CN207083025U - A kind of T-shaped translation circuit and corresponding three-phase translation circuit and converting means - Google Patents

Abstract

The utility model discloses a kind of T-shaped translation circuit and corresponding three-phase translation circuit and converting means.In T-shaped translation circuit, by adding an inductance, four diodes and two electric capacity in the T-shaped translation circuit of prior art, so that gate-controlled switch device and diode component can realize Sofe Switch, the power consumption of power device and diode component is reduced.Using the converting means of above-mentioned T-shaped translation circuit, the component increased newly in component of the prior art and the technical program is combined into circuit module, improvement cost is greatly reduced in the case of so as to be laid out in the internal wiring for not changing existing inversion/fairing substantially, topological structure is compact, busbar design is simple, extremely advantageous in electrical layout and structure design.

Description

A kind of T-shaped translation circuit and corresponding three-phase translation circuit and converting means

Technical field

It the utility model is related to field of conversion of electrical energy, and in particular to a kind of T-shaped translation circuit.

Background technology

In the prior art, the translation circuit of T-shaped layout is widely used.The translation circuit of T-shaped layout generally comprises two Individual vertically arranged gate-controlled switch device and two gate-controlled switch devices laterally set；Two vertically arranged gate-controlled switch devices Part is connected in series, one end connection positive bus-bar, other end connection negative busbar；Company between two vertically arranged gate-controlled switch devices Input/output terminal of the contact as translation circuit；Two gate-controlled switch devices laterally set are generally located on middle bridge arm, One end of middle bridge arm is connected to input/output terminal, and the another of middle bridge arm is connected to center line.Two gate-controlled switches laterally set Connected mode of the device on middle bridge arm typically has two kinds of series connection and parallel connection, and wherein parallel way is as shown in Figure 1.Wherein, may be used Control switching device includes the fly-wheel diode that IGBT is managed and is connected with the IGBT pipe inverse parallels.The electricity of T types three of the prior art Flat translation circuit is compared to double level-conversion circuits, with single IGBT pipes blocking voltage halves, harmonic wave is small, loss is low, efficiency High advantage.

In T-shaped three level-conversion circuit, the power consumption of each IGBT pipes can be divided into on-state power consumption, break-make power consumption, wherein logical Disconnected power consumption can separate logical stage power consumption and off-phases power consumption again.When working frequency is relatively low, on-state power consumption is main；But When working frequency is higher, break-make power consumption then rises to main power consumption, wherein opening stage power dissipation ratio off-phases power consumption also It is big.Therefore, in the case of higher operating frequencies, it is necessary to realize " Sofe Switch ", so-called " Sofe Switch " refers to gate-controlled switch Device can realize ZVT (ZVS), Zero Current Switch (ZCS) or zero-voltage and zero-current switch (ZVZXCS), either Curtage is risen by limited slope in make and break process.If Sofe Switch can not be realized, problems with occurs：

1st, power device (gate-controlled switch device) loss is big；And cause power device temperature to rise, not only make working frequency It can not improve, and the electric current of power device, voltage capacity are also unable to reach rating index, make power device can not be in specified bar Run under part, so as to restrict the application of three-level topology；

2nd, power device is easily secondary breakdown；Under the conditions of inductive load, there is peak voltage in power device when turning off；And Under the conditions of capacitive load, peak current when power device is opened be present；So as to easily lead to second breakdown, work(is greatly endangered The safe operation of rate device so that need to design larger safety operation area (SOA)；

3rd, larger EMI electromagnetic interferences are produced；When high-frequency work state is run, the parasitic electricity of the interpolar of power device in itself Appearance is particularly important parameter.This interelectrode capacity can produce two kinds of unfavorable factors in the switching process of power device：(1) exist When being opened under high voltage, the energy storage of interpolar parasitic capacitance is absorbed and dissipated in itself by device, certainly will produce temperature rise, and frequency gets over high temperature Rise more serious；(2) dv/dt can be coupled to output end during interelectrode capacity voltage conversion, produce electromagnetic interference, make system unstable It is fixed.In addition, interelectrode capacity can produce vibration, interference system normal work with the stray inductance in circuit；

4th, cause circuit topology very sensitive to the parasitic parameter of power device；When Sofe Switch can not be realized, Ke Nengcun Problem is led directly in upper and lower bridge arm, and due to Sofe Switch can not be realized, open time delay (dead time) also be present in power device, And at high frequencies, for influence of the deadband eliminating time to inverter performance, the corrective action taken make again be entirely The design of system becomes complicated；

5th, need to design absorbing circuit, when absorbing circuit is for limiting di/dt and the shut-off when power device is opened Dv/dt, dynamic switch track is narrowed down in the SOA of direct current place of safety, ensure power device can safe operation, but absorbing circuit Switching loss can not be eliminated, and adds the design difficulty of whole converting means again, while can also result in energy regeneration Fly-wheel diode Reverse recovery and interfering for absorbing circuit cause larger stresses of parts in journey；

6th, power device can produce noise pollution in HF switch, therefore can cause translation circuit to inputting, exporting filter The requirement of ripple device is higher.

6 problems based on more than, there is an urgent need to realize the Sofe Switch of T-shaped three level-conversion circuit.

Utility model content

The purpose of this utility model is solve the problems of the prior art, there is provided a kind of T-shaped translation circuit and corresponding Three-phase translation circuit and converting means, so that power device can realize that Sofe Switch works, so as to reduce power device and diode The power consumption of device, and solve problems of the prior art.

