CN106856378A - Intelligent half-bridge sine voltage change-over circuit based on PFC interleaving inverse excitations - Google Patents

Abstract

The invention discloses a kind of intelligent half-bridge sine voltage change-over circuit based on PFC interleaving inverse excitations, it is included：Input rectifying filter unit；PFC boost unit；Interleaving inverse excitation isolated variable unit, including first switch pipe, second switch pipe, the first transformer, the second transformer, the first diode, the second diode, the 3rd diode and the 4th diode；DC filter units, including the first electric capacity and the second electric capacity, by the first capacitance connection in rear end ground, the anode of the 4th diode passes through the second capacitance connection in rear end ground to the negative electrode of the 3rd diode；The negative pole of inversion reversed phase unit, including the 4th switching tube, the 5th switching tube, the 3rd electrochemical capacitor, the 4th electrochemical capacitor and filter inductance, the rear end of filter inductance and the 3rd electrochemical capacitor as inversion reversed phase unit output end.The present invention can filter high-frequency impulse using filter inductance, load is obtained the power frequency sinusoidal ac of high-quality, while reducing circuit cost.

Description

Intelligent half-bridge sine voltage change-over circuit based on PFC interleaving inverse excitations

Technical field

The present invention relates to voltage conversion circuit, more particularly to a kind of intelligent half-bridge sine wave based on PFC interleaving inverse excitations Voltage conversion circuit.

Background technology

In the prior art, the intelligent boost-buck conversion equipment for turning AC by AC is otherwise known as travelling insert row, in the device, voltage Change-over circuit is its Key Circuit, is a kind of circuit that can realize AC-AC conversion, can realize buck in AC-AC conversion And the function of burning voltage and frequency.But current AC-AC just most of meaningful formula equipment Market be non-isolation type topology electricity Road, and PF values are low, output voltage quality is low, security reliability is poor.Particularly during voltage conversion, more line can be produced Wave interference, and then influence quality of voltage.Additionally, existing sine voltage change-over circuit is present, circuit structure is complicated, and response is fast Spend the defect such as slow, relatively costly.In practical application, due to the high speed switching that there is switching tube during voltage conversion so that electricity Can there is certain high-frequency pulse signal in the outlet side on road, and then influence the quality of output voltage, thus be difficult to meet conversion will Ask.

The content of the invention

The technical problem to be solved in the present invention is, in view of the shortcomings of the prior art, there is provided a kind of to reduce circuit Ripple, circuit structure can be simplified, circuit cost is reduced, high-frequency crosstalk can be filtered, output voltage quality can be improved, and safely may be used The intelligent half-bridge sine voltage change-over circuit based on PFC interleaving inverse excitations for leaning on.

In order to solve the above technical problems, the present invention is adopted the following technical scheme that.

