CN204103793U - A kind of photovoltaic grid-connected inversion circuit and ON-OFF control circuit - Google Patents

Abstract

The utility model discloses a kind of photovoltaic grid-connected inversion circuit and ON-OFF control circuit, belong to technical field of photovoltaic power generation.In the utility model when photovoltaic cell group output voltage is larger than electrical network ac output voltage, chopping switching tube SWc not conducting, electric current is by bypass diode D _bflow to rear class full-bridge inverting unit, full-bridge inverting cell operation is at SPWM modulating mode; When photovoltaic cell group is less than or equal to electrical network ac output voltage, chopping switching tube SWc is operated in high-frequency PWM pattern, and full-bridge inverting unit power frequency works.Only there is one-stage transfor-mation device unit high-frequency work the utility model any time, is conducive to the raising of overall efficiency; Owing to not using Large Copacity electrolysis direct current Capacitor banks, little, the lightweight and solar photovoltaic generation system of low cost of size can be realized.

Description

A kind of photovoltaic grid-connected inversion circuit and ON-OFF control circuit

Technical field

The utility model relates to technical field of photovoltaic power generation, more particularly, relates to a kind of photovoltaic grid-connected inversion circuit and ON-OFF control circuit.

Background technology

From the viewpoint of environmental protection, the application of distributed solar energy photovoltaic generating system on residential electric power is more and more welcome on a small scale.For solar photovoltaic generation system, the single-phase sinewave inverter topological structure of non-isolated has advantage in cost, size and efficiency, and this makes non-isolated grid-connected structure have good development prospect.Non-isolated sinewave inverter main circuit mainly comprises two working portions: one is the boosting part for promoting from photovoltaic module array low-voltage; Two is for exchanging the Converting Unit being connected to electrical network or direct load-carrying high-frequency PWM modulation.

The prime of traditional two-stage type combining inverter generally adopts Boost boosting unit to promote input voltage, and rear class inverter is directly converted to alternating current.Prime boosting unit is in high-frequency PWM modulation condition always, later stage inversion unit is then with SPWM (sinusoidal pulse width modulation) mode high frequency modulated, so prime boosting part and rear class Converting Unit are operated in high frequency state simultaneously, the switching loss of switching tube is very large, is unfavorable for the raising of overall efficiency.In addition, in order to keep the voltage after boosting to be constant, the electrolytic capacitor group be connected in DC bus needs sufficiently high electric capacity.Therefore electrolytic capacitor packet size is large, and has the ripple current of higher frequency, due to the existence of equivalent series resistance, can cause power loss, and electrolysis direct current Capacitor banks is heavy, and high to temperature requirement, the life-span is short.

Through retrieval, Chinese Patent Application No. 201110353854.4, the applying date is on November 10th, 2011, invention and created name is: photovoltaic combining inverter inversion of direct current busbar voltage control method and control system, it is in parallel with Boost circuit that the photovoltaic DC-to-AC converter of this application case adds a bypass diode, and at a photovoltaic cell outlet side bulky capacitor in parallel.The voltage control method of this application case comprises the following steps: gather line voltage Vac and input direct voltage Vpv; Judge whether Vpv >=1.6Vac sets up; As being judged as YES, close Boost circuit; As being judged as NO, open Boost circuit; Inversion is carried out to input direct voltage Vpv.This application case, by adjusting busbar voltage in real time, to reduce the operating time of Boost circuit, reduces electromagnetic interference, improves system effectiveness to a certain extent.But the Boost circuit part of this application case photovoltaic DC-to-AC converter comprises two bulky capacitor, the photovoltaic DC-to-AC converter volume because of the introducing of use bulky capacitor analyzed above is large, heavy, not only easy generation high-frequency ripple current and power loss is large etc. that problem is not eased but more serious, photovoltaic DC-to-AC converter manufacturing cost is high and stability is bad; In addition, the Converting Unit of this application case is still operated in high frequency state always, and switching loss is large, and overall efficiency is low.