To reach above-mentioned purpose, the utility model adopts the following technical scheme that：

A kind of T-shaped translation circuit, including the first gate-controlled switch device, the second gate-controlled switch device, the 3rd gate-controlled switch device Part, the 4th gate-controlled switch device, inductance, the first diode, the second diode, the 3rd diode, the 4th diode, the five or two pole Pipe, the 6th diode, the first electric capacity and the second electric capacity；First gate-controlled switch device and the connection of the 4th gate-controlled switch devices in series, The drain electrode of first gate-controlled switch device or colelctor electrode connection positive bus-bar, source electrode or the emitter stage connection of the 4th gate-controlled switch device are negative Bus；Tie point between first gate-controlled switch device and the 4th gate-controlled switch device is as input/output terminal；Second controllable opens Pass device and the 3rd gate-controlled switch device are in parallel again after being concatenated respectively with the 5th diode and the 6th diode to form middle bridge arm, One end of described middle bridge arm is connected to input/output terminal, another one end for terminating to inductance of middle bridge arm, inductance it is another It is connected to center line；Wherein, the drain electrode of the second described gate-controlled switch device or colelctor electrode are connected to input/output terminal or described The source electrode or emitter stage of second gate-controlled switch device are connected to inductance；The drain electrode of the 3rd described gate-controlled switch device or colelctor electrode connect Source electrode or emitter stage to inductance or the 3rd described gate-controlled switch device are connected to input/output terminal；The first described diode Concatenated with the second diode, the negative electrode of the first diode is connected to positive bus-bar, and the anode of the second diode is connected to inductance and intermediate axle The tie point of arm, the described end of the first electric capacity one are connected to the tie point of the first diode and the second diode, it is another be connected to it is defeated Enter output end；The 3rd described diode and the 4th diode concatenation, the anode of the 4th diode are connected to negative busbar, the three or two pole The negative electrode of pipe is connected to the anode of the 6th diode；The described end of the second electric capacity one is connected to the company of the 3rd diode and the 4th diode Contact, another negative electrode for being connected to the 6th diode.

In one embodiment, on middle bridge arm, the source electrode or emitter stage of the second gate-controlled switch device are connected to inductance, the The drain electrode of two gate-controlled switch devices or colelctor electrode are connected with the negative electrode of the 5th diode, and it is defeated that the anode of the 5th diode is connected to input Go out end；The drain electrode of 3rd gate-controlled switch device or colelctor electrode are connected to inductance, the source electrode or emitter stage of the 3rd gate-controlled switch device with The anode connection of 6th diode, the negative electrode of the 6th diode are connected to input/output terminal.

In a second embodiment, on middle bridge arm, the negative electrode of the 5th diode is connected to inductance, the anode of the 5th diode with Source electrode or the emitter stage connection of second gate-controlled switch device, the drain electrode of the second gate-controlled switch device or colelctor electrode are connected to input and output End；The anode of 6th diode is connected to inductance, the negative electrode of the 6th diode and drain electrode or the colelctor electrode of the 3rd gate-controlled switch device Connection, the source electrode or emitter stage of the 3rd gate-controlled switch device are connected to input/output terminal.

Further, the first described gate-controlled switch device or the 4th described gate-controlled switch device using IGBT units or MOS cell, when using IGBT units, described IGBT units include two poles that IGBT is managed and is connected with IGBT pipe inverse parallels Pipe；When using MOS cell, described MOS cell can be for the metal-oxide-semiconductor with body diode or including the MOS without body diode Pipe and anti-paralleled diode.

Further, the second described gate-controlled switch device or the 3rd described gate-controlled switch device using IGBT units or MOS cell, when using IGBT units, described IGBT units include two poles that IGBT is managed and is connected with IGBT pipe inverse parallels Pipe；When using MOS cell, described MOS cell can be for the metal-oxide-semiconductor with body diode or including the MOS without body diode Pipe and anti-paralleled diode.

A kind of three-phase translation circuit, including the first translation circuit, the second translation circuit, the 3rd translation circuit；Described One translation circuit, the second translation circuit and the 3rd translation circuit use above-mentioned any T-shaped translation circuit；First conversion electricity The center line of the center line on road, the center line of the second translation circuit and the 3rd translation circuit is connected with each other.

A kind of converting means, using the T-shaped translation circuit of one embodiment, wherein, the first diode, the two or two pole Pipe, the second gate-controlled switch device, the 5th diode and the first electric capacity are integrated and are arranged to the first circuit module；The first described circuit The first end of module connects the negative electrode of the first diode, for being connected to positive bus-bar；Second end of the first described circuit module connects The anode of the second diode is connect, for being connected to inductance；The sun of the diode of three-terminal link the 5th of the first described circuit module Pole, for being connected to input/output terminal.

A kind of converting means, using the T-shaped translation circuit of one embodiment, wherein, the 3rd diode, the four or two pole Pipe, the 3rd gate-controlled switch device, the 6th diode and the second electric capacity are integrated and are arranged to second circuit module；Described second circuit 4th end of module connects the anode of the 4th diode, for being connected to negative busbar；5th end of described second circuit module connects Drain electrode or the colelctor electrode of the 3rd gate-controlled switch device are connect, for being connected to inductance；The six end connecting of described second circuit module The negative electrode of 6th diode, for being connected to input/output terminal.

A kind of converting means, using the T-shaped translation circuit of second embodiment, wherein, the first diode, the two or two pole Pipe, the second gate-controlled switch device, the 5th diode and the first electric capacity are integrated and are arranged to tertiary circuit module；Described tertiary circuit 7th end of module connects the negative electrode of the first diode, and for being connected to positive bus-bar, the 8th end of described tertiary circuit module connects The anode of the second diode is connect, for being connected to inductance；9th end of described tertiary circuit module connects the second gate-controlled switch device The drain electrode of part or colelctor electrode, for being connected to input/output terminal.

A kind of converting means, using the T-shaped translation circuit of second embodiment, wherein, the 3rd diode, the four or two pole Pipe, the 3rd gate-controlled switch device, the 6th diode and the second electric capacity are integrated and are arranged to the 4th circuit module；The 4th described circuit Tenth end of module connects the anode of the 4th diode, for being connected to negative busbar, the tenth one end of the 4th described circuit module The anode of the 6th diode is connected, for being connected to inductance；The 12nd end connection the 3rd of the 4th described circuit module is controllable to open The source electrode or emitter stage of device are closed, for being connected to input/output terminal.

