CN203617896U - Boost and buck hybrid power decoupling circuit used for photovoltaic grid-connected inverter - Google Patents

Abstract

The utility model discloses a boost and buck hybrid power decoupling circuit used for a photovoltaic grid-connected inverter, and relates to a circuit device of AC main lines or AC power distribution networks. The boost and buck hybrid power decoupling circuit is composed of a decoupling capacitor A, a decoupling capacitor B, a decoupling capacitor C, a switch tube A, a switch tube B, a switch tube C, a switch tube D and an inductor. According to the power decoupling circuit, the busbar voltage can be guaranteed to be stabilized at about 400V, capacity of a single capacitor is recued, voltage withstanding levels of the capacitors and the switch tubes are reduced, and the defects that large-capacity and large-size decoupling capacitors are required for an existing photovoltaic grid-connected inverter, and the existing photovoltaic grid-connected inverter is complex in structure, low in power density, large in size and high in cost are overcome.

Description

For boosting and step-down mixed type power decoupling circuit of photovoltaic combining inverter

Technical field

The technical solution of the utility model relates to the circuit arrangement of ac mains or ac distribution network, specifically boosting and step-down mixed type power decoupling circuit for photovoltaic combining inverter.

Background technology

In single-phase photovoltaic grid-connected inverter, for the output power factor that makes inverter approaches 1, the output current wave that needs control inverter be sinusoidal waveform and with line voltage same-phase, this power output that makes inverter is the pulsating power that doubles mains frequency.This pulsating power can produce low-frequency ripple on DC bus, and then causes the fluctuation of the voltage and current of photovoltaic array.But the energy sending in order to maximally utilise photovoltaic array, must make photovoltaic array fully approach its maximum power point operation.In order to be limited in the low-frequency ripple producing on DC bus, existing solution is the decoupling capacitance in photovoltaic array two ends the United Nations General Assembly, and for the DC bus-bar voltage of 400V, decoupling capacitance is generally 0.5mF/kW.This has increased volume and the cost of inverter undoubtedly.In this case, how to reduce capacitance and the volume of inverter, raising complete machine power density becomes scholar in recent years and falls over each other one of hot issue of research.

The method that document " Utility-connected power converter for maximizing power transfer from a photovoltaic source while drawing ripple-free current " proposes has increased the voltage fluctuation amplitude of bus capacitor, make the withstand voltage increase of device, thereby the selection to the withstand voltage electric capacity of height brings difficulty, and the life-span of device also can reduce.The method that document " DC bus regulation strategy for grid-connected V power generation system " proposes is by after an inductance and a capacitances in series, be connected in parallel on again on DC bus, utilize the method for LC series resonance can effectively reduce the voltage fluctuation of bus.The L of this decoupling method and the value of C are very large, and the resonance current of its generation exist fluctuate widely, increased unsteadiness to system, and this method is not suitable for small-power occasion.The voltage fluctuation of the electric capacity in document " two-stage type photovoltaic combining inverter and power decoupled research thereof " in boost decoupling zero circuit is large, between 400-1000V, high to the requirement of withstand voltage of electric capacity.CN101841252A discloses a kind of photovoltaic combining inverter of active energy decoupling, introduce a kind of active energy decoupling mode of photovoltaic combining inverter, utilized the mode of two anti exciting converter shunt capacitances, the complex structure of its device, volume is large and cost is high; CN102638059A has reported single-phase grid-connected photovoltaic power generation system power decoupling circuit and control method thereof, the decoupling zero part of single-phase grid-connected photovoltaic power generation system power decoupling circuit is wherein between full-bridge inverting and grid-connected filter, and the designing requirement to grid-connected filter and cost are all higher.

In a word, in existing single-phase photovoltaic grid-connected inverter device, still exist and need the decoupling capacitance of larger capacity and larger volume, complex structure, power density is low, volume is large and cost is high defect.