Utility model content

1. the utility model technical problem that will solve

The purpose of this utility model is what solution conventional photovoltaic inverter existed: 1) switching loss is large, overall efficiency is low; 2) owing to using big capacity electrolyte capacitor device group to cause the problems such as photovoltaic DC-to-AC converter volume is large, heavy, and power loss is large; Provide a kind of photovoltaic grid-connected inversion circuit and ON-OFF control circuit.The technical scheme that theres is provided of the utility model is provided, determines the mode of operation of 2 stage converter unit according to the magnitude relationship of input voltage and line voltage, any time can be made only to have one-stage transfor-mation device unit high-frequency work, be conducive to the raising of overall efficiency; In addition, owing to not using Large Copacity electrolysis direct current Capacitor banks, little, the lightweight and solar photovoltaic generation system of low cost of size can be realized.

2. technical scheme

For achieving the above object, the technical scheme that the utility model provides is:

A kind of photovoltaic grid-connected inversion circuit of the present utility model, comprises DC boosting unit, full-bridge inverting unit, filter unit, photovoltaic cell group and electrical network, wherein:

Described full-bridge inverting unit is connected with DC boosting unit, and this full-bridge inverting unit is by full-bridge inverting switching tube SW ₁, SW ₂, SW ₃, SW ₄the inverter bridge of composition;

Described filter unit comprises filter inductance L _fwith filter capacitor C _f, filter inductance L _ffirst end and described full-bridge inverting switching tube SW ₁, SW ₂the intermediate point of composition brachium pontis connects, this filter inductance L _fthe second end respectively with filter capacitor C _ffirst end, electrical network one end connect, the other end of electrical network and filter capacitor C _fsecond end connect; Filter capacitor C _fthe second end also with full-bridge inverting switching tube SW ₃, SW ₄the intermediate point of composition brachium pontis connects;

Described DC boosting unit comprises bypass diode D _b, boost inductance L _b, diode Dc, chopping switching tube SWc and intermediate capacitance Cc, the positive pole of photovoltaic cell group respectively with bypass diode D _bpositive pole, boost inductance L _bfirst end connect, bypass diode D _bnegative pole respectively with diode D _cnegative pole, intermediate capacitance Cc first end connect, boost inductance L _bthe second end be connected with the positive pole of diode Dc, the collector electrode of chopping switching tube SWc respectively; The negative pole of described photovoltaic cell group is connected with the emitter of chopping switching tube SWc, second end of intermediate capacitance Cc respectively.

Further, described intermediate capacitance Cc is low capacity thin-film capacitor.

The ON-OFF control circuit of a kind of photovoltaic grid-connected inversion circuit of the present utility model, comprises chopping switching tube SWc control circuit and full-bridge inverting switching tube SW ₁, SW ₂, SW ₃, SW ₄control circuit, wherein:

In described chopping switching tube SWc control circuit, the signal output part of sine-wave generator I is connected with the in-phase input end of comparator I, the input of DSP microprocessor respectively through full-wave rectifier I, the signal output part of signal picker is connected with the inverting input of comparator I, the input of DSP microprocessor respectively, the signal output part of comparator I, DSP microprocessor is connected with the input of multiplier I respectively, and the output signal of multiplier I is as the drive singal of SWc;

Described full-bridge inverting switching tube SW ₁, SW ₂, SW ₃, SW ₄in control circuit, the signal output part of sine-wave generator II is connected through the in-phase input end of full-wave rectifier II with comparator II, and the signal output part of triangular-wave generator is connected with the inverting input of comparator II; The signal output part of sine-wave generator III is connected with the in-phase input end of comparator III, and the inverting input of comparator III is connected with no-voltage; The signal output part of sine-wave generator IV is connected with the inverting input of comparator IV, and the in-phase input end of comparator IV is connected with no-voltage; The signal output part of comparator II, comparator III is connected with the input of multiplier II, and the output signal of multiplier II is as SW ₁drive singal, multiplier II connects the output signal of inverter I as SW ₂drive singal; The signal output part of comparator II, comparator IV is connected with the input of multiplier III, and the output signal of multiplier III is as SW ₃drive singal, multiplier III connects the output signal of inverter II as SW ₄drive singal.

