Background
In a flying capacitor direct-current conversion circuit of the existing mechanism, when a direct-current side is initially electrified, current charges a bus capacitor through a diode, after a stable state is reached, the voltage at two ends of a flying capacitor is 0, and at the moment, the voltage stress of a switch module is equal to an input voltage; if the withstand voltage value of the switch module is selected according to the half-bus voltage, the voltage stress allowable range of the switch module is exceeded when high voltage is input at the direct current side, and the switch module is damaged. When multiple direct current power conversion circuits are connected in parallel, because of different electrifying sequences, the condition that bus voltage is established before direct current side voltage is established exists, the voltages at two ends of the flying capacitor are zero, if a switch module is switched on, a diode bears the whole bus voltage, if the withstand voltage value of the diode is selected according to half bus voltage, the condition that the voltage stress of the diode is exceeded exists when the multiple direct current power conversion circuits are connected in parallel, and the damage is caused. Therefore, in the dc power conversion circuit in the prior art, the voltage stress of the switching device exceeds the limit, which may cause the device to be damaged.
Disclosure of Invention
The utility model aims to solve the technical problem that a need provide one kind can realize that the current-limiting charges, reduce the probability that switching device damaged the device because voltage stress surpassed the quota, improve the job stabilization nature of product and life's direct current power conversion circuit's hardware circuit basis.
To this end, the utility model provides a direct current power becomesA switching circuit, comprising: power supply ViInductor L, first switch circuit, second switch circuit, third switch circuit, first bus capacitor C1And a second bus capacitor C2Said power supply ViIs connected to the first switch circuit through the inductor L, and the first switch circuit is respectively connected with the second switch circuit, the third switch circuit and the first bus capacitor C1Connected with the first bus capacitor C respectively1And a second bus capacitor C2Connected, the second switch circuit and the second bus capacitor C2Respectively connected with the power supply ViAre connected.
The utility model discloses a further improvement lies in, third switch circuit includes third switch module S3A third one-way conducting device D6Resistance R1And a fourth unidirectional conducting device D7The third switch module S3And said third unidirectional conducting device D6Is connected to a flying capacitor C in the first switching circuitfSaid third unidirectional conducting device D6Through the resistor R1Are respectively connected to the first bus capacitors C1And a second bus capacitor C2A third switch module S3Is connected to the fourth unidirectional conducting device D7Said fourth unidirectional conducting device D7Are respectively connected to the first bus capacitor C1And a second bus capacitor C2。
The utility model discloses a further improvement lies in, first switch circuit still includes first switch module S1A first one-way conducting device D4And a second unidirectional conducting device D5The first switch module S1And said first unidirectional conducting device D4Is connected to the power supply V through the inductor LiThe first switch module S1Is connected to the fourth unidirectional conducting device D7The first unidirectional conducting device D4Respectively with the second unidirectional conducting device D5And the flying capacitor CfIs connected to the second unidirectional conducting device D5Is connected to the first bus capacitor C1One end of said first bus capacitor C1Is connected to the resistor R at the other end1Far away from the third one-way conduction device D6One terminal of said flying capacitor CfIs connected to the third unidirectional conducting device D6The positive electrode of (1).
The utility model discloses a further improvement lies in, second switch circuit still includes second switch module S2Said second switch module S2Is connected to the first switch module S1One end far away from the inductor L, and the second switch module S2Is connected to the power supply V at the other endiThe negative electrode of (1).
The utility model discloses a further improvement lies in, first switch module S1The second switch module S2And a third switch module S3The switching device in (1) includes any one of an IGBT transistor, a MOSFET transistor, and a relay.
The utility model discloses a further improvement lies in, first switch module S1Reverse parallel connected with one-way conducting device D1Said one-way conduction device D1Is connected to the first switch module S1The negative terminal of the unidirectional conducting device D1Is connected to the first switch module S1The positive terminal of (a).
