CN105071670A - Three-phase rectifying boost circuit, control method thereof and uninterruptible power supply - Google Patents
Three-phase rectifying boost circuit, control method thereof and uninterruptible power supply Download PDFInfo
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- CN105071670A CN105071670A CN201510495163.6A CN201510495163A CN105071670A CN 105071670 A CN105071670 A CN 105071670A CN 201510495163 A CN201510495163 A CN 201510495163A CN 105071670 A CN105071670 A CN 105071670A
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02J—CIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
- H02J9/00—Circuit arrangements for emergency or stand-by power supply, e.g. for emergency lighting
- H02J9/04—Circuit arrangements for emergency or stand-by power supply, e.g. for emergency lighting in which the distribution system is disconnected from the normal source and connected to a standby source
- H02J9/06—Circuit arrangements for emergency or stand-by power supply, e.g. for emergency lighting in which the distribution system is disconnected from the normal source and connected to a standby source with automatic change-over, e.g. UPS systems
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02M—APPARATUS FOR CONVERSION BETWEEN AC AND AC, BETWEEN AC AND DC, OR BETWEEN DC AND DC, AND FOR USE WITH MAINS OR SIMILAR POWER SUPPLY SYSTEMS; CONVERSION OF DC OR AC INPUT POWER INTO SURGE OUTPUT POWER; CONTROL OR REGULATION THEREOF
- H02M7/00—Conversion of ac power input into dc power output; Conversion of dc power input into ac power output
- H02M7/02—Conversion of ac power input into dc power output without possibility of reversal
- H02M7/04—Conversion of ac power input into dc power output without possibility of reversal by static converters
- H02M7/12—Conversion of ac power input into dc power output without possibility of reversal by static converters using discharge tubes with control electrode or semiconductor devices with control electrode
- H02M7/21—Conversion of ac power input into dc power output without possibility of reversal by static converters using discharge tubes with control electrode or semiconductor devices with control electrode using devices of a triode or transistor type requiring continuous application of a control signal
- H02M7/217—Conversion of ac power input into dc power output without possibility of reversal by static converters using discharge tubes with control electrode or semiconductor devices with control electrode using devices of a triode or transistor type requiring continuous application of a control signal using semiconductor devices only
- H02M7/219—Conversion of ac power input into dc power output without possibility of reversal by static converters using discharge tubes with control electrode or semiconductor devices with control electrode using devices of a triode or transistor type requiring continuous application of a control signal using semiconductor devices only in a bridge configuration
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Abstract
The invention relates to a three-phase rectifying boost circuit, a control method thereof (b) and an uninterruptible power supply. The three-phase rectifying boost circuit mainly comprises a positive cell group, a negative cell group and a rectifying boost module. The rectifying boost module comprises a first bidirectional triode thyristor, a second bidirectional triode thyristor, a third bidirectional triode thyristor, a first unidirectional triode thyristor, a second unidirectional triode thyristor, a first inductor, a second inductor, a third inductor, a three-phase full-control rectifier bridge, a first capacitor and a second capacitor. According to the invention, a power-level device can be reused; power density of the circuit is increased; configuration of a cell is reduced; application range is increased; and reliability of a cell mode is increased.
Description
Technical field
The present invention relates to rectifier boost module and uninterrupted power supply, particularly three phase rectifier booster circuit and control method, uninterrupted power supply.
Background technology
In current existing three-phase uninterrupted power supply (being called for short UPS) product, the three-phase Half bridge rectifier Boost topology of general employing monocell group mounting, under battery state boost mode, positive and negative busbar voltage sum can only be controlled, in order to maintain the balance between positive and negative busbar voltage, usually the balance of positive and negative busbar voltage is maintained by increase by bascule, as shown in Figure of description 1, cost is not only increased by the bascule additionally increased, too increase the complexity of circuit, the reliability of boosting under reducing battery state, simultaneously, bascule is when maintaining the positive and negative busbar balance of voltage, create extra power consumption, reduce the efficiency under battery state boost mode.
In addition, the battery electrode of monocell group mounting mode is connected to the rectifier boost topology of bus negative pole as shown in Figure of description 2, comprise the topology being applied to two level and three level, but in Modular UPS, multimode UPS needs CB common battery group and positive and negative busbar between each module UPS is independent, and therefore this topology cannot be applied in Modular UPS.
Modular UPS have power expanding flexibility high, be easy to the advantages such as on-line maintenance, being widely used in the fields such as bank, communication and data center at present, is the mainstream development direction of following high frequency UPS.In Modular UPS, the general three-phase positive and negative pair of Boost rectifier boost topology of double cell group mounting that adopt is as shown in Figure of description 3, adopt this topology can realize multiple module and share battery pack and positive and negative busbar between each module is independent, but compared with the three-phase half-bridge UPS rectifier boost topology mounted with monocell group, add three inductance and three thyristors.
To sum up, mainly there is following problem in prior art: the three-phase half-bridge UPS rectifier boost topology of (1) monocell group mounting cannot be applied to Modular UPS; (2) monocell group mounting three-phase half-bridge two level UPS rectifier boost topology under battery operation pattern efficiency and reliability lower.
Summary of the invention
In view of this, the object of the invention is to propose a kind of three phase rectifier booster circuit and control method thereof and uninterrupted power supply, achieve the multiplexing of power stage device, improve the power density of circuit, reduce the configuration of battery, increase range of application, improve the reliability of battery mode.
The present invention adopts following scheme to realize: a kind of three phase rectifier booster circuit, comprises positive battery group, negative battery group, a rectifier boost module, described rectifier boost module comprises the first bidirectional thyristor, the second bidirectional thyristor, the 3rd bidirectional thyristor, the first unidirectional thyristor, the second unidirectional thyristor, the first inductance, the second inductance, the 3rd inductance, three-phase full-controlled rectifier bridge, the first electric capacity, the second electric capacity, corresponding one end being connected to three-phase electricity first-phase, three-phase electricity second-phase, three-phase electricity third phase respectively, one end of one end of described first bidirectional thyristor, one end of described second bidirectional thyristor, described 3rd bidirectional thyristor, the negative electrode of described first unidirectional thyristor anode, described second unidirectional thyristor is connected respectively the negative terminal of the anode to described positive battery group, described negative battery group, and the negative terminal of described positive battery group and the anode of described negative battery group are all connected to the zero line of three-phase electricity, the negative electrode of described first unidirectional thyristor and the other end of described first bidirectional thyristor are all connected to one end of described first inductance, the other end of described second bidirectional thyristor is connected to one end of described second inductance, the other end of described 3rd bidirectional thyristor and the anode of described second unidirectional thyristor are all connected to one end of described 3rd inductance, the other end of described first inductance, the other end of the second inductance, the other end of the 3rd inductance is connected to the three-phase input end of described three-phase full-controlled rectifier bridge respectively, two outputs of described three-phase full-controlled rectifier bridge are connected to one end of described first electric capacity and one end of described second electric capacity respectively, the other end of described first electric capacity and the other end of described second electric capacity are all connected to the zero line of three-phase electricity.