Technical scheme described in the utility model is relative to prior art, the beneficial effect of acquirement：

1st, in the T-shaped translation circuit in the utility model, all gate-controlled switch devices and diode component can be realized soft Switch, i.e. ZVT (ZVS), Zero Current Switch (ZCS) or zero-voltage and zero-current switch (ZVZCS), or with limited dv/ Dt and di/dt carries out break-make switching.So as to significantly reduce the switching losses of gate-controlled switch device, translation circuit is improved Operating efficiency；Make power device be not easy to be secondary breakdown, while be eliminated dead time；

2nd, gate-controlled switch device carries out break-make switching with limited dv/dt and di/dt, thus system EMI electromagnetic interferences compared with Unrealized Sofe Switch will optimize much；

3rd, because the switching losses of gate-controlled switch device diminish so that converting means can exponentially work in conventional transformation On device working frequency, therefore output filter parameter request step-down needed for converting means, size can also reduce at double, from And be advantageous to further reduce Material Cost, reduction product size, improve product power density；

4th, compare and an inductance, four diodes and two electric capacity are merely add in prior art, the utility model, increase Add number of devices few, simple and compact structure, it is not necessary to extra increase gate-controlled switch device and control circuit；

5th, using the three-phase translation circuit of above-mentioned T-shaped translation circuit, it is likewise supplied with the effect above.

6th, it is arranged to circuit by will be combined component of the prior art with the component increased newly in the technical program Module, the technical program can be realized in the case where the internal wiring for not changing existing inversion/fairing substantially is laid out, greatly Improvement cost is reduced greatly, topological structure is compact, and busbar design is simple, extremely advantageous in electrical layout and structure design.

Brief description of the drawings

Accompanying drawing described herein is used for providing further understanding utility model, forms one of the present utility model Point, schematic description and description of the present utility model is used to explain the utility model, does not form to of the present utility model Improper restriction.In the accompanying drawings：

Fig. 1 is circuit diagram of the prior art；

Fig. 2 is the circuit diagram of the embodiment one of T-shaped translation circuit in the utility model；

Fig. 3 is the circuit diagram of the embodiment two of T-shaped translation circuit in the utility model；

Fig. 4 is that the embodiment one of the T-shaped translation circuit of the utility model carries out DC/AC conversion, and inverter output voltage is just half Vertical tube is to the operating diagram before the transverse tube change of current during cycle；

Fig. 5 is that the embodiment one of the T-shaped translation circuit of the utility model carries out DC/AC conversion, and inverter output voltage is just half First stage operating diagram of the vertical tube to the transverse tube change of current during cycle；

Fig. 6 is that the embodiment one of the T-shaped translation circuit of the utility model carries out DC/AC conversion, and inverter output voltage is just half Second stage operating diagram of the vertical tube to the transverse tube change of current during cycle；

Fig. 7 is that the embodiment one of the T-shaped translation circuit of the utility model carries out DC/AC conversion, and inverter output voltage is just half Transverse tube is to the operating diagram before the vertical tube change of current during cycle；

Fig. 8 is that the embodiment one of the T-shaped translation circuit of the utility model carries out DC/AC conversion, and inverter output voltage is just half Operating diagram of the transverse tube to the phase III of the vertical tube change of current during cycle；

Fig. 9 is that the embodiment one of the T-shaped translation circuit of the utility model carries out DC/AC conversion, and inverter output voltage is just half Operating diagram of the transverse tube to the fourth stage of the vertical tube change of current during cycle；

Figure 10 is that the embodiment one of the T-shaped translation circuit of the utility model carries out AC/DC conversion, and AC-input voltage is just half Vertical tube is to the operating diagram before the transverse tube change of current during cycle；

Figure 11 is that the embodiment one of the T-shaped translation circuit of the utility model carries out AC/DC conversion, and AC-input voltage is just half First stage operating diagram of the vertical tube to the transverse tube change of current during cycle；

Figure 12 is that the embodiment one of the T-shaped translation circuit of the utility model carries out AC/DC conversion, and AC-input voltage is just half Second stage operating diagram of the vertical tube to the transverse tube change of current during cycle；

Figure 13 is that the embodiment one of the T-shaped translation circuit of the utility model carries out AC/DC conversion, and AC-input voltage is just half Transverse tube is to the operating diagram before the vertical tube change of current during cycle；

Figure 14 is that the embodiment one of the T-shaped translation circuit of the utility model carries out AC/DC conversion, and AC-input voltage is just half Operating diagram of the transverse tube to the vertical tube change of current during cycle；

Figure 15 is the circuit diagram of the embodiment of three-phase translation circuit in the utility model；

Figure 16 is the schematic diagram of the embodiment one of converting means in the utility model；

Figure 17 is the schematic diagram of the embodiment two of converting means in the utility model.

Embodiment

In order that technical problem to be solved in the utility model, technical scheme and beneficial effect are clearer, clear, with Under in conjunction with the accompanying drawings and embodiments, the utility model is further elaborated.It is it should be appreciated that described herein specific real Example is applied only to explain the utility model, is not used to limit the utility model.

Fig. 2 shows the circuit diagram of the embodiment one of T-shaped translation circuit in the utility model.It is as shown in Fig. 2 T-shaped The embodiment two that hydrocarbon changes circuit includes the first gate-controlled switch device, the second gate-controlled switch device, the 3rd gate-controlled switch device, Four gate-controlled switch devices, inductance L, the first diode D1, the second diode D2, the 3rd diode D3, the 4th diode D4, the 5th Diode D5, the 6th diode D6, the first electric capacity C1, the second electric capacity C2, the 3rd polar capacitor C3 and quadripolarity electric capacity C4.

Wherein, the first gate-controlled switch device uses IGBT units, including the first IGBT pipes Q1 and is connected with its inverse parallel First sustained diode q1；Second gate-controlled switch device uses IGBT units, including the 2nd IGBT pipes Q2 and connects with its inverse parallel The the second sustained diode q2 connect；3rd gate-controlled switch device uses IGBT units, including the first IGBT pipes Q3 and anti-with it The 3rd sustained diode q3 being connected in parallel；4th gate-controlled switch device uses IGBT units, including the 4th IGBT pipes Q4 and with 4th sustained diode q4 of its inverse parallel connection.

First IGBT pipes Q1 and the 4th IGBT pipes Q4 are connected in series, the first IGBT pipes Q1 colelctor electrode connection positive bus-bar, the Four IGBT pipes Q4 emitter stage connection negative busbar.The colelctor electrode connection of first IGBT pipes Q1 emitter stage and the 4th IGBT pipes Q4, Tie point is as input/output terminal.

