TWI439008B - Bidrecrional power inverter circuit and electrical vehicle driving system using the same - Google Patents

Description

Bidirectional converter circuit and electric vehicle drive system

The present invention relates to a bidirectional commutation circuit, and more particularly to a bidirectional commutation circuit that can be combined with an electric vehicle drive system to provide an electric vehicle drive system with energy recharging, power factor correction, and uninterruptible power system functions.

With the development of technology, in the operation of electric vehicles (such as elevators, elevators or electric vehicles, etc.), sufficient uninterrupted power supply is essential for maintaining the normal operation of electric vehicles. The power supply of most electric vehicles is basically from the city's power supply. However, the power system often causes power shortage or interruption (such as emergency power outage) due to problems in the transmission line (such as disconnection or short circuit), which leads to electric power. The vehicle stops operating without warning, causing damage to the electric vehicle or an accident.

Accordingly, in recent years, Uninterruptible Power Supply (UPS) has been widely integrated with electric vehicles to solve the above problem of abnormal power supply. The traditional traditional power supply system is an AC power supply system, the basic system. The power supply device and the battery device are composed of a power supply device, which may include a rectifier and a voltage converter, and the battery device includes a charger and a battery. The conventional uninterruptible power supply system can generally be connected with the power supply and the load to be driven (for example, a motor). Connected to convert the AC power into DC power under normal conditions by using the power supply device to correct and rectify the power supply through the power supply device, so as to charge the battery in the power supply device during normal operation. The DC power is used for DC/AC and voltage conversion to supply the power required by the load to drive the load. When the power supply is interrupted or abnormal, the required power can not be supplied to the load. The traditional uninterruptible power supply system The energy supply can be switched instantly, and the power required by the battery device to supply the load after DC/AC and voltage conversion is temporarily transferred to compensate for the shortage of the main power supply while maintaining the quality of the supplied power.

It can be seen from the above that the conventional conventional power supply system requires two sets of voltage conversion circuits, and two control circuits are used to separately control the conversion circuit. That is to say, the traditional uninterruptible power supply system requires two sets of control circuits to separately drive and control two sets of voltage conversion circuits, and also requires two power conversion processes, thereby increasing switching loss and conduction loss, and reducing overall system circuit efficiency. .

In view of this, the embodiment of the present invention provides a bidirectional commutation circuit that can change the traditional resistance consumption braking system to an energy regeneration system by using the control circuit, thereby effectively recovering the power required for braking and improving energy regeneration. The utilization rate can also be combined with the uninterruptible power system to achieve various system power supply modes (such as mains power supply mode, energy recovery mode, battery power supply mode, etc.). In addition, the embodiment of the present invention provides that the bidirectional converter circuit only needs a set of voltage conversion circuits to achieve the required power factor correction and voltage conversion performance, thereby improving circuit conversion efficiency and power quality, and at the same time, simplifying the circuit structure. Reduce system circuit manufacturing costs.

Embodiments of the present invention provide a bidirectional commutation circuit that is suitable for use in an electric vehicle drive system for providing drive system voltage conversion. The bidirectional commutation circuit includes a first power switch, a second power switch, a third power switch, a fourth power switch, a first inductor, a first capacitor, and a control unit. The first power switch, the second power switch, the third power switch and the fourth power switch respectively have a control end, a first end, and a second And wherein the first and second power switches are connected in series, and the third and fourth power switches are connected in series. The first and second power switches and the third and fourth power switches are further connected in parallel with each other. In addition, four diodes are respectively connected between the first end and the second end of the first power switch, the second power switch, the third power switch and the fourth power switch. The first inductor and the first capacitor are connected in series to each other and to the contacts of the first and second power switches and the contacts of the third and fourth power switches. The series circuit formed by the first inductor and the first capacitor is used as a low-pass filter circuit to eliminate chopping and switching noise of the input voltage. In addition, the first inductor can also make the circuit an output form of constant current. The control unit can control the first and second by outputting a control signal to the control end of the first power switch, the control end of the second power switch, the control end of the third power switch, and the control end of the fourth power switch. The third and fourth power switches operate to set the operating mode of the bidirectional commutation circuit. In addition, the first end of the third power switch is connected to the second capacitor connected between the first end of the third power switch and the second end of the fourth power switch. Accordingly, the voltage formed across the second capacitor is the output voltage of the bidirectional commutation circuit. In addition, the bidirectional converter circuit further includes a current sensing unit and a voltage detecting unit, wherein the current sensing unit and the voltage detecting unit are respectively connected to the control unit. The current sensing unit is configured to detect a current flowing through the first inductor and feed back to the control unit. The voltage detecting unit is configured to detect an output voltage of the bidirectional commutation circuit and feed back to the control unit. The control unit may calculate the detection result of the current sensing unit and the voltage detecting unit to obtain a duty cycle of the control signals corresponding to the first, second, third, and fourth power switches.

In one embodiment of the present invention, the operation mode of the bidirectional commutation circuit is a mains power supply mode, that is, a bidirectional commutation circuit can perform power work of the city. After the rate factor correction, AC/DC conversion, and voltage boost, the load or DC link connected to the back end is provided.

In one embodiment of the invention, the operation mode of the bidirectional commutation circuit is an energy recovery mode. In the energy recovery mode, the load energy of the load such as the motor can be converted into DC/AC conversion and voltage step-down through the bidirectional converter circuit, and then incorporated into the commercial power system to save energy.

In one embodiment of the invention, the operation mode of the bidirectional commutation circuit is a battery powered mode. The battery power supply mode can provide the power required by the load when the power supply is interrupted for a reason, and the power can be boosted by the bidirectional converter circuit to drive the load to temporarily maintain the operation of the load.

An embodiment of the present invention provides an electric vehicle driving system including the above-described bidirectional commutation circuit, a first switch, a second switch motor, a motor drive unit, a battery supply module, and a drive control processing unit, wherein The battery supply module further includes a charging unit and a battery. In addition, the first switch is connected between the AC power source and the first capacitor, and can be used to control the connection between the bidirectional commutation circuit and the AC power source. The second switch is connected between the bidirectional commutation circuit and the battery, and can be used to control the connection between the bidirectional commutation circuit and the battery. The battery supply module can be used as a second power source to supply the power required by the motor when the power supply is interrupted to maintain the operation of the electric vehicle. In the case of normal power supply, the battery can also be charged when the battery does not reach the upper limit. The drive control processing unit controls the operation of the first switch, the second switch, the bidirectional commutation circuit and the motor drive unit to match the operating state of the electric vehicle drive system to establish the required power supply mode.