Further, described three-phase full-controlled rectifier bridge is the two level topology of three-phase bridge, comprises the first switching device, second switch device, the 3rd switching device, the 4th switching device, the 5th switching device, the 6th switching device, described first switching device, 3rd switching device, the collector electrode of the 5th switching device or drain electrode are connected and as the first output of described three-phase full-controlled rectifier bridge, described second switch device, 4th switching device, the emitter of the 6th switching device or source electrode are connected and as the second output of described three-phase full-controlled rectifier bridge, the collector electrode of the emitter of described first switching device or source electrode and described second switch device or drain is connected and as the first-phase input of described three-phase full-controlled rectifier bridge, the collector electrode of the emitter of described 3rd switching device or source electrode and described 4th switching device or drain is connected and as the second-phase input of described three-phase full-controlled rectifier bridge, the collector electrode of the emitter of described 5th switching device or source electrode and described 6th switching device or drain is connected and as the third phase input of described three-phase full-controlled rectifier bridge.
Further, described three-phase electricity, the first bidirectional thyristor, the second bidirectional thyristor, the 3rd bidirectional thyristor, the first inductance, the second inductance, the 3rd inductance, the first switching device and body diode, second switch device and body diode thereof, the 3rd switching device and body diode, the 4th switching device and body diode thereof, the 5th switching device and body diode, the 6th switching device and body diode thereof, the first electric capacity, the second electric capacity form the rectifier boost power stage circuit under civil power operational mode;
Described positive battery group, negative battery group, the first unidirectional thyristor, the second unidirectional thyristor, the first inductance, the second inductance, the first switching device and body diode thereof, second switch device and body diode, the 5th switching device and body diode thereof, the 6th switching device and body diode thereof, the first electric capacity, the second electric capacity form the rectifier boost power stage circuit under battery operation pattern.
Further, described three-phase full-controlled rectifier bridge is three-phase half-bridge I type three-level topology or the T-shaped three-level topology of three-phase half-bridge.
Wherein, described three-phase half-bridge I type three-level topology comprises first and closes device extremely to twelvemo, first to the 6th diode extremely, the wherein emitter of the first switching device or source electrode, collector electrode or the drain electrode of second switch device are all connected with the negative electrode of the first diode, the emitter of the 5th switching device or source electrode, collector electrode or the drain electrode of the 6th switching device are all connected with the negative electrode of the 3rd diode, the emitter of the 9th switching device or source electrode, collector electrode or the drain electrode of the tenth switching device are all connected with the negative electrode of the 5th diode, the emitter of the 3rd switching device or source electrode, collector electrode or the drain electrode of the 4th switching device are all connected with the anode of the second diode, the emitter of the 7th switching device or source electrode, collector electrode or the drain electrode of the 8th switching device are all connected with the anode of the 4th diode, the emitter of the 11 switching device or source electrode, collector electrode or the drain electrode of twelvemo pass device are all connected with the anode of the 6th diode, the anode of the first diode is connected with the negative electrode of the second diode, the anode of the 3rd diode is connected with the negative electrode of the 4th diode, the anode of the 5th diode is connected with the negative electrode of the 6th diode, the collector electrode of the first switching device or drain electrode, the collector electrode of the 5th switching device or drain electrode, the collector electrode of the 9th switching device or drain electrode are connected and as the first output of described three-phase full-controlled rectifier bridge, the emitter of the 4th switching device or source electrode, the emitter of the 8th switching device or source electrode, twelvemo is closed the emitter of device or source electrode and to be connected and as the second output of described three-phase full-controlled rectifier bridge, the collector electrode of the emitter of second switch device or source electrode and the 3rd switching device or drain is connected and as the first-phase input of described three-phase full-controlled rectifier bridge, the collector electrode of the emitter of the 6th switching device or source electrode and the 7th switching device or drain is connected and as the second-phase input of described three-phase full-controlled rectifier bridge, the collector electrode of the emitter of the tenth switching device or source electrode and the 11 switching device or drain is connected and as the third phase input of described three-phase full-controlled rectifier bridge, the anode of the first diode, the anode of the 3rd diode, the anode of the 5th diode is all connected to three-phase electricity zero line.
Wherein, the described T-shaped three-level topology of three-phase half-bridge comprises first and closes device to twelvemo, emitter or the source electrode of the emitter of the 3rd switching device or source electrode and the 4th switching device are connected, emitter or the source electrode of the emitter of the 7th switching device or source electrode and the 8th switching device are connected, and the emitter of the 11 switching device or source electrode and twelvemo close the emitter of device or source electrode is connected, the wherein collector electrode of the first switching device or drain electrode, the collector electrode of the 5th switching device or drain electrode, the collector electrode of the 9th switching device or drain electrode are connected and as the first output of described three-phase full-controlled rectifier bridge, the emitter of second switch device or source electrode, the emitter of the 6th switching device or source electrode, the emitter of the tenth switching device or source electrode are connected and as the second output of described three-phase full-controlled rectifier bridge, the emitter of the first switching device or source electrode, the collector electrode of second switch device or drain electrode, the collector electrode of the 3rd switching device or drain electrode are connected and as the first-phase input of described three-phase full-controlled rectifier bridge, the emitter of the 5th switching device or source electrode, the collector electrode of the 6th switching device or drain electrode, the collector electrode of the 7th switching device or drain electrode are connected and as the second-phase input of described three-phase full-controlled rectifier bridge, the emitter of the 9th switching device or source electrode, the collector electrode of the tenth switching device or drain electrode, the collector electrode of the 11 switching device or drain electrode are connected and as the third phase input of described three-phase full-controlled rectifier bridge, the collector electrode of the 4th switching device or drain electrode, the collector electrode of the 8th switching device or drain electrode, collector electrode or the drain electrode of twelvemo pass device are all connected to three-phase electricity zero line.
Present invention also offers a kind of control method of three phase rectifier booster circuit as described above, when civil power is normal, control described first bidirectional thyristor, the second bidirectional thyristor, the 3rd bidirectional thyristor close, control described first unidirectional thyristor, the second unidirectional thyristor disconnects, now described three phase rectifier booster circuit works in civil power operational mode;
When city's electrical anomaly, control described first bidirectional thyristor, the second bidirectional thyristor, the 3rd bidirectional thyristor, the first switching device, the 3rd switching device, the 4th switching device, the 6th switching device disconnection, control described first unidirectional thyristor, the second unidirectional thyristor closes, now described three phase rectifier booster circuit works in battery operation pattern.