2nd IGBT pipes Q2 and the 3rd IGBT pipes Q3 concatenated respectively with the 5th diode D5 and the 6th diode D6 after again simultaneously Connection forms middle bridge arm, and an end of described middle bridge arm is connected to input/output terminal, and the another of middle bridge arm is connected to inductance L's One end.The another of inductance L is connected to center line.On middle bridge arm, the 2nd IGBT pipes Q2 emitter stage is connected to inductance L, the 2nd IGBT Pipe Q2 colelctor electrode is connected with the 5th diode D5 negative electrode, and the 5th diode D5 anode is connected to input/output terminal；3rd IGBT pipes Q3 colelctor electrode is connected to inductance, and the 3rd IGBT pipes Q3 emitter stage is connected with the 6th diode D6 anode, and the six or two Pole pipe D6 negative electrode is connected to input/output terminal.

First diode D1 and the second diode D2 concatenations, the first diode D1 negative electrode are connected to positive bus-bar, the two or two pole Pipe D2 anode is connected to the tie point of inductance L and middle bridge arm；A first electric capacity C1 end is connected to the first diode D1 and second Diode D2 tie point, first the another of electric capacity C1 are connected to input/output terminal.

3rd diode D3 and the 4th diode D4 concatenations, the 4th diode D4 anode are connected to negative busbar, the three or two pole Pipe D3 negative electrode is connected to the 2nd IGBT pipes Q2 emitter stage；The ends of second electric capacity C2 mono- are connected to the 3rd diode D3 and the four or two pole Pipe D4 tie point, the second electric capacity C2 another colelctor electrode for being connected to the 2nd IGBT pipes.

3rd polar capacitor C3 positive pole connects positive bus-bar, and negative pole connects center line；Quadripolarity electric capacity C4 positive pole connects center line, bears Pole connects negative busbar.

In the present embodiment, gate-controlled switch device can also use MOS cell, and when using MOS cell, described MOS is mono- Member can be for the metal-oxide-semiconductor with body diode or including the metal-oxide-semiconductor and anti-paralleled diode without body diode.

When the embodiment one of T-shaped translation circuit works in inversion, including inverter output voltage is positive half period and inversion Output voltage two half periods of curved negative half-cycle, each half period are divided into vertical tube to the transverse tube change of current and transverse tube to the vertical tube change of current two again Individual process：

When inverter output voltage is positive half period, vertical tube is as follows to transverse tube commutation course：

Fig. 4 shows vertical tube to the state before the transverse tube change of current.Vertical tube is to before the transverse tube change of current, the first IGBT pipes Q1 and the 3rd IGBT pipes Q3 is in the conduction state, and the 2nd IGBT pipes Q2 and the 4th IGBT pipes Q4 are in cut-off state.Now, electric current is through first IGBT pipes Q1 flow direction load Z, and and because of the topological feature of circuit, although the 3rd IGBT pipes Q3 is in the no electric current of normally open By.Now, it is zero that the first electric capacity C1 voltages, which are clamped, and the first electric capacity C1 is in no-voltage discharge condition.Due to the first IGBT Pipe Q1 is turned on, therefore the second electric capacity C2 is charged to Vdc states.Now, it is zero by inductance L electric current.

The working condition of Fig. 5 shows vertical tube into transverse tube commutation course first stage.In the first phase, the 3rd IGBT Pipe Q3 is tended to remain on, and the 4th IGBT pipes Q4 keeps cut-off state, and the first IGBT pipes Q1 then goes to cut-off from conducting state State, the 2nd IGBT pipes Q2 then go to conducting state from cut-off state.As shown in figure 5, in the first IGBT pipes Q1 cut-offs, second During IGBT pipes Q2 is turned on, the second electric capacity C2 is discharged by the 4th diode D4 to load Z.At the same time, the second electric capacity C2 is charged by the 4th diode D4, the 5th diode D5, the 2nd IGBT pipes Q2 to inductance L.Due to the electricity on the second electric capacity C2 Pressure is that the voltage being gradually discharged to the zero, therefore the first IGBT pipes Q1 in turn off process is established with limited speed dV/dt, Load Z electric current is provided by the second electric capacity C2.Therefore, the first IGBT pipes Q1 is that no-voltage mode turns off, and turn-off power loss is very small, Belong to typical Sofe Switch process.Simultaneously as inductance L presence, the electric current by the 2nd IGBT pipes Q2 is equally with limited Speed di/dt is increased, and therefore, the 2nd IGBT pipes are that zero current mode turns on, and conduction loss is very small, and same category is typical soft Switching process.

Fig. 6 shows the working condition of vertical tube second stage into transverse tube commutation course.After the completion of first stage, the four or two Pole pipe D4 and the 5th diode D5 cut-offs, by inductance L electric current vanishing again, while the 4th sustained diode q4 starts Afterflow turns on.Z output levels clamper is loaded in-Vdc/2 level.Inductance L is opened by the 6th diode D6 and the 3rd IGBT pipes Q3 Beginning energy storage.And inductance L electric current is started from scratch linearly increasing, at the same time, the electric current by the 4th sustained diode q4 is year-on-year Example is reduced.After the electric current by the 4th sustained diode q4 is reduced to zero, commutation course is completed.After the completion of second stage Four sustained diode q4 end.

It is all in the 2nd IGBT pipes Q2, the 3rd IGBT pipes Q3 and the 6th diode D6, the pole of the 4th afterflow two in said process Curent change in pipe Dq4 is carried out with limited current changing rate di/dt, so in this process, the 2nd IGBT Pipe Q2 and the 3rd IGBT pipes Q3 and the above other devices are all operated in Sofe Switch state.At the same time, the 4th diode D4's is continuous Stream process is equally with limited current changing rate di/dt on or off, therefore, also belongs to Sofe Switch, can be notable Reduce D4 conduction loss.