In summary, the embodiment of the present invention provides a bidirectional commutation circuit, which requires only one set of voltage conversion circuits to achieve the required Power factor correction and voltage conversion performance, thereby reducing switching losses, improving power supply quality, and circuit conversion efficiency, while simplifying the circuit architecture and reducing system circuit manufacturing costs.

In addition, the bidirectional commutation circuit can be combined with the electric vehicle drive system to control the circuit to establish various system power supply modes (eg, mains supply mode, energy recovery mode, battery powered mode, etc.). At the same time, through the establishment of the above-mentioned power supply mode, the energy can be fully utilized, the power supply quality can be improved, and the power required for the system can be continuously supplied to maintain the system operation.

The detailed description of the present invention and the accompanying drawings are to be understood by the claims The scope is subject to any restrictions.

[Embodiment of Bidirectional Converter Circuit]

Please refer to FIG. 1. FIG. 1 is a schematic circuit diagram of a bidirectional commutation circuit 10 according to an embodiment of the present invention. The bidirectional commutation circuit 10 includes a first power switch Q1, a second power switch Q2, a third power switch Q3, a fourth power switch Q4, an inductor L1 (first inductor), a capacitor C1 (first capacitor), and a diode D1. ~D4 (first diode, second diode, third diode and fourth diode) and control unit 101. In addition, the bidirectional commutation circuit 10 further includes a current sensing unit 103 and a voltage sensing unit 105.

Briefly, the first power switch Q1 and the second power switch Q2 are connected to each other in series, and the third power switch Q3 and the fourth power switch Q4 are connected to each other in series. In addition, the first power switch Q1 and the second power switch Q2 are connected in parallel with the third power switch Q3 and the fourth power switch Q4. . The inductor L1 and the capacitor C1 are connected to each other. The inductor L1 is further connected to the junction of the first power switch Q1 and the second power switch Q2, and the capacitor C1 is connected to the junction of the third power switch Q3 and the fourth power switch Q4. The first power switch Q1, the second power switch Q2, the third power switch Q3 and the fourth power switch Q4 are respectively connected to the control unit 101, and the control unit 101 can respectively control the first power switch Q1, the second power switch Q2, and the third The operation of the power switch Q3 and the fourth power switch Q4, that is, the on and off time of the power switch. The bidirectional commutation circuit 10 can therefore perform voltage conversion, such as alternating current and direct current conversion or direct current to direct current conversion, thereby establishing a plurality of voltage conversion modes.

In detail, the first power switch Q1, the second power switch Q2, the third power switch Q3, and the fourth power switch Q4 respectively have a control end, a first end, and a second end. In addition, the cathode of the diode D1 is connected to the first end of the first power switch Q1 and the anode is connected to the second end of the first power switch Q1. The cathode of the diode D2 is connected to the first end of the second power switch Q2 and the anode is connected to the second end of the second power switch Q2. The cathode of the diode D3 is connected to the first end of the third power switch Q3 and the anode is connected to the second end of the third power switch Q3. Similarly, the cathode of the diode D4 is coupled to the first end of the fourth power switch Q4 and the anode is coupled to the second end of the fourth power switch Q4.

Next, the second end of the first power switch Q1 is connected to the first end of the second power switch Q2. The second end of the third power switch Q3 is coupled to the first end of the fourth power switch Q4. In addition, the first end of the first power switch Q1 is connected to the first end of the third power switch Q3, and the second end of the second power switch Q2 is connected to the second end of the fourth power switch Q4. Thereby the first power switch Q1 is connected in series with the second power switch Q2, and the third power The switch Q3 and the fourth power switch Q4 are connected in series. In addition, the first power switch Q1 and the second power switch Q2 and the third power switch Q3 and the fourth power switch Q4 are further connected in parallel to each other to form an architecture similar to a full bridge circuit.

One end of the inductor L1 is connected to one end of the capacitor C1, that is, the inductor L1 is connected in series with the capacitor C1. The other end of the capacitor C1 is connected to the junction of the first power switch Q1 and the second power switch Q2. The other end of the inductor L1 is connected to the junction of the third power switch Q3 and the fourth power switch Q4.

As shown in Figure 1, the input voltage V _IN (such as the AC power of the commercial power supply or the DC power supplied by the battery) can be connected to both ends of the capacitor C1, whereby the capacitor C1 can eliminate the chopping of the input power supply and switch the noise to stabilize the input. Voltage. In addition, one end of the capacitor C2 (second capacitor) is connected to the first end of the third power switch Q3, and the other end of the capacitor C2 is connected to the second end of the fourth power switch Q4. The capacitor C2 can regulate the voltage converted by the bidirectional converter circuit 10, whereby the voltage across the capacitor C2 is the output voltage V _{OUT of the} bidirectional converter circuit 10, and the output voltage V _OUT can be output to the back end. The connected load (not shown in Figure 1) is used to supply the power required by the load.

It is worth mentioning that the control ends of the first power switch Q1, the second power switch Q2, the third power switch Q3 and the fourth power switch Q4 are respectively connected to the control unit 101. That is, the control unit 101 outputs control signals PWM1~4 (for example, pulse width modulation signals) to the control end of the first power switch Q1, the control end of the second power switch Q2, and the control of the third power switch Q3. And the control end of the fourth power switch Q4 controls the on and off times of the first power switch Q1, the second power switch Q2, the third power switch Q3, and the fourth power switch Q4, and further Control the operation of the overall circuit.

Further, the current sensing unit 103 and the voltage sensing unit 105 are connected to the control unit 101, respectively. Specifically, the current sensing unit 103 can be used to detect a change in the current I _L flowing through the inductor L1 (ie, a change in input current) when the circuit operates, to the control unit 101 for performing a calculation analysis. Similarly, the voltage sensing unit 105 can be used to detect the output voltage V _{OUT of the} bidirectional commutation circuit 10 and input it to the control unit 101 for calculation analysis.

Further, the control unit 101 can control the first power according to the control signals PWM1~PWM4 of the same frequency according to the change of the circuit current I _L detected by the current sensing unit 103 and the voltage sensing unit 105 and the output voltage V _OUT . The switch Q1, the second power switch Q2, the third power switch Q3, and the fourth power switch Q4 are turned on and off, thereby establishing a voltage conversion (for example, step-up or step-down, etc.) between the alternating current and the direct current or the direct current to the direct current.

