CN112910243A - Single-phase three-level pseudo-totem-pole power factor correction circuit - Google Patents

Abstract

A single-phase three-level pseudo-totem-pole power factor correction circuit comprises a single-phase pseudo-totem-pole structure, a filter and a single-phase rectifier bridge with a bidirectional switch tube. Wherein, the single-phase pseudo totem-pole structure comprises two asymmetric bridge arms consisting of 2 full-control power switch tubes and 2 common diodes; the filter consists of two identical inductors; the single-phase rectifier with the bidirectional switch tube consists of a bridge arm consisting of 2 diodes, a group of bidirectional switch tubes, 2 identical series capacitors and a load, wherein two diodes and two fully-controlled power switch tubes form a bidirectional switch tube unit and are connected between the bridge arm of the diodes and the series capacitors. Compared with the traditional boost power factor correction rectifier, the boost power factor correction rectifier can effectively reduce the stress of the switching tube, improve the efficiency of the converter, has small conduction loss of the switching tube, and simultaneously keeps the advantage that the pseudo totem pole has no direct connection of bridge arms.

Description

Single-phase three-level pseudo-totem-pole power factor correction circuit

Technical Field

The invention relates to the technical field of power electronic electric energy conversion, in particular to a single-phase three-level pseudo totem-pole power factor correction circuit.

Background

In order to adapt to the development of economy, the efficiency of rectification and inversion equipment in a power grid is improved to become the mainstream. Reducing higher harmonics is one of the main solutions for improving the quality of electric energy, and among a large number of boost power factor correction circuits, a bridgeless power factor correction circuit is more favored than a traditional boost rectifier because a diode rectifier bridge is omitted to effectively reduce the conduction loss of devices. In a large number of bridgeless power factor correction circuits, the topology of the pseudo-totem-pole two-level rectifier, which has the advantages of high efficiency, no direct connection of bridge arms, less use of components and the like, is more advantageous than other topologies, but the structure enables the components to bear all the voltage of a power grid, so that the cost of the components is higher, and the application of the pseudo-totem-pole two-level rectifier in medium and high voltage power occasions is limited.

Three-level technology is a common way to address high voltage stress. Each switching device is subjected to half the bus voltage when the rectifier is operating. And under the same direct current side voltage condition, the power switch device in the rectifier with the three-level structure bears a smaller voltage change rate, and the system fluctuation is more gradual. The use of a three-level structure helps make the rectifier more tolerant to high voltages and can reduce costs.

Disclosure of Invention

The technical problem to be solved by the invention is as follows: how to utilize three level technology to solve in the traditional pseudo-totem-pole circuit, the problem that power device receives voltage stress is big keeps pseudo-totem-pole circuit to have the advantage such as bridge arm through-connection problem simultaneously. The invention provides a single-phase three-level power factor correction circuit based on a pseudo-totem-pole structure. The pair of fully-controlled switching tubes and the diodes in the structure realize bidirectional current circulation, can solve the problem of high voltage stress of a pseudo totem-pole circuit switching device, can effectively reduce the stress of the switching tubes and improve the efficiency of a converter compared with a traditional boost power factor correction rectifier, has small conduction loss of the switching tubes, and simultaneously reserves the advantage that the pseudo totem-pole circuit is not directly connected with a bridge arm.

The technical scheme adopted by the invention is as follows:

a single-phase three-level pseudo-totem-pole power factor correction circuit, comprising:

the single-phase pseudo totem pole structure, the filter, the single-phase rectifier bridge with two-way switching tube;

the single-phase pseudo-totem-pole structure comprises a switching tube: s₁、S₂And the diode: d₁、D₂；

The filter comprises an inductor L₁、L₂；

The single-phase rectifier bridge with the bidirectional switching tube comprises a diode D₃、D₄A set of bidirectional switch tubes and a capacitor C₁、C₂Load R_L；

The connection relationship is as follows:

switch tube S₁The drain electrodes are respectively connected with a diode D₁Anode, inductor L₁One end;

diode D₂The cathodes are respectively connected with an inductor L₂One end, switch tube S₂A source electrode;

diode D₁The cathodes are respectively connected with a switch tube S₂Drain electrode, diode D₃Cathode and capacitor C₁One end;

diode D₂The anodes are respectively connected with a switch tube S₁Source, diode D₄Anode and capacitor C₂The other end;

inductor L₁Another terminal, an inductance L₂The other ends of the two-way switch are connected with one end of an alternating current power supply;

the other end of the alternating current power supply is respectively connected with a diode D₃Anode, diode D₄Cathode and switch tube S₃Source electrode, switch tube S₄A drain electrode;

capacitor C₁The other ends are respectively connected with a diode D₅Anode, diode D₆A cathode;

switch tube S₃Drain connected diode D₅A cathode; switch tube S₄Source electrode connecting diodePipe D₆And an anode.

