CN205142070U - Big power drive system of asynchronous motor - Google Patents
Big power drive system of asynchronous motor Download PDFInfo
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- CN205142070U CN205142070U CN201520973634.5U CN201520973634U CN205142070U CN 205142070 U CN205142070 U CN 205142070U CN 201520973634 U CN201520973634 U CN 201520973634U CN 205142070 U CN205142070 U CN 205142070U
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- 238000004804 winding Methods 0.000 claims abstract description 114
- 239000003990 capacitor Substances 0.000 claims abstract description 5
- 238000004146 energy storage Methods 0.000 abstract 1
- 238000000034 method Methods 0.000 description 13
- 230000010349 pulsation Effects 0.000 description 8
- 238000005516 engineering process Methods 0.000 description 2
- 238000009413 insulation Methods 0.000 description 2
- 230000001360 synchronised effect Effects 0.000 description 2
- 230000000694 effects Effects 0.000 description 1
- 239000000178 monomer Substances 0.000 description 1
Abstract
The utility model discloses an asynchronous motor's big power drive system has solved the difficult problem of high -power three -phase asynchronous motor drive. Including electric wire netting (1), the industrial control machine, three -phase full -bridge rectifier (2), energy -storage capacitor (3), IGBT module and three -phase asynchronous motor winding, a phase winding (4) of three -phase asynchronous motor stator, B phase winding (5) and C phase winding (6) all are the settings of opening a way, after establishing ties, the 1st IGBT module (7) and the 2nd IGBT module (8) form bridge arm on the A phase winding, after establishing ties, the 3rd IGBT module (9) and fourth IGBT module (10) form bridge arm under the A phase winding, the switching pulse need not carried out in step to the last bridge arm and the lower two sets of three -phase converter IGBT modules of bridge arm of every phase winding, there is higher reliability, can adopt half the switching frequency, reach equal torque ripple, so essential up converter's loss reduction, the power device can use in the increase -volume.
Description
Technical field
The present invention relates to a kind of high-power driving system, particularly based on the high-power driving system of the threephase asynchronous of winding open circuit.
Background technology
In high-power (more than 1MW) threephase asynchronous high-power driving system, what the winding of threephase asynchronous generally adopted is star or triangle two kinds of connections, traditional drive system based on threephase asynchronous or permanent magnet motor that what drive system generally adopted is, adopts a three phase converter to drive.The subject matter of this scheme is that the monomer capacity of the prime power module I GBT of frequency converter is limited, be generally less than 1MW, along with the increase of power, the parallel connection of power model or the method for series connection must be adopted, if employing parallel method, then must ensure the synchronous of switching pulse; If employing series connection method, then must ensure that series power module realizes well all pressing, the technology that two schemes is both increasing Drive and Control Circuit virtually realizes difficulty, meanwhile, because drive system requires strict for torque pulsation, generally all need to adopt higher switching frequency (more than 1kHz) to carry out drive motors, turn increase the loss of frequency converter like this, frequency converter exports generally containing higher pulse spike, can have an impact to the insulation of motor, and affect the life-span of motor.
Summary of the invention
The present invention proposes a kind of high-power driving system of asynchronous motor, solves the technical problem that high-power threephase asynchronous motor drives difficulty.
The present invention solves above technical problem by the following technical programs:
A kind of high-power driving system of asynchronous motor, comprise electrical network, Industrial Control Computer, three-phase full-bridge rectifier, storage capacitor, IGBT module and threephase asynchronous winding, threephase asynchronous stator A phase winding, B phase winding and C phase winding are all that open circuit is arranged, first IGBT module forms brachium pontis on A phase winding after connecting with the second IGBT module, 3rd IGBT module forms brachium pontis under A phase winding after connecting with the 4th IGBT module, on A phase winding, under brachium pontis and A phase winding, brachium pontis is connected in parallel on the output DC bus of three-phase full-bridge rectifier respectively, the emitting stage of the first IGBT module is connected with one end of threephase asynchronous stator A phase winding by brachium pontis three-phase common mode reactor on A phase winding with the tie point of the second IGBT module collector electrode, the other end of threephase asynchronous stator A phase winding 4 is linked together by the emitting stage of brachium pontis three-phase common mode reactor and the 3rd IGBT module under A phase winding and the tie point of the 4th IGBT module collector electrode, 5th IGBT module forms brachium pontis on B phase winding after connecting with the 6th IGBT module, 7th IGBT module forms brachium pontis under B phase winding after connecting with the 8th IGBT module, on B phase winding, under brachium pontis and B phase winding, brachium pontis is connected in parallel on the output DC bus of three-phase full-bridge rectifier respectively, the emitting stage of the 5th IGBT module is connected with one end of threephase asynchronous stator B phase winding by brachium pontis three-phase common mode reactor on B phase winding with the tie point of the 6th IGBT module collector electrode, the other end of threephase asynchronous stator B phase winding is linked together by the emitting stage of brachium pontis three-phase common mode reactor and the 7th IGBT module under B phase winding and the tie point of the 8th IGBT module collector electrode, 9th IGBT module forms brachium pontis on C phase winding after connecting with the tenth IGBT module, 11 IGBT module forms brachium pontis under C phase winding after connecting with the 12 IGBT module, on C phase winding, under brachium pontis and C phase winding, brachium pontis is connected in parallel on the output DC bus of three-phase full-bridge rectifier respectively, the emitting stage of the 9th IGBT module is connected with one end of threephase asynchronous stator C phase winding by brachium pontis three-phase common mode reactor on C phase winding with the tie point of the tenth IGBT module collector electrode, the other end of threephase asynchronous stator C phase winding is linked together by brachium pontis three-phase common mode reactor under C phase winding and the emitting stage of the 11 IGBT module and the tie point of the 12 IGBT module collector electrode.