A kind of intelligent half-bridge sine voltage change-over circuit based on PFC interleaving inverse excitations, it is included for power network Voltage carry out rectification and filtering input rectifying filter unit, boosted for the output voltage to input rectifying filter unit The PFC boost unit of conversion, and：One interleaving inverse excitation isolated variable unit, includes first switch pipe, second switch pipe, One transformer, the second transformer, the first diode, the second diode, the 3rd diode and the 4th diode, first transformation The first end of device armature winding is connected to the output end of PFC boost unit, and the second end of the first primary winding connects The drain electrode of first switch pipe is connected to, the source electrode of the first switch pipe is connected to front end ground, and the drain electrode of the first switch pipe connects The anode of the first diode is connected to, the negative electrode of first diode is connected to the output of PFC boost unit by first resistor End, the first resistor is parallel with the 3rd electric capacity, and the first end of the second primary winding is connected to PFC boost unit Output end, the second end of the second primary winding is connected to the drain electrode of second switch pipe, the second switch pipe Source electrode be connected to front end ground, the drain electrode of the second switch pipe is connected to the anode of the second diode, second diode Negative electrode the output end of PFC boost unit is connected to by second resistance, the second resistance is parallel with the 4th electric capacity, described The grid of one switching tube and the grid of second switch pipe are respectively used to access the pwm pulse signal of two-way opposite in phase, described the The first end of one transformer secondary output winding is connected to the anode of the 3rd diode, the second end of the first transformer secondary output winding Be connected to rear end ground, the first end of the second transformer secondary output winding is connected to rear end ground, second transformer secondary output around Second end of group is connected to the negative electrode of the 4th diode, and the negative electrode of the 3rd diode and the anode of the 4th diode are used as friendship The output end of wrong flyback isolated variable unit；One DC filter units, include the first electric capacity and the second electric capacity, the three or two pole By the first capacitance connection in rear end ground, the anode of the 4th diode passes through the second capacitance connection in rear end to the negative electrode of pipe Ground；One inversion reversed phase unit, includes the 4th switching tube, the 5th switching tube, the 3rd electrochemical capacitor, the 4th electrochemical capacitor and filtering Inductance, the drain electrode of the 4th switching tube is connected to the output head anode of interleaving inverse excitation isolated variable unit, the 4th switch The source electrode of pipe is connected to the drain electrode of the 5th switching tube, and the source electrode of the 5th switching tube is connected to interleaving inverse excitation isolated variable unit Negative pole of output end, the grid of the 4th switching tube and the grid of the 5th switching tube are respectively used to access two-way opposite in phase Pwm pulse signal, the source electrode of the 4th switching tube is also attached to the front end of filter inductance, the positive pole of the 3rd electrochemical capacitor Be connected to the drain electrode of the 4th switching tube, the negative pole connection rear end ground of the 3rd electrochemical capacitor, the 3rd electrochemical capacitor it is negative Pole is also attached to the positive pole of the 4th electrochemical capacitor, and the negative pole of the 4th electrochemical capacitor is connected to the source electrode of the 5th switching tube, institute State the output end of the rear end of filter inductance and the negative pole of the 3rd electrochemical capacitor as inversion reversed phase unit.

Preferably, first resistor is connected between the grid and source electrode of the 4th switching tube, the 5th switching tube Second resistance is connected between grid and source electrode.

Preferably, the input rectifying filter unit includes socket, insurance, lightning protection resistance, common mode inhibition inductance, safety Electric capacity and rectifier bridge, the insurance are serially connected with the zero line of socket or live wire, and the front end of the common mode inhibition inductance is parallel to slotting Seat, the lightning protection resistance is parallel to the front end of common mode inhibition inductance, and the input of the safety electric capacity and rectifier bridge is parallel to The rear end of common mode inhibition inductance, the output end of the rectifier bridge is parallel with filter capacitor.

Preferably, the PFC boost unit includes boost inductance, the 3rd switching tube, the first commutation diode and second Electrochemical capacitor, the front end of the boost inductance is connected to the output end of input rectifying filter unit, the rear end of the boost inductance The drain electrode of the 3rd switching tube is connected to, the source electrode of the 3rd switching tube connects front end ground, and the grid of the 3rd switching tube is used for Access pwm control signal all the way, the anode of drain electrode first commutation diode of connection of the 3rd switching tube, first rectification The negative electrode of diode as PFC boost unit output end, and first commutation diode negative electrode connect the second electrochemical capacitor Positive pole, the negative pole of the second electrochemical capacitor connects front end ground.

Preferably, also include a MCU control unit, the grid of the first switch pipe, the grid of second switch pipe and The grid of the 3rd switching tube is connected to MCU control unit, and the MCU control unit is used to distinguishing output pwm signal to the One switching tube, second switch pipe and the 3rd switching tube, to control first switch pipe, second switch pipe and the 3rd switching tube break-make shape State.

Preferably, the MCU control unit includes single-chip microcomputer and its peripheral circuit.

Preferably, an AC sampling unit is also included, the AC sampling unit is connected to input rectifying filter unit Input and MCU control unit between, the AC sampling unit is used to gather the electricity of input rectifying filter unit AC Press and feed back to MCU control unit.

Preferably, the AC sampling unit includes amplifier, and two inputs of the amplifier are respectively by current limliting electricity Hinder and be connected to the input of input rectifying filter unit, the output end of the amplifier is connected to MCU control unit.

Preferably, the first sampling resistor is connected between the source electrode and front end ground of the 3rd switching tube, the described 3rd opens The source electrode for closing pipe is connected to MCU control unit, makes MCU control unit gather the 3rd switching tube by first sampling resistor The electric signal of source electrode.