The switch tube S₁～S₄Are all metal-oxide semiconductor field effect transistors (MOSFET) with body diodes or Insulated Gate Bipolar Transistors (IGBT).

A rectifying circuit included in the circuit is improved on a traditional pseudo-totem-pole rectifier, a group of bidirectional switching tubes are added between two capacitors to realize bidirectional circulation of current, and three-level voltage output between bridge arms is realized.

In order to realize three-level voltage output between bridge arms, a group of bidirectional switch tubes is added between two capacitors and a diode bridge arm, and each bidirectional switch tube is composed of 2 fully-controlled switch tubes S₃、S₄And two diodes D₅、D₆Component, full-control type switch tube S₃The source electrode of the transistor is connected with the other end of the power supply and the full-control type switch tube S₄Is connected with the drain electrode of the full-control type switch tube S₃And diode D₅Is connected with a fully-controlled switch tube S₄Source and diode D₆Is connected to the anode of diode D₅And diode D₆The connection point of the cathode is connected with the midpoint of the series capacitor.

The invention discloses a single-phase three-level pseudo totem-pole power factor correction circuit, which has the following beneficial effects:

1) the power factor correction circuit topology avoids a structure that two switching tubes on the same bridge arm are connected in series and then are connected in parallel to a direct current bus, the hidden danger of bridge arm direct connection is avoided, and the reliability is high;

2) in the invention, four full-control switching tubes are adopted, and each switching tube is only turned on once in one period, thereby reducing the switching loss;

3) according to the invention, two same inductors are connected in parallel in the circuit for boosting, so that the nominal values and the volumes of the boosting inductor and the output capacitor are reduced;

4) the invention adopts a pair of fully-controlled switch tubes and a pair of diodes to form a group of bidirectional switch tubes, realizes bidirectional circulation of current, combines a three-level technology and a pseudo totem-pole circuit, solves the defect of large stress on a pseudo totem-pole circuit switch device, and is suitable for high-voltage output occasions.

Drawings

FIG. 1 is a diagram of the main topology of the PFC circuit of the present invention.

FIG. 2 is a diagram of a power factor correction circuit according to the present invention.

FIG. 3 is a diagram of a power factor correction circuit according to a second embodiment of the present invention.

FIG. 4 is a diagram of a power factor correction circuit according to the present invention.

FIG. 5 is a diagram of a power factor correction circuit according to the present invention.

Fig. 6 is a schematic diagram of a power factor correction circuit according to the present invention.

Fig. 7 is a diagram illustrating a power factor correction circuit mode six according to the present invention.

FIG. 8 shows a switch tube S of the power factor correction circuit of the present invention₁～S₄Six working mode diagrams.

FIG. 9 shows a switch tube S of the power factor correction circuit of the present invention₁～S₄Corresponding pulse distribution diagram.

FIG. 10 is a waveform diagram of the input side voltage and current in the steady state of the PFC circuit according to the present invention.

FIG. 11 shows the inductance L of the power factor correction circuit in a steady state₁Current waveform diagram of (2).

FIG. 12 shows the inductance L in the steady state of the PFC circuit of the present invention₂Current waveform diagram of (2).

FIG. 13 shows the voltage u of the power factor correction circuit in a steady state_B1OAnd (4) waveform diagrams.

FIG. 14 shows the voltage u of the power factor correction circuit in a steady state_B2OAnd (4) waveform diagrams.

FIG. 15 shows the DC output voltage u of the power factor correction circuit in a steady state_dcAnd (4) waveform diagrams.

Detailed Description

A single-phase three-level pseudo-totem-pole power factor correction circuit comprises:

the single-phase pseudo totem pole structure, the filter, the single-phase rectifier bridge with two-way switching tube;

the single-phase pseudo-totem-pole structure comprises 2 full-control power switch tubes: s₁、S ₂2 common diodes: d₁、 D₂The bridge comprises 2 rectifier bridge arms consisting of switching devices and diodes, wherein each bridge arm comprises 1 power switching device and 1 clamping diode. S₁Drain and inductor L₁And a diode D₁Anode is connected to S₂Source and inductor L₂And a diode D₂The cathodes are connected.