A control method for asynchronous motor high-power driving system, comprises the following steps:
The first step, in Industrial Control Computer, set A phase standard carrier, this carrier wave is standard triangular wave, and frequency is set by industrial control unit (ICU), and this frequency is also the switching frequency of IGBT.
Second step, in Industrial Control Computer, arrange the driving voltage reference signal of the IGBT module PMW pwm switch signal on A phase winding in brachium pontis, setting principle is: calculate A phase driving voltage reference signal Ref_A+ according to the A phase driving voltage of asynchronous machine.
The A phase standard carrier signal CA1 that 3rd step, the A phase driving voltage reference signal Ref_A+ obtained by second step and the first step obtain compares, and when Ref_A+ is greater than CA1, exporting SWA is 1, otherwise is 0.The negate signal of SWA and SWA is inputted Dead Time generator respectively, finally obtains actual switch and export the first IGBT module 7 and the second IGBT module 8 that SWA+ and SWA-, SWA+ and SWA-drive phase brachium pontis in A phase in three-phase full-bridge inverting circuit respectively;
4th step, the A phase driving voltage reference signal Ref_A+ negate that second step is obtained, obtain Ref_A-, namely Ref_A+ and Ref_A-sum is zero, the carrier wave CA2 of Ref_A-is the result of CA1 time delay half switch periods, Ref_A-and CA2 compares, when Ref_A-is greater than CA2, exporting SWa is 1, otherwise be 0, the negate signal of SWa and SWa is inputted Dead Time generator respectively, finally obtain actual switch and export SWa+ and SWa-, SWa+ with SWa-drives the 3rd IGBT module and the 4th IGBT module of the lower phase brachium pontis of A phase in three-phase full-bridge inverting circuit respectively, adopt the method for half switch periods that to be staggered by CA1 and CA2, can ensure that the system switching frequency of equivalence becomes 2 times of frequency converter actual switch frequency, effectively reduce torque pulsation like this, in other words under the prerequisite ensureing same torque pulsation, the actual switch frequency of frequency converter becomes 1/2 of system switching frequency, greatly reduce the loss of frequency converter like this, add the actual capacity of frequency converter, the upper brachium pontis of B phase and lower brachium pontis, and the upper brachium pontis of C phase is identical with the control method of A phase with the control method of lower brachium pontis.
Advantage of the present invention and effect as follows, it is synchronous that the upper brachium pontis of every phase winding and lower brachium pontis two groups of three phase converter IGBT module do not need to carry out switching pulse, there is higher reliability, the switching frequency of half can be adopted, reach equal torque pulsation, the loss of frequency converter reduces so in essence, power device can use in increase-volume, add current output capability equivalently, for DC bus-bar voltage, there is higher utilance, add voltage fan-out capability equivalently, pulse spike only has the half of traditional three phase converter, therefore require to reduce to the class of insulation of motor.
Accompanying drawing explanation
Fig. 1 is structural representation of the present invention;
Fig. 2 is brachium pontis carrier waveform 21 in A phase of the present invention, A phase descends brachium pontis winding referenced drive voltage waveform 23 and A phase in brachium pontis carrier waveform 22, A phase to descend the oscillogram of brachium pontis winding referenced drive voltage waveform 24.
