The three-phase synchronous rectifier for battery charger on board vehicle comprises: three rectification units provided with respective inputs connected to respective phases of a permanent magnet generator and with respective outputs connected to a battery of a vehicle; wherein the rectification units are configured to receive at input respective phase currents of the generator and to supply at output rectified currents; and wherein each of the rectification units comprises a current sensor connected to a respective phase of the generator and a respective output circuit connected to the battery and operatively connected to said current sensor; the current sensor being configured to receive at input a respective phase current and the output circuit being configured to be piloted by means of the current sensor to generate the rectified currents; wherein the current sensor comprises at least one toroidal element made of a magnetic material crossed by a lead which conveys the phase current and at least one Hall effect sensor connected to the toroidal element and to the output circuit.

The three-phase synchronous rectifier for battery charger on board vehicle comprises: three rectification units provided with respective inputs connected to respective phases of a permanent magnet generator and with respective outputs connected to a battery of a vehicle; wherein the rectification units are configured to receive at input respective phase currents of the generator and to supply at output rectified currents; and wherein each of the rectification units comprises a current sensor connected to a respective phase of the generator and a respective output circuit connected to the battery and operatively connected to said current sensor; the current sensor being configured to receive at input a respective phase current and the output circuit being configured to be piloted by means of the current sensor to generate the rectified currents; wherein the current sensor comprises at least one toroidal element made of a magnetic material crossed by a lead which conveys the phase current and at least one Hall effect sensor connected to the toroidal element and to the output circuit.

A battery charging device includes a conversion part that converts an alternating current output from an alternating-current generator into a direct current by a switching element and supplies the direct current to a battery; a number-of-revolutions acquisition part that acquires a number of revolutions of the alternating-current generator based on a signal responsive to the operation of the alternating-current generator; and an output control part that determines an energization phase angle that defines a timing of energization of the switching element of the conversion part for supplying a charging current from the alternating-current generator to the battery, and controls energization of the switching element based on the energization phase angle.

A battery charging device includes a conversion part that converts an alternating current output from an alternating-current generator into a direct current by a switching element and supplies the direct current to a battery; a number-of-revolutions acquisition part that acquires a number of revolutions of the alternating-current generator based on a signal responsive to the operation of the alternating-current generator; and an output control part that determines an energization phase angle that defines a timing of energization of the switching element of the conversion part for supplying a charging current from the alternating-current generator to the battery, and controls energization of the switching element based on the energization phase angle.

Charging system and method using a motor driving system are proposed. The charging system includes a battery, an inverter to which D.C. power stored in the battery is applied, including a plurality of legs each including two switching elements, a motor including a plurality of coils of which first ends are respectively connected to connection nodes of the switching elements of each of the plurality of legs, and second ends are connected to each other to form a neutral point, and an inverter driving part configured to control switching of the switching elements, so that switching speeds of the switching elements are different for each mode of a motor driving mode and a charging mode so as to change magnitude of charging voltage supplied to the neutral point of the motor and to output the charging voltage to the battery.

A control device includes a communication circuit configured to acquire battery voltage information of a battery of an electronic device, and a control circuit configured to control, based on the battery voltage information, a charging voltage supply circuit that supplies a charging voltage to the electronic device at a contact point such that a voltage difference between the charging voltage and a battery voltage of the battery is a given set voltage.

The present disclosure provides a charging system and method and a power adapter. The system includes: a battery; a first rectification unit, configured to output a voltage with a first pulsating waveform; a switch unit, configured to modulate the voltage with the first pulsating waveform; a transformer, configured to output a voltage with a second pulsating waveform according to the modulated voltage; a second rectification unit, configured to rectify the voltage with the second pulsating waveform to output a voltage with a third pulsating waveform; and a control unit, configured to output the control signal to the switch unit to decrease a length of a valley of the voltage with the third pulsating waveform such that a peak value of a voltage of the battery is sampled.

Vehicle power distribution circuit for connecting between a battery and a power line connected to a generator or DC/DC-Converter. The circuit has a charging line connecting the battery to the power line for charging the battery when a forward voltage is applied by the generator or DC/DC-Converter. An ideal diode arrangement is provided in the charging line for conducting a forward current from the generator or DC/DC-Converter to the battery when the forward voltage is applied. The ideal diode arrangement prevents conduction of a reverse current from the battery to the power line when a reverse voltage is applied.

Vehicle power distribution circuit for connecting between a battery and a power line connected to a generator or DC/DC-Converter. The circuit has a charging line connecting the battery to the power line for charging the battery when a forward voltage is applied by the generator or DC/DC-Converter. An ideal diode arrangement is provided in the charging line for conducting a forward current from the generator or DC/DC-Converter to the battery when the forward voltage is applied. The ideal diode arrangement prevents conduction of a reverse current from the battery to the power line when a reverse voltage is applied.

An electric power system includes an inverter device coupled with a motor. The inverter device receives from the motor electric energy generated by dynamic braking of the motor. An energy storage device is coupled with the inverter device, and a variable resistive component is disposed between the inverter device and the energy storage device. The variable resistive component controls a direction of conduction of the electric energy from the inverter device toward the energy storage device, a resistive grid, or a system load. The variable resistive component controls the direction of conduction of the electric energy from the inverter device based on a first amount of the electric energy conducted from the inverter device, a transfer rate of the electric energy conducted from the inverter device, or one or more characteristics of the energy storage device.