The filter is composed of a filter inductor L₁、L₂The two inductors are completely identical and connected with one end of an alternating current power supply and are respectively connected with a full-control switch tube S₁Drain electrode of (1), S₂Are connected.

The single-phase rectifier bridge with the bidirectional switching tube consists of 4 diodes D₃And D₄A group of bidirectional switch tubes and 2 capacitors C₁、C₂And a load R_LAnd (4) forming. Wherein, the diode D₃Anode connected diode D₄Cathode, diode D₃、D₄The connecting point is connected with the other end of the alternating current power supply and one end of the bidirectional switch tube; the bidirectional switch tube is composed of two diodes D₅And D₆And two full-controlled switch tubes S₃、S₄Component, full-control type switch tube S₃Source electrode and full-control type switch tube S₄Is connected with the connection point of the diode bridge arm, and a fully-controlled switch tube S₃Drain electrode of and diode D₅Is connected with the cathode of the switching tube S₄Source and diode D₆Is connected to the anode of a diode D₅And diode D₆Is connected with the series capacitor C₁、C₂Are connected with each other; capacitor C₁Negative electrode of (2) and capacitor C₂Is connected with the positive electrode of the capacitor C₁Positive electrode and capacitor C₂Are connected to the load respectively.

The specific parameters of the circuit are as follows: the input side of the single-phase three-level pseudo-totem-pole power factor correction circuit has a 220V effective value of the voltage of the power grid, a 50Hz frequency and a direct currentThe output voltage at the current side is 400V, the switching frequency is 20kHz, and the filter inductance L₁＝L₂3mH, load R_LHas a resistance value of

Output capacitor C₁＝C₂＝4700μF。

A single-phase three-level pseudo-totem-pole power factor correction circuit has 6 working modes in total when the circuit works normally:

(1) three operating modes in the positive half cycle:

as shown in fig. 2, mode one: full-control type switch tube S₁、S₂、S₃And S₄Turn-off, diode D₁And a fully-controlled switch tube S₂The body diode on is forward biased to conduct, and the capacitor C₁、C₂Charging, inductance L₁And L₂Are all subjected to voltage u_s-u_dcInductance L₁、L₂Share the current i_sHas a 1_s＝i_L1+i_L2＝2i_L. Since the frequency of the input voltage is much smaller than the switching frequency, the input voltage can be considered to be constant within one switching frequency, so the inductor L₁、L₂The current at B decreases linearly₁Points and B₂Potential of the point being equal to u_dc。

As shown in fig. 3, modality two: full-control type switch tube S₁、S₂And S₄Turn-off, full-control type switch tube S₃On, diode D₂And a fully-controlled switch tube S₂The upper body diode is forward biased to conduct, and S in the bidirectional switch tube₃On, diode D₅Positive bias conducting, capacitor C₁Charging, capacitance C₂Discharging in the load loop, the inductor bearing a voltage u_s-U_dc/2, inductance L₁、L₂Share the current i_sAlso, the input voltage is considered to be constant within one switching cycle. When the power voltage is less than U_dcAt/2, the inductive current decreases linearly; when the power supply voltage is greater than U_dcAt/2, the inductor current rises linearly, at which time B₁Points and B₂Is equal to U_dc/2。

As shown in fig. 4, modality three: full-control type switch tube S₁Opening, full-control type switch tube S₂、S₃And S₄Turn-off, switch tube S₁Diode D₄Inductor L₁And a power supply forming a loop, a capacitor C₁、C₂To a load R_LSupply of power, L₁Withstand the voltage u of the network_sThe input voltage is considered constant in one cycle, the inductance L₁The current rises linearly, at this time, B₁The potential of the dots being equal to 0, B₂Potential of the point being equal to u_s。

(2) Three working modes of the negative half period:

as shown in fig. 5, modality four: full-control type switch tube S₂Opening, full-control type switch tube S₁、S₃And S₄Turn-off, switch tube S₂Diode D₃Inductor L₂And a power supply forming a loop, a capacitor C₁、C₂To a load R_LPower supply, inductance L₂Withstand the voltage u of the network_sThe input voltage is considered constant in one cycle, the inductance L₂The current rises linearly, at this time, B₂The potential of the dots being equal to 0, B₁Potential of the point being equal to u_s。

