CN101917018B - Combined control cabinet of large-power doubly-fed wind-driven generator - Google Patents
Combined control cabinet of large-power doubly-fed wind-driven generator Download PDFInfo
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- CN101917018B CN101917018B CN201010239246A CN201010239246A CN101917018B CN 101917018 B CN101917018 B CN 101917018B CN 201010239246 A CN201010239246 A CN 201010239246A CN 201010239246 A CN201010239246 A CN 201010239246A CN 101917018 B CN101917018 B CN 101917018B
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Abstract
The invention relates to a combined control cabinet of a large-power doubly-fed wind-driven generator, comprising a switch cabinet, a network side cabinet and a rotor cabinet. The switch cabinet is internally provided with a lightning arrester branch (1), a charging branch (2), a network side input branch (3) and a generator output branch (4) which are arranged in parallel, the switch cabinet is also provided with a brake loop (14), the network side cabinet is internally provided with a fast fuse unit (5), a network side power module (6), a network side controller (7), a network side reactor (8) and a contactor (9), and the rotor cabinet is internally provided with a rotor side power module (10), a rotor controller (11), a rotor side reactor (12) and a CROWBAR module (13).
Description
Technical field
The present invention relates to a kind of Combination Control cabinet of double-fed wind power generator, the Combination Control cabinet of the high-power double-fed wind power generator of especially a kind of 1.5MW.
Background technology
Control cubicle is the hinge equipment between wind-driven generator and the AC network; Be the key equipment that the operating state and the operational factor of wind-driven generator are regulated and control, at present, mostly the control cubicle that is used for wind-driven generator is the apportion element is sporadicly assembled; Not only assemble difficult in maintenance; And be easy to generate frequency interferences each other between each apportion element, and especially in high-power double-fed wind power generator, this frequency interferences even can have influence on the wind-driven generator operate as normal.
Summary of the invention
The objective of the invention is to: the difficult in maintenance and frequency interferences of the assembling that exists when being used for high-power double-fed wind power generator to the control cubicle of present apportion element assembling can have influence on the practical problem of wind-driven generator operate as normal, and a kind of Combination Control cabinet of new high-power double-fed wind power generator is provided.The objective of the invention is to realize like this: a kind of Combination Control cabinet of high-power double-fed wind power generator is characterized in that: the Combination Control cabinet is become with the rotor group by switch cubicle, net side cabinet, wherein:
A) be provided with lightning arrester branch road (1) arranged side by side, charging paths (2), net side input branch road (3) and generator output branch road (4) in the switch cubicle, also be provided with brake circuit (14) in the switch cubicle; Be provided with fast acting fuse group (5), net side power model (6), net side controller (7), network reactor (8) and contactor (9) in the net side cabinet; Be provided with rotor-side power model (10), rotor controller (11), rotor-side reactor (12) and CROWBAR module (13) in the rotor cabinet;
B) be connected with the outer AC network of Combination Control cabinet after an end of each branch switch converges in the switch cubicle; The other end is connected with corresponding electrical circuits separately respectively; Wherein: the other end of lightning arrester branch switch is through arrester ground, and the other end of charging paths switch process is by rectified three-phase circuit V
1And capacitor C
1Resistance R
1And R
2Fast acting fuse (5) by the net side behind the charging circuit of forming is connected with the DC side of rotor-side power model (6), and simultaneously, this charging circuit (2) also is connected with 2 pin with 1 pin of the middle DC port of brake circuit (14); The other end of net side input branch switch is connected with network reactor (8) input; The other end of generator output branch switch is connected with the generator output end of insertion switch cabinet;
C) in the net side cabinet, each end of the three-phase alternating current of network reactor (8) other end respectively with net side power model (6) in the L of AC side
1End L
2End L
3End connects; The other end of fast acting fuse (5) is connected with the DC side of net side power model (6); Fiber port 5 pin in fiber port 5 pin in net side controller (7) and the switch cubicle in the brake circuit (14) are connected, and fiber port 4 pin of netting in the side controller (7) are connected with fiber port 1 pin in netting side power model (6);
D) in the rotor cabinet; The rotor-end of generator is connected with U pin, V pin, the W pin of ac input end mouth in rotor-side reactor (12) one ends and the CROWBAR module (13) simultaneously, the three-phase alternating current of rotor-side reactor (12) other end each hold respectively with the rotor-side power model in the L of AC side
1End L
2End L
3End connects, and fiber port 1 pin in the CROWBAR module (13) is connected with fiber port 5 pin in the rotor controller (11), and fiber port 4 pin in the rotor controller (11) are connected with fiber port 1 pin in the rotor-side power model (10);
E) 1 pin of rotor controller (11) is a PORT COM, and 2 pin are the encoder port, and 3 pin are the theft-resistant link chain port, and they are connected with bus CAN port, line of codes Encoder port and the theft-resistant link chain safetychain port of peripheral hardware control usefulness respectively; Being connected the realization peripheral hardware through data wire between fiber port 6 pin in fiber port 6 pin in net side controller (7) and the rotor controller (11) controls and uses information sharing.