Utility model content

Technical problem to be solved in the utility model is: be provided for boosting and step-down mixed type power decoupling circuit of photovoltaic combining inverter, this power decoupling circuit can ensure that busbar voltage is stable and reduce the capacity of single electric capacity in about 400V, reduce the withstand voltage level of electric capacity and switching tube, overcome the defect that decoupling capacitance, complex structure, power density are low, volume is large and cost is high that needs larger capacity and larger volume in existing grid-connected photovoltaic inverter device.

The utility model solves this technical problem adopted technical scheme: for boosting and step-down mixed type power decoupling circuit of photovoltaic combining inverter, be made up of decoupling capacitance device A, decoupling capacitance device B, decoupling capacitance device C, switching tube A, switching tube B, switching tube C, switching tube D and an inductance, positive pole after decoupling capacitance device A and decoupling zero capacitor B series connection is connected in the collector electrode of the switching tube A after switching tube A and switching tube B series connection, be connected on the cathode node of a DC bus, negative pole after decoupling capacitance device A and decoupling zero capacitor B series connection is connected on the negative pole node of another DC bus, the emitter of switching tube B after switching tube A and switching tube B series connection is connected in the intermediate node after decoupling capacitance device A and decoupling zero capacitor B series connection, the tie point of the collector electrode of the emitter of switching tube A and switching tube B is connected in the tie point of the emitter of switching tube C and the collector electrode of switching tube D by inductance, the collector electrode of switching tube C after switching tube C and switching tube D series connection is connected in the positive pole of decoupling capacitance device C, the emitter of switching tube D after switching tube C and switching tube D series connection is connected in the negative pole of decoupling capacitance device C and is connected in the intermediate node of decoupling capacitance device A and decoupling zero capacitor B simultaneously.

Above-mentioned boosting and step-down mixed type power decoupling circuit for photovoltaic combining inverter, wherein the capacitance of decoupling capacitance device A is that 22 μ F and withstand voltage are 148V, the capacitance of decoupling capacitance device B is that 68 μ F and withstand voltage are 294V, and the capacitance of decoupling capacitance device C is that 82 μ F and withstand voltage are 294V.

It is above-mentioned that all to adopt model for boosting of photovoltaic combining inverter with switching tube A, switching tube B, switching tube C and the switching tube D of step-down mixed type power decoupling circuit be the insulated gate bipolar transistor of IKP15N65H5.

Above-mentioned boosting and step-down mixed type power decoupling circuit for photovoltaic combining inverter, wherein involved switching tube, decoupling capacitance device, inductance are all known, all components and parts can obtain by the known approach such as being purchased, and the connection of all components and parts is all also the known line connecting method of those skilled in the art.

Above-mentioned boosting and step-down mixed type power decoupling circuit for photovoltaic combining inverter, in the time being applied in photovoltaic combining inverter, positive pole after decoupling capacitance device A and decoupling zero capacitor B series connection is connected in positive pole after switching tube A and switching tube B series connection and is connected to the cathode node of a DC bus, negative pole after decoupling capacitance device A and decoupling zero capacitor B series connection is connected in the negative pole node of another DC bus, this cathode node and negative pole node are connected respectively on the positive pole and negative pole of photovoltaic array, and as the input of inverter.In the time being applied in photovoltaic combining inverter, the utility model is also the DC/DC converter of energy in bidirectional flow with step-down mixed type power decoupling circuit for boosting of photovoltaic combining inverter.

The beneficial effects of the utility model are:

Compared with prior art, substantive distinguishing features of the present utility model is: export the different of energy according to photovoltaic array produce power from inverter, the utility model works in two kinds of mode of operations of charging and discharging for boosting of photovoltaic combining inverter with step-down mixed type power decoupling circuit, has two kinds of operating states of buck circuit and boost circuit under every kind of mode of operation.

