Battery self-heating device and method, and vehicle

What is claimed is: 1 . A battery self-heating device, comprising a bridge arm converter, an energy storage element, an inductor and a controller, a first bus terminal of the bridge arm converter being connected to a positive electrode of a first power battery, and a second bus terminal of the bridge arm converter being connected to a negative electrode of a second power battery; a first end of the inductor being connected to a midpoint of the bridge arm converter, and a second end of the inductor being connected to a negative electrode of the first power battery and a positive electrode of the second power battery; the energy storage element being connected in parallel between the positive electrode of the first power battery and the negative electrode of the second power battery, a first end of the energy storage element being connected to the first bus terminal of the bridge arm converter, and a second end of the energy storage element being connected to the second bus terminal of the bridge arm converter; and the controller being configured to control, in a preset state, connection and disconnection of the bridge arm converter to enable the first power battery and the second power battery to be respectively charged/discharged by the inductor, and to respectively form a freewheeling circuit with the energy storage element to realize continuous heating of the first power battery and the second power battery. 2 . The device according to claim 1 , wherein when one of the first power battery and the second power battery is charged/discharged by the inductor, the other of the first power battery and the second power battery form a freewheeling circuit with the energy storage element. 3 . The device according to claim 2 , wherein a current flow direction when one of the first power battery and the second power battery is charged/discharged by the inductor is a first direction, a freewheeling current flow direction of the other of the first power battery and the second power battery is a second direction, and the first direction is opposite to the second direction. 4 . The device according to claim 1 , wherein the controller is configured to control, in the preset state, alternating connection and disconnection of an upper bridge arm and a lower bridge arm of the bridge arm converter to enable the first power battery and the second power battery to be respectively charged/discharged by the inductor, and to respectively form a freewheeling circuit with the energy storage element to realize continuous heating of the first power battery and the second power battery. 5 . The device according to claim 4 , wherein the controller is configured to control, in the preset state, alternating connection and disconnection of the upper bridge arm and the lower bridge arm of the bridge arm converter according to a preset duty cycle allocation setting. 6 . The device according to claim 5 , wherein the controller is configured to: in the preset state, control the upper bridge arm of the bridge arm converter to be disconnected and the lower bridge arm of the bridge arm converter to be connected when the upper bridge arm of the bridge arm converter is in a connected state, the lower bridge arm of the bridge arm converter is in a disconnected state, and duration that the upper bridge arm of the bridge arm converter reaches first preset duration in the preset duty cycle allocation setting; and control the upper bridge arm of the bridge arm converter to be connected and the lower bridge arm of the bridge arm converter to be disconnected when the lower bridge arm of the bridge arm converter is in a connected state, the upper bridge arm of the bridge arm converter is in a disconnected state, and duration that the lower bridge arm of the bridge arm converter reaches second preset duration in the preset duty cycle allocation setting. 7 . The device according to claim 6 , wherein when the upper bridge arm of the bridge arm converter is in the connected state, the inductor is switched from releasing energy to the first power battery to receiving energy of the first power battery and the energy storage element, and the energy storage element is switched from receiving the energy of the first power battery and the second power battery to releasing energy to the second power battery and the inductor according to a connection time of the upper bridge arm of the bridge arm converter; and when the lower bridge arm of the bridge arm converter is in the connected state, the inductor is switched from releasing energy to the second power battery to receiving energy of the second power battery and the energy storage element, and the energy storage element is switched from receiving energy of the first power battery and the second power battery to releasing energy to the first power battery and the inductor according to a connection time of the lower bridge arm of the bridge arm converter. 8 . The device according to claim 7 , wherein first duration that the inductor receives the energy of the first power battery and the energy storage element is greater than second duration that the inductor releases the energy to the second power battery; and third duration that the inductor receives the energy of the second power battery and the energy storage element is greater than fourth duration that the inductor releases the energy to the first power battery. 9 . The device according to claim 1 , wherein the controller is further configured to control, in the preset state, various elements in the device to be in the following four states cyclically: state one: the upper bridge arm of the bridge arm converter is connected, the lower bridge arm of the bridge arm converter is disconnected, the first power battery is discharged, the energy storage element is discharged, the second power battery is charged, and the inductor is charged, wherein the device comprises a discharge current and a freewheeling current, the discharge current flows out from the positive electrode of the first power battery, flows through the upper bridge arm of the bridge arm converter and the inductor and flows back to the negative electrode of the first power battery, and the first power battery discharges to the inductor; and the freewheeling current flows out from a positive electrode of the energy storage element, flows through the upper bridge arm of the bridge arm converter, the inductor, and the second power battery and flows back to a negative electrode of the energy storage element, and the second power battery is charged by the energy storage element; state two: the upper bridge arm of the bridge arm converter is disconnected, the lower bridge arm of the bridge arm converter is connected, the first power battery is discharged, the inductor is discharged, the second power battery is charged, and the energy storage element is charged, wherein the device comprises a charge current and a freewheeling current, the charge current flows from the inductor to the positive electrode of the second power battery, flows out from the negative electrode of the second power battery, flows through the lower bridge arm of the bridge arm converter and flows back to the inductor, and the second power battery is charged by the inductor; and the freewheeling current flows out from the positive electrode of the first power battery, flows through the energy storage element and flows back to the negative electrode of the second power battery, the first power battery is connected in series with the second power battery, and the first power battery and the second power battery discharge to the energy storage element together; state three: the upper bridge arm of the bridge arm converter is disconnected, the lower bridge