The control method of a kind of photovoltaic grid-connected inversion circuit of the present utility model, the steps include:

Step one, judge photovoltaic cell group output voltage V _inwhether be greater than electrical network ac output voltage absolute value | V _out|;

Step 2, controlled the break-make of chopping switching tube SWc by the judged result of step one, if V _in> | V _out|, then control SWc turns off; If V _in≤ | V _out|, then control SWc is operated in high-frequency PWM state;

Step 3, control full-bridge inverting switching tube SW according to the break-make of SWc ₁, SW ₂, SW ₃, SW ₄break-make, if SW _cturn off, then control SW ₁, SW ₂, SW ₃, SW ₄be operated in SPWM modulating mode, if SW _cbe operated in high-frequency PWM state, then control SW ₁, SW ₂, SW ₃, SW ₄work with power frequency modulation system.

Further, the detailed process that step 2 controls chopping switching tube SWc break-make is: sine-wave generator I produces standard AC sine wave, the in-phase input end of input comparator I and the input of DSP microprocessor after full-wave rectifier I rectification, signal picker gathers the output voltage V of photovoltaic cell group _inthe inverting input of input comparator I and the input of DSP microprocessor, compared through comparator I pulse train that obtains and be multiplied by multiplier I through the signal of DSP microprocessor processes, the pulse train control SW that multiplier I exports _cbreak-make.

Further, step 3 controls full-bridge inverting switching tube SW ₁, SW ₂, SW ₃, SW ₄the detailed process of break-make is: sine-wave generator II produces standard AC sine wave, the in-phase input end of input comparator II after full-wave rectifier II rectification, and it is V that triangular-wave generator produces amplitude _inthe inverting input of triangular wave input comparator II; Sine-wave generator III produces the in-phase input end of the sinusoidal wave input comparator III of standard AC, compares through comparator III with no-voltage; Sine-wave generator IV also produces the inverting input of the sinusoidal wave input comparator IV of standard AC, compares through comparator IV with no-voltage; The output signal of comparator II, comparator III is multiplied by multiplier II, the output signal control SW of multiplier II ₁break-make, multiplier II meets the output signal control SW of inverter I ₂break-make; The output signal of comparator II, comparator IV is multiplied by multiplier III, the output signal control SW of multiplier III ₃break-make, multiplier III meets the output signal control SW of inverter II ₄break-make.

Further, the output signal of described DSP microprocessor is pulse regulation duty ratio

3. beneficial effect

The technical scheme adopting the utility model to provide, compared with existing known technology, has following remarkable result:

(1) a kind of photovoltaic grid-connected inversion circuit of the present utility model, boost inductance L in its DC boosting unit _ba bypass diode D is parallel with in the series arm of diode Dc _b, when photovoltaic cell group output voltage is higher than line voltage, chopping switching tube SWc not conducting, electric current is by bypass diode D _bflow to full-bridge inverting unit, full-bridge inverting unit High ireguency SPWM works; When photovoltaic cell group output voltage is lower than line voltage, chopping switching tube SWc high frequency modulated, full-bridge inverting unit power frequency works; The mode of operation of 2 stage converter unit is determined according to the magnitude relationship of input voltage and line voltage, can make boost chopper and full-bridge inverting under synchronization only has stage circuit to be operated in high frequency mode, reduce total on-off times, be conducive to the raising of overall efficiency;

(2) control method of a kind of photovoltaic grid-connected inversion circuit of the present utility model, it controls prime DC boosting cell operation when PWM mode, for rear class full-bridge inverting unit provides sinusoidal half-wave voltage, rear class full-bridge inverting unit only needs power frequency switch operating can complete sinusoidal current injection electrical network; When prime DC boosting unit leads directly to, rear class full-bridge inverting cell operation is in SPWM mode; This kind of mode of operation, constant voltage is kept without the need to intermediate DC link, the film capacitor of available low capacity, small size replaces jumbo electrolytic capacitor, and achieve miniaturization and the lightness of inverter system, the job stability of inverter have also been obtained raising; In addition, when full-bridge inverting cell S PWM mode works, input current is through bypass diode D _b, and do not flow through boost inductance L _bwith diode Dc, the conduction loss of booster circuit reduces greatly.

