CN201041943Y - Flexible AC double-feeder wind power generation and transmission system - Google Patents

Flexible AC double-feeder wind power generation and transmission system Download PDF

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Publication number
CN201041943Y
CN201041943Y CNU2007200846260U CN200720084626U CN201041943Y CN 201041943 Y CN201041943 Y CN 201041943Y CN U2007200846260 U CNU2007200846260 U CN U2007200846260U CN 200720084626 U CN200720084626 U CN 200720084626U CN 201041943 Y CN201041943 Y CN 201041943Y
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side converter
winding
double
parallel
series
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段善旭
邹旭东
康勇
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Huazhong University of Science and Technology
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Huazhong University of Science and Technology
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    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02EREDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
    • Y02E10/00Energy generation through renewable energy sources
    • Y02E10/70Wind energy
    • Y02E10/72Wind turbines with rotation axis in wind direction
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02EREDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
    • Y02E10/00Energy generation through renewable energy sources
    • Y02E10/70Wind energy
    • Y02E10/76Power conversion electric or electronic aspects
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02EREDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
    • Y02E40/00Technologies for an efficient electrical power generation, transmission or distribution
    • Y02E40/30Reactive power compensation

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Abstract

A flexible AC double-fed wind power generating and transmitting system consists of a double-fed aerogenerator, an AC excitation source, a series transformer, an antiparallel bidirectional thyristor and a monitoring device. The AC excitation source consists of a parallel side convertor, a series side convertor and a capacitance. The AC end of the parallel side convertor is connected with a rotor winding of the double-fed aerogenerator. The two DC ends of the parallel side convertor and the two DC ends of the series side convertor are connected with the two ends of the capacitance respectively. The AC end of the series side convertor is connected with a primary winding of the series transformer. An auxiliary winding of the series transformer is connected with the antiparallel bidirectional thyristor in parallel. One end of the auxiliary winding of the series transformer is connected with the stator winding of a flywheel energy-storing electric motor. The monitoring device achieves bypass protections by controlling the communicating state of the antiparallel bidirectional thyristor. The utility model can conduct rapid and effective regulations to the working conditions and parameters of the power system and guarantee the power system to operate safely, economically, efficiently and excellently.

