前苏联专利SU1098527A3 Wind turbine control system

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专利摘要:
A multi-mode electronic wind turbine control system establishes a reference blade angle BR for a two-bladed, horizontal axis, variable pitch wind turbine rotor, the blade angle being regulated by a hydraulic pitch change mechanism (38). The rotor (10), via appropriate shafts and a gearbox (20), is coupled to a synchronous generator (24) to produce electrical energy which is fed to a power utility grid. The control system (36) provides closed loop pitch control for rotor acceleration rate during start-up, for rotor deceleration rate during shut-down, for speed control when the synchronous generator is off-line, and for power control when the synchronous generator is on-line. A single control integrator is used for all closed loop operating modes, with a rate limiter circuit in front of the control integrator to prevent integrator overtravel. The integrator has maximum and minimum blade angle stops, the minimum stop being variable as a function of rotor speed and wind speed. When on-line, power control is provided by a unique shaft torque control using proportional plus integral plus derivative controls in combination.
公开号:SU1098527A3
申请号:SU792806010
申请日:1979-08-16
公开日:1984-06-15
发明作者:Майкс Коз Джозеф；Питер Патрик Джон；Иван Харнер Кермит
申请人:Юнайтед Текнолоджиз Корпорейшн (Фирма)；
IPC主号:

专利说明:

link, dynamic correction and the second multiplication link, as well as the first functional converter connected by an input to the wind speed sensor and the output to the second multiplying link, the first multiplying link being connected by inputs to the rotor speed setter and the starting switch, the third comparator is connected to the rotor speed sensor , and the output of the second link multiplication - to the first selector,
4 "The system of PP, 1-3, about t l and so that the power control unit contains in series the second functional converter, the fourth comparator, aperiodic link,. an adder and a third multiply link, a fifth comparator and a second dynamic correction link connected in series, as well as a third functional converter connected by an input to the wind speed sensor, and an output to a third multiplication link, with the output of the second dynamic correction link connected to an adder, The inputs of the fifth comparator are connected to the rotor speed and electric generator speed sensors, a quarter. the comparator is connected to the torque generator sensor of the generator shaft; the second functional
the converter is connected to the wind speed sensor, and the output of the third multiplication link is connected to the third selector,
5. The system of PP. 1-4, characterized in that the integrator comprises a series-connected limiter, a sixth comparator and an integration link, as well as an integrator signal limiter connected by an input to the output of the integration link, and an output to the sixth comparator, and the output of the integration link is connected to a rotary drive blades, and the integrator limiter input is connected to the third selector.
6. The system according to claim 5, characterized in that the integrator contains a fourth functional converter to the linkage, connected by inputs to the wind speed and rotor speed sensors, and an output to the fourth functional converter, and the output of the fourth functional converter is connected to the integrator signal limiter .
The invention relates to power engineering, in particular to the automatic control of wind turbines. The control system is a wind turbine equipped with a rotary blade rotor and connected via a reducer to an electric generator, comprising a Befpa speed sensor connected in series, a blade rotation angle regulator and a Cb rotary blade drive. However, the known system does not provide the required efficiency of the wind-electric generator and the safety of its operation. The aim of the invention is to increase the efficiency of the electric generator and increase the safety of its operation. The goal is achieved by the fact that a wind turbine control system equipped with a rotary blade rotor and connected via a gearbox to an electric generator, comprising a wind speed sensor connected in series, a blade angle regulator and a rotary blade drive, further comprises a rotor speed sensor, a sensor speed of electric generator, torque sensor of electric generator shaft, rotor speed adjuster, minimum and maximum rotor acceleration adjuster, load switch electric generator and starting switch, and the blade rotation angle controller is composed of a rotor speed control unit, a rotor acceleration control unit, a power control unit, an integrator and the first, second and third selectors connected by inputs to the
the rotor speed control unit and the rotor acceleration control unit, to the first selector and the rotor acceleration control unit - to the second selector and power control unit, the integrator connected to the third selector, and the output to the rotary blade drive, to the rotor speed control unit inputs to the sensor and the setter of the rotor speed, the wind speed sensor and the start switch, the inputs of the rotor acceleration control unit are connected to the rotor speed sensor and the minimum and maximum The rotor accelerations, power control unit inputs are connected to wind speed sensors, rotor speed, electric generator speed and torque of the electric generator shaft, the integrator is connected to wind speed sensors and rotor speed sensors, and the third selector is connected to the electric generator load switch. The rotor acceleration control unit contains the first and second comparators as well as the differentiating element connected by the input to the rotor speed sensor and the output to the first and second comparators connected respectively to the maximum and minimum accelerators of the rotor, and the outputs of the first and second comparators are connected to the first and second selectors. The rotor speed control unit contains the first multiplication link, the third comparator, the first dynamic correction link and the second multiplication link, as well as the first functional converter connected by an input to the wind speed sensor, and the output to the second multiplication link, with the first multiplication link of the input connected The third comparator is connected to the rotor speed sensor, and the output of the second multiplier is connected to the first selector. The power control unit contains the second functional converter, the fourth comparator, the aperiodic link, the adder and the third multiplier link, the fifth fifth comparator and the second link of the dynamic correction, and the third function
the transducer connected by the input to the wind speed sensor and the output to the third multiplication link, the output of the second dynamic correction link is connected to an adder, the inputs of the fifth comparator are connected to rotor speed sensors and electric generator speeds, the fourth comparator is connected to a shaft torque sensor electric generator, the second functional converter is connected to the wind speed sensor, and the output of the third multiplier link is connected to the third selector.