Preferably, a D/C voltage sampling unit is also included, the D/C voltage sampling unit includes for being sequentially connected in series Two sampling resistors and the 3rd sampling resistor, the front end of second sampling resistor are connected to the defeated of interleaving inverse excitation isolated variable unit Go out end, the rear end of the 3rd sampling resistor is connected to MCU control unit, by second sampling resistor and the 3rd sampling electricity Hinder and make MCU control unit gather the electric signal of interleaving inverse excitation isolated variable unit output.

In intelligent half-bridge sine voltage change-over circuit based on PFC interleaving inverse excitations disclosed by the invention, using input Rectification filtering unit carries out output ripple DC voltage after rectification and filtering to line voltage, afterwards using PFC boost unit pair Pulsating dc voltage carries out boosting treatment, in interleaving inverse excitation isolated variable unit, wherein first switch pipe and second switch pipe Interaction conducting, the second switch pipe cut-off when first switch pipe is turned on, electric current is by the first primary winding, first switch pipe Loop is formed to front end, the first primary winding starts energy storage；When second switch pipe is turned on, first switch pipe cuts Only, electric current by the second primary winding, second switch pipe, constitute to front end loop, the second primary winding starts Energy storage, while the first primary winding is bonded to secondary windings by the first magnetic core of transformer lotus root, then through the 3rd diode to First electric capacity is charged, and forward voltage is formed on the first electric capacity；Then first switch pipe is turned on again, the cut-off of second switch pipe, First transformer energy storage, the second transformer secondary output winding is charged by the 4th diode to the second electric capacity, the shape on the second electric capacity Into negative voltage；Positive negative dc voltage is so formed on dc bus.The first diode, the two or two in foregoing circuit Pole pipe, first resistor, second resistance, the 3rd electric capacity, the 4th electric capacity are respectively the absorption electricity of first switch pipe and second switch pipe Road, for the peak voltage for absorbing the first transformer, the leakage inductance of the second transformer is produced, to subtract the voltage stress of switching tube.On State interleaving inverse excitation isolated location and achieve following beneficial effect：Turned on as a result of interaction so that the current ripples in circuit It is smaller, using relatively flexibly, while EMI, EMC in circuit disturb smaller, circuit work frequency higher, it is thus possible to improve work( Rate density, additionally, output voltage can be changed by the primary and secondary turn ratio of the first transformer of change, the second transformer, and then Realize boosting or be depressured.Based on These characteristics, the present invention achieve can reduce in circuit ripple, circuit structure, drop can be simplified Low circuit cost, output voltage quality can be improved, and the beneficial effect such as safe and reliable.On this basis, the present invention is in inversion The output end of reversed phase unit is provided with filter inductance, and the high-frequency impulse of the alternating current can be filtered using filter inductance so that negative Load is obtained in that the power frequency sinusoidal ac of high-quality, and then improves output voltage quality, to meet power demands.

Brief description of the drawings

Fig. 1 is the circuit theory diagrams of sine voltage change-over circuit.

Fig. 2 is the circuit theory diagrams of AC sampling unit in the preferred embodiment of the present invention.

Fig. 3 is the circuit theory diagrams of MCU control unit in the preferred embodiment of the present invention.

Specific embodiment

The present invention is described in more detail with reference to the accompanying drawings and examples.

The invention discloses a kind of intelligent half-bridge sine voltage change-over circuit based on PFC interleaving inverse excitations, with reference to Fig. 1 Shown in Fig. 3, its include for line voltage is carried out rectification and filtering input rectifying filter unit 10, for input The output voltage of rectification filtering unit 10 carries out the PFC boost unit 20 of boost conversion, and：