Embodiment
Below in conjunction with accompanying drawing, the present invention is described in detail:
A kind of high-power driving system of asynchronous motor, comprise electrical network 1, Industrial Control Computer, three-phase full-bridge rectifier 2, storage capacitor 3, IGBT module and threephase asynchronous winding, threephase asynchronous stator A phase winding 4, B phase winding 5 and C phase winding 6 are all that open circuit is arranged, first IGBT module 7 forms brachium pontis on A phase winding after connecting with the second IGBT module 8, 3rd IGBT module 9 forms brachium pontis under A phase winding after connecting with the 4th IGBT module 10, on A phase winding, under brachium pontis and A phase winding, brachium pontis is connected in parallel on the output DC bus of three-phase full-bridge rectifier 2 respectively, the emitting stage of the first IGBT module 7 is connected with one end of threephase asynchronous stator A phase winding 4 by brachium pontis three-phase common mode reactor 11 on A phase winding with the tie point of the second IGBT module 8 collector electrode, the other end of threephase asynchronous stator A phase winding 4 is linked together by the emitting stage of brachium pontis three-phase common mode reactor 12 and the 3rd IGBT module 9 under A phase winding and the tie point of the 4th IGBT module 10 collector electrode, 5th IGBT module 13 forms brachium pontis on B phase winding after connecting with the 6th IGBT module 14, 7th IGBT module 15 forms brachium pontis under B phase winding after connecting with the 8th IGBT module 16, on B phase winding, under brachium pontis and B phase winding, brachium pontis is connected in parallel on the output DC bus of three-phase full-bridge rectifier 2 respectively, the emitting stage of the 5th IGBT module 13 is connected with one end of threephase asynchronous stator B phase winding 5 by brachium pontis three-phase common mode reactor 11 on B phase winding with the tie point of the 6th IGBT module 14 collector electrode, the other end of threephase asynchronous stator B phase winding 5 is linked together by the emitting stage of brachium pontis three-phase common mode reactor 12 and the 7th IGBT module 15 under B phase winding and the tie point of the 8th IGBT module 16 collector electrode, 9th IGBT module 17 forms brachium pontis on C phase winding after connecting with the tenth IGBT module 18, 11 IGBT module 19 forms brachium pontis under C phase winding after connecting with the 12 IGBT module 20, on C phase winding, under brachium pontis and C phase winding, brachium pontis is connected in parallel on the output DC bus of three-phase full-bridge rectifier 2 respectively, the emitting stage of the 9th IGBT module 17 is connected with one end of threephase asynchronous stator C phase winding 6 by brachium pontis three-phase common mode reactor 11 on C phase winding with the tie point of the tenth IGBT module 18 collector electrode, the other end of threephase asynchronous stator C phase winding 6 is linked together by the emitting stage of brachium pontis three-phase common mode reactor the 12 and the 11 IGBT module 19 under C phase winding and the tie point of the 12 IGBT module 20 collector electrode.
A control method for asynchronous motor high-power driving system, comprises the following steps:
The first step, in Industrial Control Computer, set A phase standard carrier, this carrier wave is standard triangular wave, and frequency is set by industrial control unit (ICU), and this frequency is also the switching frequency of IGBT.
Second step, in Industrial Control Computer, arrange the driving voltage reference signal of the IGBT module PMW pwm switch signal on A phase winding in brachium pontis, setting principle is: calculate A phase driving voltage reference signal Ref_A+ according to the A phase driving voltage of asynchronous machine.
The A phase standard carrier signal CA1 that 3rd step, the A phase driving voltage reference signal Ref_A+ obtained by second step and the first step obtain compares, and when Ref_A+ is greater than CA1, exporting SWA is 1, otherwise is 0.The negate signal of SWA and SWA is inputted Dead Time generator respectively, finally obtains actual switch and export the first IGBT module 7 and the second IGBT module 8 that SWA+ and SWA-, SWA+ and SWA-drive phase brachium pontis in A phase in three-phase full-bridge inverting circuit respectively;
4th step, the A phase driving voltage reference signal Ref_A+ negate that second step is obtained, obtain Ref_A-, namely Ref_A+ and Ref_A-sum is zero, the carrier wave CA2 of Ref_A-is the result of CA1 time delay half switch periods, Ref_A-and CA2 compares, when Ref_A-is greater than CA2, exporting SWa is 1, otherwise be 0, the negate signal of SWa and SWa is inputted Dead Time generator respectively, finally obtain actual switch and export SWa+ and SWa-, SWa+ with SWa-drives the 3rd IGBT module 9 and the 4th IGBT module 10 of the lower phase brachium pontis of A phase in three-phase full-bridge inverting circuit respectively, adopt the method for half switch periods that to be staggered by CA1 and CA2, can ensure that the system switching frequency of equivalence becomes 2 times of frequency converter actual switch frequency, effectively reduce torque pulsation like this, in other words under the prerequisite ensureing same torque pulsation, the actual switch frequency of frequency converter becomes 1/2 of system switching frequency, greatly reduce the loss of frequency converter like this, add the actual capacity of frequency converter, the upper brachium pontis of B phase and lower brachium pontis, and the upper brachium pontis of C phase is identical with the control method of A phase with the control method of lower brachium pontis.
