CN105991058A - DC/AC conversion device and operation method thereof - Google Patents

Abstract

The present invention relates to a DC/AC conversion device and an operation method thereof. The DC/AC conversion device converts a DC input power supply into a three-phase AC output power supply, and comprises an input capacitor set, a first conversion circuit, a second conversion circuit and a control circuit. The input capacitor set is connected with the DC input power supply and has a neutral point, wherein the neutral point is connected with a first phase sequence of the three-phase AC output power supply. The first conversion circuit is connected with a second phase sequence and a third phase sequence of the three-phase AC output power supply, and the second conversion circuit is connected with the first, second and third phase sequences of the three-phase AC output power supply. The control circuit generates a plurality of control signals, and controls the first and second conversion circuits separately to convert the DC input power supply into the three-phase AC output power supply. The improved DC/AC conversion device of the present invention can achieve the purpose of saving the number of the switches, the output inductor sets and the output capacitor sets via a circuit element of which one phase sequence is simplified.

Description

DC-AC conversion equipment and operational approach thereof

Technical field

The relevant a kind of DC-AC conversion equipment of the present invention and operational approach thereof, espespecially one is applied to the sun The DC-AC conversion equipment of photovoltaic generating system and operational approach thereof.

Background technology

Refer to Fig. 1 Yu Fig. 2 and be respectively the circuit diagram of prior art DC-AC power conversion system with straight The block schematic diagram of the control circuit of stream alternating current power supply converting system.This DC-AC power conversion system system Receive a DC input voitage Sdc, and change this DC input voitage Sdc and export into a three-phase alternating current Voltage Sac.Specifically, this DC-AC power conversion system main body is this three-phase three-leg inverter. As it is shown in figure 1, element numbers is a person, for a phase in three-phase；Element numbers is b person, for three-phase In b phase；In like manner, element numbers is c person, for the c phase in three-phase.

Traditional three-phase three-leg inverter switch element quantity the most own is more, and wherein a phase at least makes With four switch elements, as a example by a phase, use tetra-switch elements of Sa1, Sa2, Sa3 and Sa4. Additionally, this three-phase three-leg inverter controls at corresponding signal control (as shown in Figure 2) and operated , there is the shortcoming that leakage current is bigger in Cheng Zhong.

Therefore, how to design a kind of DC-AC conversion equipment and operational approach thereof, can be by simplifying one The component of phase sequence, reaches the advantage of circuit reduction, and the operation of balancing circuitry of arranging in pairs or groups, accurately Control the half equal to DC input voitage of the cross-pressure on direct current input side two electric capacity, can be greatly reduced The impact of the caused leakage current of parasitic capacitor voltage, be intended to overcome and solve by inventor one Big problem.

Summary of the invention

In order to solve the problems referred to above, the present invention provides a kind of DC-AC conversion equipment, knows skill to overcome The problem of art.DC-AC conversion equipment the most of the present invention, is to change a direct-current input power supplying into one or three Cross streams out-put supply.This DC-AC conversion equipment includes an input capacitance group, one first change-over circuit And one second change-over circuit.This input capacitance group connects this direct-current input power supplying, has a neutral point； Wherein this neutral point connects one first phase sequence of this three-phase alternating current out-put supply, to provide a first path. This first change-over circuit includes one first brachium pontis and one second brachium pontis；Wherein this first brachium pontis has one first Switch on the bridge unit and the one first bridge switch unit being connected in series this first switch on the bridge unit, and even It is connected to one first junction point；This second brachium pontis has one second switch on the bridge unit and is connected in series this second One second bridge switch unit of switch on the bridge unit, and it is connected to one second junction point；Wherein this first Junction point connects one second phase sequence of this three-phase alternating current out-put supply, and to provide one second path, this is second years old Junction point connects a third phase sequence of this three-phase alternating current out-put supply, to provide one the 3rd path.This is second years old Change-over circuit includes one the 3rd brachium pontis and a four bridge legs；Wherein the 3rd brachium pontis has bridge on the 3rd and opens One the 3rd bridge switch unit closing unit and be connected in series the 3rd switch on the bridge unit, has to be formed One first end and one first tandem paths of one second end, and this first end connects this second path；This is years old Four bridge legs has one the 4th switch on the bridge unit and be connected in series the 4th switch on the bridge unit one the 4th time Bridge switch unit, has one second tandem paths of one first end and one second end to be formed, and this first End system connects the 3rd path.Wherein this second end of this first tandem paths connects this second tandem paths This second end, and reconnect this first path.This control circuit produces multiple control signals, controls respectively Make this first change-over circuit and this second change-over circuit, be this three-phase alternating current to change this direct-current input power supplying Out-put supply.

In order to solve the problems referred to above, the present invention provides the operational approach of a kind of DC-AC conversion equipment, with Overcome the problem knowing technology.The operational approach of DC-AC conversion equipment the most of the present invention provides this direct current AC conversion apparatus is to change a direct-current input power supplying into a three-phase alternating current out-put supply.This operational approach bag Include the following step: (a) provides an input capacitance group, connect this direct-current input power supplying, and it is neutral to have one Point；Wherein this neutral point connects one first phase sequence of this three-phase alternating current out-put supply, to provide a first via Footpath；B () provides one first change-over circuit, including one first brachium pontis and one second brachium pontis；Wherein this first Brachium pontis has one first switch on the bridge unit and the one first time bridge being connected in series this first switch on the bridge unit Switch element, and it is connected to one first junction point；This second brachium pontis have one second switch on the bridge unit with It is connected in series one second bridge switch unit of this second switch on the bridge unit, and is connected to one second connection Point；Wherein this first junction point connects one second phase sequence of this three-phase alternating current out-put supply, to provide one Two paths, this second junction point connects a third phase sequence of this three-phase alternating current out-put supply, to provide one Three paths；C () provides one second change-over circuit, including one the 3rd brachium pontis and a four bridge legs；Wherein should 3rd brachium pontis has one the 3rd switch on the bridge unit and is connected in series the one the 3rd of the 3rd switch on the bridge unit Bridge switch unit, has one first tandem paths of one first end and one second end to be formed, and this One end connects this second path；This four bridge legs has one the 4th switch on the bridge unit and is connected in series this One the 4th bridge switch unit of four switch on the bridge unit, has one first end and one second end to be formed One second tandem paths, and this first end system connects the 3rd path；Wherein this first tandem paths should Second end connects this second end of this second tandem paths, and reconnects this first path；And (d) provides One control circuit, produces multiple control signal, controls this first change-over circuit and this second conversion electricity respectively Road, is this three-phase alternating current out-put supply to change this direct-current input power supplying.

The DC-AC conversion equipment that the present invention is improved, can reach by simplifying the component of a phase sequence Purpose to the quantity saving switch, outputting inductance group and output capacitance group.