Further, the control mode that described three phase rectifier booster circuit works in civil power operational mode specifically comprised with the next stage:
When three-phase electricity first-phase voltage is in positive half period, control the first switching device and be in off state; First stage, control second switch device and be in conducting state, three-phase electricity first-phase voltage forms loop to the first inductance store electrical energy through the first bidirectional thyristor, the first inductance, second switch device, the second electric capacity; Second stage, controls second switch device and is in off state, the first inductive discharge, and the electric current of the first inductive discharge gets back to the first inductance, the first capacitor charging through the body diode of the first switching device, the first electric capacity, the first bidirectional thyristor;
When three-phase electricity first-phase voltage is in negative half-cycle, control second switch device and be in off state, phase III, control the first switching device and be in conducting state, three-phase electricity first-phase voltage forms loop to the first inductance store electrical energy through the first bidirectional thyristor, the first inductance, the first switching device, the first electric capacity; Fourth stage controls the first switching device and is in off state, the first inductive discharge, and the electric current of the first inductive discharge gets back to the first inductance, the second capacitor charging through the body diode of second switch device, the second electric capacity, the first bidirectional thyristor;
When three-phase electricity second-phase voltage is in positive half period, control the 3rd switching device and be in off state, first stage, control the 4th switching device and be in conducting state, three-phase electricity second-phase voltage forms loop to the second inductance store electrical energy through the second bidirectional thyristor, the second inductance, the 4th switching device, the second electric capacity; Second stage, controls the 4th switching device and is in off state, the second inductive discharge, and the electric current of the second inductive discharge gets back to the second inductance, the first capacitor charging through the body diode of the 3rd switching device, the first electric capacity, the second bidirectional thyristor;
When three-phase electricity second-phase voltage is in negative half-cycle, control the 4th switching device and be in off state, phase III, control the 3rd switching device and be in conducting state, three-phase electricity second-phase voltage forms loop to the second inductance store electrical energy through the second bidirectional thyristor, the second inductance, the 3rd switching device, the first electric capacity; Fourth stage controls the 3rd switching device and is in off state, the second inductive discharge, and the electric current of the second inductive discharge gets back to the second inductance, the second capacitor charging through the body diode of the 4th switching device, the second electric capacity, the second bidirectional thyristor;
When three-phase electricity third phase voltage is in positive half period, control the 5th switching device and be in off state, first stage, control the 6th switching device and be in conducting state, three-phase electricity third phase voltage forms loop to the 3rd inductance store electrical energy through the 3rd bidirectional thyristor, the 3rd inductance, the 6th switching device, the second electric capacity; Second stage, controls the 6th switching device and is in off state, the 3rd inductive discharge, and the electric current of the 3rd inductive discharge gets back to the 3rd inductance, the first capacitor charging through the body diode of the 5th switching device, the first electric capacity, the 3rd bidirectional thyristor;
When three-phase electricity third phase voltage is in negative half-cycle, control the 6th switching device and be in off state, phase III, control the 5th switching device and be in conducting state, three-phase electricity third phase voltage forms loop to the 3rd inductance store electrical energy through the 3rd bidirectional thyristor, the second inductance, the 5th switching device, the first electric capacity; Fourth stage controls the 3rd switching device and is in off state, the 3rd inductive discharge, and the electric current of the 3rd inductive discharge gets back to the 3rd inductance, the second capacitor charging through the body diode of the 6th switching device, the second electric capacity, the 3rd bidirectional thyristor.
Further, the control mode that described three phase rectifier booster circuit works in battery operation pattern specifically comprised with the next stage:
First stage, when control second switch device, the 5th switching device are in conducting state, positive battery group, the first unidirectional thyristor, the first inductance, second switch device, the second electric capacity composition loop are to the first inductance store electrical energy; Negative battery group, the first electric capacity, the 5th switching device, the 3rd inductance, the second unidirectional thyristor composition loop are to the 3rd inductance store electrical energy;
Second stage, when control second switch device, the 5th switching device are in off-state, first inductive discharge, the electric current of the first inductive discharge gets back to the first inductance, the first capacitor charging through the body diode of the first switching device, the first electric capacity, positive battery group, the first unidirectional thyristor; 3rd inductive discharge, the electric current of the 3rd inductive discharge gets back to the 3rd inductance, the second capacitor charging through the second unidirectional thyristor, negative battery group, the second electric capacity, the 6th switching device body diode.
The invention allows for a kind of three phase rectifier booster circuit, comprise positive battery group, negative battery group, N number of rectifier boost module, each described rectifier boost module includes the first bidirectional thyristor, the second bidirectional thyristor, the 3rd bidirectional thyristor, the first unidirectional thyristor, the second unidirectional thyristor, the first inductance, the second inductance, the 3rd inductance, three-phase full-controlled rectifier bridge, the first electric capacity, the second electric capacity, corresponding one end being connected to three-phase electricity first-phase, three-phase electricity second-phase, three-phase electricity third phase respectively, one end of one end of described first bidirectional thyristor, one end of described second bidirectional thyristor, described 3rd bidirectional thyristor, the anode of described first unidirectional thyristor, the negative electrode of described second unidirectional thyristor are connected respectively the negative terminal of the anode to described positive battery group, described negative battery group, and the negative terminal of described positive battery group and the anode of described negative battery group are all connected to the zero line of three-phase electricity, the negative electrode of described first unidirectional thyristor and the other end of described first bidirectional thyristor are all connected to one end of described first inductance, the other end of described second bidirectional thyristor is connected to one end of described second inductance, the anode of described 3rd bidirectional thyristor and described second unidirectional thyristor is all connected to one end of described 3rd inductance, described first inductance, second inductance, the other end of the 3rd inductance is connected to the three-phase input end of described three-phase full-controlled rectifier bridge respectively, two outputs of described three-phase full-controlled rectifier bridge are connected to one end of described first electric capacity and one end of described second electric capacity respectively, the other end of described first electric capacity and described second electric capacity is all connected to the zero line of three-phase electricity.
Same, first rectifier boost module 1(or N rectifier boost module N) the first bidirectional thyristor, the second bidirectional thyristor, the 3rd bidirectional thyristor, the first inductance, the second inductance, the 3rd inductance, three-phase full-controlled rectifier bridge, the first electric capacity, the second electric capacity form rectifier boost power stage circuit under civil power operational mode; Positive battery group, negative battery group, the first rectifier boost module 1(or N rectifier boost module N) the first unidirectional thyristor, the second unidirectional thyristor, the first inductance, the 3rd inductance, three-phase full-controlled rectifier bridge, the first electric capacity, the second electric capacity form rectifier boost power stage circuit under battery operation pattern.
Preferably, above described three-phase full-controlled rectifier bridge can be three-phase half-bridge two level circuit, three-phase half-bridge I type tri-level circuit or the T-shaped tri-level circuit of three-phase half-bridge.
Especially, the invention allows for a kind of uninterrupted power supply based on three phase rectifier booster circuit mentioned above, comprise described three phase rectifier booster circuit, inversion module, the input of described inversion module is connected with the output of described three-phase full-controlled rectifier bridge.
Preferably, above described three-phase full-controlled rectifier bridge can be three-phase half-bridge two level circuit, three-phase half-bridge I type tri-level circuit or the T-shaped tri-level circuit of three-phase half-bridge.
Compared with prior art, the present invention has following beneficial effect.
(1) three phase rectifier booster circuit of the present invention shares inductance, switching tube (as IGBT) constant power device under civil power operational mode and battery operation pattern, by the device in shared topology, different functions is realized under different operating mode, achieve the multiplexing of power stage device, reduce power device quantity, improve the power density of circuit, reduce circuit cost.
(2) three phase rectifier booster circuit of the present invention adopts double cell group, can CB common battery group between distinct device, reduces the configuration of battery, increases range of application.
(3) three phase rectifier booster circuit of the present invention positive and negative busbar under battery operation pattern independently boosts, the balance of positive and negative busbar can be realized without the need to additionally increasing bascule, allow the unbalanced load of positive and negative busbar band, improve the reliability of battery mode, reduce cost.
(4) three phase rectifier boost module of the present invention is in half-bridge mode of operation when civil power runs, and input voltage and input current can four phase limits be run, and rectifier possesses boosting and feedback ability simultaneously, improves the scope of application of equipment.
Accompanying drawing explanation
Fig. 1 is the two level rectifying Boost topology of three-phase bridge that prior art mounts with bascule monocell group.
Fig. 2 is the three-phase brachium pontis rectifier boost topology of prior art monocell group mounting.
Fig. 3 is three-phase positive and negative pair of Boost rectifier boost topology of prior art double cell group mounting.
Fig. 4 is three phase rectifier booster circuit schematic diagram of the present invention.
Fig. 5 is three phase rectifier booster circuit schematic diagram in the embodiment of the present invention 1.
Fig. 6 is that three-phase bridge two level rectifying boosting partial-topology of double cell mounting in the embodiment of the present invention 1 works in civil power operational mode equivalent schematic.