Drive system of the present invention provides three-phase alternating current to input by electrical network 1, is transformed into direct voltage through three-phase full-bridge rectifier 2, and form DC bus, DC bus mainly contains storage capacitor 3 and forms.DC bus connects the direct current input side of two three-phase full-bridge inverting circuit respectively.The basic composition of three-phase full-bridge inverting circuit is a power model based on IGBT and diodes in parallel, asynchronous motor has a three-phase windings, this three-phase windings is neither adopt the pattern of corner connection, the pattern that star connects neither be adopted, but 6 of three-phase windings taps are all drawn, form A phase winding 4, B phase winding 5, C phase winding 6.Three-phase full-bridge inverting circuit is connected by the upper three-phase tap of the A phase winding 4 of a three-phase common mode reactor 11 and asynchronous motor, B phase winding 5, C phase winding 6, and three-phase full-bridge inverting circuit is connected by the lower three-phase tap of the A phase winding 4 of a three-phase common mode reactor 12 and asynchronous motor, B phase winding 5, C phase winding 6.
Fig. 2 is brachium pontis carrier waveform 21 in A phase of the present invention, the lower brachium pontis carrier waveform 22 of A phase, in A phase, brachium pontis winding referenced drive voltage waveform 23 and A phase descend the oscillogram of brachium pontis winding referenced drive voltage waveform 24, Ref_A+ is brachium pontis winding referenced drive voltage waveform 23 in A phase, CA1 is brachium pontis carrier waveform in A phase, Ref_A+ and CA1 input comparator compares, when Ref_A+ is greater than CA1, exporting SWA is 1, otherwise be 0, the negate signal of SWA and SWA is inputted Dead Time generator respectively, finally obtain actual switch and export SWA+ and SWA-, SWA+ with SWA-drives the first IGBT module 7 and the second IGBT module 8 of brachium pontis in A phase in three-phase full-bridge inverting circuit respectively, Ref_A-is the lower brachium pontis winding referenced drive voltage waveform 24 of A phase Ref_A+ negate obtained, namely Ref_A+ and Ref_A-sum is zero.CA2 is the lower brachium pontis carrier waveform 22 of A phase of Ref_A-, CA2 is the result of CA1 time delay half switch periods, Ref_A-and CA2 input comparator compares, when Ref_A-is greater than CA2, exporting SWa is 1, otherwise be 0, the negate signal of SWa and SWa is inputted Dead Time generator respectively, finally obtain actual switch and export SWa+ and SWa-, SWa+ with SWa-drives the 3rd IGBT module 9 and the 4th IGBT module 10 of the lower brachium pontis of A phase in three-phase full-bridge inverting circuit respectively, adopt the method for half switch periods that to be staggered by CA1 and CA2, can ensure that the system switching frequency of equivalence becomes 2 times of frequency converter actual switch frequency, effectively reduce torque pulsation like this, in other words under the prerequisite ensureing same torque pulsation, the actual switch frequency of frequency converter becomes 1/2 of system switching frequency, greatly reduce the loss of frequency converter like this, add the actual capacity of frequency converter, B phase, and the control method of C phase is identical with foregoing description, unique difference is the relative Ref_A+ phase difference of reference signal Ref_B+ and Ref_C+ difference 120 ° and 240 °.