One interleaving inverse excitation isolated variable unit 30, includes first switch pipe Q6, second switch pipe Q7, the first transformer T1, the second transformer T2, the first diode D6, the second diode D5, the 3rd diode D7 and the 4th diode D8, described first The first end of transformer T1 armature windings is connected to the output end of PFC boost unit 20, the first transformer T1 armature windings The second end be connected to the drain electrode of first switch pipe Q6, the source electrode of the first switch pipe Q6 is connected to front end ground, described first The drain electrode of switching tube Q6 is connected to the anode of the first diode D6, and the negative electrode of the first diode D6 passes through first resistor R26 The output end of PFC boost unit 20 is connected to, the first resistor R26 is parallel with the 3rd electric capacity C5, the second transformer T2 The first end of armature winding is connected to the output end of PFC boost unit 20, the second end of the second transformer T2 armature windings The drain electrode of second switch pipe Q7 is connected to, the source electrode of the second switch pipe Q7 is connected to front end ground, the second switch pipe Q7 Drain electrode be connected to the anode of the second diode D5, the negative electrode of the second diode D5 is connected to PFC by second resistance R27 The output end of boosting unit 20, the second resistance R27 is parallel with the 4th electric capacity C6, the grid of the first switch pipe Q6 and The grid of two switching tube Q7 be respectively used to access two-way opposite in phase pwm pulse signal, described T1 level of first transformer around The first end of group is connected to the anode of the 3rd diode D7, and the second end of the first transformer T1 secondary windings is connected to rear end Ground, the first end of the second transformer T2 secondary windings is connected to rear end ground, and the of the second transformer T2 secondary windings Two ends are connected to the negative electrode of the 4th diode D8, and the negative electrode of the 3rd diode D7 and the anode of the 4th diode D8 are used as friendship The output end of wrong flyback isolated variable unit 30；

One DC filter units 40, the negative electrode for including the first electric capacity C7 and the second electric capacity C8, the 3rd diode D7 leads to Cross the first electric capacity C7 and be connected to rear end ground, the anode of the 4th diode D8 is connected to rear end ground by the second electric capacity C8；

One inversion reversed phase unit 60, includes the 4th switching tube Q2, the 5th switching tube Q4, the 3rd electrochemical capacitor C3, the 4th Electrochemical capacitor C4 and filter inductance L3, the drain electrode of the 4th switching tube Q2 is connected to the defeated of interleaving inverse excitation isolated variable unit 30 Go out proper pole, the source electrode of the 4th switching tube Q2 is connected to the drain electrode of the 5th switching tube Q4, the source of the 5th switching tube Q4 Pole is connected to the negative pole of output end of interleaving inverse excitation isolated variable unit 30, the grid and the 5th switching tube of the 4th switching tube Q2 The grid of Q4 is respectively used to access the pwm pulse signal of two-way opposite in phase, and the source electrode of the 4th switching tube Q2 is also attached to The front end of filter inductance L3, the positive pole of the 3rd electrochemical capacitor C3 is connected to the drain electrode of the 4th switching tube Q2, the 3rd electricity The negative pole connection rear end ground of solution electric capacity C3, the negative pole of the 3rd electrochemical capacitor C3 is being also attached to the 4th electrochemical capacitor C4 just Pole, the negative pole of the 4th electrochemical capacitor C4 is connected to the source electrode of the 5th switching tube Q4, the rear end of the filter inductance L3 and The negative pole of three electrochemical capacitor C3 as inversion reversed phase unit 60 output end.

In above-mentioned sine voltage change-over circuit, rectification and filter are carried out to line voltage using input rectifying filter unit 10 Output ripple DC voltage after ripple, carries out boosting treatment using PFC boost unit 20 to pulsating dc voltage afterwards, staggeredly anti- Swash in isolated variable unit 30, wherein first switch pipe Q6 interacts conducting with second switch pipe Q7, when first switch pipe Q6 conductings When second switch pipe Q7 cut-off, electric current by the first transformer T1 armature windings, form loop first switch pipe Q6 to front end, the One transformer T1 armature windings start energy storage；When second switch pipe Q7 is turned on, first switch pipe Q6 cut-offs, electric current is become by second Depressor T2 armature windings, second switch pipe Q7, front end ground constitute loop, and the second transformer T2 armature windings start energy storage, while First transformer T1 armature windings are bonded to secondary windings by the first transformer T1 magnetic core lotus roots, then through the 3rd diode D7 to first Electric capacity C7 is charged, and forward voltage is formed on the first electric capacity C7；Then first switch pipe Q6 is turned on again, and second switch pipe Q7 cuts Only, the first transformer T1 energy storage, the second transformer T2 secondary windings is charged by the 4th diode D8 to the second electric capacity C8, Negative voltage is formed on two electric capacity C8；Positive negative dc voltage is so formed on dc bus.In foregoing circuit first Diode D6, the second diode D5, first resistor R26, second resistance R27, the 3rd electric capacity C5, the 4th electric capacity C6 are respectively first The absorbing circuit of switching tube Q6 and second switch pipe Q7, for absorbing the leakage inductance generation of the first transformer T1, the second transformer T2 Peak voltage, to subtract the voltage stress of switching tube.Above-mentioned interleaving inverse excitation isolated location achieves following beneficial effect：Due to adopting With interactive conducting so that current ripples in circuit are smaller, using relatively flexibly, at the same EMI, EMC interference in circuit compared with Small, circuit work frequency is higher, it is thus possible to improve power density, additionally, by changing the first transformer T1, the second transformer The primary and secondary turn ratio of T2 can change output voltage, and then realize boosting or be depressured.Based on These characteristics, the present invention is achieved The ripple in circuit can be reduced, circuit structure can be simplified, circuit cost is reduced, output voltage quality can be improved, and safely may be used By etc. beneficial effect.On this basis, the present invention is provided with filter inductance L3 in the output end of inversion reversed phase unit 60, using filter Ripple inductance L3 can filter the high-frequency impulse in alternating current so that load is obtained in that the power frequency sinusoidal ac of high-quality, Jin Erti High output voltage quality, to meet power demands.