In order to be able to be further understood that technology, means and effect that the present invention is taked by reaching predetermined purpose, Refer to below in connection with detailed description of the invention and accompanying drawing, it is believed that the purpose of the present invention, feature and feature, Go deep into and concrete understanding when can thus obtain one, but institute's accompanying drawings only provides with reference to and illustrate use, not It is used for the present invention is any limitation as.

Accompanying drawing explanation

Fig. 1 is the circuit diagram of prior art DC-AC power conversion system；

Fig. 2 is the block schematic diagram of the control circuit of prior art DC-AC power conversion system；

Fig. 3 is the circuit diagram of DC-AC conversion equipment preferred embodiment of the present invention；

Fig. 4 A is the block schematic diagram of the control circuit first embodiment of DC-AC conversion equipment of the present invention；

Fig. 4 B is the block schematic diagram of control circuit second embodiment of DC-AC conversion equipment of the present invention；

Fig. 5 is the circuit diagram of the control signal generation circuit of DC-AC conversion equipment of the present invention；

Fig. 6 is the waveform diagram of the control signal of DC-AC conversion equipment of the present invention；

Fig. 7 A is the electric current of the positive half cycle energy storage that DC-AC conversion device operation of the present invention switches in ab phase Path schematic diagram；

Fig. 7 B is that DC-AC conversion device operation of the present invention releases the electric current of energy in the positive half cycle that ab phase switches Path schematic diagram；

Fig. 7 C is the electric current of the negative half period energy storage that DC-AC conversion device operation of the present invention switches in ab phase Path schematic diagram；

Fig. 7 D is that DC-AC conversion device operation of the present invention releases the electric current of energy in the negative half period that ab phase switches Path schematic diagram；

Fig. 8 is the circuit diagram of DC-AC another preferred embodiment of conversion equipment of the present invention；And

Fig. 9 is the flow chart of DC-AC conversion device operation method of the present invention.

Wherein, description of reference numerals is as follows:

Sdc direct-current input power supplying

Sac three-phase alternating current out-put supply

Vp the first DC voltage

Vn the second DC voltage

10 input capacitance groups

11 first change-over circuits

12 second change-over circuits

101 first electric capacity

102 second electric capacity

111 first brachium pontis

112 second brachium pontis

123 the 3rd brachium pontis

124 four bridge legs

2 control circuits

20 control signals produce circuit

201 signals reverse unit

202 first anti-gate cells

203 second anti-gate cells

204 first comparing units

205 second comparing units

21 first arithmetic elements

22 second arithmetic elements

23 balancing circuitrys

231 the 3rd arithmetic elements

232 proportional plus integral control unit

24 the 4th arithmetic elements

25 the 5th arithmetic elements

30 output filter circuits

111U the first switch on the bridge unit

111L the first bridge switch unit

112U the second switch on the bridge unit

112L the second bridge switch unit

123U the 3rd switch on the bridge unit

123L the 3rd bridge switch unit

124U the 4th switch on the bridge unit

124L the 4th bridge switch unit

La1 the first inductance

Lc1 the second inductance

La2 the 3rd inductance

Lc2 the 4th inductance

Ca1 the first electric capacity

Cc1 the second electric capacity

Ca2 the 3rd electric capacity

Cc2 the 4th electric capacity

Po neutral point

P1 the first junction point

P2 the second junction point

Pth1 first path

Pth2 the second path

Pth3 the 3rd path

Ps1 the first tandem paths

Ps2 the second tandem paths

Ph1 the first phase sequence

Ph2 the second phase sequence

Ph3 third phase sequence

T11 the first tandem paths the first end

T12 the first tandem paths the second end

T21 the second tandem paths the first end

T22 the second tandem paths the second end

Va a phase voltage

Vb b phase voltage

Vc c phase voltage

Ia a phase current

Ib b phase current

Ic c phase current

Sa a phase signals

Sb b phase signals

Sc c phase signals

The alternate signal of Sab ab

The alternate signal of Scb cb

Sab ' ab alternate correction signal

Scb ' cb alternate correction signal

Stri triangle carrier signal

S_A1First control signal

S_A2Second control signal

S_A33rd control signal

S_A44th control signal

△ Spn voltage differential signal

Lps positive half cycle tank circuit

The positive half cycle of Lpr is released can loop

Lns negative half period tank circuit

Lnr negative half period is released can loop

T0～the t2 time

S10～S40 step

Cp1, Cp2 parasitic capacitance

Icp1, Icp2 leakage current

Detailed description of the invention

The technical content and a detailed description for the present invention, coordinate graphic being described as follows:

Refer to the circuit diagram that Fig. 3 is DC-AC conversion equipment preferred embodiment of the present invention.The present invention should DC-AC conversion equipment is to change a direct-current input power supplying Sdc into a three-phase alternating current out-put supply Sac. This DC-AC conversion equipment includes input capacitance group 10,1 first change-over circuit 11,1 second conversion Circuit 12 and a control circuit 2.This input capacitance group 10 includes one first electric capacity 101 and one second Electric capacity 102, this first electric capacity 101 and this second electric capacity 102 are connected in series and receive this direct current input electricity Source Sdc.Wherein this first electric capacity 101 is connected to neutral point Po with this second electric capacity 102, to maintain The cross-pressure of this first electric capacity 101 and the second electric capacity 102 is respectively equal to this direct-current input power supplying Sdc to be provided The half of a DC input voitage.Wherein, these the first electric capacity 101 two ends across voltage swing be one First DC voltage Vp；These the second electric capacity 102 two ends across voltage swing be one second DC voltage Vn。

This three-phase alternating current out-put supply Sac has three phase sequences, respectively one first phase sequence Ph1, one Two phase sequences Ph2 and third phase sequence Ph3.For convenience of explanation, with this first phase sequence Ph1 correspondence one B phase voltage Vb, corresponding a phase voltage Va of this second phase sequence Ph2, and this third phase sequence Ph3 pair Answer c phase voltage Vc.But, it is in full a three-phase with this three-phase alternating current out-put supply Sac due to this case Illustrate as a example by balance electric source, therefore, the phase corresponding to three phase sequences of this three-phase alternating current out-put supply Sac Voltage is not with above-described embodiment for limiting.Being worth mentioning, it is defeated that this neutral point Po connects this three-phase alternating current Go out this first phase sequence Ph1 of power supply Sac, that is this neutral point Po connects this b phase voltage Vb, to carry For first path Pth1.

