A DC-DC converter includes a bridge circuit electrically connected to a DC link capacitor; an inductor and a capacitor electrically connected to the bridge circuit, in which the inductor is connected to a first end of a battery, and the capacitor is connected to the first end and a second end of the battery; a sensor configured to sense a voltage between the bridge circuit and the DC link capacitor; and a controller configured to control switching operations of the bridge circuit so that a power output by the DC-DC converter and supplied to the first end of the battery has a droop curve-shaped power value according to the sensed voltage.

A battery assembly includes a battery pack configured to supply energy to a load having a required energy, a housing enclosing the battery pack therein, a converter configured to convert an internal energy of the battery pack, and a controller configured to adjust a parameter of the converter based on information received from the load via a communication interface such that the converter converts the internal energy to the energy required by the load, wherein the converted internal energy is supplied to the load as the supplied energy.

A charging control method of power supply equipment and power supply equipment are provided. The power supply equipment includes a power stage circuit and a battery. An input power supply charges the battery through the power stage circuit. The power stage circuit includes a linear regulator and a switched capacitor converter. The linear regulator is connected with the switched capacitor converter. The linear regulator and/or the switched capacitor converter are/is selected for charging management according to charging power of the battery and/or a voltage of the battery. The charging control method can achieve relatively high charging efficiency when the battery is charged with a large current, and can achieve accurate control of the voltage of the battery when the battery is charged with a small current.

A switching power circuit for charging a battery can include: four switches extending between two ports of a low-frequency AC input voltage and an energy storage circuit, where the energy storage circuit and a primary winding of a transformer are coupled between first and second nodes, the first node is a common node of the first and second switches, and the second node is a common node of the third and fourth switches; a rectification circuit having an input terminal coupled to a secondary winding of the transformer; a DC-DC converter having an input terminal coupled to an output terminal of the rectification circuit, and generates a charging current; and a control circuit that adjusts the charging current by controlling an operation of the DC-DC converter according to a charging requirement, in order to make an average value of the charging current meet the charging requirement.

A switching power circuit for charging a battery can include: four switches extending between two ports of a low-frequency AC input voltage and an energy storage circuit, where the energy storage circuit and a primary winding of a transformer are coupled between first and second nodes, the first node is a common node of the first and second switches, and the second node is a common node of the third and fourth switches; a rectification circuit having an input terminal coupled to a secondary winding of the transformer; a DC-DC converter having an input terminal coupled to an output terminal of the rectification circuit, and generates a charging current; and a control circuit that adjusts the charging current by controlling an operation of the DC-DC converter according to a charging requirement, in order to make an average value of the charging current meet the charging requirement.

A battery charging system includes a first battery charger configured to charge a first battery, a second battery charger configured to charge a second battery, a third battery charger configured to charge a third battery, a first switch circuit configured to open and close an electrical connection between the first battery and the second battery, a second switch circuit configured to open and close an electrical connection between the second battery and the third battery, and a system controller configured to control operations of the first battery charger, the second battery charger, the third battery charger, the first switch circuit, and the second switch circuit. During a charging mode, the system controller is configured to open, by the first switch circuit, the electrical connection between the first battery and the second battery and open, by the second switch circuit, the electrical connection between the second battery and the third battery.

A battery charging system includes a first battery charger configured to charge a first battery, a second battery charger configured to charge a second battery, a third battery charger configured to charge a third battery, a first switch circuit configured to open and close an electrical connection between the first battery and the second battery, a second switch circuit configured to open and close an electrical connection between the second battery and the third battery, and a system controller configured to control operations of the first battery charger, the second battery charger, the third battery charger, the first switch circuit, and the second switch circuit. During a charging mode, the system controller is configured to open, by the first switch circuit, the electrical connection between the first battery and the second battery and open, by the second switch circuit, the electrical connection between the second battery and the third battery.

A high-power DC charger system and method to charge a battery or electric vehicle are disclosed. The system can include a high-power rectifier with a plurality of Gallium Nitride (GaN) switches and a plurality of silicon carbide (SiC) rectifying diodes. The rectifier can be configured to receive AC input and output DC voltage and a converter configured to convert the voltage from the rectifier into a DC voltage that meets the charging needs of a battery.

A battery voltage equalization device 1 includes: a transformer T including a primary winding T1 into which the output voltage of a battery pack BP is inputted and a plurality of secondary windings T2 corresponding to each of batteries B; a conversion circuit 2 that converts an AC voltage outputted by the secondary windings T2 to a DC voltage; a cutoff circuit 3 provided to cut off a conductive pathway from the conversion circuit 2 to the batteries B; and a control unit 5 that controls the energization of the primary winding T1, wherein the cutoff circuit 3 includes a first switch SW1 and the second switch SW2 which are provided in series on the conductive pathway and which are opened or closed by the control unit, a first body diode Db1 and a second body diode Db2 of which the same terminals are connected to each other and which are respectively connected in parallel with the switches, and a surge suppression resistor Rss connected in parallel with the first body diode Db 1 or the second body diode Db2 for which the direction of charging current to the batteries B is the forward direction.

A battery voltage equalization device 1 includes: a transformer T including a primary winding T1 into which the output voltage of a battery pack BP is inputted and a plurality of secondary windings T2 corresponding to each of batteries B; a conversion circuit 2 that converts an AC voltage outputted by the secondary windings T2 to a DC voltage; a cutoff circuit 3 provided to cut off a conductive pathway from the conversion circuit 2 to the batteries B; and a control unit 5 that controls the energization of the primary winding T1, wherein the cutoff circuit 3 includes a first switch SW1 and the second switch SW2 which are provided in series on the conductive pathway and which are opened or closed by the control unit, a first body diode Db1 and a second body diode Db2 of which the same terminals are connected to each other and which are respectively connected in parallel with the switches, and a surge suppression resistor Rss connected in parallel with the first body diode Db 1 or the second body diode Db2 for which the direction of charging current to the batteries B is the forward direction.