Further, first resistor R17 is connected between the grid and source electrode of the 4th switching tube Q2, the described 5th opens Second resistance R23 is connected between the grid and source electrode that close pipe Q4.

In above-mentioned inversion reversed phase unit 60, when the 4th switching tube Q2 is turned on, the 4th switching tube Q2, load, the 4th electrolysis Electric capacity C4 forms loop, produces first high-frequency impulse level to load, when the 4th switching tube Q2 is closed, by the 4th electrolysis Electric capacity C4, the body diode of the 5th switching tube Q4, filter inductance L3 form continuous current circuit；Pass through when the 5th switching tube Q4 is turned on 5th switching tube Q4, load, the 3rd electrochemical capacitor C3 form loop, and second high-frequency impulse level is formed in load, When the 5th switching tube Q4 is turned off, the body diode of the 4th switching tube Q2, the 3rd electrochemical capacitor C3, load, filter inductance L3 shapes Into continuous current circuit.4th switching tube Q2, the high-frequency drive pwm signal of the 5th switching tube Q4 are given again after power frequency modulation variation 4th switching tube Q2, the GATE poles of the 5th switching tube Q4.4th switching tube Q2, the 5th switching tube Q4 drive signals are adjusted through power frequency System, it is by sinusoidal variations to flow through the 4th switching tube Q2, the electric current of the 5th switching tube Q4.Because filter inductance L3 is to high frequency arteries and veins Punching does characteristic with high resistant, so high fdrequency component is filtered by filter inductance L3, power frequency sinusoidal ac is formed in load Pressure.The 3rd electrochemical capacitor C3, the 4th electrochemical capacitor C4 also have the effect of filtering simultaneously, can be filtered with filter inductance L3 composition direct currents Wave circuit.Inverter circuit control is simple, and circuit is with low cost only with two metal-oxide-semiconductors.

On importation, as shown in figure 1, the input rectifying filter unit 10 includes socket, insurance F2, thunder-lightning Resistance RV1, common mode inhibition inductance L1, safety electric capacity CX1 and rectifier bridge DB1, the insurance F2 are serially connected with the zero line or live wire of socket On, the front end of the common mode inhibition inductance L1 is parallel to socket, before the lightning protection resistance RV1 is parallel to common mode inhibition inductance L1 End, the input of the safety electric capacity CX1 and rectifier bridge DB1 is parallel to the rear end of common mode inhibition inductance L1, the rectifier bridge The output end of DB1 is parallel with filter capacitor C1.

On boosting part, the PFC boost unit 20 includes boost inductance L2, the 3rd switching tube Q5, the first rectification The front end of diode D1 and the second electrochemical capacitor C2, the boost inductance L2 is connected to the output of input rectifying filter unit 10 End, the rear end of the boost inductance L2 is connected to the drain electrode of the 3rd switching tube Q5, and the source electrode of the 3rd switching tube Q5 connects front end Ground, the grid of the 3rd switching tube Q5 is used to accessing pwm control signal all the way, the drain electrode connection of the 3rd switching tube Q5 the The anode of one commutation diode D1, the negative electrode of the first commutation diode D1 as PFC boost unit 20 output end, and should The negative electrode of the first commutation diode D1 connects the positive pole of the second electrochemical capacitor C2, and the negative pole of the second electrochemical capacitor C2 connects front end ground.