The utility model discloses a further improvement lies in, second switch module S2Reverse parallel connected with one-way conducting device D2Said one-way conduction device D2Is connected to the second switch module S2The negative terminal of the unidirectional conducting device D2Is connected to the second switch module S2The positive terminal of (a).
The utility model discloses a further improvement lies in, third switch module S3Reverse parallel connected with one-way conducting device D3Said one-way conduction device D3Is connected to the third switch module S3The negative terminal of the unidirectional conducting device D3Is connected to the third switch module S3The positive terminal of (a).
The utility model discloses a further improvement lies in, flying electric capacity CfIs less than the first bus capacitance C1Or second bus capacitor C2The capacity value of (c).
The utility model discloses a further improvement lies in, third switch circuit includes third switch module S3A third one-way conducting device D6Resistance R1And a fourth unidirectional conducting device D7The third switch module S3And the resistor R1Is connected to the flying capacitor C in the first switching circuitfSaid resistance R1Is connected to a third unidirectional conducting device D6The third unidirectional conducting device D6Are respectively connected to the first bus capacitor C1And a second bus capacitor C2A third switch module S3Is connected to the fourth unidirectional conducting device D7Said fourth unidirectional conducting device D7Are respectively connected to the first bus capacitor C1And a second bus capacitor C2。
Compared with the prior art, the beneficial effects of the utility model reside in that: at power supply ViWhen the voltage is just generated and the DC power conversion circuit is not started to work, the power supply ViThrough the inductor L, the first switch circuit, the third switch circuit and the second bus capacitor C2In the first switching circuit to the flying capacitor C in the first switching circuitfCharging can be realized by supplying flying capacitor CfLimiting the charging current during charging; and when the DC power conversion circuit starts to work normally and the second switch circuit is in a conducting state, the second one-way conducting device D of the first switch circuit5The borne voltage is half of the bus voltage, so that the flying capacitor C is avoidedfThe problem of damage by high voltage without pre-charging; in addition, a second switch module S of the second switch circuit2And a third switch circuitFourth unidirectional conducting device D7And a second bus capacitor C2A loop is formed so that the second switch module S2Can be controlled by the second bus capacitor C under any working state2Realize voltage clamping and avoid the phenomenon of flying capacitor CfLower voltage and second unidirectional pass device D5Switch on the voltage stress that causes the second switch circuit and exceed standard and damage, consequently, the utility model provides a direct current power conversion circuit's circuit basis, and then can realize the current-limiting well and charge, reduce switching element because voltage stress surpasss the limit and damages the probability of device, effectively improved the job stabilization nature and the life of product.
Drawings
Fig. 1 is a schematic circuit diagram of an embodiment of the present invention;
fig. 2 is a schematic circuit diagram illustrating a first state of the power-on device according to an embodiment of the present invention;
fig. 3 is a schematic circuit diagram illustrating a second state of the power-on device in an initial state according to an embodiment of the present invention;
fig. 4 is a schematic diagram of a second embodiment of the present invention when the power on is started, wherein the voltage across the flying capacitor is equal to the voltage across the first bus capacitor;
fig. 5 is a schematic diagram of a third state of the circuit in parallel connection when the power is turned on according to an embodiment of the present invention;
fig. 6 is a schematic diagram of a timing sequence of a delay control when the voltage across the flying capacitor is equal to the difference between the input voltage and the half bus in the third state when the power is turned on according to an embodiment of the present invention;
fig. 7 is a schematic diagram of a circuit principle of a fourth state of the present invention when multiple paths are connected in parallel when the power is turned on;
fig. 8 is a timing diagram illustrating a time delay control sequence of a fourth state of the multi-path parallel connection when the power is turned on according to an embodiment of the present invention;