For example, when the bidirectional converter circuit 10 is in operation, the control unit 101 can output the control signals PWM1~PWM4 of the same frequency to the first power switch according to the detected current I _L change and the output voltage V _OUT . Q1, the second power switch Q2, the third power switch Q3, and the control end of the fourth power switch Q4, to set the conduction of the first power switch Q1, the second power switch Q2, the third power switch Q3, and the fourth power switch Q4 Or the deadline, establish the required voltage conversion mode. It should be noted that the specific operation mode of the bidirectional commutation circuit 10 will be described by other embodiments, and therefore will not be described herein.

It is worth mentioning that in the bidirectional converter circuit 10, the inductor L1 and the capacitor C1 are connected in series to form an inductor-capacitor low-pass filter circuit, which can filter the noise of the input voltage source to stabilize the input voltage V _IN and also borrow The noise of the input voltage source is filtered out, and the power factor is corrected (for example, the power factor is increased), so that the phase of the voltage and the current are similar, and the quality of the supplied power is improved, and the inductor L1 can also be regarded as an output form of the constant current. .

In an embodiment, the first power switch Q1, the second power switch Q2, the third power switch Q3, and the fourth power switch Q4 may be an insulated gate bipolar transistor (IGBT). Accordingly, the control terminals of the first power switch Q1, the second power switch Q2, the third power switch Q3, and the fourth power switch Q4 are gates of the insulated gate bipolar transistor. The first ends of the first power switch Q1, the second power switch Q2, the third power switch Q3, and the fourth power switch Q4 are collectors of the insulated gate bipolar transistor. The first ends of the first power switch Q1, the second power switch Q2, the third power switch Q3, and the fourth power switch Q4 are the emitters of the insulated gate bipolar transistors. However, the first power switch Q1, the second power switch Q2, the third power switch Q3, and the fourth power switch Q4 may also be implemented by other power transistors, such as a metal oxide field field effect transistor (MOSFET). ). The current sensing unit 103 can be implemented by a current sensor such as a Hall Effect Sensor or a resistor or the like. The voltage sensing unit 105 can be implemented by a voltage sensor or a voltage dividing circuit. The control unit 101 can be implemented by an editable microprocessor (eg, a digital signal processor, DSP). The load can be changed depending on the system architecture being applied. For example, in the case of an electric vehicle, the load can be a motor.

It should be noted that the present invention does not limit the control unit 101 and current. Sensing unit 103, voltage sensing unit 105, first power switch Q1, second power switch Q2, third power switch Q3, fourth power switch Q4, and type of load, physical architecture, and/or implementation.

[Example of Operation Mode of Parallel Power Supply in Parallel Converter Circuit and Mains]

In the mains power supply mode, the bidirectional commutation circuit 10 can be used as an AC to DC conversion circuit with power factor correction efficiency. In other words, the voltage input terminal of the bidirectional commutation circuit 10 can be connected to the commercial power (hereinafter referred to as the mains), so the bidirectional commutation circuit 10 can convert the AC _AC supplied by the mains to a DC voltage and provide a DC to the back end connection. The chain (DC BUS) is either supplied to the load to drive the load. At the same time, the bidirectional commutation circuit 10 can be used to regulate the input voltage source and the power factor as previously described.

Please refer to FIG. 2A and FIG. 2B . FIG. 2A and FIG. 2B are schematic diagrams showing the operation of the positive half cycle of the mains when the circuit of the bidirectional converter circuit is operated in the mains power supply mode according to an embodiment of the present invention. Briefly, in the mains power supply mode, the control unit 101 controls the operation of the third power switch Q3 and the fourth control switch Q4 by the output control signal to convert the alternating current V _AC into the direct current V _DC .

In detail, the control unit 101 outputs the control signal PWM4 to the control terminal of the fourth power switch Q4 during the positive half cycle of the mains switching cycle to control the operation of the fourth power switch Q4 when the preset is turned on. Further, the control signal PWM4 will first turn on the fourth power switch Q4 (for example, the control signal PWM4 is a control signal of a high level amplitude). At this time, the first, second, and third power switches Q1 to Q3 are in an off state. Specifically, the control signals PWM1~3 outputted by the control unit 101 to the control terminals of the first, second, and third power switches Q1 to Q3 may be, for example, control signals of a low level amplitude. When the fourth power switch Q4 is turned on, the inductor L1 is excited and generates a magnetic field, and the energy supplied by the alternating current V _AC is stored in the inductor L1. Therefore, the inductor L1 current I _L (ie, the input current) rises so that the diode D2 is forward biased. In other words, as shown in FIG. 2A, during the positive half cycle of the mains switching cycle, when the fourth power switch Q4 is turned on, the current I _L is output by the alternating current V _AC , flowing through the inductor L1, the fourth power switch Q4, and the diode D2. And a capacitor C1, which in turn forms a loop 111 (solid solid line). At this time, the voltage level of the output _DC voltage V _{DC is} the voltage from the end point A to the end point B, that is, V _INV .

Then, when the control signal PWM4 is switched to the low-level amplitude and the fourth power switch Q4 is turned off, the inductor L1 is demagnetized via the diode D2 and the diode D3. In other words, the polarity of the inductor L1 is reversed, so that the diode D2 and the diode D3 are forward biased, so the inductor L1 will release the previously stored energy to the capacitor C2 via the diode D2 and the diode D3. (that is, charging capacitor C2), while flowing through inductor L1 current I _L will decrease, and the voltage level of output _DC voltage V _{DC is} the voltage across the capacitor C2. The voltage level of the output _DC voltage V _DC can be fed into the DC link of the back end or supplied to the load as described above. Briefly, as shown in FIG. 2B, during the positive half cycle of the mains switching cycle, when the fourth power switch Q4 is turned off, the current I _L passes through the inductor L1, the diode D2, the capacitor C2, the diode D3, and the capacitor. C1 forms a loop 113 (solid bold line).

2C and FIG. 2D, FIG. 2C and FIG. 2D are respectively schematic diagrams showing the negative half cycle operation of the mains when the circuit of the bidirectional commutation circuit 10 is operated in the mains power supply mode according to an embodiment of the present invention. During the negative half cycle of the mains switching cycle, the control signal PWM3 output by the control unit 101 to the control terminal of the third power switch Q3 first turns on the third power switch Q3 (eg, the control signal PWM3 is a high level amplitude control signal). At this time, the first, the first The second and fourth power switches Q1, Q2, and Q4 are in an off state. That is, the control signals PWM1, 2, 4 output by the control unit 101 to the control terminals of the first, second, and fourth power switches Q1, Q2, Q4 may be, for example, control signals of a low level amplitude.