Fig. 7 is that in the embodiment of the present invention 1, three-phase electricity first-phase voltage is in positive half period, rectifier boost first stage fundamental diagram.
Fig. 8 is that in the embodiment of the present invention 1, three-phase electricity first-phase voltage is in positive half period, rectifier boost second stage fundamental diagram.
Fig. 9 is that in the embodiment of the present invention 1, three-phase electricity first-phase voltage is in negative half-cycle, rectifier boost phase III fundamental diagram.
Figure 10 is that in the embodiment of the present invention 1, three-phase electricity first-phase voltage is in negative half-cycle, rectifier boost fourth stage fundamental diagram.
Figure 11 is that the two level rectifying Boost topology of three-phase bridge of double cell group mounting in the embodiment of the present invention 1 works in battery operation mode equivalent schematic diagram.
Figure 12 is battery operation pattern in the embodiment of the present invention 1, positive battery group BAT+ rectifier boost first stage fundamental diagram.
Figure 13 is in the embodiment of the present invention 1 under battery operation pattern, negative battery group BAT-rectifier boost first stage fundamental diagram.
Figure 14 is in the embodiment of the present invention 1 under battery operation pattern, positive battery group BAT+ rectifier boost second stage fundamental diagram.
Figure 15 is in the embodiment of the present invention 1 under battery operation pattern, negative battery group BAT-rectifier boost second stage fundamental diagram.
Figure 16 is the three-phase half-bridge I type three level rectifier boost partial-topology of double cell mounting in the embodiment of the present invention 1.
Figure 17 is the three-phase half-bridge T-shaped three level rectifier boost partial-topology of double cell mounting in the embodiment of the present invention 1.
Figure 18 is multichannel three phase rectifier booster circuit annexation schematic diagram in the embodiment of the present invention 2.
Figure 19 is two-way three phase rectifier booster circuit annexation schematic diagram in the embodiment of the present invention 2.
Figure 20 is uninterrupted power supply circuit schematic diagram in the embodiment of the present invention 3.
Embodiment
Below in conjunction with drawings and Examples, the present invention will be further described.
Embodiment 1.
As shown in Figure 4, present embodiments provide a kind of three phase rectifier booster circuit, comprise positive battery group BAT+, negative battery group BAT-, a rectifier boost module, described rectifier boost module comprises the first bidirectional thyristor SCR1, the second bidirectional thyristor SCR2, the 3rd bidirectional thyristor SCR3, the first unidirectional thyristor SCR4, the second unidirectional thyristor SCR5, the first inductance L 1, second inductance L 2, the 3rd inductance L 3, three-phase full-controlled rectifier bridge, the first electric capacity C1, the second electric capacity C2, corresponding one end being connected to three-phase electricity first-phase, three-phase electricity second-phase, three-phase electricity third phase respectively, one end of one end of described first bidirectional thyristor SCR1, one end of described second bidirectional thyristor SCR2, described 3rd bidirectional thyristor SCR3, the anode of described first unidirectional thyristor SCR4, the negative electrode of described second unidirectional thyristor SCR5 are connected respectively the negative terminal of the anode to described positive battery group BAT+, described negative battery group BAT-, and the negative terminal of described positive battery group BAT+ and the anode of described negative battery group BAT-are all connected to the zero line of three-phase electricity, the negative electrode of described first unidirectional thyristor SCR4 and the other end of described first bidirectional thyristor SCR1 are all connected to one end of described first inductance L 1, the other end of described second bidirectional thyristor SCR2 is connected to one end of described second inductance L 2, the other end of described 3rd bidirectional thyristor SCR3 and the anode of described second unidirectional thyristor SCR5 are all connected to one end of described 3rd inductance L 3, the other end of described first inductance L 1, the other end of the second inductance L 2, the other end of the 3rd inductance L 3 is connected to the three-phase input end of described three-phase full-controlled rectifier bridge respectively, two outputs of described three-phase full-controlled rectifier bridge are connected to one end of described first electric capacity C1 and one end of described second electric capacity C2 respectively, the other end of described first electric capacity C1 and the other end of described second electric capacity C2 are all connected to the zero line of three-phase electricity.
In the present embodiment, as shown in Figure 5, described three-phase full-controlled rectifier bridge is the two level topology of three-phase half-bridge, comprises the first switch triode Q1 and body diode D1 thereof, second switch triode Q2 and body diode D2 thereof, the 3rd switch triode Q3 and body diode D3 thereof, the 4th switch triode Q4 and body diode D4 thereof, the 5th switch triode Q5 and body diode D5 thereof, the 6th switch triode Q6 and body diode D6 thereof, described first switch triode Q1, 3rd switch triode Q3, the collector electrode of the 5th switch triode Q5 is connected and as the first output of described three-phase full-controlled rectifier bridge, described second switch triode Q2, 4th switch triode Q4, the emitter of the 6th switch triode Q6 is connected and as the second output of described three-phase full-controlled rectifier bridge, the emitter of described first switch triode Q1 is connected with the collector electrode of described second switch triode Q2 and as the first-phase input of described three-phase full-controlled rectifier bridge, the emitter of described 3rd switch triode Q3 is connected with the collector electrode of described 4th switch triode Q4 and as the second-phase input of described three-phase full-controlled rectifier bridge, the emitter of described 5th switch triode Q5 is connected with the collector electrode of described 6th switch triode Q6 and as the third phase input of described three-phase full-controlled rectifier bridge.
In the present embodiment, as shown in Figure 6, described three-phase electricity, first bidirectional thyristor SCR1, second bidirectional thyristor SCR2, 3rd bidirectional thyristor SCR3, first inductance L 1, second inductance L 2, 3rd inductance L 3, first switch triode Q1 and body diode D1 thereof, second switch triode Q2 and body diode D2 thereof, 3rd switch triode Q3 and body diode D3 thereof, 4th switch triode Q4 and body diode D4 thereof, 5th switch triode Q5 and body diode D5 thereof, 6th switch triode Q6 and body diode D6 thereof, first electric capacity C1, second electric capacity C2 forms the rectifier boost power stage circuit under civil power operational mode,
As shown in figure 11, the rectifier boost power stage circuit under described positive battery group BAT+, negative battery group BAT-, the first unidirectional thyristor SCR4, the second unidirectional thyristor SCR5, the first inductance L 1, second inductance L 2, first switch triode Q1 and body diode D1 thereof, second switch triode Q2 and body diode D2 thereof, the 5th switch triode Q5 and body diode D5 thereof, the 6th switch triode Q6 and body diode D6 thereof, the first electric capacity C1, the second electric capacity C2 formation battery operation pattern.
In the present embodiment, described three-phase full-controlled rectifier bridge is three-phase half-bridge I type tri-level circuit (as shown in figure 16) or the T-shaped three-level topology of three-phase half-bridge (as shown in figure 17).