Description

Flexible AC double-feed type wind generating and transmitting system
Technical field
The utility model belongs to distributed power generation technology and flexible AC transmission technology, is specifically related to a kind of flexible AC double-feed type wind generating and transmitting system, is applied to the trend control of distributed generation system.
Background technology
According to China's wind-powered electricity generation object of planning, the wind-powered electricity generation installed capacity of the year two thousand twenty whole nation will reach 2,000 ten thousand kilowatts.Therefore, China's electrical network will become a modernized hybrid power system with a large amount of distribution type renewable energy generating sets.A popular feature of regenerative resource is discontinuous and unstable.With the wind power generation is example, and the motive power of wind-driven generator is wind, and the random fluctuation of wind and the intermittent output characteristic that has determined wind-driven generator also are fluctuations and intermittently.When the capacity of wind energy turbine set hour, this specific character is not remarkable to the influence of electric power system, along with the access of large-scale wind power field, the increase of wind-powered electricity generation capacity proportion in system, wind energy turbine set can not be out in the cold to the influence of electric power system.Therefore, at one of preferential theme of the energy field of National Program for Medium-to Long-term Scientific and Technological Development 2006-2020 be exactly: ultra-large power transmission and distribution and power grid security guarantee.
At present, the representative direction and the main product of wind generator system product are the variable-speed constant-frequency wind power generation systems that is made of double-fed generator both at home and abroad, comprise double feed wind power generator, ac excitation power supply and supervising device, the stator winding of double feed wind power generator links to each other with three phase network; Ac excitation power supply is linked to each other with the electric capacity of side converter by common DC bus voltage of connecting by side converter in parallel and constitutes, side converter in parallel and series connection side converter are the three-phase voltage source type pwm converter of two back to back structure, and side converter wherein in parallel links to each other with double feed wind power generator rotor winding.Adopt the double-fed generation mode, broken through the traditional concept of the necessary strict synchronism operation of Mechatronic Systems, make prime mover rotating speed not limited by the generator output frequency, and the frequency of generator output voltage and electric current, amplitude and phase place are not subjected to the influence of spinner velocity and instantaneous position yet, realize flexibly connecting between the Mechatronic Systems, but do not had functions such as keying line trend.
It is the most economical operational mode of distributed generation system that distributed generation system and local area electrical network are incorporated into the power networks.Flourish along with wind generating technology, the installed capacity of being incorporated into the power networks increases day by day, the installed capacity of unit maximum has at present reached 5MW, its directly performance be interconnected between the distributed generation system, the scale of regional power grid constantly increases, then interconnected by between regional power grid forms more massive interconnected power system step by step.The formation of interconnected power system makes electric network composition complicated day by day, operation simultaneously is inharmonious with the scheduling aspect, can cause the trend irrational distribution in the electrical network, make power transmission network circulation power oscillation, power in power delivery, usually occur around sending and phenomenon such as power refluence, above-mentioned these problems cause electric energy losses a large amount of in the big interconnected network or are forced to reduce the conveying capacity of electrical network, under the serious situation even can cause the catastrophe of electric power system, make the operation of whole system and scheduling be subjected to very big influence.
When the capacity of distributed generation system accounts for whole electric power system capacity a certain proportion of the time, the transmission system of distributed generation system also can exist and causes so-called " buterfly effect " because of power transmission failure, the regional power grid that causes being made of a large amount of distributed generation systems collapses, and causes that further more massive electrical network as " dominoes " voltage collapse takes place in succession.For tackling this situation that may occur, be necessary in distributed generation system, to introduce the technological means of all kinds of flexible AC transmission elements and control, fast-changing operating condition of electric power system and operational factor are implemented effectively regulation and control fast, thereby guarantee safe, economic, efficient, the high-quality operation of electric power system under various operating modes.
Summary of the invention
The utility model provides a kind of flexible AC double-feed type wind generating and transmitting system, purpose is that fast-changing operating condition of electric power system and operational factor are implemented effectively regulation and control fast, guarantees safe, economic, efficient, the high-quality operation of electric power system under various operating modes.
The utility model proposes a kind of flexible AC double-feed type wind generating and transmitting system; comprise double feed wind power generator; ac excitation power supply and supervising device; ac excitation power supply comprises side converter in parallel; series connection side converter and electric capacity; side converter in parallel and series connection side converter are three-phase voltage source type pulse width modulated inverter; the interchange end of side converter in parallel is connected with the rotor winding of double feed wind power generator; two dc terminal of side converter in parallel are connected with the electric capacity two ends respectively with two dc terminal of series connection side converter; supervising device is used for side converter in parallel and series connection side converter are implemented monitoring; it is characterized in that: this system also comprises series transformer and inverse parallel bidirectional thyristor; former side's winding of series transformer is connected with the interchange end of series connection side converter; the two ends of series transformer pair side winding are connected with inverse parallel bidirectional thyristor two ends; one end of secondary side's winding of series transformer is connected with the stator winding of double feed wind power generator, and supervising device is realized bypass protection by the connected state of control inverse parallel bidirectional thyristor.