Accompanying drawing explanation

Fig. 1 is the structure chart of photovoltaic grid-connected inversion circuit of the present utility model;

(a) in Fig. 2 is the fundamental diagram of boost chopper part of the present utility model; (b) in Fig. 2 is the fundamental diagram of full-bridge inverting part of the present utility model;

Fig. 3 is switching pulse sequence chart of the present utility model

(a) in Fig. 4 is for driving the circuit structure diagram of chopping switching tube SWc in ON-OFF control circuit of the present utility model; (b) in Fig. 4 is for driving full-bridge inverting switching tube SW in ON-OFF control circuit of the present utility model ₁, SW ₂, SW ₃, SW ₄circuit structure diagram;

Fig. 5 is intermediate capacitance C in the utility model _cvoltage oscillogram;

Fig. 6 is filter unit input side voltage oscillogram in the utility model;

Fig. 7 is the control flow block diagram of photovoltaic grid-connected inversion circuit of the present utility model.

Label declaration in schematic diagram:

1-DC boosting unit; 2-full-bridge inverting unit; 3-filter unit; 4-photovoltaic cell group; 5-electrical network; D _b-bypass diode; L _b-boost inductance; Dc-diode; SWc-chopping switching tube; Cc-intermediate capacitance; SW ₁, SW ₂, SW ₃, SW ₄-full-bridge inverting switching tube; L _f-filter inductance; C _f-filter capacitor.

Embodiment

For understanding content of the present utility model further, in conjunction with the accompanying drawings and embodiments the utility model is described in detail.

Embodiment 1

Composition graphs 1, a kind of photovoltaic grid-connected inversion circuit of the present embodiment, comprises DC boosting unit 1, full-bridge inverting unit 2, filter unit 3, photovoltaic cell group 4 and electrical network 5, wherein:

Described DC boosting unit 1 comprises bypass diode D _b, boost inductance L _b, diode Dc, chopping switching tube SWc and intermediate capacitance Cc, the positive pole of photovoltaic cell group 4 respectively with bypass diode D _bpositive pole, boost inductance L _bfirst end connect, bypass diode D _bnegative pole respectively with diode D _cnegative pole, intermediate capacitance Cc first end connect, boost inductance L _bthe second end be connected with the positive pole of diode Dc, the collector electrode of chopping switching tube SWc respectively; The negative pole of described photovoltaic cell group 4 is connected with the emitter of chopping switching tube SWc, second end of intermediate capacitance Cc respectively.

Described full-bridge inverting unit 2 is by full-bridge inverting switching tube SW ₁, SW ₂, SW ₃, SW ₄the inverter bridge of composition, the first end of inverter bridge and intermediate capacitance C _csecond end connect, inverter bridge the second end be connected with the negative pole of photovoltaic cell group 4.

Described filter unit 3 comprises filter inductance L _fwith filter capacitor C _f, filter inductance L _ffirst end and described full-bridge inverting switching tube SW ₁, SW ₂the intermediate point of composition brachium pontis connects, this filter inductance L _fthe second end respectively with filter capacitor C _ffirst end, electrical network 5 one end connect, the other end of electrical network 5 and filter capacitor C _fsecond end connect; Filter capacitor C _fthe second end also with full-bridge inverting switching tube SW ₃, SW ₄the intermediate point of composition brachium pontis connects.

Photovoltaic cell group 4 exports the direct current input side that direct current first accesses DC boosting unit 1, DC boosting unit 1 carries out boosting inverter, direct current after boosting accesses the direct current input side of full-bridge inverting unit 2 again, full-bridge inverting unit 2 changes direct current into alternating current, by access electrical network 5 or load after filter unit 3.