This first change-over circuit 11 includes one first brachium pontis 111 and one second brachium pontis 112.Wherein this first Brachium pontis 111 has one first switch on the bridge unit 111U and is connected in series this first switch on the bridge unit The one first bridge switch unit 111L of 111U, and this first switch on the bridge unit 111U with this first Bridge switch unit 111L is commonly connected to one first junction point P1.This second brachium pontis 112 has one Two switch on the bridge unit 112U and the one second time bridge being connected in series this second switch on the bridge unit 112U are opened Close unit 112L, and this second switch on the bridge unit 112U and this second bridge switch unit 112L is altogether With being connected to one second junction point P2.Furthermore, this first junction point P1 connects this three-phase alternating current output electricity This second phase sequence Ph2 of source Sac, that is this first junction point P1 connects this phase voltage Va, to carry For one second path P th2.This second junction point P2 connect this three-phase alternating current out-put supply Sac this Three phase sequences Ph3, that is this second junction point P2 connects this c phase voltage Vc, to provide one the 3rd path Pth3。

This second change-over circuit 12 includes one the 3rd brachium pontis 123 and a four bridge legs 124.Wherein the 3rd Brachium pontis 123 has one the 3rd switch on the bridge unit 123U and is connected in series the 3rd switch on the bridge unit One the 3rd bridge switch unit 123L of 123U, has one first end T11 and one second end T12 to be formed One first tandem paths Ps1, and this first end T11 connects this second path P th2.This four bridge legs 124 have one the 4th switch on the bridge unit 124U and are connected in series the 4th switch on the bridge unit 124U's One the 4th bridge switch unit 124L, has one first end T21 and the one of one second end T22 to be formed Second tandem paths Ps2, and this first end T21 connects the 3rd path P th3.Additionally, this first string This second end T12 of connection path P s1 connects this second end T22 of this second tandem paths Ps2, and again Connect this first path Pth1.

This control circuit 2 produces multiple control signal, control respectively this first change-over circuit 11 with this second Change-over circuit 12, to reduce the leakage current that the parasitic capacitance effect of this DC input voitage is caused.

Be worth mentioning, in this DC-AC conversion equipment framework of this case, this first change-over circuit 11 this One brachium pontis 111 is substantially to should the 3rd brachium pontis 123 of the second change-over circuit 12 configure, to should The identical phase sequence of three-phase alternating current out-put supply Sac, for above-described embodiment, i.e. to should a phase voltage The a phase brachium pontis framework of Va.In like manner, this second brachium pontis 112 of this first change-over circuit 11 is substantially To should this four bridge legs 124 of the second change-over circuit 12 configure, to should three-phase alternating current out-put supply The identical phase sequence of Sac, for above-described embodiment, i.e. to should the c phase brachium pontis framework of c phase voltage Vc.

Additionally, this DC-AC conversion equipment also includes an output filter circuit 30.This output filter circuit 30 include one first outputting inductance group, one second outputting inductance group, one first output capacitance group and 1 Two output capacitance groups.This first outputting inductance group includes one first electricity being connected in this second path P th2 Sense La1 and the one second inductance Lc1 being connected in the 3rd path P th3.This second outputting inductance group bag Include one the 3rd inductance La2 that is connected in this second path P th2 and be connected in the 3rd path P th3 One the 4th inductance Lc2.Wherein this first inductance La1 is connected in series the 3rd inductance La2, and this is second years old Inductance Lc1 is connected in series the 4th inductance Lc2.

This first output capacitance group includes one first electric capacity Ca1 and the company being connected in this second path P th2 The one second electric capacity Cc1 being connected in the 3rd path P th3.This second output capacitance group includes being connected to this One the 3rd electric capacity Ca2 in second path P th2 and one the 4th electricity being connected in the 3rd path P th3 Hold Cc2.

In addition to the aforementioned circuit framework to the present invention proposes explanation, this circuit framework is also carried by the present invention Go out the control strategy of correspondence.Refer to the control circuit that Fig. 4 A is DC-AC conversion equipment of the present invention The block schematic diagram of one embodiment.

This case control strategy is controlled based on two alternate reference signals.It is described as follows: As a example by the circuit framework shown in Fig. 3, that is, this first phase sequence Ph1 this b phase voltage Vb corresponding Directly it is connected with this neutral point Po of direct current input side by this first path Pth1.Therefore, above-mentioned institute Meaning refers to be different from based on two alternate reference signals knows the circuit framework of technology use with each phase Signal Sa, based on Sb, Sc, under this case circuit framework, an an ab alternate signal Sab and cb is alternate Signal Scb is converted to multiple control signal and is used (being detailed later) providing as reference signal.Wherein should Ab alternate signal Sab is that a phase signals subtracts each other gained with b phase signals, that is, Sab=Sa-Sb；This cb Alternate signal Scb is that c phase signals subtracts each other gained with b phase signals, that is, Scb=Sc-Sb.It follows that If the circuit framework that this case is used is: this second phase sequence Ph2 this phase voltage Va corresponding is directly led to Cross this second path P th2 when being connected with this neutral point Po of direct current input side, the reference signal used It is then an a ba alternate signal Sba and ca alternate signal Sca.In like manner understand, if the electricity that this case is used Road framework is: this third phase sequence Ph3 this c phase voltage Vc corresponding is directly by the 3rd path P th3 When being connected with this neutral point Po of direct current input side, the reference signal used is then an alternate signal of ac A Sac and bc alternate signal Sbc.So, during the circuit framework difference used, relatively, just need Coordinate corresponding alternate signal to provide this to be converted to multiple control signal as reference signal to be used.

Refer to Fig. 4 A again, this control framework will flow through the most respectively this second path P th2, this first Path P th1 and an a phase current ia of the 3rd path P th3, a b phase current ib and a c phase Electric current ic is through conversion, to produce every phase signals, that is, this phase signals Sa, this b phase signals Sb And this c phase signals Sc.More specifically, this control framework of this case is by by this three-phase current ia, ib, ic Carry out changing and computing in the way of biphase coordinate (d-q axle), to simplify the complexity of control flow, and And again by biphase coordinates translation is returned three-phase coordinate, each phase signals, that is this so will be can get Phase signals Sa, this b phase signals Sb and this c phase signals Sc.Owing to d-q axle switch technology is electric power Coordinates translation technology common in system conversion, does not therefore repeat them here.

It is worth mentioning, under this circuit framework of this case, and non-immediate carries as reference signal using every phase signals It is used for being converted to multiple control signal, but by this phase signals Sa with this b phase signals Sb with input One first arithmetic element 21, performs this phase signals Sa by this first arithmetic element 21 and deducts this b phase The computing of signal Sb, to produce this ab alternate signal Sab.In like manner, this c signal Sc believes with this b Number Sb, to input one second arithmetic element 22, performs this c phase signals by this second arithmetic element 22 Sc deducts the computing of this b phase signals Sb, to produce this cb alternate signal Scb.So, obtained should Ab alternate signal Sab and this cb alternate signal Scb inputs to a control signal generation circuit 20 again, and And by carrying out computing with a triangle carrier signal Stri, to produce in order to control this first change-over circuit 11 Multiple control signals (being detailed later) with those switch elements of this second change-over circuit 12.