Side converter in parallel is made of full-control type power switch component and inductance, and the full-control type power switch component is formed the first three phase full bridge structure, and three-phase brachium pontis mid point links to each other by three pole reactor with the rotor winding of double feed wind power generator.
The series connection side converter is made of full-control type power switch component and LC low pass filter, and the full-control type power switch component is formed the second three phase full bridge structure, and three-phase brachium pontis mid point links to each other by three-phase LC low pass filter with former side's winding of series transformer.
As optimization of the present utility model, former side's winding of series transformer is connected into triangle.
The utility model can produce appreciable results aspect following:
(1) side converter in parallel is realized stator port meritorious and the decoupling zero control of reactive power and the stable control of rotating speed under the maximal wind-energy capture control strategy; The series connection side converter is operated in static series compensator mode synchronously, can realize the stable of DC bus-bar voltage and the control of circuit variableimpedance.It is the function that system possesses generating and keying line trend.
(2) side converter in parallel is realized the function of generating and stable node voltage under the maximal wind-energy capture control strategy; The series connection side converter is operated in static series compensator mode synchronously, can realize the stable of DC bus-bar voltage and the control of circuit variableimpedance.It is the function that system possesses generating and stable node voltage and keying line trend.
(3) side converter in parallel is operated in synchronous pm mode, and having to system provides function with absorbing reactive power and stable node voltage; The series connection side converter is operated in static series compensator mode synchronously, can realize the stable of DC bus-bar voltage and the control of circuit variableimpedance.It is the function that system possesses synchronous phase modulation and keying line trend.
The utility model has kept all functions of existing typical double-fed wind-driven power generation system, also can be respectively or realize that simultaneously series compensation, shunt compensation, phase shifting control, modulus of impedance fit multiple different functions such as real-time control transmission circuit trend, thereby improve line transmission ability, stability and damping system vibration, distributed power generation, the fast-changing operating condition of transmission system and operational factor are implemented effectively regulation and control fast, guarantee safe, economic, efficient, the high-quality operation of electric power system under various operating modes.
Description of drawings
Fig. 1 is the utility model system configuration schematic diagram;
Fig. 2 is the circuit topological structure figure of side converter in parallel in the utility model;
Fig. 3 is the circuit topological structure figure of series connection side converter in the utility model.
Embodiment
As shown in Figure 1, the utility model comprises double feed wind power generator 1, ac excitation power supply, series transformer 3, inverse parallel bidirectional thyristor 6 and supervising device 7.
Ac excitation power supply comprises side converter 2 in parallel, series connection side converter 4 and electric capacity 5, side converter 2 in parallel and series connection side converter 4 are three-phase voltage source type pulse width modulated inverter (PWM), the interchange end of side converter 2 in parallel is connected with the rotor winding of double feed wind power generator 1, two dc terminal of side converter 2 in parallel are connected with electric capacity 5 two ends respectively with two dc terminal of series connection side converter 4, and the interchange end of series connection side converter 4 is connected with former side's winding of series transformer 3.
Secondary side's winding two ends of series transformer 3 are connected with inverse parallel bidirectional thyristor 6 two ends, and an end a of secondary side's winding of series transformer 3 is connected with the stator winding of double feed wind power generator 1.Former side's winding of series transformer 3 is connected into triangular form, the effect optimum.
Supervising device 7 is used for side converter 2 in parallel, series connection side converter 4, inverse parallel bidirectional thyristor 6 are implemented monitoring, and monitors electric weight such as transmission line voltage, trend.Supervising device 7 is realized bypass protection by the connected state of control inverse parallel bidirectional thyristor 6.Inverse parallel bidirectional thyristor 6 disconnects when system's operate as normal, is communicated with during fault.
In electric power system is used, the stator winding of double feed wind power generator 1 is connected with an end of grid power transmission line access point, one end b of secondary side's winding of series transformer 3 is connected with the other end of grid power transmission line access point, thereby this system is serially connected with in the grid power transmission circuit.
X1 characterizes the transfer impedance before grid power transmission circuit and the utility model access point, and X2 characterizes the transfer impedance behind grid power transmission circuit and the utility model access point.
Double feed wind power generator 1 is the energy converting between mechanical parts, its structure is conventional double feed wind power generator, be similar to wire-wound asynchronous motor, the stator of electric rotating machine and rotor are all laid symmetrical three phase windings, its stator is similar to common alternating current machine stator, and stator winding is by the symmetrical threephase source excitation with fixed frequency.The electric machine rotor number of poles is identical.The rotor winding is by the symmetrical threephase source excitation with scalable frequency.Rotating speed of motor is determined by the slip frequency between the rotor.The rotor magnetic field of motor is rotation synchronously, so it has the characteristic of similar synchronous machine again.Existing many documents are described this, do not further specify here.
