CN105186900A - Five-level transformerless inverter circuit - Google Patents

Abstract

The invention relates to a five-level transformerless inverter circuit. A solar generator is arranged at an input end of the five-level transformerless inverter circuit; an alternating-current power network is arranged at an output end of the five-level transformerless inverter circuit; the five-level transformerless inverter circuit is characterized by comprising three links, which respectively are a DC link, an MID link and an AC link; the DC link comprises two inductors, two switch tubes and two diodes; the MID link comprises four capacitors; and the AC link comprises six diodes, five switch tubes, a filter inductor and a filter capacitor. According to the five-level transformerless inverter circuit, the function of converting direct-current into alternating-current is achieved; high-frequency common-mode voltage of an input terminal is avoided; meanwhile, the inductive capacity and the switching losses of switching devices are reduced; the electromagnetic interference is reduced; and high-efficiency conversion is achieved.

Description

A kind of five level transformerless inverter circuits

Technical field

The present invention relates to the circuit that a kind of direct voltage is converted into alternating voltage, be applied to new energy grid-connected power technical field.

Background technology

Solar power generation, as the important component part of new forms of energy, obtains increasing development.In solar power system, the DC conversion sent by solar panel is the core of inversion change-over circuit as solar power system of alternating current, has very important effect.

Solar energy system can be divided into self and grid type usually, the energy of the latter owing to can farthest utilize solar panel to send, and is therefore the main application type of current photovoltaic system.Inverter topology totally can be divided into band transformer isolation and Transformer-free.Isolating transformer can realize the effect isolated and boost, but Industrial Frequency Transformer volume is heavy, efficiency is low, cost is high, installs inconvenience; Although high frequency transformer volume and weight declines, often system complex, and output current exists DC component, efficiency is on the low side too; Inverter without transformer, because system configuration is simple, efficiency is high, volume is little and the low acquisition of cost develops fast, becomes the main flow of grid-connected photovoltaic power generation.

Owing to not having transformer isolation between DC source and load, there is the problem of common mode current interference in inverter without transformer.Generally because solar panel area is comparatively large, parasitic capacitance is also comparatively large over the ground, and this electric capacity changes with external environment.Due to the existence of parasitic capacitance, and the switching device in inverter switches at high frequency, therefore there is current path between the switching tube in solar panel end, parasitic capacitance and inverter, filter inductance and electrical network, thus likely forming larger common mode current, this common mode current may bring hidden danger to operating personnel's personal safety.Therefore effectively suppressing and eliminating common mode current is completely the key issue that inverter without transformer needs to solve.

At present, for the single-phase Transformer-free grid-connected photovoltaic inverter of middle low power, the full-bridge circuit of bipolar modulation and half-bridge circuit is often adopted to solve common mode current problem.The full-bridge circuit switching loss of bipolar modulation is large, and inverter output voltage is two level, and required filter inductance is large, thus efficiency is on the low side; The input voltage of half-bridge circuit needs the twice for full-bridge voltage, and often need two-stage circuit to realize, increased circuit realizes difficulty, there is the problem that conversion efficiency is low equally; When have employed the full-bridge circuit of unipolar control, its inverter output voltage is three level, and required filter inductance is less, but cannot effectively solve common mode current problem.

Summary of the invention

The object of the invention is for Transformer-free grid-connected photovoltaic inverter, the circuit that a new direct current is converted into interchange is proposed, can realize inverter voltage output is five level, output inductor can be reduced, solve the problem of common mode current simultaneously, the switching loss reducing switching device is low, thus can realize higher transformation efficiency.

In order to achieve the above object, technical scheme of the present invention there is provided a kind of five level transformerless inverter circuits, its input is solar generator, output is AC network, it is characterized in that, comprise: inductance L 1 and inductance L 2, one end of inductance L 1 and inductance L 2 is connected with the positive pole of solar generator and negative pole respectively, the switching tube one of cross-over connection series connection between the other end of inductance L 1 and inductance L 2 and switching tube two, the another one end of inductance L 1 is also connected with the anode of diode D1, and the other end of inductance L 2 is also connected with the negative electrode of diode D2;

