JP2001190096A - Wind power generation device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a wind power generation device using a permanent magnet type AC generator for generating constant power regardless of the variance of wind power. SOLUTION: A permanent magnet type AC generator 21 is rotated and driven by a propeller 20. Power generated by the generator is supplied to an inverter 22. The inverter is controlled by a signal with a specific phase difference for a signal with a frequency that is in proportion with the speed of the propeller, thus outputting constant power regardless of the variance of wind power.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a wind power generator, and more particularly to a wind power generator using a permanent magnet type alternator.

[0002]

2. Description of the Related Art In recent years, wind power generation has attracted attention from the viewpoint of environmental protection, but a synchronous AC generator is often used as a generator driven by a propeller. FIG. 1 is a configuration diagram of a conventional wind turbine generator, in which a propeller 10 is coupled to a rotor 111 which is a field pole of a synchronous AC generator 11, and drives the rotor 111 to rotate.

[0003] A coil 112 is wound around the rotor 111, and by supplying DC power to the coil 112, the rotor 111 is magnetized. Stator 1 of AC generator 11
A coil is embedded in 13, and three-phase AC power is generated by rotating the rotor 111. Rotor 1
A part of the power generated by the synchronous AC generator 11 is supplied as excitation power to the eleventh coil 112 via the exciter 12 and the slip ring 13. The exciter 12 is a transformer 121
And a thyristor 122.

After a part of the electric power generated by the generator 11 is adjusted to an appropriate voltage by the exciter transformer 121,
The light is rectified by the thyristor 122 and converted into DC power.
The output voltage of the generator 11 is controlled by controlling the firing angle of the thyristor 122 by the AVR 14.
The electric power generated by the generator 11 is once subjected to DC power by the converter 15, and then converted again by the inverter 16 into AC power having the same frequency as the system frequency. Further, the electric power reconverted into the alternating current is supplied to the system 19 via the filter 17 and the main transformer 18.

In the above-described wind power generator, the power generated by the generator 11 fluctuates according to the wind force received by the propeller 10, but by adjusting the AVR 14, the rotation speed of the propeller 10 is maintained in an appropriate range. AC power is converted to DC power. However, in the synchronous alternator 11 with AVR, it is necessary to use a slip ring to supply excitation power from the outside, but the slip ring is a mechanical contact part and is not sufficient in reliability. .

Therefore, it is conceivable to use a permanent magnet type AC generator that does not use a slip ring as the AC generator.

[0007]

However, since the permanent magnet type alternator uses a permanent magnet as a rotor, the A
VR is not required, but it is impossible to control the generated power. Therefore, the fluctuation of the generated power due to the instantaneous fluctuation of the wind and the fluctuation of the generated power due to the propeller blade overlapping the pole supporting the propeller are directly propagated to the system 19 and disturb the system 19. Unavoidable to give.

The present invention has been made in view of the above problems, and has as its object to provide a wind power generator using a permanent magnet type alternator capable of appropriately controlling generated power.

[0009]

SUMMARY OF THE INVENTION A wind power generator according to the present invention comprises a wind turbine, a permanent magnet type alternator driven by the wind turbine, and an alternating current generated by the permanent magnet type alternator. A rotation speed detector that outputs a signal having a frequency proportional to the rotation speed of the wind turbine, and a signal having a predetermined phase difference with respect to the output signal of the rotation speed detector as a control signal for the converter. And a phase difference providing unit.

In the present invention, the converter is controlled by a signal whose phase is advanced or delayed by a predetermined amount with respect to a signal having a frequency proportional to the rotation speed of the wind turbine.

[0011]

FIG. 2 is a block diagram of a wind turbine generator according to the present invention. A propeller 20 is coupled to a rotor 211 of a permanent magnet type AC generator 21 and drives the rotor 211 to rotate. A cylindrical stator 2 is provided around the rotor 211.
12 are arranged. FIG. 3 is a partial cross-sectional view of a permanent magnet type alternator used in the wind turbine generator according to the present invention. The rotor 211 includes a rotor electromagnetic steel plate 211b having a slot formed around a shaft 211a. It has a configuration in which a permanent magnet 211c is inserted into a slot.