fig. 9 is a schematic circuit diagram of an embodiment of the present invention when shut down;
fig. 10 is a schematic diagram of a driving waveform of a first state when the power of an embodiment of the present invention is off;
FIG. 11 shows an embodiment of the present invention in a first state at t1' schematic circuit diagram at time;
fig. 12 shows the first state at t when the power is off according to an embodiment of the present invention2' schematic circuit diagram at time;
fig. 13 shows the first state at t when the embodiment of the present invention is turned off3' schematic circuit diagram at time;
fig. 14 shows the first state at t when the power is off according to an embodiment of the present invention4' schematic circuit diagram at time;
fig. 15 is a schematic diagram of a driving waveform of a second state when the power of an embodiment of the present invention is off;
FIG. 16 shows an embodiment of the present invention in a second state at t when shutdown1' schematic circuit diagram at time;
FIG. 17 shows an embodiment of the present invention in a second state at t2' schematic circuit diagram at time;
FIG. 18 shows an embodiment of the present invention in a second state at t when shutdown3' schematic circuit diagram at time;
FIG. 19 shows an embodiment of the present invention in a second state at t when shutdown4' schematic circuit diagram at time;
fig. 20 is a schematic diagram of a driving waveform of a third state when the power of the embodiment of the present invention is turned off;
FIG. 21 shows a third state at t when the power is off according to an embodiment of the present invention1' schematic circuit diagram at time;
FIG. 22 shows a third state at t when the power is off according to an embodiment of the present invention2' schematic circuit diagram at time;
FIG. 23 shows a third state at t when the power is off according to an embodiment of the present invention3' schematic circuit diagram at time;
FIG. 24 shows a third state at t when the power is off according to an embodiment of the present invention4Time of day circuitA schematic diagram;
fig. 25 is a schematic diagram of a driving waveform of a fourth state when the power of the embodiment of the present invention is off;
FIG. 26 shows a fourth state at t when the power is off according to an embodiment of the present invention1' schematic circuit diagram at time;
FIG. 27 shows a fourth state at t when the power is off according to an embodiment of the present invention2' schematic circuit diagram at time;
FIG. 28 shows a fourth state at t when shutdown according to an embodiment of the present invention3' schematic circuit diagram at time;
FIG. 29 shows a fourth state at t when the power is off according to an embodiment of the present invention4Schematic of the circuit at time.
Detailed Description
Preferred embodiments of the present invention will be described in further detail with reference to the accompanying drawings.
As shown in fig. 1, this example provides a dc power conversion circuit including: power supply ViAn inductor L, a first switch circuit 1, a second switch circuit 2, a third switch circuit 3, a first bus capacitor C1And a second bus capacitor C2Said power supply ViIs connected to the first switch circuit 1 through the inductor L, and the first switch circuit 1 is respectively connected with the second switch circuit 2, the third switch circuit 3 and the first bus capacitor C1Connected with the third switch circuit 3 and the first bus capacitor C respectively1And a second bus capacitor C2Connected, the second switch circuit 2 and the second bus capacitor C2Respectively connected with the power supply ViAre connected.
As shown in fig. 1, the third switching circuit 3 in this example includes a third switching module S3A third one-way conducting device D6Resistance R1And a fourth unidirectional conducting device D7The third switch module S3And said third unidirectional conducting device D6Is connected to the flying capacitor C in the first switching circuit 1fSaid third unidirectional conducting device D6Negative pole ofOver the resistance R1Are respectively connected to the first bus capacitors C1And a second bus capacitor C2A third switch module S3Is connected to the fourth unidirectional conducting device D7Said fourth unidirectional conducting device D7Are respectively connected to the first bus capacitor C1And a second bus capacitor C2. The positive electrode in this example is also called a positive conducting terminal or positive terminal; the negative electrode is also called a negative conduction end or a negative end.