Referring to (a) and (b) in Fig. 4, the ON-OFF control circuit of a kind of photovoltaic grid-connected inversion circuit of the present embodiment, comprises chopping switching tube SWc control circuit and full-bridge inverting switching tube SW ₁, SW ₂, SW ₃, SW ₄control circuit, wherein:

In described chopping switching tube SWc control circuit, the signal output part of sine-wave generator I is connected with the in-phase input end of comparator I, the input of DSP microprocessor respectively through full-wave rectifier I, the signal output part of signal picker is connected with the inverting input of comparator I, the input of DSP microprocessor respectively, the signal output part of comparator I, DSP microprocessor is connected with the input of multiplier I respectively, and the output signal of multiplier I is as the drive singal of SWc.

Described full-bridge inverting switching tube SW ₁, SW ₂, SW ₃, SW ₄in control circuit, the signal output part of sine-wave generator II is connected through the in-phase input end of full-wave rectifier II with comparator II, and the signal output part of triangular-wave generator is connected with the inverting input of comparator II; The signal output part of sine-wave generator III is connected with the in-phase input end of comparator III, and the inverting input of comparator III is connected with no-voltage; The signal output part of sine-wave generator IV is connected with the inverting input of comparator IV, and the in-phase input end of comparator IV is connected with no-voltage; The signal output part of comparator II, comparator III is connected with the input of multiplier II, and the output signal of multiplier II is as SW ₁drive singal, multiplier II connects the output signal of inverter I as SW ₂drive singal; The signal output part of comparator II, comparator IV is connected with the input of multiplier III, and the output signal of multiplier III is as SW ₃drive singal, multiplier III connects the output signal of inverter II as SW ₄drive singal.

Fig. 2 describes the present embodiment and utilizes described ON-OFF control circuit to control the operation principle of photovoltaic grid-connected inversion circuit, and (a) in Fig. 2 is the operation principle of boost chopper part; (b) in Fig. 2 is the operation principle of full-bridge inverting part; As photovoltaic cell group 4 output voltage V _inthan electrical network 5 ac output voltage absolute value | V _out| time large, chopping switching tube SWc is in off state, and input current flows through bypass diode D _b, and do not flow through boost inductance L _bwith diode D _c, the output voltage of DC boosting unit 1 equals input direct voltage V _in, in such cases, full-bridge inverting switching tube SW ₁, SW ₂, SW ₃, SW ₄be operated in SPWM modulating mode; As photovoltaic cell group 4 output voltage V _inbe less than or equal to electrical network 5 ac output voltage absolute value | V _out| time, chopping switching tube SWc is operated in high-frequency PWM pattern, intermediate capacitance C _cuse low capacity thin-film capacitor, make the output voltage of DC boosting unit 1 produce quasi sine which amplitude modulation waveform.Now, full-bridge inverting switching tube (SW ₁~ SW ₄) with the work of power frequency modulation system, make output voltage synchronous with electrical network 5 polarity.Due under this kind of mode of operation, constant voltage is kept without the need to intermediate DC link, jumbo electrolytic capacitor is replaced with the film capacitor of low capacity, small size, the film capacitor that the present embodiment adopts is metallized polyimide second membrane of lipoprotein capacitor MEF (CL21), achieve miniaturization and the lightness of inverter system, the job stability of inverter have also been obtained raising.The present embodiment determines the mode of operation of 2 stage converter unit according to the magnitude relationship of input voltage and line voltage, can make boost chopper and full-bridge inverting under synchronization only has stage circuit to be operated in high frequency mode, reduce total on-off times, be conducive to the raising of overall efficiency.

Referring to Fig. 7, the concrete control procedure of the present embodiment is:

Step one, judge photovoltaic cell group 4 output voltage V _inwhether be greater than electrical network 5 ac output voltage absolute value | V _out|.

Step 2, controlled the break-make of chopping switching tube SWc by the judged result of step one, if V _in> | V _out|, then control SWc turns off; If V _in≤ | V _out|, then control SWc is operated in high-frequency PWM state; The detailed process controlling chopping switching tube SWc break-make is: sine-wave generator I produces standard AC sine wave, the in-phase input end of input comparator I and the input of DSP F2812 microprocessor after full-wave rectifier I rectification, signal picker gathers the output voltage V of photovoltaic cell group 4 _inthe inverting input of input comparator I and the input of DSP F2812 microprocessor, compare the pulse train obtained and the pulse regulation duty ratio exported after DSP microprocessor processes through comparator I signal is multiplied by multiplier I, the pulse train control SW that multiplier I exports _cbreak-make.