As shown in fig. 6, modality five: full-control switch S₄Turn on, turn off the rest switches, diode D₂And a fully-controlled switch tube S₁The upper body diode is forward biased to conduct, and S in the bidirectional switch tube₄On, diode D₆Positive bias conducting, capacitor C₁Charging, capacitance C₂Discharging in the load loop, the inductor bearing a voltage u_s-U_dc/2, inductance L₁、L₂Share the current i_sAlso, the input voltage is considered to be constant within one switching cycle. When the absolute value of the power supply voltage is less than U_dcWhen the current is/2, the inductive current rises linearly; when the absolute value of the power supply voltage is greater than U_dcAt/2, the inductor current decreases linearly, at which time B₁Points and B₂Is equal to-U_dc/2。

As shown in the figure7, mode six: all-control type switch tube is turned off, and inductor L₁Current of via diode D₃And a switching tube S₁Freewheeling of the body diode; inductor L₂Current of via diode D₃And D₂And then follow current. Capacitor C₁、C₂Uniformly charged, inductance L₁Withstand voltage u_s+U_dcIn the current mode, the inductor current rises, B₁、B₂Point voltage is-U_dc。

In the six operating modes shown in fig. 2 to 7, the network side inputs the current i_sTwo return paths are arranged under the modes I, II, V and VI, namely, in a power frequency period, only the inductor L is arranged in the mode III₁With current, only inductance L in mode four₂Besides the current, in other modes, the current flows through the two inductors.

FIG. 8 shows a switching tube S in accordance with the present invention₁～S₄Six working mode diagrams, as shown in fig. 8, in a cycle, the circuit has six working modes in total, when u_s>At 0, there are 0, + u_dc/2、+u_dcThree states; when u is_s<At 0, there are 0, -u_dc/2、 -u_dcIn the three states, under different working modes, each parameter of the system also changes, wherein 1 represents the conduction of the switch tube, and 0 represents the disconnection of the switch tube. FIG. 9 shows a switch tube S in the circuit of the present invention₁～S₃And a pulse distribution diagram in one cycle, wherein the gate drive voltage is unitized, the gate voltage is applied to the switching tube by 1, and the gate voltage is not applied to the switching tube by 0.

FIG. 10, FIG. 11, FIG. 12, FIG. 13, FIG. 14 and FIG. 15 show the input voltage u at the AC side under the steady state condition of the circuit of the present invention_sAnd current i_sWaveform diagram of (1), inductance L₁And L₂Current waveform diagram, voltage u_B1O、u_B2OWaveform diagram and DC output voltage u_dcAnd (4) waveform diagrams. As shown in FIG. 10, the AC input voltage is in phase with the input current by multiplying the AC voltage by a gain of 0.1 times and comparing the AC voltage with the inductive current with an oscilloscope, thereby realizing high power factor(ii) a FIG. 11 shows the current flowing through the inductor L₁Current of, by letter i_L1It is shown that FIG. 12 shows the flow inductance L₂Current of, by letter i_L2The representation proves that except the zero mode, the two inductors pass through the current in other states; FIG. 13 shows the voltage u_B1OWaveform diagram, FIG. 14 is a voltage u_B2OWave form diagram, voltage u_B1OGenerating a good three-level voltage, voltage u, in the positive half-cycle_B2OA good three-level voltage is generated in the negative half period; fig. 15 shows that the rectifier achieves dc output voltage stabilization.

Claims (3)

1. A single-phase three-level pseudo-totem-pole power factor correction circuit is characterized by comprising:

the single-phase pseudo totem pole structure, the filter, the single-phase rectifier bridge with two-way switching tube;

the single-phase pseudo-totem-pole structure comprises a switching tube: s₁、S₂And the diode: d₁、D₂；

The filter comprises an inductor L₁、L₂；

The single-phase rectifier bridge with the bidirectional switching tube comprises a diode D₃、D₄A set of bidirectional switch tubes and a capacitor C₁、C₂Load R_L；

The connection relationship is as follows:

switch tube S₁The drain electrodes are respectively connected with a diode D₁Anode, inductor L₁One end;

diode D₂The cathodes are respectively connected with an inductor L₂One end, switch tube S₂A source electrode;

diode D₁The cathodes are respectively connected with a switch tube S₂Drain electrode, diode D₃Cathode and capacitor C₁One end;

diode D₂The anodes are respectively connected with a switch tube S₁Source, diode D₄Anode and capacitor C₂The other end;

inductor L₁Another terminal, an inductance L₂The other ends of the two-way switch are connected with one end of an alternating current power supply;

the other end of the alternating current power supply is respectively connected with a diode D₃Anode, diode D₄Cathode and switch tube S₃Source electrode, switch tube S₄A drain electrode;

capacitor C₁The other ends are respectively connected with a diode D₅Anode, diode D₆A cathode;

switch tube S₃Drain connected diode D₅A cathode; switch tube S₄Source connected diode D₆And an anode.