In practical application, the third unidirectional conducting device D6And a resistance R1Can be reversed, i.e. the third switching circuit comprises a third switching module S3A third one-way conducting device D6Resistance R1And a fourth unidirectional conducting device D7The third switch module S3And the resistor R1Is connected to the flying capacitor C in the first switching circuitfSaid resistance R1Is connected to a third unidirectional conducting device D6The third unidirectional conducting device D6Are respectively connected to the first bus capacitor C1And a second bus capacitor C2A third switch module S3Is connected to the fourth unidirectional conducting device D7Said fourth unidirectional conducting device D7Are respectively connected to the first bus capacitor C1And a second bus capacitor C2。
As shown in fig. 1, the first switch circuit 1 of this embodiment further includes a first switch module S1A first one-way conducting device D4And a second unidirectional conducting device D5The first switch module S1And said first unidirectional conducting device D4Is connected to the power supply V through the inductor LiThe first switch module S1Is connected to the fourth unidirectional conducting device D7The first unidirectional conducting device D4Respectively with the second unidirectional conducting device D5And the flying capacitor CfIs connected to the second unidirectional conducting device D5Is connected to the first bus capacitor C1One end of said first bus capacitor C1Is connected to the resistor R at the other end1Far away from the third one-way conduction device D6One terminal of said flying capacitor CfIs connected to the third unidirectional conducting device D6The positive electrode of (1).
As shown in fig. 1, the second switch circuit 2 of this example further comprises a second switch module S2Said second switch module S2Is connected to the first switch module S1One end far away from the inductor L, and the second switch module S2Is connected to the power supply V at the other endiThe negative electrode of (1).
The first switch module S of this example1The second switch module S2And a third switch module S3The switching device in (1) includes any one of an IGBT transistor, a MOSFET transistor, and a relay, each being a controllable element capable of achieving both on and off states, and includes, but is not limited to, an IGBT transistor, a MOSFET transistor, or a relay.
The present example also preferably includes a load resistor RloadSaid load resistance RloadWith said first switching circuit and a first bus capacitor C1Connected, the load resistance RloadAnd the other end of said power supply ViAre connected. Of course, in practical application, this is not limited to the load resistor RloadOther resistive, capacitive or inductive loads may be used, and a subsequent circuit may be used.
As shown in fig. 1, the first switch module S of the present example1The second switch module S2And a third switch module S3The anode of the one-way conduction device is connected to the negative end of each switch device, and the cathode of the one-way conduction device is connected to the positive end of each switch device. That is, the first switch module S1Reverse parallel connected with one-way conducting device D1Said one-way conduction device D1Is connected to its switching device (first switching module S)1) The negative terminal of the unidirectional conducting device D1Is connected to its switching device (first switching module S)1) The second switch module S2And a third switch module S3The same design is also true. The reason for this is that the dc power conversion circuit can pass through the second switch module S when the input voltage and the output voltage both decrease to a reduced level or even to zero after stopping operation2Middle anti-parallel unidirectional conducting device D2And a third switch module S3Anti-parallel unidirectional conducting device D3Flying capacitor CfAnd a flying capacitor C is fed by a loop formed by the output busfDischarging to prevent flying capacitor C after circuit stopfPotential safety hazards caused by long-time voltage maintenance are avoided, and the working stability and safety controllability of the product are improved.
Second switch module S of the present example2And a fourth one-way conduction device D7And a second bus capacitor C2A loop is formed so that the second switch module S2Can be controlled by the second bus capacitor C under any working state2Realize voltage clamping and avoid the phenomenon of flying capacitor CfLower voltage and second unidirectional turn-on device D5Conduction to cause the second switch module S2The voltage stress exceeds the standard and the problem of damage is solved.
In this case, when the circuit stops operating, the first switch module S1The second switch module S2And a third switch module S3Are all in an off state. When the circuit is operating normally, the third switch module S3Remains in the on state, the first switch module S1And the second switch module S2Operating in a high frequency switching state.