When inverter output voltage is positive half period, transverse tube is as follows to vertical tube commutation course：

Fig. 7 shows inverter output voltage when being positive half period, and vertical tube is to the state after the transverse tube change of current, or perhaps transverse tube State to before the vertical tube change of current.For transverse tube to before the vertical tube change of current, the first IGBT pipes Q1 and the 4th IGBT pipes Q4 are in cut-off state, and Two IGBT pipes Q2 and the 3rd IGBT pipes Q3 are in the conduction state.Now, electric current is from inductance L, the 6th diode D6 and the 3rd IGBT Pipe Q3 flow direction loads Z.Although the 2nd IGBT pipes are in the conduction state, pass through without electric current.By inductance L electric current and process The electric current for loading Z is equal.

The working condition of Fig. 8 shows transverse tube into vertical tube commutation course phase III.In the phase III, the 3rd IGBT Pipe Q3 is tended to remain on, and the 4th IGBT pipes Q4 keeps cut-off state, and the first IGBT pipes Q1 then goes to conducting from cut-off state State, the 2nd IGBT pipes Q2 then go to cut-off state from conducting state.As shown in figure 8, in the first IGBT pipes Q1 conductings, second During IGBT pipes Q2 ends, upper half busbar voltage passes through the first IGBT pipes Q1, the 6th diode D6, the 3rd Q3 pairs of IGBT pipes Inductance L reversely pressurizes, and forces inductance L electric current linearly to reduce.At the same time, upper half bus by the first IGBT pipes Q1 to load Z establishes current supply circuit.Above-mentioned two loop is simultaneously deposited, and is worked simultaneously.As the electric current for flowing through inductance L gradually decreases, load current To the loop transition for flowing through the first IGBT pipes Q1.When the electric current for flowing through inductance L is kept to zero, the 6th diode D6 reversely ends, Because the 2nd IGBT pipes end, therefore middle bridge arm is no longer turned on.

In the first IGBT pipe Q1 turn on process, due to inductance L carry load electric currents, and electric current is in the first IGBT pipes Q1 It can not be mutated in turn on process, therefore be with limited current changing rate di/dt foundation by the first IGBT pipes Q1 electric current , therefore the first IGBT pipes Q1 turn on process is the Sofe Switch course of work.And the 2nd IGBT pipes Q2 is gone to from conducting state There is no electric current to flow through during cut-off state, fall within Sofe Switch mode of operation.

Fig. 9 shows the working condition of transverse tube fourth stage into vertical tube commutation course.After the completion of phase III, second is continuous Stream diode Dq2 reversely ends, the 3rd polar capacitor C3, the first IGBT pipes Q1, the second electric capacity C2, the 3rd diode D3, the 3rd Sustained diode q3 and inductance L composition resonance circuits, charge to the second electric capacity C2.Due to inductance L be present, as the second electric capacity C2 When to charge to voltage be Vdc, the 3rd sustained diode q3 and the 3rd diode D3 reversely end, and charging and commutation course are completed, Return to the state that electric current flows to load Z through the first IGBT pipes Q1, i.e., the state shown in Fig. 4.

In the second electric capacity C2 charging processes, the 3rd diode D3 and the 3rd sustained diode q3 are with limited electric current Rate of change di/dt turn on and cut-off, therefore, the 3rd diode D3 and the 3rd sustained diode q3 conducting and procedures of turn-off Middle switching loss is very low, belongs to Sofe Switch mode of operation.

Change of current when commutation course and inverter output voltage when inverter output voltage is negative half-cycle are positive half period Journey is similar, and vertical tube is equally required for undergoing two stages to the transverse tube change of current or transverse tube to the vertical tube change of current, will not be described in detail herein.

When translation circuit works in rectification, including AC-input voltage is positive half period and AC-input voltage is negative half Two half periods of cycle, each half period are divided into vertical tube to the transverse tube change of current and transverse tube to two processes of the vertical tube change of current again：

When AC-input voltage is positive half period, vertical tube is as follows to transverse tube commutation course：

Figure 10 shows vertical tube to state before the transverse tube change of current.Vertical tube is to before the transverse tube change of current, the first IGBT pipes Q1 and the 3rd IGBT pipes Q3 is in the conduction state, and the 2nd IGBT pipes Q2 and the 4th IGBT pipes Q4 are in cut-off state.Rectified current is continuous from first Stream diode Dq1 flows to bus.3rd IGBT pipes Q3 is turned on but passed through without electric current.First electric capacity C1 is in no-voltage electric discharge State.Second electric capacity C2 is charged to Vdc states, and now inductance L electric current is zero.

Figure 11 shows vertical tube to the working condition of transverse tube commutation course first stage.In the first stage, the 3rd IGBT is managed Q3 is tended to remain on, and the 4th IGBT pipes Q4 keeps cut-off state.And the first IGBT pipes Q1 then goes to cut-off shape from conducting state State, the 2nd IGBT pipes Q2 then go to conducting state from cut-off state.As shown in figure 11, in the process, the 3rd electric capacity C3 both ends Voltage inductance L both ends are added to by the first sustained diode q1, the 5th diode D5, the 2nd IGBT pipes Q2.Due to electricity Feel L presence, start from scratch by the electric current of middle bridge arm linearly increasing；At the same time, by the first sustained diode q1's Electric current is linearly reduced, until increasing to rectified current by inductance L electric current, now the first sustained diode q1 ends.

Due to the first sustained diode q1 presence, the process that the first IGBT pipes Q1 goes to cut-off from conducting belongs to zero electricity Pressure, zero-current switching.Due to inductance L presence, the 2nd IGBT pipes Q2 from cut-off go to conducting during electric current be linearly to increase Add, therefore the 2nd IGBT pipes Q2 turn on process belongs to zero current passing.Both of which is typical Sofe Switch process.

Figure 12 shows that vertical tube is hard up for money the working condition of stream process second stage to transverse tube.After the completion of first stage, first Sustained diode q1 ends, and the second electric capacity C2 passes through the 2nd IGBT pipes Q2, the 4th diode D4, the 5th diode D5 and inductance L starts to discharge.After discharging into zero.Second stage is completed.