(1) under the power situation producing lower than photovoltaic array to electrical network power output:

At the voltage of decoupling capacitance device A during higher than the voltage of decoupling capacitance device C, in the time of switching tube A conducting, the anti-paralleled diode of decoupling capacitance device A, switching tube A, inductance, switching tube C and decoupling zero capacitor C form loop, decoupling capacitance device A energy flow is to decoupling capacitance device C, give inductance and decoupling zero capacitor C charging, inductive current increases; In the time that switching tube A closes, the anti-paralleled diode of inductance, switching tube B, switching tube C and decoupling zero capacitor C form loop, and inductance afterflow is to decoupling capacitance device C charging, and inductive current reduces.Now switching tube A works in high frequency state, and operating circuit is buck circuit working state.

At the voltage of decoupling capacitance device A, during lower than the voltage of decoupling capacitance device C, in the time of switching tube A and switching tube D conducting, decoupling capacitance device A, switching tube A, inductance and switching tube D form loop, and decoupling capacitance device A is to induction charging, and inductive current increases; In the time that switching tube D closes, the anti-paralleled diode of decoupling capacitance device A, switching tube A, inductance, switching tube C and decoupling zero capacitor C form loop, and decoupling capacitance device A and inductance are jointly to decoupling capacitance device C charging, and inductive current reduces.Now switching tube A works in low frequency state, and switching tube C works in high frequency state, and operating circuit is boost circuit working state.

In control procedure, it is stable that DC bus-bar voltage keeps, in the whole process of charging to decoupling capacitance device 3 at decoupling capacitance device 1, due to the reduction of the voltage of decoupling capacitance device 1, thereby the voltage of decoupling capacitance device 2 rises, decoupling capacitance device 2 storage compartment excess energies.

Through above process, the excess energy of photovoltaic array is stored in decoupling capacitance device B and decoupling zero capacitor C.

(2) under the power situation producing higher than photovoltaic array to electrical network power output:

At the voltage of decoupling capacitance device C during higher than the voltage of decoupling capacitance device A, in the time of switching tube C conducting, the anti-paralleled diode of decoupling capacitance device C, switching tube C, inductance, switching tube A and decoupling zero capacitor A form loop, decoupling capacitance device C energy flow is to decoupling capacitance device A, release energy to inductance and decoupling zero capacitor A, inductive current increases; In the time that switching tube D is closed, the anti-paralleled diode of the anti-paralleled diode of switching tube A, inductance, switching tube D and decoupling zero capacitor A form loop, and inductance afterflow releases energy to decoupling capacitance device A, and inductive current reduces.Now switching tube D works in high frequency state, and operating circuit is buck circuit working state.

At the voltage of decoupling capacitance device C, during lower than the voltage of decoupling capacitance device A, in the time of switching tube B and switching tube C conducting, decoupling capacitance device C, switching tube C, inductance and switching tube B form loop, and decoupling capacitance device C is to induction charging, and inductive current increases; In the time that switching tube B closes, the anti-paralleled diode of decoupling capacitance device C, switching tube C, inductance, switching tube A and decoupling zero capacitor A form loop, and decoupling capacitance device C and inductance are jointly to decoupling capacitance device A electric discharge, and inductive current reduces.Now switching tube C works in low frequency state, and switching tube B works in high frequency state, and operating circuit is boost circuit working state.

In control procedure, it is stable that DC bus-bar voltage keeps, at decoupling capacitance device C in the whole process of decoupling capacitance device A electric discharge, due to the rising of the voltage of decoupling capacitance device A, thereby the voltage drop of decoupling capacitance device B, the part excess energy that decoupling capacitance device B stores is discharged in system.

Through above process, the excess energy being stored in decoupling capacitance device B and decoupling zero capacitor C is discharged in the middle of system.