In this example, the power supply ViWhen the voltage is just generated and the DC power conversion circuit is not started to work, the power supply ViThrough the inductor L, the first switch circuit 1, the third switch circuit 3 and the second bus capacitor C2In the first switching circuit 1Flying capacitor CfCharging can be realized by supplying flying capacitor CfThe charging current is limited during charging.
Flying capacitor C of the present examplefIs less than the first bus capacitance C1Or second bus capacitor C2The capacity value of (c). In the charging process before starting up, the second bus capacitor C2The charged charge is equal to flying capacitor CfThe charged charge and the first bus capacitor C1The sum of the charged charges. Due to flying capacitor CfThe capacitance value of the first bus capacitor C is far less than that of the first bus capacitor C1Or second bus capacitor C2So that the flying capacitor C is chargedfThe voltage is substantially equal to the first bus capacitor C1Voltage and second bus capacitance C2I.e. half the total bus voltage. Therefore, when the circuit starts to work normally, the second switch module S2In the on state, the second one-way conduction device D5The upper borne voltage is half of the bus voltage, so that the flying capacitor C is avoidedfThere is no problem of damage by high voltage due to precharging.
Therefore, the circuit foundation of the direct current power conversion circuit is provided, current-limiting charging can be well achieved, the probability that the switch device is damaged due to the fact that voltage stress exceeds the limit is reduced, and the working stability and the service life of the product are effectively improved. More specifically, the following detailed descriptions of four states of power on and power off are provided.
According to the difference between the DC voltage and the bus voltage, the present embodiment has four power-on states.
The first state is that there is no voltage on the bus side and the input is first powered up. Initial state Vi=0,VbusWhen the dc power source at the input of the dc power conversion circuit is initially powered on, as shown in fig. 2, the dc power conversion circuit outputs current via the power source ViPositive terminal, the inductor L, a first unidirectional conducting device D4Flying capacitor CfA third one-way conducting device D6Resistance R1A second bus capacitor C2And a power supply ViNegative end loop implementation to flying capacitor CfCharging of (2). Second bus capacitor C2The charged charge is equal to flying capacitor CfThe charged charge and the first bus capacitor C1The sum of the charged charges. Due to flying capacitor CfThe capacitance value of the first bus capacitor C is far less than that of the first bus capacitor C1Or second bus capacitor C2So that the flying capacitor C is chargedfThe voltage is substantially equal to the first bus capacitor voltage C1And a second bus capacitor C2Voltage, i.e. half the total bus voltage. Capacitor C to be flownfWhen the voltage is equal to or close to half the bus voltage, the third switch module S is closed3. Flying capacitor CfThe voltage is equal to or close to half of the bus voltage, so that flying capacitor C is prevented from being used when the direct-current power supply is initially electrifiedfThe voltage at two ends is 0, and the direct current power supply is directly loaded on the second switch module S through the inductor L, the first single-phase conducting device D4 and the flying capacitor Cf path2Resulting in a condition where the second switch module S2 exceeds half bus stress. The resistor R1Can realize the flying capacitor CfLimiting the charging current during charging; vbusIs the bus voltage.
In fig. 2, the output current through the power supply V is indicated by the bold lineiPositive terminal, the inductor L, a first unidirectional conducting device D4Flying capacitor CfA third one-way conducting device D6Resistance R1A second bus capacitor C2And a power supply ViNegative end loop implementation to flying capacitor CfCharging of (1); the following circuit diagrams of various states (the circuit diagrams included in fig. 3 to 29) of this example each show the flow direction indication of the electric signal thereof by using a bold line.