When AC-input voltage is positive half period, transverse tube is as follows to vertical tube commutation course：

Figure 13 show vertical tube terminate to transverse tube commutation course after state, that is to say transverse tube to the shape before the vertical tube change of current State.Now, the second electric capacity C2 electric discharges terminate, and rectified current is carried by the 5th diode D5, the 2nd IGBT pipes Q2 and inductance L.The One IGBT pipes Q1 and the 4th IGBT pipes Q4 is in cut-off state, and the 2nd IGBT pipes Q2 and the 3rd IGBT pipes Q3 are in the conduction state. Wherein, the 3rd IGBT pipes Q3 is although in the conduction state but no electric current flows through.And the first electric capacity C1 and the second electric capacity C2 locate In no-voltage discharge condition.Electric current by inductance L is rectified current.

Figure 14 shows transverse tube to the working condition of vertical tube commutation course.Transverse tube is to during the vertical tube change of current, the 3rd IGBT pipes Q3 Tending to remain on, the 4th IGBT pipes Q4 keeps cut-off state, and the first IGBT pipes Q1 then goes to conducting state from cut-off state, 2nd IGBT pipes Q2 then goes to cut-off state from conducting state.During the 2nd IGBT pipes Q2 ends, due to the second electric capacity C2 presence, rectified current are gone to by the second electric capacity C2 from by the 2nd IGBT pipes Q2.2nd IGBT pipes Q2 voltage is from zero Start linear increase, category no-voltage, zero-current switching.Input source Z by the 3rd sustained diode q3, the 3rd diode D3 and Inductance L charges to the second electric capacity C2.When inductance L electric current is gradually from rectified current vanishing, the second electric capacity C2 completes to charge Cheng Zhong, the electric current that rectified current flow to bus through the first sustained diode q1 gradually increase, due to the first sustained diode q1 Presence, the first IGBT pipe Q1 no currents pass through, therefore the first IGBT pipes Q1 turn on process belongs to zero current, no-voltage is led It is logical.It was found from above-mentioned analysis, in transverse tube into vertical tube commutation course, the first IGBT pipes Q1 and the 2nd IGBT pipes Q2 conducting and cut Only process is Sofe Switch process.

When the electric current vanishing by inductance L, when the second electric capacity C2 completes charging, the 3rd diode D3 and the 3rd afterflow two Pole pipe Dq3 ends, and the first sustained diode q1 conductings, completes whole commutation course.Return to Figure 10 state.

Change of current when commutation course and AC-input voltage when AC-input voltage is negative half-cycle are positive half period Journey is similar, and vertical tube is also similar to the transverse tube change of current or transverse tube to vertical tube commutation course, will not be described in detail herein.

Fig. 3 shows the circuit diagram of the embodiment two of T-shaped translation circuit in the utility model.It is as shown in Fig. 2 T-shaped The embodiment two that hydrocarbon changes circuit includes the first gate-controlled switch device, the second gate-controlled switch device, the 3rd gate-controlled switch device, Four gate-controlled switch devices, inductance L, the first diode D1, the second diode D2, the 3rd diode D3, the 4th diode D4, the 5th Diode D5, the 6th diode D6, the first electric capacity C1, the second electric capacity C2, the 3rd polar capacitor C3 and quadripolarity electric capacity C4.

Wherein, the first gate-controlled switch device uses IGBT units, including the first IGBT pipes Q1 and is connected with its inverse parallel First sustained diode q1；Second gate-controlled switch device uses IGBT units, including the 2nd IGBT pipes Q2 and connects with its inverse parallel The the second sustained diode q2 connect；3rd gate-controlled switch device uses IGBT units, including the first IGBT pipes Q3 and anti-with it The 3rd sustained diode q3 being connected in parallel；4th gate-controlled switch device uses IGBT units, including the 4th IGBT pipes Q4 and with 4th sustained diode q4 of its inverse parallel connection.

First IGBT pipes Q1 and the 4th IGBT pipes Q4 are connected in series, the first IGBT pipes Q1 colelctor electrode connection positive bus-bar, the Four IGBT pipes Q4 emitter stage connection negative busbar.The colelctor electrode connection of first IGBT pipes Q1 emitter stage and the 4th IGBT pipes Q4, Tie point is as input/output terminal.

2nd IGBT pipes Q2 and the 3rd IGBT pipes Q3 concatenated respectively with the 5th diode D5 and the 6th diode D6 after again simultaneously Connection forms middle bridge arm, and an end of described middle bridge arm is connected to input/output terminal, and the another of middle bridge arm is connected to inductance L's One end.The another of inductance L is connected to center line.On middle bridge arm, the 5th diode D5 negative electrode is connected to inductance L, the 5th diode D5 anode is connected with the 2nd IGBT pipes Q2 emitter stage, and the 2nd IGBT pipes Q2 colelctor electrode is connected to input/output terminal.Six or two Pole pipe D6 anode is connected to inductance, and the 6th diode D6 negative electrode is connected with the 3rd IGBT pipes Q3 colelctor electrode, the 3rd IGBT pipes Q3 emitter stage is connected to input/output terminal.

First diode D1 and the second diode D2 concatenations, the first diode D1 negative electrode are connected to positive bus-bar, the two or two pole Pipe D2 anode is connected to the tie point of inductance L and middle bridge arm；A first electric capacity C1 end is connected to the first diode D1 and second Diode D2 tie point, first the another of electric capacity C1 are connected to input/output terminal.

3rd diode D3 and the 4th diode D4 concatenations, the 4th diode D4 anode are connected to negative busbar, the three or two pole Pipe D3 negative electrode is connected to the 2nd IGBT pipes Q2 emitter stage；The ends of second electric capacity C2 mono- are connected to the 3rd diode D3 and the four or two pole Pipe D4 tie point, the second electric capacity C2 another colelctor electrode for being connected to the 2nd IGBT pipes.

3rd polar capacitor C3 positive pole connects positive bus-bar, and negative pole connects center line；Quadripolarity electric capacity C4 positive pole connects center line, bears Pole connects negative busbar.

In the present embodiment, gate-controlled switch device can also use MOS cell, and when using MOS cell, described MOS is mono- Member can be for the metal-oxide-semiconductor with body diode or including the metal-oxide-semiconductor and anti-paralleled diode without body diode.

Embodiment two gate-controlled switch device and diode in commutation course realize that the principle of Sofe Switch and embodiment one are near Seemingly, will not be described in detail herein.