Above-mentioned PFC boost unit 20, when filter capacitor C1 output half-wave alternating voltages are sampled, PFC enters boost mode, Turn the PF values that AC is intelligently depressured conversion topologies circuit to improve AC, be by the second filtered voltages of electrochemical capacitor C2 after boosting 400V, specific boosting principle is as follows：When 3rd switching tube Q5 is turned on, the boosted inductance L2 of electric current on filter capacitor C1, the Three switching tube Q5 to GND form loop, boost inductance L2 storage energy；When the 3rd switching tube Q5 is turned off, meeting on boost inductance The induced electromotive force more much higher than input voltage is formed, induced electromotive force forms unidirectional pulse electricity after carrying out rectification through continued flow tube D1 Pressure is given the second electrochemical capacitor C2 electric capacity and enters filtering again, is filtered into the DC voltage of 400V.And the 3rd switching tube Q5 is basis The change of input AC amendment ripple that control chip is adopted increases or reduces the ON time of the 3rd switching tube Q5 so that electric current with Voltage-phase becomes unanimously to improve PF values.

As a kind of preferred embodiment, Fig. 3 is refer to, the present embodiment also includes a MCU control unit 80, and described first opens Grid, the grid of second switch pipe Q7 and the grid of the 3rd switching tube Q5 for closing pipe Q6 are connected to MCU control unit 80, institute MCU control unit 80 is stated for distinguishing output pwm signal to first switch pipe Q6, second switch pipe Q7 and the 3rd switching tube Q5, To control first switch pipe Q6, second switch pipe Q7 and the 3rd switching tube Q5 on off operating modes.Further, the MCU controls are single Unit 80 includes single-chip microcomputer U1 and its peripheral circuit.

For the ease of monitoring the electric signal of AC, Fig. 2 is refer to, the present embodiment also includes an AC sampling unit 70, the AC sampling unit 70 is connected between the input of input rectifying filter unit 10 and MCU control unit 80, described AC sampling unit 70 is used to gather the voltage of the AC of input rectifying filter unit 10 and feed back to MCU control unit 80.

Further, the AC sampling unit 70 includes two inputs difference of amplifier U9B, the amplifier U9B The input of input rectifying filter unit 10 is connected to by current-limiting resistance, the output end of the amplifier U9B is connected to MCU controls Unit processed 80.

For the ease of carrying out Real-time Collection to electric current, is connected between the source electrode and front end ground of the 3rd switching tube Q5 One sampling resistor R2A, the source electrode of the 3rd switching tube Q5 is connected to MCU control unit 80, by first sampling resistor R2A and make MCU control unit 80 gather the 3rd switching tube Q5 source electrodes electric signal.

Used as a kind of preferred embodiment, in order to be acquired to DC side electric signal, the present embodiment also includes a D/C voltage Sampling unit 50, the D/C voltage sampling unit 50 includes the second sampling resistor R13 and the 3rd sampling resistor being sequentially connected in series The front end of R15, the second sampling resistor R13 is connected to the output end of interleaving inverse excitation isolated variable unit 30, and the described 3rd adopts The rear end of sample resistance R15 is connected to MCU control unit 80, by the second sampling resistor R13 and the 3rd sampling resistor R15 MCU control unit 80 is made to gather the electric signal of the output of interleaving inverse excitation isolated variable unit 30.

Intelligent half-bridge sine voltage change-over circuit based on PFC interleaving inverse excitations disclosed by the invention, it has PF high Value, is capable of achieving power network and isolates with output end, and security is very high.Output can be automatically adjusted in input full voltage range Voltage, can fix output frequency, and output voltage is, with sinewave output, automatic shaping function to be pressed with to alternating current, additionally, Circuit of the present invention is simple, easy to control, and containing voltage and current sampling circuit, can anti-surge voltage and electric current.

The above is preferred embodiments of the present invention, is not intended to limit the invention, all in technology model of the invention Interior done modification, equivalent or improvement etc. are enclosed, be should be included in the range of of the invention protection.