When a second state occurs when the plurality of direct current converters are connected in parallel, when one or more other direct current converters are started, the bus voltage is already established; the corresponding direct current converter is not started, and at the moment, the bus is electrified before the input side of the direct current side is electrified; and when the input power supply at the direct current side is electrified, the input voltage is higher than the bus voltage. At an initial state ofVi=0,Vbus>0, the DC power conversion circuit is powered on and Vi>VbusAs shown in FIG. 3, the DC power conversion circuit outputs current via a power supply ViPositive terminal, the inductor L, a first unidirectional conducting device D4Flying capacitor CfA third one-way conducting device D6Resistance R1A second bus capacitor C2And a power supply ViNegative end loop implementation to flying capacitor CfCharging of (2). As flying capacitor CfVoltage V acrossfEqual to the first bus capacitance C1When the voltage is applied to both ends, as shown in FIG. 4, the DC power conversion circuit outputs a current through a power supply ViPositive terminal, the inductor L, a first unidirectional conducting device D4Flying capacitor CfA third one-way conducting device D6Resistance R1A second bus capacitor C2And a power supply ViNegative end loop, output current through power supply ViPositive terminal, the inductor L, a first unidirectional conducting device D4A second one-way conduction device D5A first bus capacitor C1A second bus capacitor C2And a power supply ViNegative end loop for realizing the first bus capacitor C1A second bus capacitor C2And flying capacitor CfAnd (6) charging. After the DC power conversion circuit reaches the steady state, the third switch module S is closed3And completing the power-on process.
And in the third state, when the multiple direct current converters are connected in parallel, the bus is electrified before the direct current input side is electrified, and after the direct current input side is electrified, the voltage is lower than the total bus and higher than the half bus voltage. When multiple paths are connected in parallel, Vi=0,Vbus>0, DC power conversion circuit is powered on and Vbus/2<Vi<VbusThe output current of the DC power conversion circuit is supplied by a power supply ViPositive terminal, the inductor L, a first unidirectional conducting device D4Flying capacitor CfA third one-way conducting device D6Resistance R1A second bus capacitor C2And a power supply ViNegative end loop implementation to flying capacitor CfAs shown in fig. 5. As shown in fig. 6, whenFlying capacitor CfVoltage V acrossfEqual to the input voltage Vi and half-bus VbusIn the case of a difference of/2, the first switching module S is closed1Delaying a period of time to ensure the first switch module S1After complete conduction, the second switch module S is closed2And the second switch module S is closed after delaying for a period of time2And the first switch module S is closed after delaying for a period of time1Thereby giving flying capacitor CfCharging the capacitor C to be flown by repeating the above stepsfAfter the voltage is equal to half of the bus voltage, the second switching module S is closed2And the first switch module S is closed after delaying for a period of time1Closing the third switch module S after a delay of a certain time3And completing the power-on process.
The fourth state is a case where the bus is powered on before the dc input side when the multiple dc converters are connected in parallel, and the voltage is less than half the bus voltage after the dc input side is powered on, as shown in fig. 7. When multiple paths are connected in parallel, Vi=0,Vbus=VbusDC power conversion circuit is powered on and Vi<Vbus/2. Closing the first switch module S1Delaying a period of time to ensure the first switch module S1After complete conduction, the second switch module S is closed2And the second switch module S is closed after delaying for a period of time2And the first switch module S is closed after delaying for a period of time1Thereby giving flying capacitor CfCharging the capacitor C to be flown by repeating the above stepsfAfter the voltage is equal to half of the bus voltage, the second switching module S is closed2And the first switch module S is closed after delaying for a period of time1Closing the third switch module S after a delay of a certain time3The power-up process is completed as shown in fig. 8.
In this example, at shutdown, t1' bus and input are powered down at the same time, t2' time flying capacitor CfVoltage V acrossfGreater than the whole bus voltage VbusAs shown in FIG. 9, current passes through flying capacitor CfPositive terminal and second one-way conducting device D5A first bus capacitor C1A second bus capacitor C2The second switch module is reversely connected with a one-way conduction device D in parallel2And a third switch module S3And a flying capacitor CfNegative terminal, implementing flying capacitor CfAnd (4) discharging. t is t3The voltage of the bus at the moment is lower than the shutdown voltage of the auxiliary power supply, the auxiliary power supply is turned off, and the third switch module S3Cut off, current passes through flying capacitor CfPositive terminal and second one-way conducting device D5A first bus capacitor C1A second bus capacitor C2A second switch module S2Reverse parallel unidirectional conducting device D2And a third switch module S3Reverse parallel unidirectional conducting device D3And a flying capacitor CfA negative terminal. t is t4The circuit reaches a steady state, the voltage is all zero, and the shutdown is finished.