Wherein, as shown in figure 16, described three-phase half-bridge I type three-level topology comprises first and closes device Q1 to Q12 to twelvemo, first to the 6th diode D1 to D6, the wherein emitter of the first switching device Q1 or source electrode, collector electrode or the drain electrode of second switch device Q2 are all connected with the negative electrode of the first diode D1, the emitter of the 5th switching device Q5 or source electrode, collector electrode or the drain electrode of the 6th switching device Q6 are all connected with the negative electrode of the 3rd diode D3, the emitter of the 9th switching device Q9 or source electrode, collector electrode or the drain electrode of the tenth switching device Q10 are all connected with the negative electrode of the 5th diode D5, the emitter of the 3rd switching device Q3 or source electrode, collector electrode or the drain electrode of the 4th switching device Q4 are all connected with the anode of the second diode D2, the emitter of the 7th switching device Q7 or source electrode, collector electrode or the drain electrode of the 8th switching device Q8 are all connected with the anode of the 4th diode D4, the emitter of the 11 switching device Q11 or source electrode, collector electrode or the drain electrode of twelvemo pass device Q12 are all connected with the anode of the 6th diode D6, the anode of the first diode D1 is connected with the negative electrode of the second diode D2, the anode of the 3rd diode D3 is connected with the negative electrode of the 4th diode D4, the anode of the 5th diode D5 is connected with the negative electrode of the 6th diode D6, the collector electrode of the first switching device Q1 or drain electrode, the collector electrode of the 5th switching device Q5 or drain electrode, the collector electrode of the 9th switching device Q9 or drain electrode are connected and as the first output of described three-phase full-controlled rectifier bridge, the emitter of the 4th switching device Q4 or source electrode, the emitter of the 8th switching device Q8 or source electrode, twelvemo is closed the emitter of device Q12 or source electrode and to be connected and as the second output of described three-phase full-controlled rectifier bridge, the collector electrode of the emitter of second switch device Q2 or source electrode and the 3rd switching device Q3 or drain is connected and as the first-phase input of described three-phase full-controlled rectifier bridge, the collector electrode of the emitter of the 6th switching device Q6 or source electrode and the 7th switching device Q7 or drain is connected and as the second-phase input of described three-phase full-controlled rectifier bridge, the collector electrode of the emitter of the tenth switching device Q10 or source electrode and the 11 switching device Q11 or drain is connected and as the third phase input of described three-phase full-controlled rectifier bridge, the anode of the first diode D1, the anode of the 3rd diode D3, the anode of the 5th diode D5 is all connected to three-phase electricity zero line.
Wherein, as shown in figure 17, the described T-shaped three-level topology of three-phase half-bridge comprises first and closes device to twelvemo, emitter or the source electrode of the emitter of the 3rd switching device Q3 or source electrode and the 4th switching device Q4 are connected, emitter or the source electrode of the emitter of the 7th switching device Q7 or source electrode and the 8th switching device Q8 are connected, and the emitter of the 11 switching device Q11 or source electrode and twelvemo close the emitter of device Q12 or source electrode is connected, the wherein collector electrode of the first switching device Q1 or drain electrode, the collector electrode of the 5th switching device Q5 or drain electrode, the collector electrode of the 9th switching device Q9 or drain electrode are connected and as the first output of described three-phase full-controlled rectifier bridge, the emitter of second switch device Q2 or source electrode, the emitter of the 6th switching device Q6 or source electrode, the emitter of the tenth switching device Q10 or source electrode are connected and as the second output of described three-phase full-controlled rectifier bridge, the emitter of the first switching device Q1 or source electrode, the collector electrode of second switch device Q2 or drain electrode, the collector electrode of the 3rd switching device Q3 or drain electrode are connected and as the first-phase input of described three-phase full-controlled rectifier bridge, the emitter of the 5th switching device Q5 or source electrode, the collector electrode of the 6th switching device Q6 or drain electrode, the collector electrode of the 7th switching device Q7 or drain electrode are connected and as the second-phase input of described three-phase full-controlled rectifier bridge, the emitter of the 9th switching device Q9 or source electrode, the collector electrode of the tenth switching device Q10 or drain electrode, the collector electrode of the 11 switching device Q11 or drain electrode are connected and as the third phase input of described three-phase full-controlled rectifier bridge, the collector electrode of the 4th switching device Q4 or drain electrode, the collector electrode of the 8th switching device Q8 or drain electrode, collector electrode or the drain electrode of twelvemo pass device Q12 are all connected to three-phase electricity zero line.
The present embodiment also proposed a kind of control method of three phase rectifier booster circuit as described above, is specially:
When civil power is normal, control described first bidirectional thyristor SCR1, the second bidirectional thyristor SCR2, the 3rd bidirectional thyristor SCR3 closes, control described first unidirectional thyristor SCR4, the second unidirectional thyristor SCR5 disconnects, now described three phase rectifier booster circuit works in civil power operational mode;
When city's electrical anomaly, control described first bidirectional thyristor SCR1, the second bidirectional thyristor SCR2, the 3rd bidirectional thyristor SCR3, the first switch triode Q1, the 3rd switch triode Q3, the 4th switch triode Q4, the 6th switch triode Q6 disconnect, control described first unidirectional thyristor SCR4, the second unidirectional thyristor SCR5 closed, now described three phase rectifier booster circuit works in battery operation pattern.
Further, in the present embodiment, the control mode that described three phase rectifier booster circuit works in civil power operational mode specifically comprised with the next stage:
As shown in Figure 7, when three-phase electricity first-phase voltage is in positive half period, control the first switching tube Q1 and be in off state; First stage, control second switch triode Q2 and be in conducting state, three-phase electricity first-phase voltage forms loop to the first inductance L 1 store electrical energy through the first bidirectional thyristor SCR1, the first inductance L 1, second switch triode Q2, the second electric capacity C2; As shown in Figure 8, second stage, control second switch triode Q2 and be in off state, first inductance L 1 is discharged, the electric current that first inductance L 1 is discharged is got back to the first inductance L 1, first electric capacity C1 charge through the body diode of the first switch triode Q1, the first electric capacity C1, the first bidirectional thyristor SCR1;
As shown in Figure 9, when three-phase electricity first-phase voltage is in negative half-cycle, control second switch triode Q2 and be in off state, phase III, control the first switch triode Q1 and be in conducting state, three-phase electricity first-phase voltage forms loop to the first inductance L 1 store electrical energy through the first bidirectional thyristor SCR1, the first inductance L 1, first switch triode Q1, the first electric capacity C1; As shown in Figure 10, fourth stage controls the first switch triode Q1 and is in off state, first inductance L 1 is discharged, the electric current that first inductance L 1 is discharged is got back to the first inductance L 1, second electric capacity C2 charge through the body diode of second switch triode Q2, the second electric capacity C2, the first bidirectional thyristor SCR1;
When three-phase electricity second-phase voltage is in positive half period, control the 3rd switch triode Q3 and be in off state, first stage, control the 4th switch triode Q4 and be in conducting state, three-phase electricity second-phase voltage forms loop to the second inductance L 2 store electrical energy through the second bidirectional thyristor SCR2, the second inductance L 2, the 4th switch triode Q4, the second electric capacity C2; Second stage, control the 4th switch triode Q4 and be in off state, second inductance L 2 is discharged, and the electric current that the second inductance L 2 is discharged is got back to the second inductance L 2, first electric capacity C1 charge through the body diode of the 3rd switch triode Q3, the first electric capacity C1, the second bidirectional thyristor SCR2;
When three-phase electricity second-phase voltage is in negative half-cycle, control the 4th switch triode Q4 and be in off state, phase III, control the 3rd switch triode Q3 and be in conducting state, three-phase electricity second-phase voltage forms loop to the second inductance L 2 store electrical energy through the second bidirectional thyristor SCR2, the second inductance L 2, the 3rd switch triode Q3, the first electric capacity C1; Fourth stage controls the 3rd switch triode Q3 and is in off state, second inductance L 2 is discharged, the electric current that second inductance L 2 is discharged is got back to the second inductance L 2, second electric capacity C2 charge through the body diode of the 4th switch triode Q4, the second electric capacity C2, the second bidirectional thyristor SCR2;
When three-phase electricity third phase voltage is in positive half period, control the 5th switch triode Q5 and be in off state, first stage, control the 6th switch triode Q6 and be in conducting state, three-phase electricity third phase voltage forms loop to the 3rd inductance L 3 store electrical energy through the 3rd bidirectional thyristor SCR3, the 3rd inductance L 3, the 6th switch triode Q6, the second electric capacity C2; Second stage, control the 6th switch triode Q6 and be in off state, 3rd inductance L 3 is discharged, and the electric current that the 3rd inductance L 3 is discharged is got back to the 3rd inductance L 3, first electric capacity C1 charge through the body diode of the 5th switch triode Q5, the first electric capacity C1, the 3rd bidirectional thyristor SCR3;
When three-phase electricity third phase voltage is in negative half-cycle, control the 6th switch triode Q6 and be in off state, phase III, control the 5th switch triode Q5 and be in conducting state, three-phase electricity third phase voltage forms loop to the 3rd inductance L 3 store electrical energy through the 3rd bidirectional thyristor SCR3, the second inductance L 2, the 5th switch triode Q5, the first electric capacity C1; Fourth stage controls the 3rd switch triode Q3 and is in off state, 3rd inductance L 3 is discharged, the electric current that 3rd inductance L 3 is discharged is got back to the 3rd inductance L 3, second electric capacity C2 charge through the body diode of the 6th switch triode Q6, the second electric capacity C2, the 3rd bidirectional thyristor SCR3.