Known from the above, decoupling capacitance device A, decoupling capacitance device B decoupling capacitance device C's is withstand voltage all lower than DC bus-bar voltage, and has reduced the capacity of electric capacity, makes the smaller volume of decoupling capacitance device.Switching tube A, switch B, switching tube C, the maximum voltage that switching tube D bears is the ceiling voltage of decoupling capacitance device A and decoupling capacitance device C, all lower than DC bus-bar voltage, thereby the lower loss of switching tube has guaranteed the efficiency of photovoltaic combining inverter.

Compared with prior art, marked improvement of the present utility model is:

(1) the utility model has reduced the volume of the decoupling capacitance of photovoltaic combining inverter, thereby reduces the volume of photovoltaic combining inverter.

(2) the utility model is ensureing under the stable prerequisite in DC bus-bar voltage 400V left and right, compared with the structure of existing decoupling zero circuit, the decoupling capacitance of stored energy has two, be decoupling capacitance device B and decoupling zero capacitor C, thereby reduce the capacity of electric capacity, and the translation circuit of decoupling zero unit is to boost and the two-way DC/DC converter that combines of reduction voltage circuit, makes the withstand voltage all lower than DC bus-bar voltage of decoupling capacitance required in decoupling zero circuit and switching tube.

(3) in existing decoupling zero mode, needing the capacity of decoupling capacitance device is amount 500uF/kw, and it is 158uF/kw that the utility model decoupling zero circuit only needs the capacity of decoupling capacitance device.The reduction of decoupling capacitance device capacity and the withstand voltage reduction of switching tube in the utility model, reduced decoupling zero capacitance body and amassed and improved complete machine power density.

In a word, the utility model has overcome existing grid-connected photovoltaic inverter device and has needed the decoupling capacitance of larger capacity and larger volume, complex structure, power density is low, volume is large and cost is high defect for boosting of photovoltaic combining inverter with step-down mixed type power decoupling circuit.

Accompanying drawing explanation

Below in conjunction with drawings and Examples, the utility model is further illustrated.

Fig. 1 boosting and the structural representation of step-down mixed type power decoupling circuit for photovoltaic combining inverter that be the utility model.

Fig. 2 is the schematic diagram of the application of the utility model in photovoltaic combining inverter.

Fig. 3 a-3h is the course of work principle schematic that the utility model is applied to photovoltaic combining inverter.

Fig. 4 is that the application test result of the utility model embodiment is tested the main waveform obtaining.

In figure, 1. decoupling capacitance device A, 2. decoupling capacitance device B, 3. decoupling capacitance device C, 4. switching tube A, 5. switching tube B, 6. switching tube C, 7. switching tube D, 8. inductance, 9. photovoltaic array, 10. cathode node, 11. intermediate nodes, 12. negative pole nodes, the tie point of the collector electrode of the emitter of 13. switching tube A4 and switching tube B5, the tie point of the collector electrode of the emitter of 14. switching tube C6 and switching tube D7,15. DC buss, 16. inverters, 17. electrical networks.

Embodiment

Embodiment illustrated in fig. 1 showing, for boosting and step-down mixed type power decoupling circuit of photovoltaic combining inverter, formed by decoupling capacitance device A1, decoupling capacitance device B2, decoupling capacitance device C3, switching tube A4, switching tube B5, switching tube C6, switching tube D7 and an inductance 8; positive pole after decoupling capacitance device A1 and decoupling zero capacitor B2 series connection is connected in the collector electrode of the switching tube A4 after switching tube A4 and switching tube B5 series connection, be connected on the cathode node 10 of a DC bus 15, negative pole after decoupling capacitance device A1 and decoupling zero capacitor B2 series connection is connected on the negative pole node 12 of another DC bus 15, the emitter of switching tube B after switching tube A4 and switching tube B5 series connection is connected in the intermediate node 11 after decoupling capacitance device A1 and decoupling zero capacitor B2 series connection, the tie point 13 of the collector electrode of the emitter of switching tube A4 and switching tube B5 is connected in the tie point 14 of the emitter of switching tube C6 and the collector electrode of switching tube D7 by inductance 8, the collector electrode of switching tube C6 after switching tube C6 and switching tube D7 series connection is connected in the positive pole of decoupling capacitance device C3, the emitter of switching tube D7 after switching tube C6 and switching tube D7 series connection is connected in the negative pole of decoupling capacitance device C3, the negative pole of decoupling capacitance device C3 is connected in the intermediate node 11 of decoupling capacitance device A1 and decoupling zero capacitor B2 simultaneously.