Based on the DC power conversion circuit of this example, according to duty ratio D and flying capacitor CfAnd half bus VbusThe difference in/2 is the following four states.
1. Duty cycle D<0.5, flying capacitor CfVoltage V offGreater than half of the bus Vbus/2
2. Duty cycle D>0.5, flying capacitor CfVoltage V offGreater than half of the bus Vbus/2
3. Duty cycle D<0.5, flying capacitor CfVoltage V offLess than half of bus Vbus/2
4. Duty cycle D>0.5, flying capacitor CfVoltage V offLess than half of bus Vbus/2
The following is a specific analysis of the normal operation of the dc power conversion circuit in this example.
1. In the first state of the present example at shutdown, when the duty ratio D is<0.5, flying capacitor CfVoltage V offGreater than half of the bus VbusAt/2, the current of the inductor L and the first switch module S1And a second switch module S2The driving waveforms are shown in fig. 10. T is a switching period, a first switching module S1And a second switch module S2For drive signals 180 degrees apart, t is present1’、t2’、t3' and t4' four operating states, as shown in fig. 11 to 14. t is t1' constantly turning on the first switch module S1The output current of the DC power conversion circuit passes through a power supply ViPositive terminal, the inductance L, a first switch module S1And a third switch module S3Flying capacitor CfA second one-way conduction device D5A first bus capacitor C1A second bus capacitor C2And a power supply ViThe negative terminal, as shown in fig. 11. t is t2' moment-off first switch module S1The output current of the DC power conversion circuit passes through a power supply ViPositive terminal, the inductor L, a first unidirectional conducting device D4A second one-way conduction device D5A first bus capacitor C1A second bus capacitor C2And a power supply ViThe negative terminal, as shown in fig. 12. t is t3' constantly turning on the second switch module S2The output current of the DC power conversion circuit passes through a power supply ViPositive terminal, the inductor L, a first unidirectional conducting device D4Flying capacitor CfAnd a third switch module S3A second switch module S2And a power supply ViThe negative terminal, as shown in fig. 13. t is t4' moment-off second switch module S2The output current of the DC power conversion circuit passes through a power supply ViPositive terminal, the inductor L, a first unidirectional conducting device D4A second one-way conduction device D5A first bus capacitor C1A second bus capacitor C2And a power supply ViThe negative terminal, as shown in fig. 14.
2. In the second state of the present example at shutdown, when the duty ratio D is>0.5, flying capacitor CfVoltage V offGreater than half of the bus VbusCurrent of inductor L and first switch module S at time 21A second switch module S2The driving waveforms are shown in fig. 15. T is a switching period, a first switching module S1And a second switch module S2For drive signals 180 degrees apart, t is present1’、t2’、t3' and t4' four operating states, e.g. the figure16 to 19. t is t1' constantly turning on the first switch module S1The output current of the DC power conversion circuit passes through a power supply ViPositive terminal, the inductance L, a first switch module S1A second switch module S2And a power supply ViThe negative terminal, as shown in fig. 16. t is t2' moment-off second switch module S2The output current of the DC power conversion circuit passes through a power supply ViPositive terminal, the inductance L, a first switch module S1And a third switch module S3Flying capacitor CfA second one-way conduction device D5A first bus capacitor C1A second bus capacitor C2And a power supply ViNegative terminal, as shown in fig. 17. t is t3' constantly turning on the second switch module S2The output current of the DC power conversion circuit passes through a power supply ViPositive terminal, the inductance L, a first switch module S1A second switch module S2And a power supply ViThe negative terminal, as shown in fig. 18. t is t4' moment-off first switch module S1The output current of the DC power conversion circuit passes through a power supply ViPositive terminal, the inductor L, a first unidirectional conducting device D4Flying capacitor CfAnd a third switch module S3A second switch module S2And a power supply ViNegative terminal, as shown in fig. 19.