Refer to the square of control circuit the second embodiment that Fig. 4 B is DC-AC conversion equipment of the present invention Schematic diagram.This second embodiment and the first embodiment maximum difference shown in Fig. 4 A are this control circuit 2 Also include balancing circuitry 23, the 4th arithmetic element 24 and one the 5th arithmetic element 25.This balance Circuit 23 includes one the 3rd arithmetic element 231 and a proportional plus integral control unit (PI controller) 232. 3rd arithmetic element 231 receives this first DC voltage Vp and this second unidirectional current of direct current input side Pressure Vn, performs this first DC voltage Vp by the 3rd arithmetic element 231 and deducts this second unidirectional current The computing of pressure Vn, to produce the voltage difference between this two DC voltage.Further, then by this proportional integral Control unit 232 carries out proportional integral computing to this voltage difference, to produce a stable voltage differential signal △ Spn。

4th arithmetic element 24 receives this ab alternate signal Sab and this voltage differential signal △ Spn, performs This ab alternate signal Sab deducts the computing of this voltage differential signal △ Spn, to produce an alternate correction of ab Signal Sab '.In like manner, the 5th arithmetic element 25 receives this cb alternate signal Scb and this voltage difference Signal △ Spn, performs this cb alternate signal Scb and deducts the computing of this voltage differential signal △ Spn, to produce A raw cb alternate correction signal Scb '.In other words, by this balancing circuitry 23 by this direct current input side The voltage difference of this first DC voltage Vp and this second DC voltage Vn carry out computing and conversion after, institute Produce this voltage differential signal △ Spn and be the compensation dosage of the balance between two voltages.And again by the 4th Arithmetic element 24 and the calculating of the 5th arithmetic element 25, be bound to the alternate letter of this ab by this compensation dosage Number Sab and this cb alternate signal Scb, this ab obtained alternate correction signal Sab ' is alternate with this cb Revise signal Scb ' as reference signal, it is provided that multiple control signals of conversion gained are to this first conversion Circuit 11 is controlled with this second change-over circuit 12, to maintain this first electric capacity 101 and this second electricity Hold the cross-pressure of 102, that is this first DC voltage Vp is equal to more accurately with this second DC voltage Vn The half of this DC input voitage.

Refer to the control signal that Fig. 5 is DC-AC conversion equipment of the present invention and produce the circuit diagram of circuit. This control signal produces circuit 20 and includes an anti-gate cell 202, of signals reverse unit 201,1 first Second anti-gate cell 203,1 first comparing unit 204 and one second comparing unit 205.This first ratio Relatively unit 204 has an inverting input, a non-inverting input and an outfan.This is noninverting defeated Entering end and receive an ab alternate signal Sab, this inverting input receives a triangle carrier signal Stri, and this is defeated Go out end output one first control signal S_A1.And this outfan connects this first anti-gate cell 202 with defeated Go out one the 3rd control signal S_A3.That is, this first control signal S_A1With the 3rd control signal S_A3For The high frequency switching signal that level is complementary.Wherein this triangle carrier signal Stri is a high-frequency carrier signal.

This second comparing unit 205 has an inverting input, a non-inverting input and an outfan. This non-inverting input connects this signals reverse unit 201 and receives this ab alternate signal Sab again, and this is anti-phase Input receives this triangle carrier signal Stri, this outfan output one second control signal S_A2.And should Outfan connects this second anti-gate cell 203 to export one the 4th control signal S_A4.That is, this is second years old Control signal S_A2With the 4th control signal S_A4For the high frequency switching signal that level is complementary.

Being worth mentioning, this non-inverting input of this first comparing unit 204 above-mentioned receives an alternate letter of ab Number Sab echoes in being initially mentioned: the circuit framework that this case is used is corresponding to this first phase sequence Ph1 This b phase voltage Vb is directly connected with this neutral point Po of direct current input side by this first path Pth1 Time, the reference signal used is then for this ab alternate signal Sab and this cb alternate signal Scb.Change speech It, under this circuit framework, during to perform a circuitry phase switching control, this first comparing unit 204 This non-inverting input then receive this ab alternate signal Sab so that this control signal produce circuit 20 Those control signals S corresponding to generation_A1～S_A4.In like manner, under this circuit framework, to perform c During circuitry phase switching control, it is alternate that this non-inverting input of this first comparing unit 204 then receives this cb Signal Scb so that this control signal produces circuit 20 and produces those corresponding control signals SC1～SC4. As for the operating instruction of this DC-AC conversion equipment, by hereinafter there being detailed elaboration.

Refer to the waveform diagram of the control signal that Fig. 6 is DC-AC conversion equipment of the present invention.Hold Described, for convenience of explanation with explanation, Fig. 6 will be should corresponding to this first phase sequence Ph1 with circuit framework B phase voltage Vb is directly connected with this neutral point Po of direct current input side by this first path Pth1, and And to perform the reference signal that used of a circuitry phase switching control be to be said as a example by this ab alternate signal Sab Bright.Specifically, this control signal produces circuit 20 is this ab alternate signal Sab according to reference signal This first control signal S produced_A1Control this first switch on the bridge unit of this first change-over circuit 11 111U, the 3rd control signal S_A3Control the 3rd switch on the bridge unit of this second change-over circuit 12 123U, this second control signal S_A2Control this first bridge switch unit of this first change-over circuit 11 111L and the 4th control signal S_A4Control the 3rd bridge switch list of this second change-over circuit 12 Unit 123L.

Produce circuit 20 as this control signal to be produced by this cb alternate signal Scb according to reference signal Those control signals SC1～SC4 control this second switch on the bridge of this first change-over circuit 11 with correspondence On the 4th of unit 112U and this second bridge switch unit 112L and this second change-over circuit 12 Bridge switch unit 124U and the 4th bridge switch unit 124L.This part operation illustrates, due to action Principle is little with execution a circuitry phase switching control difference, therefore refers to its explanation, does not repeats them here.

Referring to Fig. 6 again, when this alternate signal Sab is positive half cycle (time t0～t1 are interval), this is first years old Control signal S_A1Threeth control signal S complementary with level_A3For high frequency switching signal, this second control Signal S_A2It is a low level signal and the 4th control signal S_A4It it is a high level signal.Wherein this One control signal S_A1With the 3rd control signal S_A3For pulse width modulating signal (PWM signal).Value Obtaining one to carry, the switching frequency (switching frequency) of this pulse width modulating signal carries equal to this triangle The frequency of ripple signal Stri.