Embodiment illustrated in fig. 2 showing, the applicable cases of the utility model in photovoltaic combining inverter is: the positive pole boosting after connecting with the decoupling capacitance device A1 of step-down mixed type power decoupling circuit (explanation of embodiment as shown in Figure 1) and decoupling zero capacitor B2 for photovoltaic combining inverter in this figure shown in dotted line frame is connected in positive pole after switching tube A4 and switching tube B5 series connection and is connected to the cathode node 10 of a DC bus, negative pole after decoupling capacitance device A1 and decoupling zero capacitor B2 series connection is connected in the negative pole node 12 of another DC bus, this cathode node 10 and negative pole node 12 are connected respectively on the positive pole and negative pole of photovoltaic array 9, and as the input of inverter 16.In the time being applied in photovoltaic combining inverter, the utility model is also the DC/DC converter of energy in bidirectional flow with step-down mixed type power decoupling circuit for boosting of photovoltaic combining inverter.

Fig. 3 a-3h illustrated embodiment shows, the course of work principle that the utility model is applied to photovoltaic combining inverter is as follows:

Fig. 3 a illustrated embodiment shows, the utility model is applied in the course of work of photovoltaic combining inverter, operating circuit is in giving decoupling capacitance device C3 when charging, switching tube A4 conducting, the buck circuit working state that switching tube B5, switching tube C6 and switching tube D7 turn-off.

Fig. 3 b illustrated embodiment shows, the utility model is applied in the course of work of photovoltaic combining inverter, operating circuit is in the time giving decoupling capacitance device C3 charging, and switching tube A4, switching tube B5, switching tube C6 and switching tube D7 be the buck circuit working state of shutoff all.

Fig. 3 c illustrated embodiment shows, the utility model is applied in the course of work of photovoltaic combining inverter, operating circuit is in giving decoupling capacitance device C3 when charging, switching tube A4 and switching tube D7 conducting, the boost circuit working state that switching tube B5 and switching tube C6 turn-off.

Fig. 3 d illustrated embodiment shows, the utility model is applied in the course of work of photovoltaic combining inverter, operating circuit is in giving decoupling capacitance device C3 when charging, switching tube A4 conducting, the boost circuit working state that switching tube B5, switching tube C6 and switching tube D7 turn-off.

Fig. 3 e illustrated embodiment shows, the utility model is applied in the course of work of photovoltaic combining inverter, operating circuit in the time that decoupling capacitance device C3 discharges, switching tube C6 conducting, the buck circuit working state that switching tube A4, switching tube B5 and switching tube D7 turn-off.

Fig. 3 f illustrated embodiment shows, the utility model is applied in the course of work of photovoltaic combining inverter, operating circuit in the time that decoupling capacitance device C3 discharges, the buck circuit working states that switching tube A4, switching tube B5, switching tube C6 and switching tube D7 all turn-off.

Fig. 3 g illustrated embodiment shows, the utility model is applied in the course of work of photovoltaic combining inverter, operating circuit in the time that decoupling capacitance device C3 discharges, switching tube B5 and switching tube C6 conducting, the boost circuit working state that switching tube A4 and switching tube D7 turn-off.

Fig. 3 h illustrated embodiment shows, the utility model is applied in the course of work of photovoltaic combining inverter, operating circuit in the time that decoupling capacitance device C3 discharges, switching tube C6 conducting, the boost circuit working state that switching tube A4, switching tube B5 and switching tube D7 turn-off.