Claims (10)

1. a kind of intelligent half-bridge sine voltage change-over circuit based on PFC interleaving inverse excitations, it is characterised in that include for Line voltage is carried out rectification and filtering input rectifying filter unit (10), for the defeated of input rectifying filter unit (10) Going out voltage carries out the PFC boost unit (20) of boost conversion, and：

One interleaving inverse excitation isolated variable unit (30), includes first switch pipe (Q6), second switch pipe (Q7), the first transformer (T1), the second transformer (T2), the first diode (D6), the second diode (D5), the 3rd diode (D7) and the 4th diode (D8), the first end of the first transformer (T1) armature winding is connected to the output end of PFC boost unit (20), described first Second end of transformer (T1) armature winding is connected to the drain electrode of first switch pipe (Q6), the source electrode of the first switch pipe (Q6) Front end ground is connected to, the drain electrode of the first switch pipe (Q6) is connected to the anode of the first diode (D6), the one or two pole The negative electrode for managing (D6) is connected to the output end of PFC boost unit (20), the first resistor (R26) by first resistor (R26) The 3rd electric capacity (C5) is parallel with, the first end of the second transformer (T2) armature winding is connected to PFC boost unit (20) Output end, the second end of the second transformer (T2) armature winding is connected to the drain electrode of second switch pipe (Q7), described second The source electrode of switching tube (Q7) is connected to front end ground, and the drain electrode of the second switch pipe (Q7) is connected to the sun of the second diode (D5) Pole, the negative electrode of second diode (D5) is connected to the output end of PFC boost unit (20), institute by second resistance (R27) State second resistance (R27) and be parallel with the 4th electric capacity (C6), the grid of the first switch pipe (Q6) and second switch pipe (Q7) Grid is respectively used to access the pwm pulse signal of two-way opposite in phase, the first end of the first transformer (T1) secondary windings The anode of the 3rd diode (D7) is connected to, the second end of the first transformer (T1) secondary windings is connected to rear end ground, institute The first end for stating the second transformer (T2) secondary windings is connected to rear end ground, the second of the second transformer (T2) secondary windings End is connected to the negative electrode of the 4th diode (D8), and the negative electrode of the 3rd diode (D7) and the anode of the 4th diode (D8) are made It is the output end of interleaving inverse excitation isolated variable unit (30)；

One DC filter units (40), include the first electric capacity (C7) and the second electric capacity (C8), the moon of the 3rd diode (D7) Pole is connected to rear end ground by the first electric capacity (C7), and the anode of the 4th diode (D8) is connected to by the second electric capacity (C8) Rear end ground；

One inversion reversed phase unit (60), include the 4th switching tube (Q2), the 5th switching tube (Q4), the 3rd electrochemical capacitor (C3), 4th electrochemical capacitor (C4) and filter inductance (L3), the drain electrode of the 4th switching tube (Q2) are connected to interleaving inverse excitation isolated variable The output head anode of unit (30), the source electrode of the 4th switching tube (Q2) is connected to the drain electrode of the 5th switching tube (Q4), described The source electrode of the 5th switching tube (Q4) is connected to the negative pole of output end of interleaving inverse excitation isolated variable unit (30), the 4th switching tube (Q2) grid and the grid of the 5th switching tube (Q4) is respectively used to access the pwm pulse signal of two-way opposite in phase, described the The source electrode of four switching tubes (Q2) is also attached to the front end of filter inductance (L3), and the positive pole of the 3rd electrochemical capacitor (C3) is connected to The drain electrode of the 4th switching tube (Q2), the negative pole connection rear end ground of the 3rd electrochemical capacitor (C3), the 3rd electrochemical capacitor (C3) negative pole is also attached to the positive pole of the 4th electrochemical capacitor (C4), and the negative pole of the 4th electrochemical capacitor (C4) is connected to the 5th The source electrode of switching tube (Q4), the rear end of the filter inductance (L3) and the negative pole of the 3rd electrochemical capacitor (C3) are used as inversion paraphase list The output end of first (60).

2. the intelligent half-bridge sine voltage change-over circuit of PFC interleaving inverse excitations is based on as claimed in claim 1, and its feature exists In, first resistor (R17) is connected between the grid and source electrode of the 4th switching tube (Q2), the 5th switching tube (Q4) Second resistance (R23) is connected between grid and source electrode.

