Energy conversion apparatus and safety control method therefor

What is claimed is: 1. An energy conversion apparatus, comprising: a battery; a motor inverter, having a first terminal and a second terminal respectively connected to a first end and a second end of the battery, and comprising an upper bridge arm and a lower bridge arm; a first switch module including at least one first switch connected between the first terminal of the motor inverter and the first end of the battery or the second terminal of the motor inverter and the second end of the battery; a motor winding having a first end connected to the motor inverter; a second switch module having a first end connected to a second end of the motor winding; a first capacitor having a first end connected to the second switch module and a second end connected to the second terminal of the motor inverter; a second capacitor having a first end connected to the first terminal of the motor inverter and a second end connected to the second terminal of the motor inverter; and a controller coupled to the first switch module and motor inverter and configured to control the first switch module to be off to disconnect the battery from the second capacitor and the motor inverter, and control the motor inverter to release energy stored in the first capacitor and the second capacitor when the second switch module is on by: 1) Controlling the upper bridge arm of the motor inverter to be on, so that the second capacitor charges the first capacitor; 2) Controlling the upper bridge arm to be off, and controlling the lower bridge arm of the motor inverter to be on and off alternately, so as to release energy stored in the charged first capacitor; and repeating steps of 1) and 2) until a voltage of the second capacitor is lower than a preset voltage. 2. The energy conversion apparatus according to claim 1 , wherein the first end of the motor winding is connected to a mid-point between the upper bridge arm and the lower bridge arm of the motor inverter. 3. The energy conversion apparatus according to claim 1 , wherein the controller is further configured to control a time when the second capacitor charges the first capacitor according to a vehicle type, a capacitance value of the first capacitor, and a capacitance value of the second capacitor. 4. The energy conversion apparatus according to claim 1 , wherein, to control the lower bridge arm of the motor inverter to be on and off alternately, the controller is further configured to: control a duty cycle of the lower bridge arm to gradually increase from a first duty cycle to a second duty cycle, and control the duty cycle of the lower bridge arm to gradually decrease from the second duty cycle to the first duty cycle. 5. The energy conversion apparatus according to claim 1 , wherein the second switch module being turned on comprises at least one of the following: the second switch module is sintered; after charging of the battery is completed through the energy conversion apparatus, the second switch module is controlled to be turned on; after self-heating of the battery is completed through the energy conversion apparatus, the second switch module is controlled to be turned on; or after a driving function is completed through the energy conversion apparatus, the second switch module is controlled to be turned on. 6. An energy conversion apparatus, comprising: a first switch module; a motor inverter, having a first bus terminal connected with a first end of a battery and a second bus terminal connected with a second end of the battery and comprising an upper bridge arm and a lower bridge arm, wherein the first switch module is configured to control connection and disconnection between the first bus terminal of the motor inverter and the first end of the battery; or the first switch module is configured to control connection and disconnection between the second bus terminal of the motor inverter and the second end of the battery; or the first switch module is configured to control connection and disconnection between the first bus terminal of the motor inverter and the first end of the battery and connection and disconnection between the second bus terminal of the motor inverter and the second end of the battery; a motor winding, having a first end connected with a midpoint end of the motor inverter; a second switch module and a first capacitor, wherein the second switch module and the first capacitor are serial-connected; a first end of the serial-connected second switch module and the first capacitor is connected with a second end of the motor winding; and a second end of the serial-connected second switch module and the first capacitor is connected with the second bus terminal of the motor inverter; a second capacitor having a first end connected to a first terminal of the motor inverter and a second end connected to a second terminal of the motor inverter; and a controller coupled to the first switch module and motor inverter and configured to: control the first switch module to be turned off based on a command representing release of an accumulator, to disconnect the battery from the second capacitor and the motor inverter, and control the motor inverter to release energy stored in the first capacitor and the second capacitor when the second switch module is turned on by: 1) Controlling the upper bridge arm of the motor inverter to be on, so that the second capacitor charges the first capacitor; 2) Controlling the upper bridge arm to be off, and controlling the lower bridge arm of the motor inverter to be on and off alternately, so as to release energy stored in the charged first capacitor; and repeating steps of 1) and 2) until a voltage of the second capacitor is lower than a preset voltage. 7. A safety control method for an energy conversion apparatus, wherein the energy conversion apparatus comprises: a first switch module; a motor inverter, having a first bus terminal connected with a first end of a battery and a second bus terminal connected with a second end of the battery and comprising an upper bridge arm and a lower bridge arm, wherein the first switch module is configured to control connection and disconnection between the first bus terminal of the motor inverter and the first end of the battery; or the first switch module is configured to control connection and disconnection between the second bus terminal of the motor inverter and the second end of the battery; or the first switch module is configured to control connection and disconnection between the first bus terminal of the motor inverter and the first end of the battery and connection and disconnection between the second bus terminal of the motor inverter and the second end of the battery; a motor winding, having a first end connected with a midpoint end of the motor inverter; a second switch module and a first capacitor, wherein the second switch module and the first capacitor are serial-connected; a first end of the serial-connected second switch module and the first capacitor is connected with a second end of the motor winding; and a second end of the serial-connected second switch module and the first capacitor is connected with the second bus terminal of the motor inverter; and a second capacitor having a first end connected to a first terminal of the motor inverter and a second end connected to a second terminal of the motor inverter; wherein the method comprises: controlling the first switch module to be turned off to disconnect the battery from the second capacitor and the motor inverter, and controlling the motor inverter to release energy stored in the first capacitor and the second capacitor when the second switch module is turned on by: 1) Controlling the upper bridge arm of the motor inverter to be on, so that the second capacitor char