(time t1～t2 is interval), this second control signal S when this alternate signal Sab is negative half period_A2With The 4th control signal S that level is complementary_A4For high frequency switching signal, this first control signal S_A1It is one low Level signal and the 3rd control signal S_A3It it is a high level signal.Wherein this second control signal S_A2 With the 4th control signal S_A4For pulse width modulating signal (PWM signal).It is worth mentioning, this pulse The switching frequency (switching frequency) of the bandwidth modulation signals frequency equal to this triangle carrier signal Stri Rate.

Referring to Fig. 7 A is the positive half cycle energy storage that DC-AC conversion device operation of the present invention switches in ab phase Current path schematic diagram.Under this alternate signal Sab is the operation of positive half cycle, this first control signal S_A1 For high frequency switched conductive this first switch on the bridge unit 111U, the 3rd control signal S_A3High frequency switching cuts Only the 3rd switch on the bridge unit 123U, this second control signal S_A2End this first bridge switch unit 111L and the 4th control signal S_A4Turn on the 3rd bridge switch unit 123L, and this first electricity Sense La1 and the 3rd inductance La2 is stored energy operation, and therefore, this DC-AC conversion equipment is just providing one Half cycle tank circuit Lps be sequentially this direct-current input power supplying Sdc, this first switch on the bridge unit 111U, This first inductance La1, the 3rd inductance La2, this phase voltage Va, this b phase voltage Vb, this neutrality Point Po, this second electric capacity 102, return this direct-current input power supplying Sdc.

The positive half cycle switched in ab phase release can current path schematic diagram.When this alternate signal Sab is just half Under week operation, this first control signal S_A1For high frequency switching cut-off this first switch on the bridge unit 111U, 3rd control signal S_A3High frequency switched conductive the 3rd switch on the bridge unit 123U, this second control letter Number S_A2End this first bridge switch unit 111L and the 4th control signal S_A4Turn on the 3rd time Bridge switch unit 123L, and this first inductance La1 and the 3rd inductance La2 can operate for releasing, therefore, This DC-AC conversion equipment provides a positive half cycle to release and can be sequentially this first inductance La1, is somebody's turn to do by loop Lpr 3rd inductance La2, this phase voltage Va, this b phase voltage Vb, the 3rd bridge switch unit 123L, 3rd switch on the bridge unit 123U, returns this first inductance La1.

Referring to Fig. 7 C is the negative half period energy storage that DC-AC conversion device operation of the present invention switches in ab phase Current path schematic diagram.Under alternate signal Sab is negative half period operation, this second control signal S_A2 For high frequency switched conductive this first bridge switch unit 111L, the 4th control signal S_A4High frequency switching cuts Only the 3rd bridge switch unit 123L, this first control signal S_A1End this first switch on the bridge unit 111U and the 3rd control signal S_A3Turn on the 3rd switch on the bridge unit 123U, and this first Inductance La1 and the 3rd inductance La2 is stored energy operation, and therefore, this DC-AC conversion equipment provides one Negative half period tank circuit Lns is sequentially this direct-current input power supplying Sdc, this first electric capacity 101, this neutral point Po, this b phase voltage Vb, this phase voltage Va, the 3rd inductance La2, this first inductance La1, should First bridge switch unit 111L, returns this direct-current input power supplying Sdc.

Referring to Fig. 7 D is that the negative half period that DC-AC conversion device operation of the present invention switches in ab phase releases energy Current path schematic diagram.Under alternate signal Sab is negative half period operation, this second control signal S_A2 For high frequency switching cut-off this first bridge switch unit 111L, the 4th control signal S_A4High frequency switching is led Logical 3rd bridge switch unit 123L, this first control signal S_A1End this first switch on the bridge unit 111U and the 3rd control signal S_A3Turn on the 3rd switch on the bridge unit 123U, and this first Inductance La1 and the 3rd inductance La2 can operate for releasing, and therefore, this DC-AC conversion equipment provides one Negative half period is released can loop Lnr be sequentially the 3rd inductance La2, this first inductance La1, bridge is opened on the 3rd Close unit 123U, the 3rd bridge switch unit 123L, this b phase voltage Vb, this phase voltage Va, Return the 3rd inductance La2.

Refer to the circuit diagram that Fig. 8 is DC-AC another preferred embodiment of conversion equipment of the present invention.Fig. 8 The circuit topography of this DC-AC conversion equipment shown is substantially identical with this preferred embodiment shown in Fig. 3, In other words, element or the unit of the identical label of Fig. 8 with Fig. 3 are substantially the same, therefore by this another relatively The circuit of good embodiment, can reach circuit function as indicated in fig. 3 and effect equally.Should as Fig. 8 The operating instruction of circuit does not repeats them here, can be corresponding refering to Fig. 3 itself and the elaboration of description.

Refer to the flow chart that Fig. 9 is DC-AC conversion device operation method of the present invention.This DC-AC Conversion equipment is to change a direct-current input power supplying into a three-phase alternating current out-put supply.Under this operational approach includes Row step: first, it is provided that an input capacitance group, connects this direct-current input power supplying, and has a neutral point； Wherein this neutral point connects one first phase sequence of this three-phase alternating current out-put supply, to provide a first path (S10).Wherein this input capacitance group includes one first electric capacity and one second electric capacity, this first electric capacity with this Two capacitances in series connect and receive this direct-current input power supplying.Wherein this first electric capacity is connected with this second electric capacity In this neutral point, to maintain the cross-pressure of this first electric capacity and the second electric capacity to be respectively equal to this direct-current input power supplying The half of the DC input voitage provided.Wherein, these the first electric capacity two ends across voltage swing be One first DC voltage；These the second electric capacity two ends across voltage swing be one second DC voltage.

Then, it is provided that one first change-over circuit, including one first brachium pontis and one second brachium pontis；Wherein this One brachium pontis has one first switch on the bridge unit and be connected in series this first switch on the bridge unit one first time Bridge switch unit, and it is connected to one first junction point；This second brachium pontis has one second switch on the bridge unit Be connected in series one second bridge switch unit of this second switch on the bridge unit, and be connected to one second even Contact；Wherein this first junction point connects one second phase sequence of this three-phase alternating current out-put supply, to provide one Second path, this second junction point connects a third phase sequence of this three-phase alternating current out-put supply, to provide one 3rd path (S20).

Then, it is provided that one second change-over circuit, including one the 3rd brachium pontis and a four bridge legs；Wherein this Three brachium pontis have one the 3rd switch on the bridge unit and be connected in series the 3rd switch on the bridge unit one the 3rd time Bridge switch unit, has one first tandem paths of one first end and one second end to be formed, and this first End connects this second path；This four bridge legs has one the 4th switch on the bridge unit and is connected in series the 4th One the 4th bridge switch unit of switch on the bridge unit, has one first end and the one of one second end to be formed Second tandem paths, and this first end connects the 3rd path；Wherein this first tandem paths this second End connects this second end of this second tandem paths, and reconnects this first path (S30).