Electric capacity C1, electric capacity C2, electric capacity C3 and electric capacity C4 that between the negative electrode and the anode of diode D2 of diode D1, cross-over connection is connected, reference point of potential (0) is drawn between electric capacity C2 and electric capacity C3, this reference point of potential is direct-connected between switching tube one and switching tube two, and the circuit between electric capacity C1 and electric capacity C2 and the circuit between electric capacity C3 and electric capacity C4 are connected to the circuit between one end of circuit between one end of inductance L 1 and the positive pole of solar generator and inductance L 2 and the negative pole of solar generator respectively;

The switching tube three that cross-over connection is connected is gone back between the negative electrode and the anode of diode D2 of diode D1, switching tube four, switching tube five and switching tube six, inverter output voltage point is drawn between switching tube four and switching tube five, inverter output voltage point is connected with AC network via filter circuit, filter circuit is serially connected between inverter output voltage point and reference point of potential, reference point of potential is connected with the anode of diode D5 and the negative electrode of diode D6 respectively, the negative electrode of diode D5 is connected with the negative electrode of one end of switching tube seven and diode D7, the anode of diode D6 is connected with the anode of the other end of switching tube seven and diode D8, the anode of diode D7 and the negative electrode of diode D8 are connected with inverter output voltage point, the anode of diode D3 is connected with the circuit between electric capacity C1 with electric capacity C2, the negative electrode of diode D3 is connected with the circuit between switching tube three with switching tube four, the negative electrode of diode D4 is connected with the circuit between electric capacity C3 with electric capacity C4, the anode of diode D3 is connected with the circuit between switching tube five with switching tube six.

Preferably, described switching tube one, switching tube two, switching tube three, switching tube four, switching tube five, switching tube six, switching tube seven or be the anti-and switching transistor of diode of inner band, or form after diode inverse parallel by independently switching transistor with independently, or use independently switching transistor.

Preferably, switching transistor is made up of switching device.

Preferably, described switching device or be igbt transistor, or be mosfet transistor group.

Preferably, described filter circuit or be made up of filter inductance and filter capacitor, or be made up of filter inductance.

Preferably, described filtered electrical is perhaps single electric capacity, or is the combination of multiple Capacitance parallel connection.

Preferably, described electric capacity C1, described electric capacity C2, described electric capacity C3 and described electric capacity C4 or be single electrochemical capacitor, or be the combination of multiple electrochemical capacitor parallel connection, or be the electrochemical capacitor combination in parallel with thin-film capacitor.

Present invention achieves the function that direct current is converted into interchange, and avoid input terminal and occur high frequency common mode voltage, reduce the switching loss of inductive capacity and switching device simultaneously, reduce electromagnetic interference, achieve high efficiency conversion.

Accompanying drawing explanation

Fig. 1 is single-phase five level inverter without transformers;

Fig. 2 is translation circuit operating state;

Fig. 3 is positive half cycle A district, power generation circuit;

Fig. 4 is positive half cycle A district, continuous current circuit;

Fig. 5 is positive half cycle B district, power generation circuit;

Fig. 6 is positive half cycle B district, continuous current circuit;

Fig. 7 is negative half period A district, power generation circuit;

Fig. 8 is negative half period A district, continuous current circuit;

Fig. 9 is negative half period B district, power generation circuit;

Figure 10 is negative half period B district, continuous current circuit;

Figure 11 is that inversion exports five level voltages.

Embodiment

For making the present invention become apparent, hereby with preferred embodiment, and accompanying drawing is coordinated to be described in detail below.

The present invention proposes a kind of direct current and transforms the circuit exchanged, and can be used for solar grid-connected generating, the input of this circuit is solar generator SG, and output is AC network Ug.It comprises three links, is DC link, MID link and AC link respectively.Wherein, DC link comprises two inductance L 1 ~ L2, two switching tube S1 ~ S2, two diode D1 ~ D2; MID link comprises four electric capacity C1 ~ C4; AC link comprises six diode D3 ~ D8, five switching tube S3 ~ S7 and filter inductance Lf and filter capacitor Cf, as shown in Figure 1.

In DC link, inductance L 1 one end is connected to the anode of solar generator SG, the other end is connected to one end of switching tube S1 and the positive pole of diode D1, one end of the other end connecting valve pipe S2 of switching tube S1, the other end of switching tube S2 is connected to the negative electrode of inductance L 2 and diode D2, and the other end of inductance L 2 is connected to the negative terminal of solar generator SG.In addition, the negative electrode of diode D1 and the anode of diode D2 are connected respectively to 1 end and 4 ends of MID link.