From both examples above as can be seen that in T-shaped translation circuit in the utility model, all gate-controlled switch devices Sofe Switch can be realized with diode component, i.e. ZVT (ZVS), Zero Current Switch (ZCS) or zero-voltage zero-current is opened Close (ZVZCS), or break-make switching is carried out with limited dv/dt and di/dt.So as to significantly reduce the logical of gate-controlled switch device Breakdown consumes, and improves the operating efficiency of translation circuit；When making power device be not easy to be secondary breakdown, while being eliminated dead band Between.

Gate-controlled switch device carries out break-make switching with limited dv/dt and di/dt, therefore system EMI electromagnetic interferences are more not Realize that Sofe Switch will optimize much.

Because the switching losses of gate-controlled switch device diminish so that converting means can exponentially work in conventional transformation dress Put on working frequency, therefore output filter parameter request step-down needed for converting means, size can also reduce at double, so as to Be advantageous to further reduce Material Cost, reduction product size, improve product power density.

Compare and an inductance, four diodes and two electric capacity are merely add in prior art, the utility model, increase Number of devices is few, simple and compact structure, it is not necessary to extra increase gate-controlled switch device and control circuit.

Figure 15 shows the circuit diagram of the embodiment of three-phase translation circuit in the utility model.As shown in figure 15, it is real The three-phase translation circuit applied in example includes the first translation circuit, the second translation circuit, the 3rd translation circuit；First translation circuit, The T-shaped translation circuit of second translation circuit and the 3rd translation circuit described by using the embodiment one of above-mentioned T-shaped translation circuit； The center line of the center line of first translation circuit, the center line of the second translation circuit and the 3rd translation circuit is connected with each other.Certainly, first becomes Changing circuit, the second translation circuit, the 3rd translation circuit can also be using the T described by the embodiment two of above-mentioned T-shaped translation circuit Type translation circuit, effect are the same.

Above-mentioned three-phase translation circuit can equally realize gate-controlled switch device as a result of foregoing T-shaped translation circuit The effect of part Sofe Switch.

Figure 16 is the schematic diagram of the embodiment one of converting means.It is T-shaped conversion used by the embodiment one of converting means T-shaped translation circuit described by the embodiment one of circuit.First diode D1 therein, the second diode D2, second controllable open Close device, the 5th diode D5 and the first electric capacity C1 integration and be arranged to the first circuit module U1.3rd diode D3 therein, Four diode D4, the 3rd gate-controlled switch device, the 6th diode D6 and the second electric capacity C2 are integrated and are arranged to second circuit module U2.

First circuit module U1 first end S1 the first diodes of connection D1 negative electrode, for being connected to positive bus-bar；First electricity Road module U1 second end S2 the second diodes of connection D2 anode, for being connected to inductance；First circuit module U1 the 3rd end The diode D5 of S3 connections the 5th anode, for being connected to input/output terminal.

The second circuit module U2 diode D4 of the 4th end S4 connections the 4th anode, for being connected to negative busbar；Second electricity 3rd IGBT pipes Q3 colelctor electrode in the road module U2 gate-controlled switch device of the 5th end S5 connections the 3rd, for being connected to inductance L；The The two circuit module U2 diode D6 of the 6th end S6 connections the 6th negative electrode, for being connected to input/output terminal.

It should be noted that the first circuit module U1 or second circuit module U2 can be with individualisms.

Figure 17 is the schematic diagram of the embodiment two of converting means.It is T-shaped conversion used by the embodiment two of converting means T-shaped translation circuit described by the embodiment two of circuit.First diode D1 therein, the second diode D2, second controllable open Close device, the 5th diode D5 and the first electric capacity C1 integration and be arranged to tertiary circuit module U3.3rd diode D3 therein, Four diode D4, the 3rd gate-controlled switch device, the 6th diode D6 and the second electric capacity C2 are integrated and are arranged to the 4th circuit module U4.

Tertiary circuit module U3 the 7th end S7 the first diodes of connection D1 negative electrode, for being connected to positive bus-bar, the 3rd electricity Road module U3 the 8th end S8 the second diodes of connection D2 anode, for being connected to inductance L；Tertiary circuit module U3 the 9th end 2nd IGBT pipes Q2 colelctor electrode in S9 connection the second gate-controlled switch devices, for being connected to input/output terminal.

The 4th circuit module U4 diode D4 of the tenth end S10 connections the 4th anode, it is described for being connected to negative busbar The 4th circuit module U4 diode D6 of the tenth one end S11 connections the 6th anode, for being connected to inductance L；The 4th described electricity 3rd IGBT pipes Q3 emitter stage in the road module U4 gate-controlled switch device of the 12nd end S12 connections the 3rd, for being connected to input Output end.

It should be noted that tertiary circuit module U3 or the 4th circuit module U4 can be with individualisms.

From the embodiment of above-mentioned two converting means it will be seen that due to by component of the prior art and this skill The component increased newly in art scheme is combined into circuit module, can not change the inner wire of existing inversion/fairing substantially The technical program is realized in road in the case of being laid out, and greatly reduces improvement cost, and topological structure is compact, and busbar design is simple, pole To be advantageous to electrical layout and structure design.

Preferred embodiment of the present utility model is description above described, it is to be understood that the utility model is not limited to Embodiment is stated, and the exclusion to other embodiment should not be regarded as.By enlightenment of the present utility model, those skilled in the art combine The change that known or prior art, knowledge are carried out also should be regarded as in the scope of protection of the utility model.