2. The single-phase three-level pseudo-totem-pole power factor correction circuit of claim 1, characterized in that: the switch tube S₁～S₄Both MOSFETs with body diodes or IGBTs.

3. A single-phase three-level pseudo-totem-pole power factor correction circuit according to claim 1 or 2, characterized in that:

when the circuit normally works, 6 working modes are provided:

(1) three operating modes in the positive half cycle:

the first mode is as follows: full-control type switch tube S₁、S₂、S₃And S₄Turn-off, diode D₁And a fully-controlled switch tube S₂The body diode on is forward biased to conduct, and the capacitor C₁、C₂Charging, inductance L₁And L₂Are all subjected to voltage u_s-u_dcInductance L₁、L₂Share the current i_sHas a 1_s＝i_L1+i_L2＝2i_L(ii) a Since the frequency of the input voltage is much smaller than the switching frequency, the input voltage can be considered to be constant within one switching frequency, so the inductor L₁、L₂The current at B decreases linearly₁Points and B₂Potential of the point being equal to u_dc；

Mode two: full-control type switch tube S₁、S₂And S₄Turn-off, full-control type switch tube S₃On, diode D₂And a fully-controlled switch tube S₂The upper body diode is forward biased to conduct, and S in the bidirectional switch tube₃On, diode D₅Positive bias conducting, capacitor C₁Charging, capacitance C₂Discharging in the load loop, the inductor bearing a voltage u_s-U_dc/2, inductance L₁、L₂Share the current i_sSimilarly, the input voltage is considered to be constant within one switching cycle; when the power voltage is less than U_dcAt/2, the inductive current decreases linearly; when the power supply voltage is greater than U_dcAt/2, the inductor current rises linearly, at which time B₁Points and B₂Is equal to U_dc/2；

Mode three: full-control type switch tube S₁Opening, full-control type switch tube S₂、S₃And S₄Turn-off, switch tube S₁Diode D₄Inductor L₁And a power supply forming a loop, a capacitor C₁、C₂To a load R_LSupply of power, L₁Withstand the voltage u of the network_sThe input voltage is considered constant in one cycle, the inductance L₁The current rises linearly, at this time, B₁The potential of the dots being equal to 0, B₂Potential of the point being equal to u_s；

(2) Three working modes of the negative half period:

and a fourth mode: full-control type switch tube S₂Opening, full-control type switch tube S₁、S₃And S₄Turn-off, switch tube S₂Diode D₃Inductor L₂And a power supply forming a loop, a capacitor C₁、C₂To a load R_LPower supply, inductance L₂Withstand the voltage u of the network_sThe input voltage is considered constant in one cycle, the inductance L₂The current rises linearly, at this time, B₂The potential of the dots being equal to 0, B₁Potential of the point being equal to u_s；

A fifth mode: full-control switch S₄Turn on, turn off the rest switches, diode D₂And a fully-controlled switch tube S₁The upper body diode is forward biased to conduct, and S in the bidirectional switch tube₄On, diode D₆Positive bias conducting, capacitor C₁Charging, capacitance C₂Discharging in the load loop, the inductor bearing a voltage u_s-U_dc/2, inductance L₁、L₂Share the current i_sSimilarly, the input voltage is considered to be constant within one switching cycle; when the absolute value of the power supply voltage is less than U_dcWhen the current is/2, the inductive current rises linearly; when the absolute value of the power supply voltage is greater than U_dcAt/2, the inductor current decreases linearly, at which time B₁Points and B₂Is equal to-U_dc/2；

A sixth mode: all-control type switch tube is turned off, and inductor L₁Current of via diode D₃And a switching tube S₁Freewheeling of the body diode; inductor L₂Current of via diode D₃And D₂Afterflow; capacitor C₁、C₂Uniformly charged, inductance L₁Withstand voltage u_s+U_dcIn the current mode, the inductor current rises, B₁、B₂Point voltage is-U_dc。

Images