But ac excitation power supply adopts two PWM voltage source type converter structures of slip power four quadrant running, and its end is connected with the rotor winding of double feed wind power generator 1, and the other end is connected with former side's winding of series transformer 3.When requiring to possess power generation conditions according to wind speed, can be with the resolver of regarding as of double feed wind power generator 1 equivalence.Side converter 2 in parallel adopts the vector control technology of stator flux orientation, cause under the service conditions of rotating speed wide variation in the wind speed variation, can realize stator port active power and the decoupling zero control of reactive power or the decoupling zero control of stator port active power and node voltage under the maximal wind-energy capture control.Series connection side converter 4 adopts the directed vector control of power network current (series transformer 3 secondary side's winding currents), can realize the stable control of intermediate link DC bus-bar voltage and the equiva lent impedance on the adjusting electrical network transmission line, change active power and reactive power on the transmission line with this, thereby reach the purpose of keying line trend.When not possessing power generation conditions, can be with the static transformator of regarding as of double feed wind power generator 1 equivalence.Side converter 2 in parallel adopts the vector control technology of stator flux orientation, can implement control to the reactive power or the node voltage of stator port, and the control idea of series connection side converter 4 is the same.
As shown in Figure 2, side converter 2 in parallel is made of full-control type power switch component and inductance, and the full-control type power switch component is formed the first three phase full bridge structure 8, and three-phase brachium pontis mid point links to each other by three pole reactor 9 with the rotor winding of double feed wind power generator 1.
The needed detection limit of side converter 2 controls in parallel comprises stator voltage, stator current, rotor current, DC bus-bar voltage and rotor position angle.When possessing power generation conditions, control procedure is as follows: detect stator voltage, obtain angle, stator voltage resultant vector locus mutually by hardware or software Suo, after ignoring the influence of stator resistance, obtain stator magnetic linkage amplitude and stator magnet current flow angle, and and detected rotor position angle be used for control system and rotate control under the dq coordinate system synchronously.The instruction of stator active power is the function of rotating speed, and according to different maximal wind-energy capture control strategies, the mode of providing is different, and the instruction of stator reactive power then provides according to the requirement of grid company.Actual stator active power and reactive power obtain after being calculated by stator voltage that detects and stator current, as the feedback quantity of control system.Dicyclo control binary channels strategy under the synchronous rotating frame is, the feedback quantity of instruction of stator active power and stator active power obtains the q axle instruction of rotor current by pi regulator, the d axle instruction of rotor current is obtained by pi regulator or is obtained by pi regulator by the detected value of stator voltage amplitude instruction with the stator voltage amplitude by the feedback quantity of stator reactive power instruction with the stator reactive power, carrying out PI with the value of feedback that is obtained after by coordinate transform by detected rotor current again regulates, and the influence of the cross-couplings voltage that motor dq shaft current is produced in the consideration real system, adopt certain de control, finally obtain rotor dq axle command voltage, and the process coordinate transform obtains the control command of rotor three-phase reference voltage as side converter 2 in parallel, thereby the control rotor excitation current is realized stator port active power and the decoupling zero control of reactive power or the decoupling zero control of stator port active power and node voltage under the maximal wind-energy capture control.When not possessing power generation conditions, dicyclo control binary channels strategy under the synchronous rotating frame is with described basic identical before, difference is, this moment, stator active power was instructed to zero, another passage is still given instruction of stator reactive power or the instruction of stator voltage amplitude, thereby can implement control to the reactive power or the node voltage of stator port.
As shown in Figure 3, series connection side converter 4 is made of full-control type power switch component and LC low pass filter, the full-control type power switch component is formed the second three phase full bridge structure 11, and three-phase brachium pontis mid point is connected by three-phase LC low pass filter 10 with former side's winding of series transformer 3.
The needed detection limit of series connection side converter 4 controls comprises inductive current and capacitance voltage and series transformer 3 secondary side's winding currents of DC bus-bar voltage, three-phase LC low pass filter 10.Control procedure is as follows: detect the power network current in the secondary side's winding that flows through series transformer 3, after considering the type of attachment of series transformer 3 former side's windings and secondary side's winding and needing the impedance property of simulation, by hardware or software Suo phase, obtain the capacitance voltage of three-phase LC low pass filter 10, be the angle, voltage resultant vector locus of former side's winding of series transformer 3, be used for control system and rotate control under the dq coordinate system synchronously.Binary channels strategy under the synchronous rotating frame adopts the many ring controls based on the inductive current of three-phase LC low pass filter 10 and capacitance voltage.The DC bus-bar voltage instruction is instructed by the capacitance voltage d axle that pi regulator obtains three-phase LC low pass filter 10 with detected DC bus-bar voltage feedback quantity, and the capacitance voltage q axle instruction of three-phase LC low pass filter 10 is by needed linear impedance compensation or the decision of voltage compensation reference quantity.The capacitance voltage dq axle instruction of three-phase LC low pass filter 10 is instructed by the inductive current dq axle that pi regulator obtains three-phase LC low pass filter 10 through the dq shaft voltage feedback quantity that obtains after the coordinate transform with the capacitance voltage of detected three-phase LC low pass filter 10, inductive current with detected three-phase LC low pass filter 10 carries out the PI adjusting through the dq shaft current feedback quantity that obtains after the coordinate transform again, and the influence of the cross-couplings voltage that converter dq shaft current is produced in the consideration real system, adopt certain de control, side converter 4 three phase full bridge structure brachium pontis mid point dq axle command voltages finally obtain connecting, and the process coordinate transform obtains the control command of three phase full bridge structure brachium pontis mid point three-phase reference voltage as series connection side converter 4, realize the stable control of intermediate link DC bus-bar voltage and the equiva lent impedance on the adjusting electrical network transmission line, change active power and reactive power on the transmission line with this, thereby reach the purpose of keying line trend.