In MID link, electric capacity C1 ~ C4 connects successively, and wherein one end of electric capacity C1 is connected to the negative electrode of diode D1 in DC link and one end of AC link breaker in middle pipe S3; The C1 other end is connected to the anode of one end of electric capacity C2, one end of inductance L 1 and AC link diode D3.One end of electric capacity C2 is connected to the anode of one end of C1, one end of C3, one end of inductance L 1 and AC link diode D3; The other end of C2 is connected to one end of C3, the anode of the centre of DC link S1, S2 series connection and AC link diode D5, the negative electrode of D6 and one end of electrical network.One end of electric capacity C3 is connected to one end of C2, the anode of the centre of DC link S1, S2 series connection and AC link diode D5, the negative electrode of D6 and one end of electrical network; The other end of electric capacity C3 is connected to one end of inductance L 2 and the negative electrode of AC link diode D4 in one end of electric capacity C4, DC link.One end of electric capacity C4 is connected to the negative electrode of diode D4 in the one end of inductance L 2 in one end of electric capacity C3, DC link and AC link; The other end of C4 is connected to the anode of diode D2 in DC link and one end of AC link breaker in middle pipe S6.In DC link, two electric capacity C2, C3 series connection, series connection end is designated as " 0 ", and with solar generator SG is in parallel, can set a reference potential, be designated as " 0V ", then in MID link, electric capacity C2, C3 are respectively+Upv and-Upv relative to the voltage of 0V point, when the output voltage of solar generator SG is Vdc, the voltage on electric capacity C2, C3 is 0.5Vdc, and this voltage can be used as the input voltage of AC link.

In AC link, switching tube S3 ~ S6 successively head and the tail connects, S3 and S4 connects, S4 and S5 connects, S5 and S6 connects, the other end of S3 connects the negative electrode of DC link diode D1 and one end of MID link electric capacity C1, and the other end of S6 connects the anode of DC link diode D2 and one end of MID link electric capacity C4.The negative electrode of diode D3 is connected in the middle of switching tube S3, S4, and the anode of diode D3 is connected in the middle of MID link electric capacity C1, C2, and the anode of diode D4 is connected in the middle of switching tube S5, S6, and the negative electrode of diode D4 is connected in the middle of MID link electric capacity C3, C4.Inductance L f connects between switching tube S4 and S5, and electric capacity Cf connects between outputting inductance Lf and electrical network 0V end.

DC link can realize the lifting to solar generator SG output voltage, when SG output voltage is lower than line voltage currency, DC link shows as booster circuit, voltage after lifting is applied to MID link, ensure that the voltage of MID link is greater than line voltage currency, the power stage to electrical network can be realized.

MID link is formed primarily of electrochemical capacitor, at grid cycle not in the same time, the output voltage of MID link varies in size, and is the magnitude of voltage of a dynamic change, and this magnitude of voltage is determined according to the magnitude relationship of solar generator SG output voltage and line voltage currency.In traditional inverter, the voltage of MID link is all fixed value, and the dynamic electrochemical capacitor change in voltage of this low frequency can improve the life-span of electrochemical capacitor, improves the reliability of system.MID link, as the input of AC link, provides energy to AC link, and then provides energy to electrical network.

The converting direct-current voltage into alternating-current voltage that MID link exports by AC link.Dynamic for MID link direct voltage, according to the size of line voltage value, is reverse into the potential pulse of five level by this link, and ensures that the amplitude of this pulse is greater than current electric grid magnitude of voltage.

In the single-phase five level inverter without transformers that the present invention proposes, according to the magnitude relationship of solar generator SG output voltage and line voltage, determine whether DC link works, the size of MID link output voltage and performance loop corresponding to AC link.In positive and negative grid cycle, corresponding DC link, MID link, AC link operating circuit are all not identical, respectively have four kinds of operating states.

In these four kinds of states, the sequential of the driving pulse of each switching tube as shown in Figure 2, wherein S1 ~ S7 represents the driving pulse of switching tube S1 ~ S7 respectively, and switching tube S1, S2 of DC link need at times according to line voltage the switching over being fixed pulse duration; Switching tube S3 ~ the S7 of AC link is at times according to the needs of the line voltage switching over according to the pulse duration of electrical network sine wave modulation.