When the third power switch Q3 is turned on, the inductor L1 is excited and generates a magnetic field, and the energy supplied by the alternating current V _AC is stored. At this time, the inductor L1 current I _L rises, so that the diode D1 is forward biased. In other words, as shown in FIG. 2C, when the negative half cycle of the mains and the third power switch Q3 are turned on, the current is output from the alternating current V _AC , and flows through the capacitor C1, the diode D1, the third power switch Q3, and the inductor L1. Loop 115 (bold solid line). At this time, the voltage level of the output _DC voltage V _{DC is} the voltage from the end point B to the end point A, that is, V _INV .

Then, when the control signal PWM3 is switched to the low-level amplitude to cause the third power switch Q3 to enter the off state, the inductor L1 is demagnetized via the diode D1 and the diode D4 at this time. Specifically, the polarity of the inductor L1 voltage is reversed, so that the diode D1 and the diode D4 are forward biased, whereby the inductor L1 releases the previously stored energy to the diode D1 and the diode D4. Capacitor C2 (that is, charging capacitor C2). At the same time, the current I _L flowing through the inductor L1 will decrease, and the voltage level of the output _DC voltage V _{DC is} the voltage across the capacitor C2. In other words, as shown in Fig. 2D, in the negative half cycle of the mains and the first When the three power switch Q3 is turned off, the current I _L passes through the diode D4, the inductor L1, the capacitor C1, the diode D1, and further forms the loop 117 (bold solid line), and the mains is corrected by the power factor and the alternating current is After rectification, the output power is sent to the back-end circuit, such as a DC bus or directly to the drive load.

Accordingly, it is known to those skilled in the art that the bidirectional commutation circuit 10 approximates a boost converter in the above operation mode, so that the control unit 101 can be turned on and off by the third and fourth. The power switches Q3 and Q4 establish a mains power supply mode. In addition, the control unit 101 also adjusts the voltage level of the output DC power V _DC by adjusting the duty cycles of the third and fourth power switches Q3 and Q4. As described above, the control unit 101 can control the third and the first according to the change of the inductance L1 current detected by the current sensing unit 103 and the voltage level of the direct current V _DC of the output detected by the voltage sensing unit 105. The operation of four power switches Q3 and Q4. It should be noted that the present invention does not limit the actual implementation of the control unit 101 or the actual control mode of the third and fourth power switches. 2A-2D are only one operational schematic diagram of the bidirectional commutation circuit, and are not intended to limit the present invention.

[Energy recovery operation mode embodiment of bidirectional commutation circuit]

In the energy recovery power supply mode, the bidirectional commutation circuit 10 can function as a DC to AC conversion circuit. Accordingly, the load in this embodiment is a motor and is connected to the output of the bidirectional commutation circuit 10. Specifically, the bidirectional commutation circuit 10 can recover the energy of the motor brake operation to the AC BUS to save energy. To put it simply, when the motor is braking, the motor braking energy is converted into alternating current feedback to the mains. Similarly, if the input terminal of the bidirectional commutation circuit 10 is a DC power source, such as a battery, the bidirectional converter circuit 10 can also step down the energy of the motor brake operation and then charge the battery when the battery does not reach the upper limit capacitance.

In detail, in the energy recovery power supply mode, each of the mains switching period control units 101 alternately controls the operations of the first power switch Q1 and the fourth power switch Q4 and the second power switch Q2 and the third power switch Q3. In other words, the control unit 101 outputs the control signals PWM1~PWM4 to the control end of the first power switch Q1, the control end of the second power switch Q2, the control end of the third power switch Q3, and the control end of the fourth power switch Q4, respectively. Set The on or off time of the first, second, third and fourth power switches Q1 to Q4 is determined.

Further, please refer to FIG. 3A and FIG. 3B. FIG. 3A and FIG. 3B are schematic diagrams showing the operation of the positive half cycle of the mains during operation of the circuit of the bidirectional commutation circuit 10 in the energy recovery power supply mode according to an embodiment of the present invention. During the positive half cycle of each mains switching cycle, the control signals PWM2, PWM3 output by the control unit 101 first turn on the second power switch Q2 and the third power switch Q3 (eg, the control signals PWM2, PWM3 are controlled to a high level amplitude) signal). At the same time, the control signals PWM1 and PWM4 output by the control unit 101 first cause the first power switch Q1 and the fourth power switch Q4 to be in an off state (the control signals PWM1 and PWM4 are, for example, control signals of a low level amplitude).

When the second power switch Q2 and the third power switch Q3 are turned on, the inductor L1 is excited and generates a magnetic field. Inductor L1 stores the energy released by capacitor C2. At this time, the inductor L1 current I _L rises, so that the diodes D1 to D4 are reverse biased, and thus the circuit is broken as shown in FIG. 3A. In other words, as shown in FIG. 3A, during the positive half cycle of the mains switching cycle, when the second power switch Q2 and the third power switch Q3 are turned on, the current I _L is output from the capacitor C2 via the third power switch Q3, the inductor L1, and the capacitor. C1, the second power switch Q2, and further a loop 121 (solid solid line). At this time, the voltage level of the output DC power V _DC fed back to the AC power V _{AC is} the voltage from the end point A to the end point B, that is, V _INV .

Then, when the control signal PWM3 is switched to the low level amplitude, so that the third power switch Q3 enters the off state, the inductor L1 releases energy to the capacitor C1 via the second power switch Q2, the diode D4, and the inductor L1 current I _L also It will fall. This energy is incorporated into the alternating current V _AC connected to the capacitor C1, thereby achieving energy recovery, ie energy regeneration. In other words, as shown in FIG. 3B, during the positive half cycle of the mains switching cycle, when the third power switch Q3 is turned off and the second power switch Q2 is turned on, the current I _L flows through the capacitor L1 through the capacitor C1 and the second power switch. Q2 and diode D4 form a loop 123 (solid bold line).

Referring to FIG. 3C and FIG. 3D , FIG. 3C and FIG. 3D respectively illustrate schematic diagrams of the positive half cycle operation of the mains when the circuit of the bidirectional commutation circuit is operated in the energy recovery power supply mode according to an embodiment of the present invention. During the negative half cycle of the mains switching cycle, the control signals PWM1, PWM4 output by the control unit 101 first turn on the first power switch Q1 and the fourth power switch Q4 (eg, the control signals PWM1, PWM4 are high level amplitude control signals) . At the same time, the control signals PWM2 and PWM3 output by the control unit 101 cause the second power switch Q2 and the third power switch Q3 to be in an off state (for example, the control signals PWM2 and PWM3 are control signals of a low level amplitude).

