosure also relates to a method for preventing dew condensation of a charging device.

Abstract: According to various aspects and embodiments, a power device is provided. The power device includes an input configured to receive input power, an output configured to provide output power to a load, a power conversion circuit coupled to the input and configured with a first output line and a second output line, the first output line coupled to the output and configured to provide output current at the output, a capacitor coupled to a junction of the first output line and the output, and coupled to the second output line, and a controller coupled to the power conversion circuit. The controller is configured to receive a first current measurement for the first output line receive a first voltage measurement across the capacitor, and determine a load current based on the first current measurement and the first voltage measurement.

Abstract: An uninterruptible power supply (UPS) system (100) comprises a plurality of UPS units (UPS-1, UPS-2) connected in parallel. Each UPS unit comprises a power converter (124) for supplying a share (i load 1, i_load_2) of a total load current (i_tot). The total load is shared automatically between UPS units of power ratings, in a proportionate manner. A controller 130 of each converter is arranged to establish real-time feedback control of a current supplied by the power converter. An exchange current (i_exch) for each converter represents an imbalance between an output current of the converter in question and output currents of the parallel converters. Exchange current sensing circuits of the parallel-connected UPS units are connected together. The controller steers the exchange current of each converter toward a value (i_exc_c) that is a non-zero proportion of a current (i_mut) sensed within the converter.

Abstract: The present disclosure relates to a controller, a circuit and method for controlling a power converter using pulse width modulation (PWM). At least one logic block (13, 15, 16) of the controller is configured to remove a command (4) which is configured to control the other power semiconductor switch (2) in a half-bridge (1,2) so that the other power semiconductor switch (2) remains in a non-conductive state while an antiparallel diode (6) allows an electric current (5) to pass in one direction, called the diode's forward direction, while blocking current in the opposite direction. In case the diode (6) is conducting instead of the other power semiconductor switch during the duration of the state of the command, the switching command (4) for the latter is omitted.

Abstract: The present disclosure relates to a controller, a circuit and method for controlling a power converter using pulse width modulation (PWM). At least one logic block (13, 15, 16) of the controller is configured to remove a command (4) which is configured to control the other power semiconductor switch (2) in a half-bridge (1,2) so that the other power semiconductor switch (2) remains in a non-conductive state while an antiparallel diode (6) allows an electric current (5) to pass in one direction, called the diode's forward direction, while blocking current in the opposite direction. In case the diode (6) is conducting instead of the other power semiconductor switch during the duration of the state of the command, the switching command (4) for the latter is omitted.

Abstract: An uninterruptible power supply (UPS) system (100) comprises a plurality of UPS units (UPS-1, UPS-2) connected in parallel. Each UPS unit comprises a power converter (124) for supplying a share (i load 1, i_load—2) of a total load current (i_tot). The total load is shared automatically between UPS units of power ratings, in a proportionate manner. A controller 130 of each converter is arranged to establish real-time feedback control of a current supplied by the power converter. An exchange current (i_exch) for each converter represents an imbalance between an output current of the converter in question and output currents of the parallel converters. Exchange current sensing circuits of the parallel-connected UPS units are connected together. The controller steers the exchange current of each converter toward a value (i_exc_c) that is a non-zero proportion of a current (i_mut) sensed within the converter.