The stator 212 is disposed at a predetermined gap from the rotor 211. The stator 212 has a stator frame 212a and a stator electromagnetic steel plate 2 having slots formed therein.
12b and a coil 212c housed in the slot. Then, the rotor 2 is driven by the propeller 20.
When 11 rotates, three-phase AC power is induced in coil 212c of stator 212.

The power generated by the generator 21 is converted into DC power by a converter 22 and supplied to an inverter 24 via a capacitor 23. DC power is supplied to the inverter 24
Is again converted into AC power, and then supplied to the system 27 via the filter 25 and the main transformer 26. The converter 22 includes six switching elements (for example, thyristors) 221 to 226 connected in a three-phase bridge and a gate control unit 227.
Is controlled by the gate control unit 227.

The inverter 24 includes six transistors 241 to 246 connected in a three-phase bridge and an on / off control unit 2.
The on / off timing of each of the transistors 241 to 246 is controlled by an on / off control unit 247. Furthermore, the wind power generator according to the present invention includes a generator 2
1 includes a control system for controlling the generated power. The control system includes a rotation angle sensor 281 directly connected to the rotor 211 of the generator 21, a DC voltage sensor 282 for detecting a DC voltage, and a controller 29. You.

The controller 29 is composed of, for example, a microcomputer and has a CPU
91, memory 292, input interface (input I /
F) 293 and an output interface (output I /
F) 294. A reference position sensor 281 and a DC power sensor 282 are connected to the input I / F 293. The output I / F 294 is connected to the gate control unit 237.

FIG. 4 is a functional diagram of the first embodiment of the wind turbine generator according to the present invention. The pulse output from the rotation angle sensor 281 is guided to the phase difference applying section 40. The phase difference φ set by the phase difference setting unit 41 is also guided to the phase difference providing unit 40, and the phase difference providing unit 40 delays (or advances) the phase by φ with respect to the pulse output from the rotation angle sensor 281. ) The converter control signal λ is output to the converter 22. The phase difference providing unit 40 and the phase difference setting unit 4
1 is actually incorporated in the controller 29.

FIG. 5 is a diagram for explaining the function of the phase difference providing unit. A solid line indicates a pulse output from the rotation angle sensor 281 and a broken line indicates a converter control signal λ. That is,
For example, a signal whose phase is delayed (or advanced) by a phase difference φ set by the setting unit 282 with respect to a square pulse output from the rotation angle sensor 281 which is a shaft encoder is output to the converter 22 as a converter control signal λ. You. Then, converter 22 controls the ignition angle of the switching element based on converter control signal λ.

According to the present embodiment, it is possible to keep the generated power substantially constant even when the wind power fluctuates. In the first embodiment, the phase difference is set directly, but in practice, the target generated power is often set. FIG. 6 is a functional diagram of the second embodiment of the wind turbine generator according to the present invention, and enables setting a target generated power.

That is, the pulse output from the rotation angle sensor 281 is guided to the phase difference providing section 40 built in the first load control section 60, and the converter control signal λ is output. The phase difference is supplied to the reference phase difference setting unit 61 via the first switching unit 601.
Or from the target generated power setting unit 62 and the target phase difference determination unit 602. Normally, the target phase difference φ (= f (m)) is determined by the target phase difference determining unit 602 as a function of the target generated power m set by the target generated power setter 62, and is determined via the first switching unit 601. A predetermined phase difference is applied to the pulse output from the rotation angle sensor 281 by being guided to the phase difference applying unit 40.

When the advance or delay of the phase difference becomes excessive, the reference phase difference is set in order to prevent the arc-angle control in the converter 22 from being impossible (ie, the step-out state). The reference phase difference φ set by the setting unit 61
₀ (= for example, “0”) is guided to the phase difference providing unit 40 via the first switching unit 601. According to the present embodiment, not only can the target generated power be set appropriately by the target generated power setting device 62, but also if the wind power becomes excessively strong or weak, the first switching unit 601 is operated. By controlling the converter 22 with the reference phase difference φ ₀ set by the reference phase difference setting unit 61 for the phase difference, it is possible to prevent the converter 22 from going out of step.

FIG. 7 is a functional diagram of a third embodiment of the wind turbine generator according to the present invention. The follow-up to the target generated power is improved by feeding back the DC power output from the converter 22. In other words, the pulse output from the rotation angle sensor 281 is guided to the phase difference providing section 40 built in the second load control section 70, is provided with a phase difference, and is output as the converter control signal λ. The phase difference is determined by the phase difference determination unit 701 in the reference phase difference setting unit 61.
, The DC power output from the converter 22 detected by the DC power sensor 283, and the second
Is determined based on the set DC power d output from the switching unit 702.