Finally, it is provided that a control circuit, produce multiple control signal, control this first change-over circuit respectively With this second change-over circuit, it is this three-phase alternating current out-put supply stream (S40) to change this direct-current input power supplying.

Additionally, this operational approach also includes providing an output filter circuit.This output filter circuit includes one First outputting inductance group, one second outputting inductance group, one first output capacitance group and one second output electricity Appearance group.This first outputting inductance group includes one first inductance being connected on this second path and is connected to this One second inductance on 3rd path.This second outputting inductance group includes be connected on this second path one 3rd inductance and one the 4th inductance being connected on the 3rd path.Wherein this first inductance is connected in series this 3rd inductance, this second inductance is connected in series the 4th inductance.

This first output capacitance group includes one first electric capacity being connected on this second path and is connected to this One second electric capacity on three paths.This second output capacitance group includes one be connected on this second path Three electric capacity and one the 4th electric capacity being connected on the 3rd path.

Furthermore, control circuit also includes a balancing circuitry, one the 4th arithmetic element and one the 5th computing list Unit.This balancing circuitry includes one the 3rd arithmetic element and a proportional plus integral control unit.3rd computing list Unit receives this first DC voltage and this second DC voltage, perform this first DC voltage deduct this second The computing of DC voltage, to produce a voltage difference.This proportional plus integral control unit receives this voltage difference, holds The proportional integral computing of this voltage difference of row, to produce a voltage differential signal.4th arithmetic element receives should The alternate signal of ab and this voltage differential signal, perform the alternate signal of this ab and deduct this voltage differential signal, to produce A raw ab alternate correction signal.5th arithmetic element receives the alternate signal of this cb and this voltage differential signal, Perform the alternate signal of this cb and deduct this voltage differential signal, to produce a cb alternate correction signal.Wherein should Ab alternate correction signal and this cb alternate correction signal produce circuit to input this control signal, to produce Those control signals, it is provided that conversion gained multiple control signals to this first change-over circuit with this second turn Change circuit to be controlled, to maintain the cross-pressure of this first electric capacity and this second electric capacity, that is this first direct current Voltage and this second DC voltage are more accurately equal to the half of this DC input voitage.

In sum, the present invention has following feature and an advantage:

1, the DC-AC conversion equipment that the present invention is improved is utilized, can be by simplifying the circuit elements of a phase sequence Part, reaches to save switch, outputting inductance group and the quantity of output capacitance group；And

2, by the design of this first change-over circuit Yu this second change-over circuit, it is achieved this outputting inductance group Energy storage can operate with releasing, and the operation of this balancing circuitry 23 of arranging in pairs or groups, by this direct current input side this first After the voltage difference of DC voltage Vp and this second DC voltage Vn carries out computing and changes, produced this electricity Pressure difference signal △ Spn is the compensation dosage of the balance between two voltages, to maintain this first electric capacity 101 and to be somebody's turn to do The cross-pressure of the second electric capacity 102, that is this first DC voltage Vp is more accurate with this second DC voltage Vn Ground, equal to the half of this DC input voitage, so can be greatly reduced the caused leakage of parasitic capacitor voltage The impact of electric current.

The above, the detailed description of preferred embodiment the most of the present invention with graphic, the spy of the present invention Levying and be not limited thereto, and be not used to limit the present invention, all scopes of the present invention should be with following right Claimed range is as the criterion, the embodiment of all spirit changes similar with it meeting the claims in the present invention, all should It is included in scope of the invention, any is familiar with the personnel of this technology in the field of the invention, can be light Easily think and change or modify and all can contain the scope of the claims in following this case.

Claims (20)

1. a DC-AC conversion equipment, to change a direct-current input power supplying into a three-phase alternating current output electricity Source；It is characterized in that, this DC-AC conversion equipment includes:

One input capacitance group, connects this direct-current input power supplying, and has a neutral point；Wherein this neutral point Connect one first phase sequence of this three-phase alternating current out-put supply, to provide a first path；

One first change-over circuit, including one first brachium pontis and one second brachium pontis；Wherein this first brachium pontis has One first switch on the bridge unit and the one first bridge switch list being connected in series this first switch on the bridge unit Unit, and it is connected to one first junction point；This second brachium pontis has one second switch on the bridge unit and the company of series connection Connect one second bridge switch unit of this second switch on the bridge unit, and be connected to one second junction point；Its In this first junction point connect one second phase sequence of this three-phase alternating current out-put supply, to provide one second path, This second junction point connects a third phase sequence of this three-phase alternating current out-put supply, to provide one the 3rd path；

One second change-over circuit, including one the 3rd brachium pontis and a four bridge legs；Wherein the 3rd brachium pontis has One the 3rd switch on the bridge unit and one the 3rd bridge switch list being connected in series the 3rd switch on the bridge unit Unit, to form one first tandem paths with one first end and one second end, and the connection of this first end should Second path；This four bridge legs has one the 4th switch on the bridge unit and is connected in series the 4th switch on the bridge One the 4th bridge switch unit of unit, to form one second series connection with one first end and one second end Path, and this first end connects the 3rd path；Wherein this second end connection of this first tandem paths should This second end of second tandem paths, and reconnect this first path；And

One control circuit, produces multiple control signal, control respectively this first change-over circuit with this second turn Change circuit, be this three-phase alternating current out-put supply to change this direct-current input power supplying.

2. DC-AC conversion equipment as claimed in claim 1, it is characterised in that also include:

One output filter circuit, including:

One first outputting inductance group, including one first inductance being connected on this second path be connected to this One second inductance on 3rd path；

One second outputting inductance group, including one the 3rd inductance being connected on this second path be connected to this One the 4th inductance on 3rd path；Wherein this first inductance is connected in series the 3rd inductance, this second electricity Sense is connected in series the 4th inductance；

One first output capacitance group, including one first electric capacity being connected on this second path be connected to this One second electric capacity on 3rd path；And

One second output capacitance group, including one the 3rd electric capacity being connected on this second path be connected to this One the 4th electric capacity on 3rd path.

3. DC-AC conversion equipment as claimed in claim 2, it is characterised in that this control circuit is extremely Including that a control signal produces circuit less, this control signal produces circuit and includes:

One signals reverse unit；

One first anti-gate cell；

One second anti-gate cell；

One first comparing unit, has an inverting input, a non-inverting input and an outfan； This non-inverting input receives an alternate signal, and this inverting input receives a triangle carrier signal；This is defeated Go out end output one first control signal, and this outfan connects this first anti-gate cell with output one the 3rd Control signal；Wherein this triangle carrier signal is a high-frequency carrier signal；And

One second comparing unit, has an inverting input, a non-inverting input and an outfan； This non-inverting input connects this signals reverse unit and receives this alternate signal again, and this inverting input receives This triangle carrier signal；This outfan output one second control signal, and this outfan connect this second Anti-gate cell is to export one the 4th control signal.