In the present invention: described net side power model (6) and all integrated unsteady flow module of rotor-side power model (10), every side contains three integrated unsteady flow modules, and their AC side is respectively L
1End L
2End L
3End, and corresponding with cross streams electricity; Described network reactor (8) and rotor-side reactor (12) are integrated reactor module, and the reactor in the integrated reactor module is a three-phase alternating current reactance device.
In the present invention: described integrated unsteady flow module is by housing IGBT module, cooling fan and capacitor group to be wrapped in wherein; Described integrated reactor module is by housing and base reactor and cooling fan to be wrapped in wherein, and their housing all is to adopt metal material to make.
In the present invention: described net side controller (6) and rotor controller (10) are the controller of JNFD-1500-ZKB, and described CROWBAR module (13) is JNFD-1500-YYCROWBAR, described brake circuit V
2Be JNFD-1500-ZDZJ.
The invention has the advantages that: because net side power model and rotor-side power model all adopt integrated unsteady flow module and integrated reactor module (described integrated unsteady flow module and integrated reactor module propose patent application to State Intellectual Property Office with the title of " great power conversion circuit module " and " integrated reactor module " respectively on the same day by this case applicant); They all have independently metal shell; Not only make the control cubicle assembling safeguard convenient; And can prevent the frequency interferences that the apportion interelement exists in the control cubicle, guarantee the operate as normal of high-power dual feedback wind power generation system; Owing to adopt the structure of combination sideboard, simultaneously, the model of net side controller and rotor controller is identical, after connecting through data wire between them, can realize that peripheral hardware control uses information sharing, makes structure compactness more; The brake circuit V that is provided with in the lightning arrester branch road that is provided with in the switch cubicle, the net side cabinet
2And the CROWBAR module that is provided with in the rotor cabinet; Can guarantee that the Combination Control cabinet is under the adverse circumstances of thunderstorm; And direct voltage fault or rotor AC excitation signal overload occurs or when unusual, handle in real time, guarantees the operate as normal of high-power double-fed wind power generator group.
Description of drawings
Fig. 1 is the sketch map of Combination Control cabinet element arrangements embodiment of the present invention;
Fig. 2 is the electrical schematic diagram of Combination Control cabinet of the present invention
Among the figure: I, switch cubicle, II, net side cabinet, III, rotor cabinet;
1, lightning arrester branch road, 2, charging paths, 3, net side input branch road, 4, generator output branch road; 5, fast acting fuse group, 6, net side power model, 7, the net side controller, 8, network reactor; 9, contactor, 10, the rotor-side power model, 11, rotor controller; 12, rotor-side reactor, 13, the CROWBAR module, 14, brake circuit.
Embodiment
Accompanying drawing discloses the concrete structure of the embodiment of the invention without limitation, below in conjunction with accompanying drawing embodiments of the invention is done further to describe.
Visible by Fig. 1; The present invention is the Combination Control cabinet that is formed by switch cubicle I, net side cabinet II and rotor cabinet III combination back; Wherein, Be provided with lightning arrester branch road 1 arranged side by side, charging paths 2, net side input branch road 3 and generator output branch road 4 among the switch cubicle I, be provided with fast acting fuse group 5, net side power model 6, net side controller 7, network reactor 8 and contactor 9 among the net side cabinet II; Be provided with rotor-side power model 10, rotor controller 11, rotor-side reactor 12 and CROWBAR module 13 among the rotor cabinet III.
Visible by Fig. 2:
In switch cubicle I: an end of each branch switch converges the back and is connected with AC network outside the Combination Control cabinet, and the other end is connected with corresponding electrical circuits separately respectively, wherein: lightning arrester branch switch F
1The other end through lightning arrester FL
1Ground connection, charging paths switch F
3The other end through by relay K M
2Rectified three-phase circuit V
1And capacitor C
1Resistance R
1And R
2Behind the charging circuit of forming by the fast acting fuse F of net side
12, F
13, F
14, F
15, F
16And F
17B with rotor-side power model 6
+, B
-Connect, charging circuit also is connected with the DC port of brake circuit 14; The other end of net side input branch switch F5 is connected with network reactor 8 inputs in netting side cabinet II; Generator output branch switch Q
1The other end be connected with the stator output of the generator G of insertion switch cabinet.