3. In the third state of the present example at shutdown, when the duty ratio D is<0.5, flying capacitor CfVoltage V offLess than half of bus VbusCurrent of inductor L and first switch module S at time 21A second switch module S2The driving waveforms are shown in fig. 20. T is a switching period, a first switching module S1And a second switch module S2For drive signals 180 degrees apart, t is present1’、t2’、t3' and t4' four operating states, as shown in fig. 21 to 24. t is t1' constantly turning on the first switch module S1The output current of the DC power conversion circuit passes through a power supply ViPositive terminal, the inductance L, a first switch module S1And a fourth one-way conduction device D7The second bus barContainer C2And a power supply ViNegative terminal, as shown in fig. 21. t is t2' moment-off first switch module S1The output current of the DC power conversion circuit passes through a power supply ViPositive terminal, the inductor L, a first unidirectional conducting device D4Flying capacitor CfAnd a third switch module S3And a fourth one-way conduction device D7A second bus capacitor C2And a power supply ViThe negative terminal, as shown in fig. 22. t is t3' constantly turning on the second switch module S2The output current of the DC power conversion circuit passes through a power supply ViPositive terminal, the inductor L, a first unidirectional conducting device D4Flying capacitor CfAnd a third switch module S3A second switch module S2And a power supply ViNegative terminal, as shown in fig. 23. t is t4' moment-off second switch module S2The output current of the DC power conversion circuit passes through a power supply ViPositive terminal, the inductor L, a first unidirectional conducting device D4Flying capacitor CfAnd a third switch module S3And a fourth one-way conduction device D7A second bus capacitor C2And a power supply ViThe negative terminal, as shown in fig. 24.
4. In the fourth state of the present example at shutdown, when the duty ratio D is>0.5, flying capacitor CfVoltage V offLess than half of bus VbusCurrent of inductor L and first switch module S at time 21A second switch module S2The driving waveforms are shown in fig. 25. T is a switching period, a first switching module S1And a second switch module S2For drive signals 180 degrees apart, t is present1’、t2’、t3' and t4' four operating states, as shown in fig. 25 to 29. t is t1' constantly turning on the first switch module S1The output current of the DC power conversion circuit passes through a power supply ViPositive terminal, the inductance L, a first switch module S1A second switch module S2And a power supply ViThe negative terminal, as shown in fig. 26. t is t2' moment-off second switch module S2The output current of the DC power conversion circuit is supplied by a power supplyViPositive terminal, the inductance L, a first switch module S1And a fourth one-way conduction device D7A second bus capacitor C2And a power supply ViNegative terminal, as shown in fig. 27. t is t3' constantly turning on the second switch module S2The output current of the DC power conversion circuit passes through a power supply ViPositive terminal, the inductance L, a first switch module S1A second switch module S2And a power supply ViNegative terminal, as shown in fig. 28. t is t4' moment-off first switch module S1The output current of the DC power conversion circuit passes through a power supply ViPositive terminal, the inductor L, a first unidirectional conducting device D4Flying capacitor CfAnd a third switch module S3A second switch module S2And a power supply ViNegative terminal, as shown in fig. 29.
The above-mentioned embodiments are the preferred embodiments of the present invention, and the scope of the present invention is not limited to the above-mentioned embodiments, and the scope of the present invention includes and is not limited to the above-mentioned embodiments, and all equivalent changes made according to the shape and structure of the present invention are within the protection scope of the present invention.