Step 3, control full-bridge inverting switching tube SW according to the break-make of SWc ₁, SW ₂, SW ₃, SW ₄break-make, if SW _cturn off, then control SW ₁, SW ₂, SW ₃, SW ₄be operated in SPWM modulating mode, if SW _cbe operated in high-frequency PWM state, then control SW ₁, SW ₂, SW ₃, SW ₄work with power frequency modulation system.Control full-bridge inverting switching tube SW ₁, SW ₂, SW ₃, SW ₄the detailed process of break-make is: sine-wave generator II produces standard AC sine wave, the in-phase input end of input comparator II after full-wave rectifier II rectification, and it is V that triangular-wave generator produces amplitude _inthe inverting input of triangular wave input comparator II; Sine-wave generator III produces the in-phase input end of the sinusoidal wave input comparator III of standard AC, compares through comparator III with no-voltage; Sine-wave generator IV also produces the inverting input of the sinusoidal wave input comparator IV of standard AC, compares through comparator IV with no-voltage; The output signal of comparator II, comparator III is multiplied by multiplier II, the output signal control SW of multiplier II ₁break-make, multiplier II meets the output signal control SW of inverter I ₂break-make; The output signal of comparator II, comparator IV is multiplied by multiplier III, the output signal control SW of multiplier III ₃break-make, multiplier III meets the output signal control SW of inverter II ₄break-make.

Fig. 3 describes the pulse train of each switching tube of the present embodiment, at the positive half period of AC sine output voltage, and SW ₃not conducting, SW ₄straight-through, when photovoltaic cell group 4 output voltage is greater than AC sine output voltage, chopping switching tube SWc not conducting, full-bridge inverting switching tube SW ₁, SW ₂conducting is modulated through SPWM; When photovoltaic cell group 4 output voltage is less than or equal to AC sine output voltage, chopping switching tube SW _caccording to duty ratio high frequency modulated, SW ₁straight-through, SW ₂not conducting.At the negative half-cycle of AC sine output voltage, SW ₁not conducting, SW ₂straight-through, when the negative value of photovoltaic cell group 4 output voltage is less than AC sine output voltage, chopping switching tube SW _cnot conducting, full-bridge inverting switching tube SW ₃, SW ₄conducting is modulated through SPWM; When the negative value of photovoltaic cell group 4 output voltage is greater than AC sine output voltage, chopping switching tube SW _caccording to duty ratio high frequency modulated, full-bridge inverting switching tube SW ₃straight-through, SW ₄not conducting.

Fig. 5 and 6 is the concrete simulation waveform figure of the present embodiment, and wherein, Fig. 5 is intermediate capacitance C _cvoltage oscillogram, Fig. 6 is filter unit 3 input side voltage oscillogram.Photovoltaic cell group 4 voltage 160V in the present embodiment, electrical network 5 voltage 220Vrms, electrical network 5 frequency f _grid=50Hz, boost inductance L _b=0.9mH, intermediate capacitance C _c=2.2uF, filter inductance L _f=1mH, filter capacitor C _f=10uF, switching frequency f=50kHz.

A kind of photovoltaic grid-connected inversion circuit described in embodiment 1 and ON-OFF control circuit, when control prime DC boosting unit 1 is operated in PWM mode, for rear class full-bridge inverting unit provides sinusoidal half-wave voltage, rear class full-bridge inverting unit 2 only needs power frequency switch operating can complete sinusoidal current injection electrical network; When prime DC boosting unit 1 leads directly to, rear class full-bridge inverting unit 2 works in SPWM mode, and only there is one-stage transfor-mation device unit high-frequency work any time; This kind of mode of operation, constant voltage is kept without the need to intermediate DC link, the film capacitor of available low capacity, small size replaces jumbo electrolytic capacitor, and achieve miniaturization and the lightness of inverter system, the job stability of inverter have also been obtained raising; In addition, when full-bridge inverting cell S PWM mode works, input current is through bypass diode D _b, and do not flow through boost inductance L _bwith diode Dc, the conduction loss of booster circuit reduces greatly.