Among the net side cabinet II: each end of the three-phase alternating current of network reactor 8 other ends respectively with the AC side L of net side power model 6
1End L
2End L
3End connects; The other end of fast acting fuse group 5 and the DC side B that nets side power model 6
+, B
-Connect; Fiber port 5 pin among fiber port 5 pin of net in the side controller 7 and the switch cubicle I in the brake circuit 14 are connected, and fiber port 4 pin of netting in the side controller 7 are connected with fiber port 1 pin in netting side power model 6.
Among the rotor cabinet III; The rotor of generator G simultaneously with rotor-side reactor 12 1 ends and CROWBAR module 13 in exchange port U pin, V pin, W pin is connected, each holds respectively the AC side L with rotor-side power model 10 three-phase alternating current of rotor-side reactor 12 other ends
1End L
2End L
3End connects, and 1 fiber port of CROWBAR module 13 is connected with fiber port 5 pin in the rotor controller 11, and fiber port 4 pin in the rotor controller 11 are connected with fiber port 1 pin in the rotor-side power model 10.
In addition; 1 pin in the rotor controller 11 among the rotor cabinet III is a PORT COM; 2 pin are the encoder port, and 3 pin are the theft-resistant link chain port, and they are connected with bus CAN port, line of codes Encoder port and the theft-resistant link chain safetychain port of peripheral hardware control usefulness respectively; Being connected the realization peripheral hardware through data wire between fiber port 6 pin in fiber port 6 pin of net in the side controller 7 and the rotor controller 11 controls and uses information sharing
In the present embodiment: described net side controller 6 and rotor controller 10 are the controller of JNFD-1500-ZKB; Described CROWBAR module 13 is JNFD-1500-YYCROWBAR; Described brake circuit 14 is JNFD-1500-ZDZJ; Described net side power model 6 and all integrated unsteady flow module of rotor-side power model 10, every side contains three integrated unsteady flow modules, and each integrated unsteady flow module corresponds respectively to a cross streams; Described network reactor 8 is integrated reactor module with rotor-side reactor 12, and the reactor in the said integrated reactor module is a three-phase alternating current reactance device.
Described integrated unsteady flow module is by housing IGBT module, cooling fan and capacitor group to be wrapped in wherein; Described integrated reactor module is by housing and base reactor and cooling fan to be wrapped in wherein, and their housing all is to adopt metal material to make.This case applicant proposes patent application to State Intellectual Property Office with integrated unsteady flow module and integrated reactor module and the application's case on the same day in the lump.
Claims (1)
1. the Combination Control cabinet of a high-power double-fed wind power generator is characterized in that: the Combination Control cabinet is become with the rotor group by switch cubicle, net side cabinet, wherein:
A) be provided with lightning arrester branch road (1) arranged side by side, charging paths (2), net side input branch road (3) and generator output branch road (4) in the switch cubicle, also be provided with brake circuit (14) in the switch cubicle; Be provided with fast acting fuse group (5), net side power model (6), net side controller (7), network reactor (8) and contactor (9) in the net side cabinet; Be provided with rotor-side power model (10), rotor controller (11), rotor-side reactor (12) and CROWBAR module (13) in the rotor cabinet;
B) be connected with the outer AC network of Combination Control cabinet after an end of each branch switch converges in the switch cubicle; The other end is connected with corresponding electrical circuits separately respectively; Wherein: the other end of lightning arrester branch switch is through arrester ground, and the other end of charging paths switch process is by rectified three-phase circuit V
1And capacitor C
1Resistance R
1And R
2Fast acting fuse group (5) by the net side behind the charging circuit of forming is connected with the DC side of rotor-side power model (6), and simultaneously, charging circuit (2) also is connected with 2 pin with 1 pin of the middle DC port of brake circuit (14); The other end of net side input branch switch is connected with network reactor (8) input; The other end of generator output branch switch is connected with the generator output end of insertion switch cabinet;
C) in the net side cabinet, each end of the three-phase alternating current of network reactor (8) other end respectively with net side power model (6) in the L of AC side
1End L
2End L
3End connects; The other end of fast acting fuse group (5) is connected with the DC side of net side power model (6); Fiber port 5 pin in fiber port 5 pin in net side controller (7) and the switch cubicle in the brake circuit (14) are connected, and fiber port 4 pin of netting in the side controller (7) are connected with fiber port 1 pin in netting side power model (6);