4. DC-AC conversion equipment as claimed in claim 3, it is characterised in that when this exchange exports When alternate power supply is positive half cycle, this first control signal is high frequency with the 3rd control signal of level complementation Switching signal, this second control signal are a low level signal and the 4th control signal is a high level Signal；This exchange exports alternate power supply when being negative half period, this complementary with level of this second control signal the Four control signals be high frequency switching signal, this first control signal be a low level signal and the 3rd control Signal processed is a high level signal.

5. DC-AC conversion equipment as claimed in claim 4, it is characterised in that when this three-phase alternating current Exporting alternate power supply is the operation of positive half cycle, this this first switch on the bridge of the first control signal high frequency switched conductive Unit, the 3rd control signal high frequency switching cut-off the 3rd switch on the bridge unit, this second control signal End this first bridge switch unit and time the 4th control signal turns on the 3rd bridge switch unit, This first inductance and the 3rd inductance are stored energy operation, and this DC-AC conversion equipment provides a positive half cycle storage Can loop be sequentially this direct-current input power supplying, this first switch on the bridge unit, this first inductance, the 3rd Inductance, a phase voltage of this three-phase alternating current out-put supply, the b phase voltage of this three-phase alternating current out-put supply, This neutral point and this second electric capacity are constituted.

6. DC-AC conversion equipment as claimed in claim 4, it is characterised in that when this three-phase alternating current Exporting alternate power supply is the operation of positive half cycle, this first control signal be high frequency switching cut-off this on first bridge open Close unit, the 3rd control signal high frequency switched conductive the 3rd switch on the bridge unit, this second control letter Number ending this first bridge switch unit and the 4th control signal turns on the 3rd bridge switch unit Time, this first inductance and the 3rd inductance can operate for releasing, and this DC-AC conversion equipment offer one is just partly Release in week can loop be sequentially this first inductance, the 3rd inductance, this three-phase alternating current out-put supply a phase electric Bridge on pressure, the b phase voltage of this three-phase alternating current out-put supply, the 3rd bridge switch unit and the 3rd Switch element is constituted.

7. DC-AC conversion equipment as claimed in claim 4, it is characterised in that when this three-phase alternating current Exporting alternate power supply is negative half period operation, and this second control signal is that this first time bridge of high frequency switched conductive is opened Close unit, the 4th control signal high frequency switching cut-off the 3rd bridge switch unit, this first control letter Number ending this first switch on the bridge unit and the 3rd control signal turns on the 3rd switch on the bridge unit Time, this first inductance and the 3rd inductance are stored energy operation, and this DC-AC conversion equipment provides one negative half Week tank circuit to be sequentially this direct-current input power supplying, this first electric capacity, this neutral point, this three-phase alternating current defeated Go out the b phase voltage of power supply, a phase voltage of this three-phase alternating current out-put supply, the 3rd inductance, this first Inductance and this first bridge switch unit are constituted.

8. DC-AC conversion equipment as claimed in claim 4, it is characterised in that when this three-phase alternating current Exporting alternate power supply is negative half period operation, and this second control signal is that high frequency switching this first time bridge of cut-off is opened Close unit, the 4th control signal high frequency switched conductive the 3rd bridge switch unit, this first control letter Number ending this first switch on the bridge unit and the 3rd control signal turns on the 3rd switch on the bridge unit Time, this first inductance and the 3rd inductance can operate for releasing, this DC-AC conversion equipment provide one negative partly Release in week can loop be sequentially the 3rd inductance, this first inductance, the 3rd switch on the bridge unit, the 3rd Bridge switch unit, the b phase voltage of this three-phase alternating current out-put supply and this three-phase alternating current out-put supply A phase voltage is constituted.

9. DC-AC conversion equipment as claimed in claim 3, it is characterised in that this alternate signal by Each phase signals subtracts each other generation；The one alternate signal of ab be an a phase signals deduct one b phase signals produce, one The alternate signal of cb is that a c phase signals deducts the generation of this b phase signals.

10. the DC-AC conversion equipment as described in claim 9, it is characterised in that this control electricity Road also includes:

One balancing circuitry, including:

One the 3rd arithmetic element, receives this first DC voltage and this second DC voltage, perform this first DC voltage deducts the computing of this second DC voltage, to produce a voltage difference；And

One proportional plus integral control unit, receives this voltage difference, performs the proportional integral computing of this voltage difference, To produce a voltage differential signal；

One the 4th arithmetic element, receives the alternate signal of this ab and this voltage differential signal, performs this ab alternate Signal deducts this voltage differential signal, to produce an ab alternate correction signal；And

One the 5th arithmetic element, receives the alternate signal of this cb and this voltage differential signal, performs this cb alternate Signal deducts this voltage differential signal, to produce a cb alternate correction signal；

Wherein this ab alternate correction signal and this cb alternate correction signal produce electricity to input this control signal Road, to produce described control signal.

The operational approach of 11. 1 kinds of DC-AC conversion equipments, this DC-AC conversion equipment is to change one Direct-current input power supplying is a three-phase alternating current out-put supply, it is characterised in that this operational approach includes following step Rapid:

A () provides an input capacitance group, connect this direct-current input power supplying, and have a neutral point；Wherein This neutral point connects one first phase sequence of this three-phase alternating current out-put supply, to provide a first path；

B () provides one first change-over circuit, including one first brachium pontis and one second brachium pontis；Wherein this first Brachium pontis has one first switch on the bridge unit and the one first time bridge being connected in series this first switch on the bridge unit Switch element, and it is connected to one first junction point；This second brachium pontis have one second switch on the bridge unit with It is connected in series one second bridge switch unit of this second switch on the bridge unit, and is connected to one second connection Point；Wherein this first junction point connects one second phase sequence of this three-phase alternating current out-put supply, to provide one Two paths, this second junction point connects a third phase sequence of this three-phase alternating current out-put supply, to provide one Three paths；

C () provides one second change-over circuit, including one the 3rd brachium pontis and a four bridge legs；Wherein the 3rd Brachium pontis has one the 3rd switch on the bridge unit and one the 3rd time bridge being connected in series the 3rd switch on the bridge unit Switch element, to form one first tandem paths with one first end and one second end, and this first end Connect this second path；This four bridge legs has one the 4th switch on the bridge unit and is connected in series on the 4th One the 4th bridge switch unit of bridge switch unit, has the one the of one first end and one second end to be formed Two tandem paths, and this first end connects the 3rd path；Wherein this second end of this first tandem paths Connect this second end of this second tandem paths, and reconnect this first path；And

D () provides a control circuit, produce multiple control signal, control respectively this first change-over circuit with This second change-over circuit, is this three-phase alternating current out-put supply to change this direct-current input power supplying.