In the present embodiment, the control mode that described three phase rectifier booster circuit works in battery operation pattern specifically comprised with the next stage:
First stage, as shown in Figure 12 and Figure 13, when control second switch triode Q2, the 5th switch triode Q5 are in conducting state, positive battery group BAT+, the first unidirectional thyristor SCR4, the first inductance L 1, second switch triode Q2, the second electric capacity C2 form loop to the first inductance L 1 store electrical energy; Negative battery group BAT-, the first electric capacity C1, the 5th switch triode Q5, the 3rd inductance L 3, second unidirectional thyristor SCR5 form loop to the 3rd inductance L 3 store electrical energy;
Second stage, as shown in Figure 14 and Figure 15, when control second switch triode Q2, the 5th switch triode Q5 are in off-state, first inductance L 1 is discharged, the electric current that first inductance L 1 is discharged is got back to the first inductance L 1, first electric capacity C1 charge through the body diode of the first switch triode Q1, the first electric capacity C1, positive battery group BAT+, the first unidirectional thyristor SCR4; 3rd inductance L 3 is discharged, and the electric current that the 3rd inductance L 3 is discharged is got back to the 3rd inductance L 3, second electric capacity C2 charge through the second unidirectional thyristor SCR5, negative battery group BAT-, the second electric capacity C2, the 6th switch triode Q2 body diode.
Embodiment two.
The invention allows for a kind of three phase rectifier booster circuit, as shown in figure 18, comprise positive battery group BAT+, negative battery group BAT-, N number of rectifier boost module, each described rectifier boost module includes the first bidirectional thyristor SCR1, the second bidirectional thyristor SCR2, the 3rd bidirectional thyristor SCR3, the first unidirectional thyristor SCR4, the second unidirectional thyristor SCR5, the first inductance L 1, second inductance L 2, the 3rd inductance L 3, three-phase full-controlled rectifier bridge, the first electric capacity C1, the second electric capacity C2, corresponding one end being connected to three-phase electricity first-phase, three-phase electricity second-phase, three-phase electricity third phase respectively, one end of one end of described first bidirectional thyristor SCR1, one end of described second bidirectional thyristor SCR2, described 3rd bidirectional thyristor SCR3, the anode of described first unidirectional thyristor SCR4, the negative electrode of described second unidirectional thyristor SCR5 are connected respectively the negative terminal of the anode to described positive battery group BAT+, described negative battery group BAT-, and the negative terminal of described positive battery group BAT+ and the anode of described negative battery group BAT-are all connected to the zero line of three-phase electricity, the negative electrode of described first unidirectional thyristor SCR4 and the other end of described first bidirectional thyristor SCR1 are all connected to one end of described first inductance L 1, the other end of described second bidirectional thyristor SCR2 is connected to one end of described second inductance L 2, the anode of described 3rd bidirectional thyristor SCR3 and described second unidirectional thyristor SCR5 is all connected to one end of described 3rd inductance L 3, described first inductance L 1, second inductance L 2, the other end of the 3rd inductance L 3 is connected to the three-phase input end of described three-phase full-controlled rectifier bridge respectively, two outputs of described three-phase full-controlled rectifier bridge are connected to one end of described first electric capacity C1 and one end of described second electric capacity C2 respectively, the other end of described first electric capacity C1 and described second electric capacity C2 is all connected to the zero line of three-phase electricity.Preferably, Figure 19 is be the circuit diagram of 2 for N.
Same, first rectifier boost module 1(or N rectifier boost module N) the first bidirectional thyristor SCR1, the second bidirectional thyristor SCR2, the 3rd bidirectional thyristor SCR3, the first inductance L 1, second inductance L 2, the 3rd inductance L 3, three-phase full-controlled rectifier bridge, the first electric capacity C1, the second electric capacity C2 form rectifier boost power stage circuit under civil power operational mode; Positive battery group BAT+, negative battery group BAT-, the first rectifier boost module 1(or N rectifier boost module N) the first unidirectional thyristor SCR4, the second unidirectional thyristor SCR5, the first inductance L 1, the 3rd inductance L 3, three-phase full-controlled rectifier bridge, the first electric capacity C1, the second electric capacity C2 form rectifier boost power stage circuit under battery operation pattern.
Preferably, above described three-phase full-controlled rectifier bridge can be three-phase half-bridge two level circuit, three-phase half-bridge I type tri-level circuit or the T-shaped tri-level circuit of three-phase half-bridge.
Embodiment 3.
Especially, the present embodiment also proposed a kind of uninterrupted power supply based on three phase rectifier booster circuit mentioned above, as shown in figure 20, comprise described three phase rectifier booster circuit, inversion module, the input of described inversion module is connected with the output of described three-phase full-controlled rectifier bridge.
Same, the rectifier boost power stage circuit under the first bidirectional thyristor SCR1, the second bidirectional thyristor SCR2, the 3rd bidirectional thyristor SCR3, the first inductance L 1, second inductance L 2, the 3rd inductance L 3, three-phase full-controlled rectifier bridge, the first electric capacity C1, the second electric capacity C2 formation civil power operational mode; Rectifier boost power stage circuit under positive battery group BAT+, negative battery group BAT-, the first unidirectional thyristor SCR4, the second unidirectional thyristor SCR5, the first inductance L 1, the 3rd inductance L 3, three-phase full-controlled rectifier bridge, the first electric capacity C1, the second electric capacity C2 formation battery operation pattern.
Preferably, three-phase full-controlled rectifier bridge described in the present embodiment can be three-phase half-bridge two level circuit, three-phase half-bridge I type tri-level circuit or the T-shaped tri-level circuit of three-phase half-bridge.
The foregoing is only preferred embodiment of the present invention, all equalizations done according to the present patent application the scope of the claims change and modify, and all should belong to covering scope of the present invention.