When the first power switch Q1 and the fourth power switch Q4 are turned on, the inductor L1 is excited to generate a magnetic field to store the energy released by the capacitor C2, at which time the inductor L1 current I _L rises. The diodes D1 to D4 are in a reverse bias, and thus are broken as shown in Fig. 3C. In other words, as shown in FIG. 3C, when the first power switch Q1 and the fourth power switch Q4 are turned on during the negative half cycle of the mains switching cycle, the current I _L is output from the capacitor C2 via the first power switch Q1, the capacitor C1, and the inductor. L1, fourth power switch Q4, and further form a loop 125 (bold solid line). At this time, the voltage level of the output DC power V _DC fed back to the AC power V _{AC is} the voltage from the end point B to the end point A, that is, V _INV .

Then, when the control signal PWM4 is switched to the low level so that the fourth power switch Q4 enters the off state, the inductor L1 releases energy to the capacitor C1 via the first power switch Q1 and the diode D3, and the inductor L1 current I _L also follows. decline. This energy is incorporated into the AC power source connected to capacitor C1, thereby completing the energy recovery of a mains switching cycle. In other words, the current I _L will be as shown in FIG. 3D. During the negative half cycle of the mains switching cycle, when the fourth power switch Q4 is turned off and the first power switch Q1 is turned on, the inductor L1 flows through the diode D3, first. The power switch Q1 and the capacitor C1 form a loop 127 (solid bold line).

Accordingly, it is known to those skilled in the art that the bidirectional commutation circuit 10 is similar to a buck converter in the above operation mode. Therefore, the control unit 101 can be turned on and off by the first and second. The third and fourth power switches Q1~Q4 recover the driving load energy into the mains to establish an energy recovery power supply mode. In addition, the control unit 101 also adjusts the voltage level of the direct current _{DC DC} of the output terminal by adjusting the duty cycles of the first, second, third, and fourth power switches Q1 to Q4. As described above, the control unit 101 can control the first, according to the change of the inductance L1 current I _L detected by the current sensing unit 103 and the _DC voltage of the output terminal detected by the voltage sensing unit 105. The operation of the second, third and fourth power switches Q1 to Q4.

It should be noted that the present invention does not limit the actual implementation manner of the control unit 101 or the actual control modes of the first, second, third, and fourth power switches Q1 to Q4. In addition, FIG. 3A to FIG. 3D are only schematic diagrams of operations of the bidirectional commutation circuit, and are not intended to limit the present invention.

[Battery-Powered Operation Mode Embodiment of Bidirectional Converter Circuit]

The input end of the bidirectional commutation circuit 10 can be connected to a DC power source such as a battery, that is, the bidirectional commutation circuit 10 can perform DC/DC conversion. Further, the bidirectional commutation circuit 10 can boost the voltage provided by the battery and then regulate the load connected to the output terminal by using the capacitor C2 to maintain the load operation.

Please refer to FIG. 4A and FIG. 4B . FIG. 4A and FIG. 4B are respectively schematic diagrams showing the operation of the circuit of the bidirectional commutation circuit operating in the battery power supply mode according to an embodiment of the present invention. Briefly, the control unit 101 controls the operation of the fourth power switch Q4 to boost the battery voltage V _BAT (first direct current) connected across the capacitor C1 and output it to the load to drive the load. Specifically, the control signal PWM4 output by the control unit 101 first turns on the fourth power switch Q4 (for example, the control signal PWM4 is a control signal of a high level amplitude). At this time, the first, second, and third power switches Q1 to Q3 are in an off state. That is to say, the control signals PWM1~3 outputted by the control unit 101 to the control terminals of the first, second and third power switches Q1 to Q3 may be, for example, control signals of a low level amplitude. As shown in FIG. 4A, when the fourth power switch Q4 is turned on, the inductor L1 is excited and generates a magnetic field, and the energy (V _BAT ) supplied by the battery is stored in the inductor L1. Therefore, the inductor L1 current I _L (ie, the input current) rises so that the diode D2 is forward biased. The current I _L is output by the battery, flows through the inductor L1, the fourth power switch Q4, the diode D2, and the capacitor C1, thereby forming a loop 131 (solid solid line). The voltage level of the DC power V _DC (second DC) outputted at this time is the voltage from the end point A to the end point B, that is, V _INV .

Then, when the control signal PWM4 is switched to the low level amplitude, so that the fourth power switch Q4 enters the off state, the polarity of the inductor L1 is reversed, so that the diode D2 and the diode D3 are forward biased, so the inductor L1 will The previously stored energy is released to the capacitor C2 via the diode D2 and the diode D3 (ie, the capacitor C2 is charged) while flowing through the inductor L1 current I _L . In other words, as shown in FIG. 4B, when the fourth power switch Q4 is turned off, the current I _L passes through the inductor L1, the diode D2, the capacitor C2, the diode D3, and the capacitor C1, thereby forming a loop 133 (bold solid line) ).

Incidentally, those skilled in the art should know that the operation mode of the bidirectional commutation circuit 10 in the battery power supply mode is similar to the positive half cycle of the bidirectional commutation circuit 10 in the mains power supply mode, and therefore will not be described herein. need 4A-4B are only one operational schematic diagram of the bidirectional commutation circuit, and are not intended to limit the present invention. In addition, the type of the battery, the physical architecture may be set according to actual use requirements, and is not intended to limit the present invention.

[Application example of single pole elevator system]

Please refer to FIG. 5. FIG. 5 is a block diagram showing the architecture of the elevator driving system 2 according to an application embodiment of the present invention. The elevator drive system 2 includes an AC power source 21, an uninterruptible power system 23, a motor drive unit 25, and a motor 27. In this embodiment, the AC power source 21 is a commercial power source. The uninterruptible power system 23 includes a switch S1 (first switch), a switch S2 (second switch), a bidirectional commutation unit 237, a drive control processing unit 231, a battery 233, and a charging unit 235. The bidirectional commutation unit 237 includes a bidirectional commutation circuit 10 (not shown in FIG. 5). The uninterruptible power system 23 is connected between the commercial power 21 and the motor drive unit 25. The motor drive unit 25 is connected to the motor 27. The elevator drive system 2 can operate in one of a mains power supply mode, an energy recovery mode, and a battery power supply mode depending on the system power state.

Further, the switch S1 is connected between the commercial power 21 and the bidirectional commutation unit 237. The switch S2 is connected between the battery 233 and the bidirectional commutation unit 237.