Embodiment

The boosting with the composition of step-down mixed type power decoupling circuit as shown in Fig. 1 embodiment for photovoltaic combining inverter of the present embodiment, its connection and methods for using them in photovoltaic combining inverter is as shown in Fig. 2 embodiment, wherein, the capacitance of decoupling capacitance device A1 is that 22 μ F and withstand voltage are 148V, the capacitance of decoupling capacitance device B2 is that 68 μ F and withstand voltage are 294V, the capacitance of decoupling capacitance device C3 is that 82 μ F and withstand voltage are 294V, switching tube A4, switching tube B5, it is the insulated gate bipolar transistor of IKP15N65H5 that switching tube C6 and switching tube D7 all adopt model, the inductance value of inductance 8 is 2mH.Photovoltaic array 9 adopt the form of cell panel series connection make its output voltage at 350V between 500V, electrical network 17 frequencies are 50Hz, the voltage that keeps DC bus 15 in application is 400V(ripple ± 2%), photovoltaic combining inverter output voltage is that effective value is the alternating current that 220V, frequency are 50Hz, and output average power is 1kW.This is used for boosting of photovoltaic combining inverter and is 40kHz with the switching frequency of all switching tubes of step-down mixed type power decoupling circuit.

Fig. 4 has provided the application test result of the present embodiment and has tested the main waveform obtaining.Wherein, the output current of photovoltaic combining inverter is sinusoidal waveform, minimum voltage and the maximum voltage of decoupling capacitance device B2 are respectively 252V and 294V, its magnitude of a voltage fluctuation is 42V, average voltage is 273V, the change in voltage of decoupling capacitance device C3 and decoupling capacitance device B2 change basically identical, and the minimum and maximum value of the voltage of DC bus 15 is respectively 408V and 392V, and ripple factor is 4%.This experimental result and theory analysis are basically identical.

Claims (3)

1. for the boosting and step-down mixed type power decoupling circuit of photovoltaic combining inverter, it is characterized in that: formed by decoupling capacitance device A, decoupling capacitance device B, decoupling capacitance device C, switching tube A, switching tube B, switching tube C, switching tube D and an inductance, positive pole after decoupling capacitance device A and decoupling zero capacitor B series connection is connected in the collector electrode of the switching tube A after switching tube A and switching tube B series connection, be connected on the cathode node of a DC bus, negative pole after decoupling capacitance device A and decoupling zero capacitor B series connection is connected on the negative pole node of another DC bus, the emitter of switching tube B after switching tube A and switching tube B series connection is connected in the intermediate node after decoupling capacitance device A and decoupling zero capacitor B series connection, the tie point of the collector electrode of the emitter of switching tube A and switching tube B is connected in the tie point of the emitter of switching tube C and the collector electrode of switching tube D by inductance, the collector electrode of switching tube C after switching tube C and switching tube D series connection is connected in the positive pole of decoupling capacitance device C, the emitter of switching tube D after switching tube C and switching tube D series connection is connected in the negative pole of decoupling capacitance device C and is connected in the intermediate node of decoupling capacitance device A and decoupling zero capacitor B simultaneously.

2. according to boosting and step-down mixed type power decoupling circuit for photovoltaic combining inverter described in claim 1, it is characterized in that: wherein the capacitance of decoupling capacitance device A is that 22 μ F and withstand voltage are 148V, the capacitance of decoupling capacitance device B is that 68 μ F and withstand voltage are 294V, and the capacitance of decoupling capacitance device C is that 82 μ F and withstand voltage are 294V.

According to described in claim 1 for the boosting and step-down mixed type power decoupling circuit of photovoltaic combining inverter, it is characterized in that: it is the insulated gate bipolar transistor of IKP15N65H5 that switching tube A, switching tube B, switching tube C and switching tube D wherein all adopts model.

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