Claims (11)
1. a three phase rectifier booster circuit, is characterized in that: comprise positive battery group, negative battery group, a rectifier boost module, described rectifier boost module comprises the first bidirectional thyristor, the second bidirectional thyristor, the 3rd bidirectional thyristor, the first unidirectional thyristor, the second unidirectional thyristor, the first inductance, the second inductance, the 3rd inductance, three-phase full-controlled rectifier bridge, the first electric capacity, the second electric capacity, corresponding one end being connected to three-phase electricity first-phase, three-phase electricity second-phase, three-phase electricity third phase respectively, one end of one end of described first bidirectional thyristor, one end of described second bidirectional thyristor, described 3rd bidirectional thyristor, the anode of described first unidirectional thyristor, the negative electrode of described second unidirectional thyristor are connected respectively the negative terminal of the anode to described positive battery group, described negative battery group, and the negative terminal of described positive battery group and the anode of described negative battery group are all connected to the zero line of three-phase electricity, the negative electrode of described first unidirectional thyristor and the other end of described first bidirectional thyristor are all connected to one end of described first inductance, the other end of described second bidirectional thyristor is connected to one end of described second inductance, the other end of described 3rd bidirectional thyristor and the anode of described second unidirectional thyristor are all connected to one end of described 3rd inductance, the other end of described first inductance, the other end of the second inductance, the other end of the 3rd inductance is connected to the three-phase input end of described three-phase full-controlled rectifier bridge respectively, two outputs of described three-phase full-controlled rectifier bridge are connected to one end of described first electric capacity and one end of described second electric capacity respectively, the other end of described first electric capacity and the other end of described second electric capacity are all connected to the zero line of three-phase electricity.
2. a kind of three phase rectifier booster circuit according to claim 1, it is characterized in that: described three-phase full-controlled rectifier bridge is the two level topology of three-phase bridge, comprises the first switching device, second switch device, the 3rd switching device, the 4th switching device, the 5th switching device, the 6th switching device, described first switching device, 3rd switching device, the collector electrode of the 5th switching device or drain electrode are connected and as the first output of described three-phase full-controlled rectifier bridge, described second switch device, 4th switching device, the emitter of the 6th switching device or source electrode are connected and as the second output of described three-phase full-controlled rectifier bridge, the collector electrode of the emitter of described first switching device or source electrode and described second switch device or drain is connected and as the first-phase input of described three-phase full-controlled rectifier bridge, the collector electrode of the emitter of described 3rd switching device or source electrode and described 4th switching device or drain is connected and as the second-phase input of described three-phase full-controlled rectifier bridge, the collector electrode of the emitter of described 5th switching device or source electrode and described 6th switching device or drain is connected and as the third phase input of described three-phase full-controlled rectifier bridge.
3. a kind of three phase rectifier booster circuit according to claim 2, is characterized in that:
Described three-phase electricity, first bidirectional thyristor, second bidirectional thyristor, 3rd bidirectional thyristor, first inductance, second inductance, 3rd inductance, first switching device and body diode thereof, second switch device and body diode thereof, 3rd switching device and body diode thereof, 4th switching device and body diode thereof, 5th switching device and body diode thereof, 6th switching device and body diode thereof, first electric capacity, second electric capacity forms the rectifier boost power stage circuit under civil power operational mode,
Described positive battery group, negative battery group, the first unidirectional thyristor, the second unidirectional thyristor, the first inductance, the second inductance, the first switching device and body diode thereof, second switch device and body diode, the 5th switching device and body diode thereof, the 6th switching device and body diode thereof, the first electric capacity, the second electric capacity form the rectifier boost power stage circuit under battery operation pattern.
4. a kind of three phase rectifier booster circuit according to claim 1, is characterized in that: described three-phase full-controlled rectifier bridge is three-phase half-bridge I type three-level topology or the T-shaped three-level topology of three-phase half-bridge.
5. a kind of three phase rectifier booster circuit according to claim 4, it is characterized in that: described three-phase half-bridge I type three-level topology comprises first and closes device to twelvemo, first to the 6th diode, the wherein emitter of the first switching device or source electrode, collector electrode or the drain electrode of second switch device are all connected with the negative electrode of the first diode, the emitter of the 5th switching device or source electrode, collector electrode or the drain electrode of the 6th switching device are all connected with the negative electrode of the 3rd diode, the emitter of the 9th switching device or source electrode, collector electrode or the drain electrode of the tenth switching device are all connected with the negative electrode of the 5th diode, the emitter of the 3rd switching device or source electrode, collector electrode or the drain electrode of the 4th switching device are all connected with the anode of the second diode, the emitter of the 7th switching device or source electrode, collector electrode or the drain electrode of the 8th switching device are all connected with the anode of the 4th diode, the emitter of the 11 switching device or source electrode, collector electrode or the drain electrode of twelvemo pass device are all connected with the anode of the 6th diode, the anode of the first diode is connected with the negative electrode of the second diode, the anode of the 3rd diode is connected with the negative electrode of the 4th diode, the anode of the 5th diode is connected with the negative electrode of the 6th diode, the collector electrode of the first switching device or drain electrode, the collector electrode of the 5th switching device or drain electrode, the collector electrode of the 9th switching device or drain electrode are connected and as the first output of described three-phase full-controlled rectifier bridge, the emitter of the 4th switching device or source electrode, the emitter of the 8th switching device or source electrode, twelvemo is closed the emitter of device or source electrode and to be connected and as the second output of described three-phase full-controlled rectifier bridge, the collector electrode of the emitter of second switch device or source electrode and the 3rd switching device or drain is connected and as the first-phase input of described three-phase full-controlled rectifier bridge, the collector electrode of the emitter of the 6th switching device or source electrode and the 7th switching device or drain is connected and as the second-phase input of described three-phase full-controlled rectifier bridge, the collector electrode of the emitter of the tenth switching device or source electrode and the 11 switching device or drain is connected and as the third phase input of described three-phase full-controlled rectifier bridge, the anode of the first diode, the anode of the 3rd diode, the anode of the 5th diode is all connected to three-phase electricity zero line.
6. a kind of three phase rectifier booster circuit according to claim 4, is characterized in that: the described T-shaped three-level topology of three-phase half-bridge comprises first and closes device to twelvemo, emitter or the source electrode of the emitter of the 3rd switching device or source electrode and the 4th switching device are connected, emitter or the source electrode of the emitter of the 7th switching device or source electrode and the 8th switching device are connected, and the emitter of the 11 switching device or source electrode and twelvemo close the emitter of device or source electrode is connected, the wherein collector electrode of the first switching device or drain electrode, the collector electrode of the 5th switching device or drain electrode, the collector electrode of the 9th switching device or drain electrode are connected and as the first output of described three-phase full-controlled rectifier bridge, the emitter of second switch device or source electrode, the emitter of the 6th switching device or source electrode, the emitter of the tenth switching device or source electrode are connected and as the second output of described three-phase full-controlled rectifier bridge, the emitter of the first switching device or source electrode, the collector electrode of second switch device or drain electrode, the collector electrode of the 3rd switching device or drain electrode are connected and as the first-phase input of described three-phase full-controlled rectifier bridge, the emitter of the 5th switching device or source electrode, the collector electrode of the 6th switching device or drain electrode, the collector electrode of the 7th switching device or drain electrode are connected and as the second-phase input of described three-phase full-controlled rectifier bridge, the emitter of the 9th switching device or source electrode, the collector electrode of the tenth switching device or drain electrode, the collector electrode of the 11 switching device or drain electrode are connected and as the third phase input of described three-phase full-controlled rectifier bridge, the collector electrode of the 4th switching device or drain electrode, the collector electrode of the 8th switching device or drain electrode, collector electrode or the drain electrode of twelvemo pass device are all connected to three-phase electricity zero line.