The operational approach of 12. DC-AC conversion equipments as claimed in claim 11, it is characterised in that Also include:

One output filter circuit is provided, including:

One first outputting inductance group, including one first inductance being connected on this second path be connected to this One second inductance on 3rd path；

One second outputting inductance group, including one the 3rd inductance being connected on this second path be connected to this One the 4th inductance on 3rd path；Wherein this first inductance is connected in series the 3rd inductance, this second electricity Sense is connected in series the 4th inductance；

One first output capacitance group, including one first electric capacity being connected on this second path be connected to this One second electric capacity on 3rd path；And

One second output capacitance group, including one the 3rd electric capacity being connected on this second path be connected to this One the 4th electric capacity on 3rd path.

The operational approach of 13. DC-AC conversion equipments as claimed in claim 12, it is characterised in that This control circuit at least includes that a control signal produces circuit, and this control signal produces circuit and includes:

One signals reverse unit；

One first anti-gate cell；

One second anti-gate cell；

One first comparing unit, has an inverting input, a non-inverting input and an outfan； This non-inverting input receives an alternate signal, and this inverting input receives a triangle carrier signal；This is defeated Go out end output one first control signal, and this outfan connects this first anti-gate cell with output one the 3rd Control signal；Wherein this triangle carrier signal is a high-frequency carrier signal；And

One second comparing unit, has an inverting input, a non-inverting input and an outfan； This non-inverting input connects this signals reverse unit and receives this alternate signal again, and this inverting input receives This triangle carrier signal；This outfan output one second control signal, and this outfan connect this second Anti-gate cell is to export one the 4th control signal.

The operational approach of 14. DC-AC conversion equipments as claimed in claim 13, it is characterised in that When this exchange alternate power supply of output is positive half cycle, the 3rd control that this first control signal is complementary with level Signal processed be high frequency switching signal, this second control signal be that a low level signal and the 4th controls letter Number it is a high level signal；When this exchange alternate power supply of output is negative half period, this second control signal and electricity The 4th flat complementary control signal be high frequency switching signal, this first control signal be a low level signal And the 3rd control signal be a high level signal.

The operational approach of 15. DC-AC conversion equipments as claimed in claim 14, it is characterised in that Being the operation of positive half cycle when this three-phase alternating current exports alternate power supply, this first control signal high frequency switched conductive should First switch on the bridge unit, the 3rd control signal high frequency switching end the 3rd switch on the bridge unit, are somebody's turn to do Second control signal ends this first bridge switch unit and the 4th control signal turns on the 3rd time bridge During switch element, this first inductance and the 3rd inductance are stored energy operation, and this DC-AC conversion equipment carries For a positive half cycle tank circuit be sequentially this direct-current input power supplying, this first switch on the bridge unit, this first Inductance, the 3rd inductance, a phase voltage of this three-phase alternating current out-put supply, this three-phase alternating current out-put supply B phase voltage, this neutral point and this second electric capacity constituted.

The operational approach of 16. DC-AC conversion equipments as claimed in claim 14, it is characterised in that Being the operation of positive half cycle when this three-phase alternating current exports alternate power supply, this first control signal is high frequency switching cut-off This first switch on the bridge unit, the 3rd control signal high frequency switched conductive the 3rd switch on the bridge unit, This second control signal ends this first bridge switch unit and the 4th control signal turns on the 3rd time During bridge switch unit, this first inductance and the 3rd inductance can operate for releasing, this DC-AC conversion equipment There is provided a positive half cycle to release and can be sequentially this first inductance, the 3rd inductance, this three-phase alternating current output electricity in loop The a phase voltage in source, the b phase voltage of this three-phase alternating current out-put supply, the 3rd bridge switch unit and 3rd switch on the bridge unit is constituted.

The operational approach of 17. DC-AC conversion equipments as claimed in claim 14, it is characterised in that Being negative half period operation when this three-phase alternating current exports alternate power supply, this second control signal is high frequency switched conductive This first bridge switch unit, the 4th control signal high frequency switching cut-off the 3rd bridge switch unit, This first control signal ends this first switch on the bridge unit and the 3rd control signal turns on the 3rd During bridge switch unit, this first inductance and the 3rd inductance are stored energy operation, this DC-AC conversion equipment A negative half period tank circuit is provided to be sequentially this direct-current input power supplying, this first electric capacity, this neutral point, be somebody's turn to do The b phase voltage of three-phase alternating current out-put supply, a phase voltage of this three-phase alternating current out-put supply, the 3rd electricity Sense, this first inductance and this first bridge switch unit are constituted.

The operational approach of 18. DC-AC conversion equipments as claimed in claim 14, it is characterised in that Being negative half period operation when this three-phase alternating current exports alternate power supply, this second control signal is high frequency switching cut-off This first bridge switch unit, the 4th control signal high frequency switched conductive the 3rd bridge switch unit, This first control signal ends this first switch on the bridge unit and the 3rd control signal turns on the 3rd During bridge switch unit, this first inductance and the 3rd inductance can operate for releasing, this DC-AC conversion equipment There is provided a negative half period to release and can be sequentially the 3rd inductance, this first inductance, the 3rd switch on the bridge list in loop Unit, the 3rd bridge switch unit, the b phase voltage of this three-phase alternating current out-put supply and this three-phase alternating current The a phase voltage of out-put supply is constituted.

The operational approach of 19. DC-AC conversion equipments as claimed in claim 13, it is characterised in that This alternate signal is subtracted each other generation by each phase signals；The one alternate signal of ab is that an a phase signals deducts a b and believes Number produce, an alternate signal of cb be a c phase signals deduct this b phase signals produce.

The operational approach of 20. DC-AC conversion equipments as claimed in claim 19, it is characterised in that This control circuit also includes:

One balancing circuitry, including:

One the 3rd arithmetic element, receives this first DC voltage and this second DC voltage, perform this first DC voltage deducts the computing of this second DC voltage, to produce a voltage difference；And

One proportional plus integral control unit, receives this voltage difference, performs the proportional integral computing of this voltage difference, To produce a voltage differential signal；

One the 4th arithmetic element, receives the alternate signal of this ab and this voltage differential signal, performs this ab alternate Signal deducts this voltage differential signal, to produce an ab alternate correction signal；And

One the 5th arithmetic element, receives the alternate signal of this cb and this voltage differential signal, performs this cb alternate Signal deducts this voltage differential signal, to produce a cb alternate correction signal；

Wherein this ab alternate correction signal and this cb alternate correction signal produce electricity to input this control signal Road, to produce described control signal.