Schematically above be described the utility model and execution mode thereof, this description does not have restricted, and also just one of the execution mode of the present utility model shown in accompanying drawing, actual structure is not limited thereto.So, if those of ordinary skill in the art enlightens by it, when not departing from the utility model and creating aim, design the frame mode similar to this technical scheme and embodiment without creationary, protection range of the present utility model all should be belonged to.

Claims (3)

1. a photovoltaic grid-connected inversion circuit, comprises DC boosting unit (1), full-bridge inverting unit (2), filter unit (3), photovoltaic cell group (4) and electrical network (5), wherein:

Described full-bridge inverting unit (2) is connected with DC boosting unit (1), and this full-bridge inverting unit (2) is by full-bridge inverting switching tube SW ₁, SW ₂, SW ₃, SW ₄the inverter bridge of composition;

Described filter unit (3) comprises filter inductance L _fwith filter capacitor C _f, filter inductance L _ffirst end and described full-bridge inverting switching tube SW ₁, SW ₂the intermediate point of composition brachium pontis connects, this filter inductance L _fthe second end respectively with filter capacitor C _ffirst end, electrical network (5) one end connect, the other end of electrical network (5) and filter capacitor C _fsecond end connect; Filter capacitor C _fthe second end also with full-bridge inverting switching tube SW ₃, SW ₄the intermediate point of composition brachium pontis connects; It is characterized in that:

Described DC boosting unit (1) comprises bypass diode D _b, boost inductance L _b, diode Dc, chopping switching tube SWc and intermediate capacitance Cc, the positive pole of photovoltaic cell group (4) respectively with bypass diode D _bpositive pole, boost inductance L _bfirst end connect, bypass diode D _bnegative pole respectively with diode D _cnegative pole, intermediate capacitance Cc first end connect, boost inductance L _bthe second end be connected with the positive pole of diode Dc, the collector electrode of chopping switching tube SWc respectively; The negative pole of described photovoltaic cell group (4) is connected with the emitter of chopping switching tube SWc, second end of intermediate capacitance Cc respectively.

2. a kind of photovoltaic grid-connected inversion circuit according to claim 1, is characterized in that: described intermediate capacitance Cc is low capacity thin-film capacitor.

3. an ON-OFF control circuit for photovoltaic grid-connected inversion circuit, is characterized in that: comprise chopping switching tube SWc control circuit and full-bridge inverting switching tube SW ₁, SW ₂, SW ₃, SW ₄control circuit, wherein:

In described chopping switching tube SWc control circuit, the signal output part of sine-wave generator I is connected with the in-phase input end of comparator I, the input of DSP microprocessor respectively through full-wave rectifier I, the signal output part of signal picker is connected with the inverting input of comparator I, the input of DSP microprocessor respectively, the signal output part of comparator I, DSP microprocessor is connected with the input of multiplier I respectively, and the output signal of multiplier I is as the drive singal of SWc;

Described full-bridge inverting switching tube SW ₁, SW ₂, SW ₃, SW ₄in control circuit, the signal output part of sine-wave generator II is connected through the in-phase input end of full-wave rectifier II with comparator II, and the signal output part of triangular-wave generator is connected with the inverting input of comparator II; The signal output part of sine-wave generator III is connected with the in-phase input end of comparator III, and the inverting input of comparator III is connected with no-voltage; The signal output part of sine-wave generator IV is connected with the inverting input of comparator IV, and the in-phase input end of comparator IV is connected with no-voltage; The signal output part of comparator II, comparator III is connected with the input of multiplier II, and the output signal of multiplier II is as SW ₁drive singal, multiplier II connects the output signal of inverter I as SW ₂drive singal; The signal output part of comparator II, comparator IV is connected with the input of multiplier III, and the output signal of multiplier III is as SW ₃drive singal, multiplier III connects the output signal of inverter II as SW ₄drive singal.