Specifically, the switches S1 and S2 respectively have a control end, a first end and a second end. The positive terminal of the commercial power 21 is connected to the first end of the switch S1, and the second end of the switch S1 is connected to the bidirectional commutation unit 237. The negative pole of the commercial power 21 is connected to the bidirectional commutation unit 237. Accordingly, the switch S1 can be used to switch the connection between the commercial power 21 and the bidirectional commutation unit 237. The positive and negative terminals of the commercial power supply 21 are connected to the charging unit 235.

The first end of the switch S2 is connected between the second end of the switch S1 and the bidirectional commutation unit 237, and the second end of the switch S2 is connected to the positive pole of the battery 233. end. The negative terminal of the battery 233 is connected to the bidirectional commutation unit 237. Accordingly, the switch S2 can be used to switch the connection between the battery 233 and the bidirectional commutation unit 237.

The bidirectional commutation unit 237 is further connected to the motor drive unit 25, and the motor drive unit 25 is connected to the motor 27. Further, the drive control processing unit 231 is connected to the control terminal of the switch S1, the control terminal of the switch S2, the bidirectional commutation unit 237, and the motor drive unit 25, respectively.

The drive control processing unit 231 can switch to establish different power supply modes, such as a mains power supply mode, an energy recovery mode, and a battery power supply mode, by controlling the operations of the switches S1, S2 and the bidirectional commutation unit 237. The drive control processing unit 231 can determine whether the charging unit 235 charges the battery by detecting the capacitance of the battery 233. Further, the drive control processing unit 231 can control the motor drive unit 25 to adjust the operational state of the motor 27 such as the rotational direction of the motor 27, the rotational rotational speed, and the like.

Please refer to FIG. 6. FIG. 6 is a schematic diagram showing the operation of the elevator driving system 2 operating in the utility power supply mode according to an application embodiment of the present invention. For example, when the single pole elevator drive system 2 is operated in the mains power supply mode (normal operation mode), the drive control processing unit 231 controls the on switch S1 to turn off the switch S2. The drive control processing unit 231 also drives the control bidirectional commutation unit 237 to enter the mains power supply mode. The control and operation mode is the same as that of the above embodiment, and therefore will not be described herein. The commercial power supply 21 outputs the AC power to the bidirectional commutation unit 237 via the transmission line, and is boosted by the power factor correction and the voltage conversion, and then outputs the DC power V _DC and is regulated by the capacitor C2 and supplied to the motor drive unit 25 to drive the motor 27 so that The elevator is running normally. At the same time, the commercial power supply 21 also outputs an AC power source to the charging unit 235 via the transmission line to charge the battery 233 when the drive control processing unit 231 detects that the battery 233 does not reach the upper limit.

For example, please refer to FIG. 7. FIG. 7 is a schematic diagram showing the operation of the single pole elevator driving system 2 in the energy recovery mode according to an application embodiment of the present invention. When the motor 27 is braking, the drive control processing unit 231 can operate the single pole elevator drive system 2 in the energy recovery mode by controlling the bidirectional commutation unit 237 and the motor drive unit 25. The control and operation mode of the bidirectional commutation unit 237 is the same as that of the above embodiment, and therefore will not be described herein. Briefly, when the motor 27 is braking, the bidirectional commutation unit 237 can drive the motor 27 to drive energy recovery via buck and power adjustment and then merge it into the mains 21 via the transmission line. Similarly, the driving energy of the recovered motor 27 can also output an AC power source to the charging unit 235 via the transmission line. When the driving control processing unit 231 detects that the battery 233 has not reached the upper limit of the capacity, the charging unit 235 charges the battery 233.

Next, please refer to FIG. 8. FIG. 8 is a schematic diagram showing the operation of the single pole elevator driving system 2 operating in the battery power supply mode according to an application embodiment of the present invention. When the commercial power supply 21 is powered off (for example, the transmission line is broken or short-circuited), the drive control processing unit 231 controls the conduction switch S2 to turn off the switch S1 to operate the single-pole elevator drive system 2 in the battery power supply mode (emergency operation mode), in other words, the drive control process. The unit 231 cuts off the connection of the monopole elevator drive system 2 to the mains 21 and turns to the battery 233. Thereby, the single pole elevator drive system 2 turns the battery 233 to temporarily supply the power required by the motor 27, for example, when the utility power 21 is powered off, providing sufficient power to safely park the elevator to the nearest or most suitable floor.

Similarly, the drive control processing unit 231 drives and controls the bidirectional commutation unit 237 to enter the battery power supply mode. The control and operation mode is the same as that of the above embodiment, and therefore will not be described herein. The battery 233 outputs a DC power supply to the bidirectional commutation unit 237 via the transmission line, and then outputs a DC power V _DC , which is regulated by the capacitor C2 and supplied to the motor drive unit 25 to drive the motor 27 to operate the elevator normally.

Incidentally, in actual implementation, the motor 27 can be a three-phase motor. The motor drive unit 25 can be realized by a three-phase full-bridge inverter circuit, and the three-phase full-bridge circuit can be composed of six power transistors and six diodes. The charging circuit of the charging unit 235 is composed of a diode, a power transistor, a capacitor, an inductor, and the like. The battery 233 can be implemented with a lithium battery. It should be noted that the present invention does not limit the type, physical architecture, and/or actual implementation of the battery 233, the charging unit 235, the motor drive unit 25, and the motor 27. In addition, FIGS. 5-8 are only an application mode of the bidirectional commutation circuit 10 of FIG. 1, and are not intended to limit the present invention. In other words, the bidirectional commutation circuit 10 can be applied to other types of electric vehicle drive systems, such as electric vehicles. In general, the present invention does not limit the application mode of the bidirectional converter circuit 10 of FIG. 1, and those skilled in the art should be able to infer other practical applications of the bidirectional converter circuit 10, and thus will not be described herein.

It should be noted that the coupling relationship between the components in the above embodiments includes direct or indirect electrical connection, as long as the required electrical signal transmission function can be achieved, and the present invention is not limited. The technical means in the above embodiments may be combined or used alone, and the components may be added, removed, adjusted or replaced according to their functions and design requirements, and the invention is not limited. After the description of the above embodiments, those skilled in the art should be able to deduce the embodiments thereof, and no further details are provided herein.

[Possible effects of the examples]

In summary, the bidirectional commutation circuit provided by the embodiment of the present invention, the bidirectional commutation circuit can be formed by a capacitor and a filter circuit and four The power switch establishes a commutation circuit with power factor correction and voltage conversion. In addition, by controlling the power switch to be turned on and off, various power supply modes are established, such as a mains power supply mode, an energy recovery mode, and a battery power supply mode. The bidirectional commutation circuit can perform functions such as power factor correction, voltage conversion, and rectification on the input current source, thereby improving voltage conversion efficiency, reducing line loss, and improving power quality.