(1) operating state of positive half period

At the positive half period of electrical network, when the input voltage value+Upv of AC link is greater than line voltage value Ug, as shown in the A district of positive half period in Fig. 2, DC link does not work, switching tube S1, S2 are in off state always, and diode D1, D2 end, and inductance L 1, L2 no current flow through.Output voltage+the Upv of solar generator SG is applied directly on inverse switch pipe S4 through the diode D3 of AC link, by the high-frequency action (such as 20kHz) of switching tube S4, S7, realize the conversion of direct current to alternating voltage, now switching tube S3 is in off state always.

In the A district of positive half period, only have switching tube S4, S7 high-frequency operation, the two complementary conducting, other switching tubes all do not work.

When the input voltage value+Upv of AC link is less than line voltage value Ug, as shown in the B district of positive half period in Fig. 2, DC link works, according to the size of B district line voltage, switching tube S1 high-frequency switches (such as 20kHz), by electric capacity C2 terminal voltage 0.5Vdc, inductance L 1, the effect of diode D1 and electric capacity C1, the terminal voltage of electric capacity C1 is lifted to the amplitude being greater than electric capacity C2 terminal voltage 0.5Vdc, then electric capacity C1, voltage after C2 series connection is necessarily greater than Vdc, be designated as nVdc (2 > n > 1), this voltage is as the input voltage of AC link, Simultaneous Switching pipe S3 high-frequency synchronous with switching tube S4 switches, S7 and S3, S4 complementation switches, achieve the conversion of direct current to alternating voltage.

In the B district of positive half period, the equal high-frequency operation of switching tube pipe S1, S3, S4, S7.

State 1: positive half period-A district-generating

When switching tube S4 conducting, voltage+Upv on electric capacity C2 charges to inductance L f as the input voltage of AC link, electric current flows out from 2 ends of electric capacity C2, successively through diode D3, switching tube S4, inductance L f, electrical network Ug, and then flow into electric capacity C2, now inverter output voltage Vinv (tie point 5 namely in the middle of switching tube S4, S5 and the voltage between reference point 0) is 0.5Vdc, and current direction is shown in Fig. 3.

State 2: positive half period-A district-afterflow

When switching tube S4 turns off, switch S 7 conducting, voltage on electric capacity C2 cannot charge to inductance L f, because inductive current can not suddenly change, electric current is successively through inductance L f, electrical network Ug, diode D5, switching tube S7, diode D8, and then flow into inductance L f, now inverter output voltage Vinv is 0V, and current direction is shown in Fig. 4.

State 3: positive half period-B district-generating

When switching tube S3, S4 conducting, voltage nVdc (voltage namely between 1 and 0) after electric capacity C1 series capacitance C2 charges to inductance L f as the input voltage of AC link, electric current flows out from 1 end of electric capacity C1, successively through switching tube S3, switching tube S4, inductance L f, electrical network Ug, and then flow into electric capacity C2, now inverter output voltage Vinv is nVdc, and current direction is shown in Fig. 5.

State 4: positive half period-B district-afterflow

When switching tube S3, S4 turn off, switch S 7 conducting, voltage on electric capacity C1, C2 cannot charge to inductance L f, because inductive current can not suddenly change, electric current successively through inductance L f, electrical network Ug, diode D5, switching tube S7, diode D8, and then flow into inductance L f, and now inverter output voltage Vinv is 0V, this state is identical with the continuous current circuit in A district, and current direction is shown in Fig. 6.

By four kinds of operating states of positive half period, achieve the switching of inverter voltage between 0V, 0.5Vdc, nVdc.

(2) operating state of negative half-cycle

At the negative half-cycle of electrical network, when the input voltage value of AC link | when-Upv| is greater than line voltage value Ug, as shown in the A district of negative half-cycle in Fig. 2, DC link does not work, switching tube S1, S2 are in off state always, and diode D1, D2 end, and inductance L 1, L2 no current flow through.Output voltage-the Upv of solar generator SG is applied directly on inverse switch pipe S5 through the diode D4 of AC link, by the high-frequency action (such as 20kHz) of switching tube S5, S7, realize the conversion of direct current to alternating voltage, now switching tube S6 is in off state always.