The integrator contains a serial connected limiter, a sixth comparator and an integration link, as well as an integrator signal limiter connected by an input to the output of the integration link, and an output to a sixth comparator, the output of the integration link is connected to the rotary blade drive, and the third signal of the integrator signal is connected to the third selector. The integrator contains a quarter functional converter and a division link connected by inputs to wind and rotor speed sensors, and the output to a fourth functional converter, with the output of the fourth functional converter connected to the integrator signal limiter. FIG. 1 schematically shows the wind on the turbine; in fig. 2 - block diagram of the wind turbine control system; in fig. 3 is a block diagram of the adjustment of the angle of rotation of the blades; in fig. 4 is a block diagram of a rotor acceleration control unit; in fig. 5 shows a block diagram of a rotor speed control unit; FIG. 6 is a block diagram of a power control unit; in fig. 7 -.: Integrator block diagram; in fig. 8 is a block diagram of a third selector. The wind on the turbine (Fig. 1) is equipped with a rotor 1 with rotary blades 2. The system for controlling a wind turbine equipped with a rotary blade rotor and connected via a gearbox 3 to an electric generator 4 contains a wind speed sensor 5 connected in series, the regulator 6 angles of rotation of blades, actuator 7 of rotary blades, rotor speed sensor 8, electric generator speed sensor 9, torque generator sensor 10 of shaft 51 of an electric generator, rotor speed setting device 11, rotor minimum and maximum acceleration settings 12, 13 the load generator switch 14 and the start switch 15. In addition, in FIG. 2 shows communication lines 16-27. . The blade angle regulator (Fig. 3) contains a rotor speed control unit 28, a rotor acceleration control unit 29, a power control unit 30, an integrator 31, a first selector 33 and a third selector 34. In addition, in FIG. 3 shows the communication links 35-41, the rotor acceleration control unit (fig. 4) contains the first comparator 42, the second comparator 43 and the rune differential circuit 44. In addition, in fig. 4 shows amplifiers 45 and 46. The rotor speed control unit (FIG. 5) comprises serially connected first multiplier 47, third comparator 48, first dynamic correction link 49, second multiplier 50, and first functional transducer 51. Power control unit (FIG. 6) contains in series the second functional converter 52, the fourth comparator 53, the aperiodic link 54, the adder 55 and the third link of the multiplication 56, the fifth comparator 57 connected in series, and the second link of the dynamic corrector 58, as well as the third functional converter 59, In addition, in FIG. 6 shows dividing link 60. The integrator (FIG. 7) contains a series-connected limiter 61J, a sixth comparator 62, an integration link 63, an integration signal limiter 64, a fourth functional converter 65 and a division element 66. The third selector (Fig. 8) contains the seventh comparator 67, second adder 68, and fourth and fifth links 69, 70 multiplied. The wind on the turbine (Fig. 1), equipped with a rotor 1 with two diametrically located rotary blades 2, transmits rotational movement to the electric generator and can be rotated in the direction of the prevailing wind. The wind turbine control system (Fig. 2) operates as follows. 27 The rotational motion of the blades is transmitted through the gearbox 3 to the electric generator 4, the output voltage of which is fed through line 16 to the switch 14 of the electric generator and from the output of the latter through line 17 enters the network to the consumer. The signal corresponding to the state of the switch 15 (1/0, which corresponds to the state of the switch on and off), via line 19 goes to the blade angle adjuster 6, which controls the position of the rotary blades 2 according to the signals of the wind speed sensor 5, sensor 8 the speed of the rotor, sensor 9 of the speed of the electric generator and sensor 10 of the torque moment of the shaft of the electric generator, by acting on the drive 7 of the rotary blades 2. In addition, the regulator 6 receives signals from the setting device 11 of the rotor speed, setting devices 12, 13 minimum and maximum the maximum acceleration of the rotor and the starting switch 15. In this case, four modes of operation are realized. The first control mode — start is realized when the average wind speed reaches a value at which the wind on the turbine and the generator can work with a return of useful power. In this mode, the blades shift from their vane position (90 °) in the direction of a small pitch. so that the blades could provide a torque that increases the speed of the rotor and generator to the nominal value without loss of speed or without acceleration. The second control mode is speed control when load is disconnected. As the speed of the generator increases, it is used to maintain a given speed by changing the angle of rotation of the blades and to adjust the phase ratio between the generator and the network. The third control mode is control when the load is connected. As soon as the generator has reached a speed that provides a given frequency, and the phase of the generator is adjusted so that it matches the network, the generator is connected to the network. The angle of rotation of the blades is then adjusted to maintain the desired power level. At high wind speeds, the rotor can develop a power exceeding the required one, therefore, power control is carried out by measuring the shaft torque (current or power can be measured; an elec- trical generator). The fourth control mode is a stop which is realized by increasing the angle of the blade rotation to the vane position (90 °). The regulator of the angle of rotation of the blades (Fig. 3) works as follows. When a start command is issued, line 24 is given a signal corresponding to a logical one, which solves the passage of the signal coming in line 25 from the rotor speed generator 11. At the output of the rotor speed control unit 28 (line 35), a signal p.j is generated, which arrives at the first selector 32. At the same time, the rotor acceleration control unit 29 generates a signal / bd at the output (line 36), also arriving at the first selector. The first selector 32 is a scheme for selecting the maximum signal value, and since the signal is RD-algebraically larger than the signal / i | g, then at the output of the first selector (line 39) the signal rd (corresponds to the p signal. In addition, at the output of block 29 The signal p which, via line 37, is fed to the input of the second selector 33, which is a circuit for selecting the minimum value of the signal, and generates an output signal (line 40) corresponding to the signal q. Since the load is disconnected, the third selector 34 provides the passage signal / j to integrator 31. As the rotor speed increases, the value of the signal Np coming through line 20 increases, and depending on the signal coming through line 23, the value of signal / jj in line 35 increases until it exceeds the value of signal d in line 36, coming from block 29 and formed depending on the signal N (line 20) and setpoint signals for minimum and maximum rotor accelerations, then the first selector 32 passes the signal b. to the input of the second selector 33, and since the signal fb | M ( as the dd signal is still less than the signal (ijj On the second selector 33 via line 37, the signal at the output of the second and third selectors corresponds to p, .., and thus the speed is not controlled by acceleration, which corresponds to the steady state operation at constant wind speed. When a command to stop the wind turbine is received, the signal - / bff y at the output of the first selector 32 corresponds to the signal jft, but the second selector 33 allows the signal, i-, from the acceleration control unit 29 to pass, which ensures a reduction in speed. When operating with a connected load, the third selector 34 passes a signal / B received through line 38 from power control unit 30, whose input receives signals from wind speed sensors, rotor speeds, electric generator speeds and torque on lines 23, 20, 22, 21. The rotor acceleration control unit (Fig. 4) operates as follows. The signal from the rotor speed sensor, fed through line 20 to differentiator 44, is fed to the first and second comparators 42, 43, where it is compared with the signals to these comparators on lines 27, 26 from the rotor minimum and maximum accelerators. The difference signals formed by the first and second Comparators 42, 43 are amplified by amplifiers 45, 46 and are passed via lines 36, 37 to the first and second selectors, respectively. The rotor speed control unit (Fig. 5) operates as follows. Start signal In the form of a logical unit, it enters via line 24 to the first link of multiplication 47 and ensures the passage of a signal from the target. the speed of the rotor, passed through line 25, to the third comparator 48, to the other input of which through line 20 is fed a signal from the rotor speed sensor. From the output of the third comparator 48, the differential signal goes through the first link of dynamic correction to the second link of multiplication 50, to another input of which a signal comes from the output of the first functional converter 5.1 that implements the desired dependence of the control signal on the signal of the wind speed sensor input to the first functional converter on line 23. From the output of the second link, multiplying 50 the signal and., regulating the speed, goes through line 35 to the first selector. The power control unit (Fig. 6) operates as follows. The signal received via line 21 from the torque sensor of the shaft of the electric generator to the fourth compiler 53 is compared with a predetermined signal from the output of the second functional converter 52, which realizes the required dependency of the driver signal from the signal of the wind speed sensor fed to the second functional input converter 52 via line 23. The differential signal from the output of the fourth comparator 53 through the aperiodic link 54 is fed to the adder 55. At the same time to the second input of the adder through the second link din The amic correction 58 provides a signal proportional (with a permissible degree of approximation) to the torque derivative generated by the fifth comparator 57, to the inputs of which the signal from the rotor speed sensor is fed via line 20, and to dividing link 60 by a constant factor 22 signal from the electric generator speed sensor. To the input adder 55 from the second dynamic correction link 58, a signal is received that depends on the first and. The second output torque S to the other input is a delayed signal, depending on the torque, which allows to receive at the output of the adder 55 a signal that depends on the torque and the first two of its output, which ensures (after integration) the implementation proportional, integral, and derivative controls on the shaft torque signal. The compensation of the nonlinearity of the rotor aerodynamic characteristics of the signal from the output of the adder 55 is fed to the third multiplication link 56, where it is corrected for the signal from the wind speed sensor through the third functional converter 59 to the other input of the third multiplier 56. The received power control signal from the output the third link multiply 56 through line 38 enters the third selector. The integrator (FIG. 7) operates track1 (in this manner. The control signal comes from the third selector on line 41 through limiter 61 to the sixth comparator 62, which is compared with the signal of the integration signal limiter 64, having a zero value if the signal at the output of the integration link 63 is otherwise, the difference signal from the output of the sixth comparator goes to the integration link 63, where it is integrated and fed to the rotary blade drive as a control signal. The upper limit of the control signal corresponds to the vane position of the blades (90), and the lower value is adjusted depending on the ratio of rotor speed to wind speed, which is formed by dividing 66, to the input of which sensors arrive at lines 23, 20 wind speed and rotor speed sensor. The lower limit of the control signal is required to depend on the ratio of rotor speed to wind speed formed by a fourth functional transducer 65., The third selector (Fig. 8) works as follows. Signals from the second selector and from the power control unit are fed to the input of the third selector