It is worth mentioning that this circuit can be used in electric vehicle drive systems, such as elevators and electric vehicles. Taking the elevator drive system as an example, when operating in the mains supply mode, the bidirectional commutation circuit can convert the mains from AC to DC and then boost it to the motor, and also charge the built-in battery of the drive system. When the mains is interrupted for some reason, the emergency switch is powered by the battery, that is, enters the battery power supply mode, and the bidirectional commutation circuit can supply the power of the battery to the motor after being boosted, so that the elevator can safely stop at the nearest and most suitable floor. According to this, the bidirectional converter circuit can replace the traditional resistance consumption brake system, such as when the motor is emergency braking, enters the energy recovery mode, and the bidirectional commutation circuit converts the brake energy recovery into the commercial power after the pressure reduction, and the battery does not reach the upper limit capacitance. When charging the battery, it saves energy.

The above description is only an embodiment of the present invention, and is not intended to limit the scope of the invention.

10‧‧‧Bidirectional commutation circuit

101‧‧‧Control unit

103‧‧‧ Current sensing unit

105‧‧‧Voltage sensing unit

111, 113, 115, 117, 121, 123, 125, 127, 131, 133‧‧‧ circuits

21‧‧‧Power

23‧‧‧ Uninterruptible power system

231‧‧‧Drive Control Processing Unit

233‧‧‧Battery

235‧‧‧Charging unit

237‧‧‧Bidirectional converter unit

25‧‧‧Motor drive unit

27‧‧‧Motor

I _L ‧‧‧current

V _AC ‧‧‧AC

V _DC ‧‧‧DC

V _IN ‧‧‧ input voltage

V _BAT ‧‧‧Battery voltage

V _OUT ‧‧‧ output voltage

S1, S2‧‧‧ switch

PWM1~PWM4‧‧‧ control signal

Q1‧‧‧First power switch

Q2‧‧‧second power switch

Q3‧‧‧ third power switch

Q4‧‧‧fourth power switch

D1~D4‧‧‧ Diode

L1‧‧‧Inductance

C1, C2‧‧‧ capacitor

A, B‧‧‧ endpoint

FIG. 1 is a schematic circuit diagram of a bidirectional commutation circuit according to an embodiment of the present invention.

2A is a schematic diagram of operation of a bidirectional commutation circuit operating in a mains power supply mode according to an embodiment of the invention.

2B is a bidirectional commutation circuit according to an embodiment of the present invention. Schematic diagram of the operation of the mains power supply mode.

FIG. 2C is a schematic diagram of the operation of the bidirectional commutation circuit operating in the mains power supply mode according to an embodiment of the invention.

FIG. 2D is a schematic diagram of the operation of the bidirectional commutation circuit operating in the mains power supply mode according to an embodiment of the invention.

FIG. 3A is a schematic diagram of operation of a bidirectional commutation circuit operating in a braking energy recovery mode according to an embodiment of the invention.

FIG. 3B is a schematic diagram of the operation of the bidirectional commutation circuit operating in the braking energy recovery mode according to another embodiment of the present invention.

FIG. 3C is a schematic diagram of the operation of the bidirectional commutation circuit operating in the braking energy recovery mode according to another embodiment of the present invention.

FIG. 3D is a schematic diagram of the operation of the bidirectional commutation circuit operating in the braking energy recovery mode according to another embodiment of the present invention.

FIG. 4A is a schematic diagram of operation of a bidirectional commutation circuit operating in a battery power supply mode according to another embodiment of the present invention.

FIG. 4B is a schematic diagram of operation of a bidirectional commutation circuit operating in a battery power supply mode according to another embodiment of the present invention.

FIG. 5 is a functional block diagram of an elevator driving system architecture according to an application embodiment of the present invention.

FIG. 6 is a schematic diagram of operation of an elevator driving system operating in a mains power supply mode according to an application embodiment of the present invention.

FIG. 7 is a schematic diagram of the operation of the elevator driving system operating in the energy recovery mode according to an application embodiment of the present invention.

FIG. 8 is a schematic diagram of the operation of the elevator driving system operating in the battery power supply mode according to an application embodiment of the present invention.

10‧‧‧Bidirectional commutation circuit

101‧‧‧Control unit

103‧‧‧ Current sensing unit

105‧‧‧Voltage sensing unit

V _IN ‧‧‧ input voltage

V _OUT ‧‧‧ output voltage

PWM1~PWM4‧‧‧ control signal

Q1‧‧‧First power switch

Q2‧‧‧second power switch

Q3‧‧‧ third power switch

Q4‧‧‧fourth power switch

D1~D4‧‧‧ Diode

L1‧‧‧Inductance

C1, C2‧‧‧ capacitor

I _L ‧‧‧current

Claims (10)