D) in the rotor cabinet; The rotor-end of generator is connected with U pin, V pin, the W pin of ac input end mouth in rotor-side reactor (12) one ends and the CROWBAR module (13) simultaneously, the three-phase alternating current of rotor-side reactor (12) other end each hold respectively with the rotor-side power model in the L of AC side
1End L
2End L
3End connects, and fiber port 1 pin in the CROWBAR module (13) is connected with fiber port 5 pin in the rotor controller (11), and fiber port 4 pin in the rotor controller (11) are connected with fiber port 1 pin in the rotor-side power model (10);
E) 1 pin of rotor controller (11) is a PORT COM, and 2 pin are the encoder port, and 3 pin are the theft-resistant link chain port, and they are connected with bus CAN port, line of codes Encoder port and the theft-resistant link chain safetychain port of peripheral hardware control usefulness respectively; Being connected the realization peripheral hardware through data wire between fiber port 6 pin in fiber port 6 pin in net side controller (7) and the rotor controller (11) controls and uses information sharing;
Described net side power model (6) and all integrated unsteady flow module of rotor-side power model (10), every side contains three integrated unsteady flow modules, and their AC side is respectively L
1End L
2End L
3End, and corresponding with cross streams electricity respectively; Described network reactor (8) and rotor-side reactor (12) are integrated reactor module, and the reactor in the integrated reactor module is a three-phase alternating current reactance device;
Described integrated unsteady flow module is by housing IGBT module, cooling fan and capacitor group to be wrapped in wherein; Described integrated reactor module is by housing and base reactor and cooling fan to be wrapped in wherein, and their housing all is to adopt metal material to make.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN201010239246A CN101917018B (en) | 2010-07-28 | 2010-07-28 | Combined control cabinet of large-power doubly-fed wind-driven generator |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN201010239246A CN101917018B (en) | 2010-07-28 | 2010-07-28 | Combined control cabinet of large-power doubly-fed wind-driven generator |
Publications (2)
Publication Number | Publication Date |
---|---|
CN101917018A CN101917018A (en) | 2010-12-15 |
CN101917018B true CN101917018B (en) | 2012-10-03 |
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CN201010239246A Expired - Fee Related CN101917018B (en) | 2010-07-28 | 2010-07-28 | Combined control cabinet of large-power doubly-fed wind-driven generator |
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CN (1) | CN101917018B (en) |
Families Citing this family (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN103378550B (en) * | 2012-04-28 | 2016-12-14 | 艾默生网络能源有限公司 | A kind of wind power electrical cabinet |
CN103138674B (en) * | 2013-03-28 | 2015-11-11 | 北京索德电气工业有限公司 | High-power brushless double-fed motor variable frequency speed control system and control method |
CN107817452A (en) * | 2016-08-31 | 2018-03-20 | 天津瑞能电气有限公司 | Reactor platform is used in a kind of wind-power electricity generation frequency conversion device complete machine detection |
Citations (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US5861684A (en) * | 1995-12-27 | 1999-01-19 | Tandem Computers Incorporated | Flexible implementation of distributed DC power |
CN101252339A (en) * | 2008-03-26 | 2008-08-27 | 卧龙电气集团股份有限公司 | Polyphase electric machine variable frequency speed regulator |
EP2086087A2 (en) * | 2008-01-24 | 2009-08-05 | Honeywell International Inc. | Electronic Load Control Unit (ELCU) used as bus tie breaker in electrical power distribution |
CN101651330A (en) * | 2009-09-23 | 2010-02-17 | 哈尔滨九洲电气股份有限公司 | Crowbar protecting device of double-feed wind-electricity converter |
CN201781290U (en) * | 2010-07-28 | 2011-03-30 | 南京高传机电自动控制设备有限公司 | Combination control cabinet of high-power double-fed wind driven generator |
-
2010
- 2010-07-28 CN CN201010239246A patent/CN101917018B/en not_active Expired - Fee Related
Patent Citations (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US5861684A (en) * | 1995-12-27 | 1999-01-19 | Tandem Computers Incorporated | Flexible implementation of distributed DC power |
EP2086087A2 (en) * | 2008-01-24 | 2009-08-05 | Honeywell International Inc. | Electronic Load Control Unit (ELCU) used as bus tie breaker in electrical power distribution |
CN101252339A (en) * | 2008-03-26 | 2008-08-27 | 卧龙电气集团股份有限公司 | Polyphase electric machine variable frequency speed regulator |
CN101651330A (en) * | 2009-09-23 | 2010-02-17 | 哈尔滨九洲电气股份有限公司 | Crowbar protecting device of double-feed wind-electricity converter |
CN201781290U (en) * | 2010-07-28 | 2011-03-30 | 南京高传机电自动控制设备有限公司 | Combination control cabinet of high-power double-fed wind driven generator |
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CN101917018A (en) | 2010-12-15 |
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