In the A district of negative half-cycle, only have switching tube S5, S7 high-frequency operation, the two complementary conducting, other switching tubes all do not work.

When the input voltage value of AC link | when-Upv| is less than line voltage value Ug, as shown in the B district of negative half-cycle in Fig. 2, DC link works, according to the size of B district line voltage, switching tube S2 high-frequency switches (such as 20kHz), by electric capacity C3 terminal voltage 0.5Vdc, inductance L 3, the effect of diode D3 and electric capacity C4, the terminal voltage of electric capacity C4 is lifted to the amplitude being greater than electric capacity C3 terminal voltage 0.5Vdc, then electric capacity C3, voltage after C4 series connection is for be necessarily greater than Vdc, be designated as nVdc (2 > n > 1), this voltage is as the input voltage of AC link, Simultaneous Switching pipe S5 high-frequency synchronous with switching tube S6 switches, S7 and S5, S6 complementation switches, achieve the conversion of direct current to alternating voltage.

In the B district of negative half-cycle, the equal high-frequency operation of switching tube pipe S2, S5, S6, S7.

State 1: negative half-cycle-A district-generating

When switching tube S5 conducting, voltage-Upv on electric capacity C3 charges to inductance L f as the input voltage of AC link, electric current flows out from 0 end of electric capacity C3, successively through electrical network Ug, inductance L f, switching tube S5, diode D4, and then flow into electric capacity C3, now inverter output voltage Vinv is-0.5Vdc, and current direction is shown in Fig. 7.

State 2: negative half-cycle-A district-afterflow

When switching tube S5 turns off, switch S 7 conducting, voltage on electric capacity C3 cannot charge to inductance L f, because inductive current can not suddenly change, electric current is successively through diode D7, switching tube S7, diode D6, electrical network Ug, and then flow into inductance L f, now inverter output voltage Vinv is 0V, and current direction is shown in Fig. 8.

State 3: negative half-cycle-B district-generating

When switching tube S5, S6 conducting, voltage nVdc (voltages namely between 0 and 4) after electric capacity C3 series capacitance C4 charges to inductance L f as the input voltage of AC link, electric current flows out from 0 end of electric capacity C3, successively through electrical network Ug, inductance L f, switching tube S5, switching tube S6, and then flow into electric capacity C4, now inverter output voltage Vinv is-nVdc, and current direction is shown in Fig. 9.

State 4: negative half-cycle-B district-afterflow

When switching tube S5, S6 turn off, switch S 7 conducting, voltage on electric capacity C3, C4 cannot charge to inductance L f, because inductive current can not suddenly change, electric current successively through diode D7, switching tube S7, diode D6, electrical network Ug, and then flow into inductance L f, and now inverter output voltage Vinv is 0V, this state is identical with the continuous current circuit in A district, and current direction is shown in Figure 10.

By four kinds of operating states of negative half-cycle, achieve the switching of inverter voltage between 0V ,-0.5Vdc ,-nVdc.

So at a grid cycle, inverter output voltage includes-nVdc ,-0.5Vdc, 0V, 0.5Vdc, nVdc five electric pressures, and inverter voltage waveform as shown in Figure 11.

In the A district of positive half cycle, the switching voltage on switching tube S7 is AC link input voltage 0.5Vdc; Switching tube S3 (or A district-S6 of negative half-cycle) does not work, and the switching voltage of switching tube S4 (or A district-S5 of negative half-cycle) is 0.5Vdc.

At positive half cycle in B district, the switching voltage on switching tube S7 is the half of AC link input voltage nVdc, and the switching voltage of S7 is 0.5nVdc; The input voltage nVdc of AC link is shared in switching tube S3, switching tube S4 (or B district-S5, S6 of positive half cycle) series connection, then the switching voltage of S3, S4 (or S5, S6) is 0.5nVdc.So in a switch periods, according to the relation of solar generator SG and line voltage, the switching voltage of B district switching tube S3, S4, S5, S6, S7 is between 0.5Vdc-Vdc.

Relative to the circuit such as full-bridge or half-bridge, the switching voltage of switching tube is always input voltage Vdc, so the switching loss of this five level inverter circuits breaker in middle pipe is relatively little, is conducive to improving conversion efficiency, during Simultaneous Switching action, dv/dt is little, and the electromagnetic interference caused is less.