Claims (1)
1. the high-power driving system of an asynchronous motor, comprise electrical network (1), Industrial Control Computer, three-phase full-bridge rectifier (2), storage capacitor (3), IGBT module and threephase asynchronous winding, it is characterized in that, the A phase winding (4) of threephase asynchronous stator, the B phase winding (5) of threephase asynchronous stator and the C phase winding (6) of threephase asynchronous stator are all that open circuit is arranged, first IGBT module (7) forms brachium pontis on A phase winding after connecting with the second IGBT module (8), 3rd IGBT module (9) forms brachium pontis under A phase winding after connecting with the 4th IGBT module (10), on A phase winding, under brachium pontis and A phase winding, brachium pontis is connected in parallel on the output DC bus of three-phase full-bridge rectifier (2) respectively, the emitting stage of the first IGBT module (7) is connected with one end of threephase asynchronous stator A phase winding (4) by brachium pontis three-phase common mode reactor (11) on A phase winding with the tie point of the second IGBT module (8) collector electrode, the other end of threephase asynchronous stator A phase winding (4) is linked together by brachium pontis three-phase common mode reactor (12) under A phase winding and the emitting stage of the 3rd IGBT module (9) and the tie point of the 4th IGBT module (10) collector electrode, 5th IGBT module (13) forms brachium pontis on B phase winding after connecting with the 6th IGBT module (14), 7th IGBT module (15) forms brachium pontis under B phase winding after connecting with the 8th IGBT module (16), on B phase winding, under brachium pontis and B phase winding, brachium pontis is connected in parallel on the output DC bus of three-phase full-bridge rectifier (2) respectively, the emitting stage of the 5th IGBT module (13) is connected with one end of threephase asynchronous stator B phase winding (5) by brachium pontis three-phase common mode reactor (11) on B phase winding with the tie point of the 6th IGBT module (14) collector electrode, the other end of threephase asynchronous stator B phase winding (5) is linked together by brachium pontis three-phase common mode reactor (12) under B phase winding and the emitting stage of the 7th IGBT module (15) and the tie point of the 8th IGBT module (16) collector electrode, 9th IGBT module (17) forms brachium pontis on C phase winding after connecting with the tenth IGBT module (18), 11 IGBT module (19) forms brachium pontis under C phase winding after connecting with the 12 IGBT module (20), on C phase winding, under brachium pontis and C phase winding, brachium pontis is connected in parallel on the output DC bus of three-phase full-bridge rectifier (2) respectively, the emitting stage of the 9th IGBT module (17) is connected with one end of threephase asynchronous stator C phase winding (6) by brachium pontis three-phase common mode reactor (11) on C phase winding with the tie point of the tenth IGBT module (18) collector electrode, the other end of threephase asynchronous stator C phase winding (6) is linked together by brachium pontis three-phase common mode reactor (12) under C phase winding and the emitting stage of the 11 IGBT module (19) and the tie point of the 12 IGBT module (20) collector electrode.
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| CN201520973634.5U CN205142070U (en) | 2015-11-30 | 2015-11-30 | Big power drive system of asynchronous motor |
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| CN201520973634.5U CN205142070U (en) | 2015-11-30 | 2015-11-30 | Big power drive system of asynchronous motor |
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| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN105429555A (en) * | 2015-11-30 | 2016-03-23 | 北京赛思亿电气科技有限公司 | High-power drive system for asynchronous motor and control method of high-power drive system |
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Cited By (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN105429555A (en) * | 2015-11-30 | 2016-03-23 | 北京赛思亿电气科技有限公司 | High-power drive system for asynchronous motor and control method of high-power drive system |
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Address after: 214105 room 806-813, block C, Chong Dong building, 88, Dan Shan Road, Xishan Town, Xishan, Wuxi. Co-patentee after: SHANXI FENXI HEAVY INDUSTRY Co.,Ltd. Patentee after: WUXI SILENT ELECTRIC SYSTEM (SES) TECHNOLOGY Co.,Ltd. Address before: 100097 room 506 and 507, block B, Jia Hao International Center, 116 Zizhu Road, Haidian District, Beijing. Co-patentee before: SHANXI FENXI HEAVY INDUSTRY Co.,Ltd. Patentee before: BEIJING CSE ELECTRICAL SCIENCE & TECHNOLOGY CO.,LTD. |
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Address after: Plot 83-D, Development Zone, Xinwu District, Wuxi City, Jiangsu Province, 214105 Patentee after: China Shipbuilding Saisiyi (Wuxi) Electrical Technology Co.,Ltd. Country or region after: Zhong Guo Patentee after: China State Shipbuilding Corporation Fenxi Heavy Industry Co.,Ltd. Address before: 214105 room 806-813, block C, Chong Dong building, 88, Dan Shan Road, Xishan Town, Xishan, Wuxi. Patentee before: WUXI SILENT ELECTRIC SYSTEM (SES) TECHNOLOGY Co.,Ltd. Country or region before: Zhong Guo Patentee before: SHANXI FENXI HEAVY INDUSTRY Co.,Ltd. |