7. a control method for three phase rectifier booster circuit as claimed in claim 2, is characterized in that:
When civil power is normal, control described first bidirectional thyristor, the second bidirectional thyristor, the 3rd bidirectional thyristor close, control described first unidirectional thyristor, second unidirectional thyristor disconnect, now described three phase rectifier booster circuit works in civil power operational mode;
When city's electrical anomaly, control described first bidirectional thyristor, the second bidirectional thyristor, the 3rd bidirectional thyristor SCR3, the first switching device, the 3rd switching device, the 4th switching device, the 6th switching device disconnection, control described first unidirectional thyristor, the second unidirectional thyristor closes, now described three phase rectifier booster circuit works in battery operation pattern.
8. the control method of a kind of three phase rectifier booster circuit according to claim 7, is characterized in that: the control mode that described three phase rectifier booster circuit works in civil power operational mode specifically comprised with the next stage:
When three-phase electricity first-phase voltage is in positive half period, control the first switching device and be in off state; First stage, control second switch device and be in conducting state, three-phase electricity first-phase voltage forms loop to the first inductance store electrical energy through the first bidirectional thyristor, the first inductance, second switch device, the second electric capacity; Second stage, controls second switch device and is in off state, the first inductive discharge, and the electric current of the first inductive discharge gets back to the first inductance, the first capacitor charging through the body diode of the first switching device, the first electric capacity, the first bidirectional thyristor;
When three-phase electricity first-phase voltage is in negative half-cycle, control second switch device and be in off state, phase III, control the first switching device and be in conducting state, three-phase electricity first-phase voltage forms loop to the first inductance store electrical energy through the first bidirectional thyristor, the first inductance, the first switching device, the first electric capacity; Fourth stage controls the first switching device and is in off state, the first inductive discharge, and the electric current of the first inductive discharge gets back to the first inductance, the second capacitor charging through the body diode of second switch device, the second electric capacity, the first bidirectional thyristor;
When three-phase electricity second-phase voltage is in positive half period, control the 3rd switching device and be in off state, first stage, control the 4th switching device and be in conducting state, three-phase electricity second-phase voltage forms loop to the second inductance store electrical energy through the second bidirectional thyristor, the second inductance, the 4th switching device, the second electric capacity; Second stage, controls the 4th switching device and is in off state, the second inductive discharge, and the electric current of the second inductive discharge gets back to the second inductance, the first capacitor charging through the body diode of the 3rd switching device, the first electric capacity, the second bidirectional thyristor;
When three-phase electricity second-phase voltage is in negative half-cycle, control the 4th switching device and be in off state, phase III, control the 3rd switching device and be in conducting state, three-phase electricity second-phase voltage forms loop to the second inductance store electrical energy through the second bidirectional thyristor, the second inductance, the 3rd switching device, the first electric capacity; Fourth stage controls the 3rd switching device and is in off state, the second inductive discharge, and the electric current of the second inductive discharge gets back to the second inductance, the second capacitor charging through the body diode of the 4th switching device, the second electric capacity, the second bidirectional thyristor;
When three-phase electricity third phase voltage is in positive half period, control the 5th switching device and be in off state, first stage, control the 6th switching device and be in conducting state, three-phase electricity third phase voltage forms loop to the 3rd inductance store electrical energy through the 3rd bidirectional thyristor, the 3rd inductance, the 6th switching device, the second electric capacity; Second stage, controls the 6th switching device and is in off state, the 3rd inductive discharge, and the electric current of the 3rd inductive discharge gets back to the 3rd inductance, the first capacitor charging through the body diode of the 5th switching device, the first electric capacity, the 3rd bidirectional thyristor;
When three-phase electricity third phase voltage is in negative half-cycle, control the 6th switching device and be in off state, phase III, control the 5th switching device and be in conducting state, three-phase electricity third phase voltage forms loop to the 3rd inductance store electrical energy through the 3rd bidirectional thyristor, the second inductance, the 5th switching device, the first electric capacity; Fourth stage controls the 3rd switching device and is in off state, the 3rd inductive discharge, and the electric current of the 3rd inductive discharge gets back to the 3rd inductance, the second capacitor charging through the body diode of the 6th switching device, the second electric capacity, the 3rd bidirectional thyristor.
9. the control method of a kind of three phase rectifier booster circuit according to claim 7, is characterized in that: the control mode that described three phase rectifier booster circuit works in battery operation pattern specifically comprised with the next stage:
First stage, when control second switch device, the 5th switching device are in conducting state, positive battery group, the first unidirectional thyristor, the first inductance, second switch device, the second electric capacity composition loop are to the first inductance store electrical energy; Negative battery group, the first electric capacity, the 5th switching device, the 3rd inductance, the second unidirectional thyristor composition loop are to the 3rd inductance store electrical energy;
Second stage, when control second switch device, the 5th switching device are in off-state, first inductive discharge, the electric current of the first inductive discharge gets back to the first inductance, the first capacitor charging through the body diode of the first switching device, the first electric capacity, positive battery group, the first unidirectional thyristor; 3rd inductive discharge, the electric current of the 3rd inductive discharge gets back to the 3rd inductance, the second capacitor charging through the second unidirectional thyristor, negative battery group, the second electric capacity, the 6th switching device body diode.
10. a three phase rectifier booster circuit, is characterized in that: comprise positive battery group, negative battery group, N number of rectifier boost module, each described rectifier boost module includes the first bidirectional thyristor, the second bidirectional thyristor SCR2, the 3rd bidirectional thyristor, the first unidirectional thyristor, the second unidirectional thyristor, the first inductance, the second inductance, the 3rd inductance, three-phase full-controlled rectifier bridge, the first electric capacity, the second electric capacity, corresponding one end being connected to three-phase electricity first-phase, three-phase electricity second-phase, three-phase electricity third phase respectively, one end of one end of described first bidirectional thyristor, one end of described second bidirectional thyristor, described 3rd bidirectional thyristor, the anode of described first unidirectional thyristor, the negative electrode of described second unidirectional thyristor are connected respectively the negative terminal of the anode to described positive battery group, described negative battery group, and the negative terminal of described positive battery group and the anode of described negative battery group are all connected to the zero line of three-phase electricity, the negative electrode of described first unidirectional thyristor and the anode of described first bidirectional thyristor are all connected to one end of described first inductance, the other end of described second bidirectional thyristor is connected to one end of described second inductance, the other end of described 3rd bidirectional thyristor and the anode of described second unidirectional thyristor are all connected to one end of described 3rd inductance, described first inductance, second inductance, the other end of the 3rd inductance is connected to the three-phase input end of described three-phase full-controlled rectifier bridge respectively, two outputs of described three-phase full-controlled rectifier bridge are connected to one end of described first electric capacity and one end of described second electric capacity respectively, the other end of described first electric capacity and described second electric capacity is all connected to the zero line of three-phase electricity.
11. 1 kinds of uninterrupted power supplys based on any described three phase rectifier booster circuit of claim 1 to 6, it is characterized in that: comprise described three phase rectifier booster circuit, inversion module, the input of described inversion module is connected with the output of described three-phase full-controlled rectifier bridge.
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PCT/CN2015/088722 WO2017024642A1 (en) | 2015-08-13 | 2015-09-01 | Three-phase rectifier boost circuit and control method therefor, and uninterruptible power supply |
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