In the circuit, the mid point of electrical network is connected with the mid point of electric capacity C2, C3, and the common-mode voltage acting on solar panel parasitic capacitance over the ground equals the voltage 0.5Vdc on electric capacity C2, C3, so can not form common mode current.

In this circuit, inverter output voltage waveform is five level, and harmonic content is few, and required filtering inductance is little, is conducive to reducing system cost and power loss.

Claims (7)

1. a level transformerless inverter circuit, its input is solar generator (SG), output is AC network (Ug), it is characterized in that, comprise: inductance L 1 and inductance L 2, one end of inductance L 1 and inductance L 2 is connected with the positive pole of solar generator (SG) and negative pole respectively, the switching tube one (S1) of cross-over connection series connection between the other end of inductance L 1 and inductance L 2 and switching tube two (S2), the another one end of inductance L 1 is also connected with the anode of diode D1, and the other end of inductance L 2 is also connected with the negative electrode of diode D2;

The electric capacity C1 that cross-over connection is connected between the negative electrode and the anode of diode D2 of diode D1, electric capacity C2, electric capacity C3 and electric capacity C4, reference point of potential (0) is drawn between electric capacity C2 and electric capacity C3, this reference point of potential (0) is direct-connected between switching tube one (S1) and switching tube two (S2), circuit between electric capacity C1 and electric capacity C2 and the circuit between electric capacity C3 and electric capacity C4 are connected to the circuit between one end of circuit between one end of inductance L 1 and the positive pole of solar generator (SG) and inductance L 2 and the negative pole of solar generator (SG) respectively,

The switching tube three (S3) that cross-over connection is connected is gone back between the negative electrode and the anode of diode D2 of diode D1, switching tube four (S4), switching tube five (S5) and switching tube six (S6), inverter output voltage point (5) is drawn between switching tube four (S4) and switching tube five (S5), inverter output voltage point (5) is connected with AC network (Ug) via filter circuit, filter circuit is serially connected between inverter output voltage point (5) and reference point of potential (0), reference point of potential (0) is connected with the anode of diode D5 and the negative electrode of diode D6 respectively, the negative electrode of diode D5 is connected with one end of switching tube seven (S7) and the negative electrode of diode D7, the anode of diode D6 is connected with the other end of switching tube seven (S7) and the anode of diode D8, the anode of diode D7 and the negative electrode of diode D8 are connected with inverter output voltage point (5), the anode of diode D3 is connected with the circuit between electric capacity C1 with electric capacity C2, the negative electrode of diode D3 is connected with the circuit between switching tube three (S3) with switching tube four (S4), the negative electrode of diode D4 is connected with the circuit between electric capacity C3 with electric capacity C4, the anode of diode D3 is connected with the circuit between switching tube five (S5) with switching tube six (S6).

2. a kind of five level transformerless inverter circuits as claimed in claim 1, it is characterized in that: described switching tube one (S1), switching tube two (S2), switching tube three (S3), switching tube four (S4), switching tube five (S5), switching tube six (S6), switching tube seven (S7) or the switching transistor for the anti-also diode of inner band, or form after diode inverse parallel by independently switching transistor with independently, or use independently switching transistor.

3. a kind of five level transformerless inverter circuits as claimed in claim 2, is characterized in that: switching transistor is made up of switching device.

4. a kind of five level transformerless inverter circuits as claimed in claim 3, is characterized in that: described switching device or be igbt transistor, or are mosfet transistor group.

5. a kind of five level transformerless inverter circuits as claimed in claim 1, is characterized in that: described filter circuit or be made up of filter inductance and filter capacitor, or are made up of filter inductance.

6. a kind of five level transformerless inverter circuits as claimed in claim 5, is characterized in that: described filtered electrical is perhaps single electric capacity, or is the combination of multiple Capacitance parallel connection.

7. a kind of five level transformerless inverter circuits as claimed in claim 1, it is characterized in that: described electric capacity C1, described electric capacity C2, described electric capacity C3 and described electric capacity C4 or for single electrochemical capacitor, or be the combination of multiple electrochemical capacitor parallel connection, or be the electrochemical capacitor combination in parallel with thin-film capacitor.