via lines 40, 38, which are fed to the fourth and fifth multipliers 69, 70. The other inputs of the links receive a signal from the generator's load switch the selector on line 19. With the load connected, the value of this signal corresponds to one and the output signal of the fifth multiplier link 70 corresponds to the signal coming from. power control unit. At the input of the fourth multiplier 69, the signal from the generator load switch is fed through the seventh Comparator 67, where it is compared with the unit and is therefore inverted. Thus, when the load is connected, the output signal of the fourth multiplier 69 is zero, and the signal at the output of the second adder 68 corresponds to the signal from the power control unit. With the load disconnected, the output signal of the fifth multiplier 70 is equal to zero, and the output signal of the fourth multiplication link 69 and the signal at the output of the adder 68 correspond to the signal from the second selector. Thus, the third selector switches control depending on whether the load is on or off. Introduction of the rotor speed sensor, electric generator speed sensor, 2712 electric generator shaft torque sensor, 2712 electric generator speed setting, rotor minimum speed and maximum accelerator speed controllers, electric generator load switch and starting switch to the control system by the turbine blades in the form of a rotor speed control unit, a power control unit, an integrator, and the first, second and third selectors allows you to increase the efficiency of the electric generator optimize management and improve its work safety by control signals restrictions and optimizing start-up and shutdown processes.
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权利要求:
Claims (6)
[1]
. 1. A WIND TURBINE CONTROL SYSTEM, equipped with a rotor with rotary blades and connected through a gearbox with an electric generator, comprising serially connected wind speed sensor, a rotational angle control of the blades and a rotary blade drive, characterized in that, in order to increase the efficiency of the generator and increase its safety work, it additionally contains a rotor speed sensor, a generator speed sensor, a generator torque shaft sensor, a rotor speed adjuster, a minimum setpoint of the maximum and maximum rotor accelerations, the generator’s load switch and the start switch, and the blade rotation angle adjuster .. is made up of the rotor speed control unit, rotor acceleration control unit, power control unit, integrator and first, second and third selectors connected by inputs to the rotor speed control unit and the rotor acceleration control unit, to the first selector and the rotor acceleration control unit, to the second selector and power control unit, and int the hegator is connected by an input to the third selector, and by an output to the drive of the rotary blades, the inputs of the rotor speed control unit are connected to the sensor and the rotor speed control unit, the wind speed sensor and the start switch, the inputs of the rotor acceleration control unit are connected to the rotor speed sensor and the minimum and maximum switches rotor accelerations, inputs of the power control unit are connected to sensors of wind speed, rotor speed, generator speed and generator shaft torque, integrat p is connected to the sensors of the wind speed and rotor speed, and a third selector switch is connected to an electric load.
[2]
2. The system according to p. 1, characterized in that the control unit 'acceleration of the rotor contains the first and second Comparators, as well as a differentiating element connected to the input to the rotor speed sensor, and the output to the first and second comparators associated respectively with the maximum and minimum acceleration of the rotor, and the outputs _{4 of the} first and second comparators are connected respectively to the first and second selectors.
[3]
3. The system of claims. 1 and 2, characterized in _{that the} rotor speed control unit comprises the first multiplication link, the third comparator, the first dynamic correction link and the second multiplication link, as well as the first functional converter connected to the wind speed sensor by the input and the output by to the second link of multiplication, and the first link of multiplication is connected by inputs to the rotor speed controller and the start switch, the third comparator is connected to the rotor speed sensor, and the output of the second link of multiplication is to the first Elector.
[4]
4. The system of claims. 1-3 ·, tl and the fact that the power control unit contains connected in series to the second functional Converter, the fourth comparator, aperiodic link,. the adder and the third link of multiplication, the fifth comparator and the second link of dynamic correction, as well as the third functional converter connected to the wind speed sensor by the input, and the output to the third link of the multiplication, the output of the second dynamic correction link connected to the adder, the inputs the fifth comparator is connected to the rotor speed and electric generator speed sensors; the fourth, the comparator is connected to the sensors * *. generator shaft torque, the second functional 'converter is connected to a wind speed sensor, and the output of the third multiplication link is connected to the third selector,
[5]
5. The system of claims. 1-4, characterized in that the integrator contains a serially connected limiter, a sixth comparator and an integration link, as well as an integrator signal limiter connected by an input to the output of the integration link and an output to the sixth comparator, the output of the integration link being connected to the rotary blade drive, and the input of the integrator signal limiter is connected to the third selector.
[6]
6. Pop system. 5, characterized in that the integrator contains a fourth functional converter and a division link connected by inputs to the Wind speed and rotor speed sensors, and an output to the fourth functional converter, the output of the fourth functional converter connected to the integrator signal limiter .