A bidirectional commutation circuit includes: a first power switch having a control end, a first end and a second end; and a second power switch having a control end, a first end, and a second end, wherein the first end of the second power switch is connected to the second end of the first power switch; a third power switch has a control end, a first end, and a second end, wherein The first end of the third power switch is connected to the first end of the first power end; the fourth power switch has a control end, a first end and a second end, wherein the fourth power switch The first end is connected to the second end of the third power switch, and the second end of the fourth power switch is connected to the second end of the second power switch; a first inductor having a first end and a first end a second end, wherein the second end of the first inductor is connected to a junction of the third power switch and the fourth power switch; a first capacitor has a first end and a second end, wherein the first end The first end of the capacitor is connected to the first end of the first inductor, and the first end The second end is connected to the junction of the first power switch and the second power switch; a first diode is connected between the first and second ends of the first power switch; and a second diode Connected between the first and second ends of the second power switch a third diode connected between the first and second ends of the third power switch; a fourth diode connected between the first and second ends of the fourth power switch; a control unit, configured to respectively output a control signal to the control end of the first power switch, the control end of the second power switch, the control end of the third power switch, and the control end of the fourth power switch Controlling the operation of the first, second, third, and fourth power switches, thereby setting an operation mode of the bidirectional commutation circuit, and connecting the first end and the fourth connected to the third power switch A second capacitor between the second ends of the power switches is charged; wherein a voltage formed across the second capacitor is an output voltage of the bidirectional commutation circuit; wherein an alternating current is coupled to the first The two ends of the capacitor are used as an input power source, and the control unit performs power factor correction and AC exchange on the AC power by switching the on and off times of the third power switch and the fourth power switch during the switching period of the alternating current. Straight A DC output voltage after the conversion, the inverter circuit of the bidirectional mode of operation a mains supply line mode. The bidirectional converter circuit of claim 1, wherein the bidirectional converter circuit further comprises: a current sensing unit for detecting a current flowing through the first inductor and feeding back the current a control unit; and a voltage detecting unit for detecting the output voltage of the bidirectional converter circuit and feeding back the control unit; wherein the control unit detects the current sensing unit and the voltage detecting unit As a result, a computational analysis is performed to obtain duty cycles corresponding to the control signals of the first, second, third, and fourth power switches, respectively. The bidirectional converter circuit of claim 1, wherein the operation mode of the bidirectional commutation circuit is at least one of the mains power supply mode, an energy recovery mode, and a battery power supply mode. The bidirectional converter circuit of claim 3, wherein the alternating current is connected to the two ends of the first capacitor, and the control unit controls the first power switch by switching, in the switching period of the alternating current The on and off time of the second power switch, the third power switch and the fourth power switch, and the DC current released by the second capacitor is converted into DC to AC, and then converted into the AC power, the bidirectional commutation circuit The operation mode is the energy recovery mode; when a battery is connected to the two ends of the first capacitor, and the control unit controls the conduction and the off time of the fourth power switch, the battery outputs one of the first direct currents When the DC-DC conversion is performed to output a second DC power, the operation mode of the bidirectional commutation circuit is the battery power supply mode. A bidirectional commutation circuit includes: a first power switch having a control end, a first end and a second end; and a second power switch having a control end, a first end and a second end, its The first end of the second power switch is connected to the second end of the first power switch; the third power switch has a control end, a first end and a second end, wherein the third power switch The first end is connected to the first end of the first power end; a fourth power switch has a control end, a first end and a second end, wherein the first end of the fourth power switch is connected to the first end The second end of the fourth power switch is connected to the second end of the second power switch; the first inductor has a first end and a second end, wherein the first end The second end of the first inductor is connected to the junction of the third power switch and the fourth power switch; a first capacitor has a first end and a second end, wherein the first end of the first capacitor An end is connected to the first end of the first inductor, and the second end of the first capacitor is connected to a junction of the first power switch and the second power switch; a first diode is connected to the first end Between the first and second ends of the power switch; a second diode connected to the second power switch Between the first and second ends; a third diode connected between the first and second ends of the third power switch; a fourth diode connected to the fourth power switch First, between the second end And a control unit, configured to respectively output a control signal to the control end of the first power switch, the control end of the second power switch, the control end of the third power switch, and the fourth power switch a control terminal for controlling operation of the first, second, third, and fourth power switches, thereby setting an operation mode of the bidirectional commutation circuit, and connecting the first end connected to the third power switch a second capacitor between the second ends of the fourth power switch is charged; wherein a voltage formed across the second capacitor is an output voltage of the bidirectional converter circuit; wherein an alternating current is connected to the first The two ends of a capacitor, and the control unit controls the on and off times of the first power switch, the second power switch, the third power switch, and the fourth power switch by switching, in a switching period of the alternating current, The operation mode of the bidirectional commutation circuit is an energy recovery mode when the DC power discharged by the second capacitor is converted into DC-to-AC and then converted into the AC power. A bidirectional commutation circuit includes: a first power switch having a control end, a first end and a second end; and a second power switch having a control end, a first end and a second end, The first end of the second power switch is connected to the second end of the first power switch; the third power switch has a control end, a first end and a second end, The first end of the third power switch is connected to the first end of the first power end; the fourth power switch has a control end, a first end and a second end, wherein the fourth power switch The first end is connected to the second end of the third power switch, and the second end of the fourth power switch is connected to the second end of the second power switch; a first inductor has a first end and a first end a second end, wherein the second end of the first inductor is connected to a junction of the third power switch and the fourth power switch; a first capacitor has a first end and a second end, wherein the first end The first end of the first capacitor is connected to the first end of the first power switch, and the second end of the first capacitor is connected to the contact point of the first power switch and the second power switch; Connected between the first and second ends of the first power switch; a second diode connected between the first and second ends of the second power switch; a third diode Connecting between the first and second ends of the third power switch; a fourth diode connected to the fourth power switch Between the first and second ends; and a control unit configured to output a control signal to the control terminal of the first power switch, the control terminal of the second power switch, the power switch of the third The control terminal and the control end of the fourth power switch are configured to control operation of the first, second, third, and fourth power switches, thereby setting an operation mode of the bidirectional commutation circuit, and connecting to the Charging a second capacitor between the first end of the third power switch and the second end of the fourth power switch; wherein a voltage formed across the second capacitor is one of the bidirectional commutation circuits An output voltage; wherein when a battery is connected to the two ends of the first capacitor, and the control unit controls the conduction and the off time of the fourth power switch, the first DC power outputted by the battery is DC-DC When the second direct current is output after the conversion, the operation mode of the bidirectional commutation circuit is a battery power supply mode. An electric vehicle drive system having a bidirectional commutation circuit as described in claim 1 is applicable to a motor for driving an electric vehicle, comprising: a motor drive unit connected to the bidirectional commutation circuit and Between the motors, the driving direction and speed of the motor are controlled; a battery supply module includes a charging unit and a battery, wherein the charging unit is used for charging the battery, and the battery is used for outputting a DC power supply; a first switch connected between an AC power source and the bidirectional converter circuit for controlling a connection between the bidirectional commutation circuit and the AC power source; and a second switch, the bidirectional commutation Between the circuit and the battery for controlling the a connection between the bidirectional converter circuit and the battery; and a drive control processing unit configured to set an operation mode of the electric vehicle drive system, and control the first switch, the second switch, the The bidirectional commutation circuit and the operation of the motor drive unit. The electric vehicle driving system of claim 7, wherein the driving control processing unit supplies the alternating current power supply to the driving motor through the bidirectional commutation circuit by turning on the first switch and cutting off the second switch. The power is simultaneously charged to the battery via the charging unit, thereby establishing a mains power supply mode. The electric vehicle driving system of claim 7, wherein the driving control processing unit controls the bidirectional commutation circuit to convert the kinetic energy of the motor into electric power and feed back to the mains to establish an energy recovery. mode. The electric vehicle driving system of claim 7, wherein the driving control processing unit, when detecting the mains power failure, turns on the second switch and turns off the first switch, so that the battery will be output The DC power supply provides power required for motor drive via the bidirectional commutation circuit to establish a battery power mode.