Claims (10)

1. a kind of T-shaped translation circuit, it is characterized in that：Including the first gate-controlled switch device, the second gate-controlled switch device, the 3rd controllable Switching device, the 4th gate-controlled switch device, inductance, the first diode, the second diode, the 3rd diode, the 4th diode, Five diodes, the 6th diode, the first electric capacity and the second electric capacity；

First gate-controlled switch device and the connection of the 4th gate-controlled switch devices in series, the drain electrode of the first gate-controlled switch device or colelctor electrode Connect positive bus-bar, source electrode or emitter stage the connection negative busbar of the 4th gate-controlled switch device；

Tie point between first gate-controlled switch device and the 4th gate-controlled switch device is as input/output terminal；

Second gate-controlled switch device and the 3rd gate-controlled switch device concatenated respectively with the 5th diode and the 6th diode after again simultaneously Connection formed among bridge arm, an end of described middle bridge arm is connected to input/output terminal, another inductance that is connected to of middle bridge arm One end, the another of inductance are connected to center line；Wherein, it is defeated to be connected to input for the drain electrode of the second described gate-controlled switch device or colelctor electrode The source electrode or emitter stage for going out end or the second described gate-controlled switch device are connected to inductance；The 3rd described gate-controlled switch device Drain or colelctor electrode is connected to the source electrode of inductance or the 3rd described gate-controlled switch device or emitter stage is connected to input/output terminal；

The first described diode and the second diode concatenation, the negative electrode of the first diode are connected to positive bus-bar, the second diode Anode is connected to the tie point of inductance and middle bridge arm, and the described end of the first electric capacity one is connected to the first diode and the second diode Tie point, it is another to be connected to input/output terminal；

The 3rd described diode and the 4th diode concatenation, the anode of the 4th diode are connected to negative busbar, the 3rd diode Negative electrode is connected to the anode of the 6th diode；The described end of the second electric capacity one is connected to the connection of the 3rd diode and the 4th diode Point, another negative electrode for being connected to the 6th diode.

2. a kind of T-shaped translation circuit as claimed in claim 1, it is characterized in that, on middle bridge arm, the second gate-controlled switch device Source electrode or emitter stage are connected to inductance, and the drain electrode of the second gate-controlled switch device or colelctor electrode are connected with the negative electrode of the 5th diode, the The anode of five diodes is connected to input/output terminal；The drain electrode of 3rd gate-controlled switch device or colelctor electrode are connected to inductance, and the 3rd is controllable The source electrode or emitter stage of switching device are connected with the anode of the 6th diode, and the negative electrode of the 6th diode is connected to input/output terminal.

3. a kind of T-shaped translation circuit as claimed in claim 1, it is characterized in that, on middle bridge arm, the negative electrode of the 5th diode connects To inductance, the anode of the 5th diode is connected with the source electrode or emitter stage of the second gate-controlled switch device, the second gate-controlled switch device Drain electrode or colelctor electrode be connected to input/output terminal；The anode of 6th diode is connected to inductance, the negative electrode and the 3rd of the 6th diode The drain electrode of gate-controlled switch device or colelctor electrode connection, the source electrode or emitter stage of the 3rd gate-controlled switch device are connected to input/output terminal.

4. a kind of T-shaped translation circuit as claimed any one in claims 1 to 3, it is characterized in that, the first described gate-controlled switch Device or the 4th described gate-controlled switch device use IGBT units or MOS cell, when using IGBT units, described IGBT Unit includes the diode that IGBT is managed and is connected with IGBT pipe inverse parallels；When using MOS cell, described MOS cell can be Metal-oxide-semiconductor with body diode or including the metal-oxide-semiconductor and anti-paralleled diode without body diode.

5. a kind of T-shaped translation circuit as claimed any one in claims 1 to 3, it is characterized in that, the second described gate-controlled switch Device or the 3rd described gate-controlled switch device use IGBT units or MOS cell, when using IGBT units, described IGBT Unit includes the diode that IGBT is managed and is connected with IGBT pipe inverse parallels；When using MOS cell, described MOS cell can be Metal-oxide-semiconductor with body diode or including the metal-oxide-semiconductor and anti-paralleled diode without body diode.

6. a kind of three-phase translation circuit, it is characterized in that, including the first translation circuit, the second translation circuit, the 3rd translation circuit；Institute The first translation circuit, the second translation circuit and the 3rd translation circuit stated are used as any one of claim 1 to 5 A kind of T-shaped translation circuit；The center line of the center line of first translation circuit, the center line of the second translation circuit and the 3rd translation circuit is mutual Connection.

7. a kind of converting means, it is characterized in that, including a kind of T-shaped translation circuit as described in claim 2, wherein, first Diode, the second diode, the second gate-controlled switch device, the 5th diode and the first electric capacity are integrated and are arranged to the first circuit mould Block；

The first end of the first described circuit module connects the negative electrode of the first diode, for being connected to positive bus-bar；Described first Second end of circuit module connects the anode of the second diode, for being connected to inductance；3rd end of the first described circuit module The anode of the 5th diode is connected, for being connected to input/output terminal.

8. a kind of converting means, it is characterized in that, including a kind of T-shaped translation circuit as described in claim 2, wherein, the 3rd Diode, the 4th diode, the 3rd gate-controlled switch device, the 6th diode and the second electric capacity are integrated and are arranged to second circuit mould Block；

4th end of described second circuit module connects the anode of the 4th diode, for being connected to negative busbar；Described second 5th end of circuit module connects drain electrode or the colelctor electrode of the 3rd gate-controlled switch device, for being connected to inductance；The second described electricity The negative electrode of the diode of six end connecting the 6th of road module, for being connected to input/output terminal.

9. a kind of converting means, it is characterized in that, including a kind of T-shaped translation circuit as described in claim 3, wherein, first Diode, the second diode, the second gate-controlled switch device, the 5th diode and the first electric capacity are integrated and are arranged to tertiary circuit mould Block；

7th end of described tertiary circuit module connects the negative electrode of the first diode, for being connected to positive bus-bar, the described the 3rd 8th end of circuit module connects the anode of the second diode, for being connected to inductance；9th end of described tertiary circuit module Drain electrode or the colelctor electrode of the second gate-controlled switch device are connected, for being connected to input/output terminal.

10. a kind of converting means, it is characterized in that, including a kind of T-shaped translation circuit as described in claim 3, wherein, the 3rd Diode, the 4th diode, the 3rd gate-controlled switch device, the 6th diode and the second electric capacity are integrated and are arranged to the 4th circuit mould Block；

Tenth end of the 4th described circuit module connects the anode of the 4th diode, for being connected to negative busbar, the described the 4th The tenth one end of circuit module connects the anode of the 6th diode, for being connected to inductance；The tenth of the 4th described circuit module Two ends connect the source electrode or emitter stage of the 3rd gate-controlled switch device, for being connected to input/output terminal.