类似技术:

公开号 | 公开日 | 专利标题

SU1098527A3|1984-06-15|Wind turbine control system

Boukhezzar et al.2005|Nonlinear control of variable speed wind turbines for power regulation

CN105134485B|2017-10-27|A kind of double-fed Wind turbine inertia frequency modulation active rotating speed Protection control system and method

US4695736A|1987-09-22|Variable speed wind turbine

US4339666A|1982-07-13|Blade pitch angle control for a wind turbine generator

EP0223729B1|1990-11-14|Torque control for a variable speed wind turbine

CN102444541B|2013-11-06|Control device and control method for compensating torque adjusting delay of wind generating set

SE444599B|1986-04-21|REGULATORY DEVICE FOR WIND TOUR DRIVE GENERATOR IN AN ELECTRIC PRODUCING WIND POWER PLANT

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JPS6339500A|1988-02-19|Controlling method for wind power generator

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CN109039180A|2018-12-18|The fractional order control method of double fed induction generators and network process

CN103281022B|2015-04-01|Double-efficiency fuzzy optimization control method for doubly-fed wind generator

Wang et al.2015|Sliding mode control for maximum wind energy capture of DFIG-based wind turbine

JPS62123997A|1987-06-05|Wind power generator

Jabr et al.2005|Adaptive vector control for slip energy recovery in doubly-fed wind driven induction generator

KR102008230B1|2019-10-21|Wind turbine system with limitting output and method controlling the same

Elbeji et al.2020|Pitch Angle Control of a Wind Turbine Conversion System at High Wind Speed

Xing et al.2016|Coordinated pitch and generator control for wind turbine flexible power tracking

SU1534747A1|1990-01-07|Device for control of synchronized synchronous generator of wind power plant

同族专利:

公开号 | 公开日

FI792440A|1980-02-15|

FI76627C|1988-11-10|

IL57944A|1983-12-30|

EP0008584A1|1980-03-05|

AU4963079A|1980-02-21|

KR840002220B1|1984-12-03|

EP0008584B1|1981-12-30|

NO158557C|1988-09-28|

JPS6345509B2|1988-09-09|

US4193005A|1980-03-11|

ZA793946B|1980-07-30|

FI76627B|1988-07-29|

CA1120538A|1982-03-23|

BR7904968A|1980-05-06|

AU526931B2|1983-02-10|

DK344079A|1980-02-18|

IL57944D0|1979-11-30|

JPS5529085A|1980-03-01|

IN151737B|1983-07-16|

DE2961688D1|1982-02-18|

NO158557B|1988-06-20|

KR830001519A|1983-05-17|

NO792639L|1980-02-19|

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法律状态:

优先权:

申请号 | 申请日 | 专利标题

US05/934,658|US4193005A|1978-08-17|1978-08-17|Multi-mode control system for wind turbines|

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