The set DC power d is set to the reference DC power setter 7
Reference DC power set in step 1 and target generated power setter 6
One of the target DC powers determined by the target DC power determining unit 703 based on the target generated power set in step 2 is selected by the second switching unit 702. Normally, the target DC power d = f determined by the target DC power determination unit 703 based on the target generated power m set by the target generated power setter 62
(M), DC power detected by the DC power sensor 283,
The phase difference is determined based on the reference phase difference set by the reference phase difference setting device 61, and the converter control signal λ is determined based on the phase difference.

When the leading or lagging of the phase difference becomes excessive, the reference DC power is set to prevent the angle-of-arc control in the converter 22 from becoming impossible (ie, out of step). The reference DC power m ₀ set by the setting unit 71 is guided to the phase difference providing unit 40 via the second switching unit 702 and the phase difference determining unit 701. Reference generated power m ₀
The reference phase difference setting unit 61 also supplies the reference phase difference φ ₀ in order to prevent the converter 22 from stepping out even when the control is performed under the control of the controller 22.

According to the present embodiment, the responsiveness to the target generated power is improved by feeding back the DC power output from the converter 22.

[0025]

According to the wind power generator according to the present invention, even when a permanent magnet type AC generator is used as a generator, it is possible to take out a constant generated power irrespective of wind fluctuations.

[Brief description of the drawings]

FIG. 1 is a configuration diagram of a conventional wind power generator.

FIG. 2 is a configuration diagram of a wind turbine generator according to the present invention.

FIG. 3 is a partial sectional view of a permanent magnet type alternator.

FIG. 4 is a functional diagram of the first embodiment of the wind turbine generator according to the present invention.

FIG. 5 is an explanatory diagram of a function of a phase difference providing unit.

FIG. 6 is a functional diagram of a second embodiment of the wind turbine generator according to the present invention.

FIG. 7 is a functional diagram of a third embodiment of the wind turbine generator according to the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 20 ... Propeller 21 ... Permanent magnet type alternator 211 ... Rotor 212 ... Stator 22 ... Converter 221-226 ... Thyristor 227 ... Gate control part 23 ... Capacitor 24 ... Inverter 241-246 ... Transistor 247 ... ON-OFF control part 25 ... Filter 26 ... Main transformer 27 ... System

 ──────────────────────────────────────────────────続 き Continued on the front page F-term (reference) JB15 5H621 AA03 BB10 GB10 HH01

Claims (3)

[Claims] A wind turbine; a permanent magnet AC generator that is driven to rotate by the wind turbine; a converter that converts AC power generated by the permanent magnet AC generator into DC power; A rotation speed detector that outputs a signal having a frequency proportional to, a signal having a predetermined phase difference with respect to an output signal of the rotation speed detector, and a phase difference providing unit that outputs a signal for controlling the converter, A wind power generator comprising: 2. A reference phase difference setting unit for setting a reference phase difference, a target generated power setting unit for setting a target generated power, and a target generated power set by the target generated power setting unit. A target phase difference determining unit for determining the target phase difference, and one of the reference phase difference set by the reference phase difference setting unit and the target phase difference determined by the target phase difference determining unit in the phase difference providing unit. The wind turbine generator according to claim 1, further comprising: a switching unit that outputs a phase difference provided to an output signal of the rotation speed detector. 3. A reference DC power setting section for setting a reference DC power; a target generated power setting section for setting a target generated power; and a target based on the target generated power set by the target generated power setting section. A target DC power determining unit that determines DC power, and a second that outputs one of the reference DC power set by the reference generated power setting unit and the target DC power determined by the target DC power determining unit as set DC power. A switching unit, a DC power detection unit that detects DC power output from the converter, a reference phase difference setting unit for setting a reference phase difference, and a set DC power output from the second switching unit. The phase difference providing unit applies the output signal of the rotation speed detector based on the DC power detected by the DC power detecting unit and the reference phase difference set by the reference phase difference setting unit. The wind turbine generator according to claim 1, further comprising: a phase difference determining unit that determines a given phase difference.