Claims (4)

1. flexible AC double-feed type wind generating and transmitting system; comprise double feed wind power generator (1); ac excitation power supply and supervising device (7); ac excitation power supply comprises side converter in parallel (2); series connection side converter (4) and electric capacity (5); side converter (2) in parallel and series connection side converter (4) are three-phase voltage source type pulse width modulated inverter; the interchange end of side converter in parallel (2) is connected with the rotor winding of double feed wind power generator (1); two dc terminal of side converter in parallel (2) are connected with electric capacity (5) two ends respectively with two dc terminal of series connection side converter (4); supervising device (7) is used for side converter in parallel (2) and series connection side converter (4) are implemented monitoring; it is characterized in that: this system also comprises series transformer (3) and inverse parallel bidirectional thyristor (6); former side's winding of series transformer (3) is connected with the interchange end of series connection side converter (4); the two ends of the secondary side's winding of series transformer (3) are connected with inverse parallel bidirectional thyristor (6) two ends; secondary side's winding of series transformer (3) is connected with the stator winding of double feed wind power generator (1), and supervising device (7) is realized bypass protection by the connected state of control inverse parallel bidirectional thyristor (6).
2. flexible AC double-feed type wind generating and transmitting system according to claim 1 is characterized in that: former side's winding of series transformer (3) is connected into triangle.
3. flexible AC double-feed type wind generating and transmitting system according to claim 1 and 2, it is characterized in that: side converter in parallel (2) is made of full-control type power switch component and inductance, the full-control type power switch component is formed the first three phase full bridge structure (8), and three-phase brachium pontis mid point links to each other by three pole reactor (9) with the rotor winding of double feed wind power generator (1).
4. flexible AC double-feed type wind generating and transmitting system according to claim 1 and 2, it is characterized in that: series connection side converter (4) is made of full-control type power switch component and LC low pass filter, the full-control type power switch component is formed the second three phase full bridge structure (11), and three-phase brachium pontis mid point links to each other by three-phase LC low pass filter (10) with former side's winding of series transformer (3).
CNU2007200846260U 2007-04-30 2007-04-30 Flexible AC double-feeder wind power generation and transmission system Expired - Lifetime CN201041943Y (en)

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Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN102324742A (en) * 2011-09-13 2012-01-18 上海交通大学 Dynamic power flow control device and method of controllable transformer
CN102790575A (en) * 2012-06-25 2012-11-21 华中科技大学 Control method and system for permanent magnet synchronous motor based on current prediction
CN105899805A (en) * 2013-11-05 2016-08-24 开放水知识产权有限公司 Turbulence compensation system and method for turbine generators
CN111064200A (en) * 2019-11-27 2020-04-24 武汉船用电力推进装置研究所(中国船舶重工集团公司第七一二研究所) Railway purification power supply device and fault exit protection method thereof

Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN102324742A (en) * 2011-09-13 2012-01-18 上海交通大学 Dynamic power flow control device and method of controllable transformer
CN102790575A (en) * 2012-06-25 2012-11-21 华中科技大学 Control method and system for permanent magnet synchronous motor based on current prediction
CN102790575B (en) * 2012-06-25 2014-10-29 华中科技大学 Control method and system for permanent magnet synchronous motor based on current prediction
CN105899805A (en) * 2013-11-05 2016-08-24 开放水知识产权有限公司 Turbulence compensation system and method for turbine generators
CN111064200A (en) * 2019-11-27 2020-04-24 武汉船用电力推进装置研究所(中国船舶重工集团公司第七一二研究所) Railway purification power supply device and fault exit protection method thereof
CN111064200B (en) * 2019-11-27 2022-04-05 武汉船用电力推进装置研究所(中国船舶重工集团公司第七一二研究所) Railway purification power supply device and fault exit protection method thereof

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