3. the intelligent half-bridge sine voltage change-over circuit of PFC interleaving inverse excitations is based on as claimed in claim 1, and its feature exists In the input rectifying filter unit (10) includes socket, insurance (F2), lightning protection resistance (RV1), common mode inhibition inductance (L1), safety electric capacity (CX1) and rectifier bridge (DB1), the insurance (F2) are serially connected with the zero line of socket or live wire, the common mode The front end for suppressing inductance (L1) is parallel to socket, and the lightning protection resistance (RV1) is parallel to the front end of common mode inhibition inductance (L1), institute The input for stating safety electric capacity (CX1) and rectifier bridge (DB1) is parallel to the rear end of common mode inhibition inductance (L1), the rectifier bridge (DB1) output end is parallel with filter capacitor (C1).

4. the intelligent half-bridge sine voltage change-over circuit of PFC interleaving inverse excitations is based on as claimed in claim 1, and its feature exists In, the PFC boost unit (20) include boost inductance (L2), the 3rd switching tube (Q5), the first commutation diode (D1) and Second electrochemical capacitor (C2), the front end of the boost inductance (L2) is connected to the output end of input rectifying filter unit (10), institute The rear end for stating boost inductance (L2) is connected to the drain electrode of the 3rd switching tube (Q5), and the source electrode of the 3rd switching tube (Q5) connects front end Ground, the grid of the 3rd switching tube (Q5) is used to access pwm control signal all the way, and the drain electrode of the 3rd switching tube (Q5) connects The anode of the first commutation diode (D1) is connect, the negative electrode of first commutation diode (D1) is used as PFC boost unit (20) Output end, and first commutation diode (D1) negative electrode connect the second electrochemical capacitor (C2) positive pole, the second electrochemical capacitor (C2) negative pole connects front end ground.

5. the intelligent half-bridge sine voltage change-over circuit of PFC interleaving inverse excitations is based on as claimed in claim 4, and its feature exists In, also include a MCU control unit (80), the grid of the first switch pipe (Q6), the grid of second switch pipe (Q7) and The grid of the 3rd switching tube (Q5) is connected to MCU control unit (80), and the MCU control unit (80) for exporting respectively Pwm signal to first switch pipe (Q6), second switch pipe (Q7) and the 3rd switching tube (Q5), with control first switch pipe (Q6), Second switch pipe (Q7) and the 3rd switching tube (Q5) on off operating mode.

6. the intelligent half-bridge sine voltage change-over circuit of PFC interleaving inverse excitations is based on as claimed in claim 5, and its feature exists In the MCU control unit (80) includes single-chip microcomputer (U1) and its peripheral circuit.

7. the intelligent half-bridge sine voltage change-over circuit of PFC interleaving inverse excitations is based on as claimed in claim 5, and its feature exists In, an AC sampling unit (70) is also included, the AC sampling unit (70) is connected to input rectifying filter unit (10) Input and MCU control unit (80) between, the AC sampling unit (70) is for gathering input rectifying filter unit (10) voltage of AC and MCU control unit (80) is fed back to.

8. the intelligent half-bridge sine voltage change-over circuit of PFC interleaving inverse excitations is based on as claimed in claim 7, and its feature exists In the AC sampling unit (70) includes amplifier (U9B), and two inputs of the amplifier (U9B) pass through current limliting respectively Resistance and be connected to the input of input rectifying filter unit (10), it is single that the output end of the amplifier (U9B) is connected to MCU controls First (80).

9. the intelligent half-bridge sine voltage change-over circuit of PFC interleaving inverse excitations is based on as claimed in claim 5, and its feature exists In being connected with the first sampling resistor (R2A), the 3rd switching tube between the source electrode and front end ground of the 3rd switching tube (Q5) (Q5) source electrode is connected to MCU control unit (80), and MCU control unit (80) is made by first sampling resistor (R2A) Gather the electric signal of the 3rd switching tube (Q5) source electrode.

10. the intelligent half-bridge sine voltage change-over circuit of PFC interleaving inverse excitations, its feature are based on as claimed in claim 5 It is also to include a D/C voltage sampling unit (50), the D/C voltage sampling unit (50) includes second for being sequentially connected in series Sampling resistor (R13) and the 3rd sampling resistor (R15), the front end of second sampling resistor (R13) be connected to interleaving inverse excitation every From the output end of converter unit (30), the rear end of the 3rd sampling resistor (R15) is connected to MCU control unit (80), by Second sampling resistor (R13) and the 3rd sampling resistor (R15) and make MCU control unit (80) gather interleaving inverse excitation isolation and become Change the electric signal of unit (30) output.