KR20090072412A - Wind generator - Google Patents

Abstract

An aero-generator is provided to facilitate processing of the sensing hole and to reduce the thickness of the sensing plate. An aero-generator comprises a rotor(100) which consists of a plurality of blades and a hub(120); a naucelle(200) wherein components converting rotational kinetic energy of the rotor to the electrical energy are embedded; a locking plate(500) wherein a plurality of locking holes(510) are formed so that a rod(710) of the locking apparatus is hang on the plane; a sensing plate(800) which rotates with the locking plate, wherein a plurality of sensing holes(810) are formed in the plane; and a speed detection sensor(400) which detects rotation speed of the rotor according to rotation of the sensing plate.

Description

Wind generators

The present invention relates to a wind generator, and more particularly to a structure for detecting the rotational speed of the rotor for a wind generator.

In general, a wind generator is a power converter that converts kinetic energy of air, that is, energy obtained from wind resources, into rotational kinetic energy and then into electrical energy.

The wind generator is largely composed of a rotor (1), a nucelle (2) and a tower portion (3) as shown in FIG.

At this time, the rotor (1) is a blade that is rotated by the wind resources, the nussel (2) is a portion containing various components for converting the rotational kinetic energy obtained by the rotation of the rotor (1) into electrical energy. The tower unit 3 is configured to support the rotor 1 and the nussel 2 while being installed on the ground.

A plurality of detection sensors 4 for detecting a rotational speed of the rotor 1 are provided at a connection portion between the rotor 1 and the nussel 2 of the above-described wind generator.

At this time, each of the detection sensor 4 is configured as a non-contact eddy current sensor, the rotation of the rotor 1 by counting the number of the locking holes (5a) of the locking plate 5 passing through the front portion of each detection sensor (4) The speed will be detected.

The locking plate 5 is a ring-shaped plate which is installed in the hub of the rotor 1 and the rotating shaft 6 penetrates to the center thereof, and the piston rods of the plurality of locking devices 7 fixed to the nussel 2. (7a) is a series of configurations configured to prevent rotation (or flow) of the rotor 1 while being selectively inserted into each of the ranging holes (5a).

In recent years, the diameter of the piston rod 7a is also gradually increased to increase the locking performance by the locking device 7 due to the enlargement of the wind power generator, and the thickness of the locking plate 5 is also gradually thickened.

However, as described above, the conventional structure for detecting the rotor rotation speed is difficult to apply to an enlarged wind generator.

That is, while the size (diameter) of the locking plate 5 is limited, the diameter of the piston rod 7a constituting the locking device 7 gradually increases, so that each locking hole formed in the locking plate 5 is formed. Since the diameter of 5a is also inevitably large, the number of the locking holes 5a is substantially reduced.

Due to this, the rotor rotation speed measurement due to the lack of the number of the locking holes (5a) was not accurate, especially in the low speed state considering that the rotation speed of the rotor 1 is approximately 10 ~ 20RPM level of the locking hole (5a) As the number of is small, the error of measuring the rotational speed frequently occurred.

Of course, in order to solve the above problem, the number of the locking holes 5a can be increased by further increasing the overall diameter of the locking plate 5. However, as the size of the wind generator increases, the thickness of the locking plate 5 also has to be gradually increased, which makes it difficult to process the locking hole 5a, thereby causing an increase in the processing cost of the locking hole 5a.

The present invention has been made to solve the various problems of the prior art described above, the object of the present invention is to enable the universal use of the locking plate irrespective of the size of the wind generator, even if the rotating shaft is operated at low speed rotation of the rotor It is to provide a wind generator with a new type of rotor speed detection structure that allows the measurement of the speed accurately.

According to the wind power generator of the present invention for achieving the above object (rotor) consisting of a plurality of blades and hub; A nucelle in which various accessories are incorporated for converting rotational kinetic energy obtained by the rotation of the rotor into electrical energy; A locking plate installed at an opposite portion of the hub of the hub to be rotated together with the hub, and having a plurality of locking holes formed on a surface thereof so as to receive a rod of the locking device; A sensing plate installed along a circumference of the locking plate and rotating together with the locking plate, the sensing plate having a plurality of sensing holes formed on a surface thereof; And a speed detection sensor fixedly installed at a portion corresponding to each sensing hole of the sensing plate, among the portions of the nussel, to detect a rotational speed of the rotor according to the rotation of the sensing plate. do.

Here, the sensing plate is characterized in that the thickness is formed thinner than the locking plate.

In addition, the spacing between the sensing holes formed in the sensing plate is narrower than the spacing between the locking holes formed in the locking plate.

In addition, the sensing plate is divided into a plurality, characterized in that coupled to the locking plate, respectively.

The wind generator of the present invention as described above can significantly improve the reliability of the detection result through the improvement of the structure for detecting the rotational speed of the rotor.

That is, since the sensing holes sensed by the speed detection sensor are formed on the sensing plate, which is a separate part from the locking plate on which the locking holes used for the rotor locking device are formed, the number of the sensing holes may be formed as much as possible. Since it is possible to keep the distance between each other narrow, the reliability of sensing can be improved.

In addition, the wind generator of the present invention can form a thin thickness of the sensing plate because the sensing plate is used only for the speed detection of the rotor, and thus the process for the processing of each sensing hole can be carried out conveniently. Has an effect.

Hereinafter, with reference to Figures 3 and 4 attached to a preferred embodiment of the wind generator of the present invention described above.

First, the wind generator according to the embodiment of the present invention is largely configured to include a rotor 100, a nussel 200, a locking plate 500, a sensing plate 800 and a speed detection sensor 400. .

This will be described in more detail for each component as follows.

First, the rotor 100 will be described with reference to FIG. 3.

The rotor 100 is a portion which obtains rotational kinetic energy while being rotated by wind, and includes a plurality of blades (not shown) and a hub 120 in which each of the blades is installed.

Next, the nacelle 200 will be described.

The nussel 200 is a series of components for converting the rotational kinetic energy obtained by the rotation of the rotor 100 into electrical energy, there are a variety of accessories for the above-described energy conversion.

In particular, the front end of the rotating shaft 600 is connected to the hub 120 of the rotor 100, the rear end of the rotating shaft 600 is connected to the interior of the nussel 200 is the rotor by the rotating shaft 210 1000 rotational kinetic energy is provided to the nussel 200.

Next, the locking plate 300 will be described.

The locking plate 300 is a portion in which the locking by the rotor locking device 700 is performed, and the rotor locking device 700 refers to the rotor 100 at the time of maintenance of the wind generator or installation of the wind generator. A series of devices to prevent rotation.

In this case, the rotor locking device 700 includes a rod 710 that protrudes selectively, and the locking plate 500 includes a plurality of locking holes 510 through which the rod 710 penetrates. Is done.

In particular, the locking plate 500 is installed in the opposite portion of the hub 120 of each of the portions of the hub 120, the rotation shaft 600 of connecting the hub 120 and the nussel 200 It is formed in a ring shape to surround the circumference.

Next, the sensing plate 800 and the speed detection sensor 400 will be described.

The sensing plate 800 is configured separately from the locking plate 500 and is installed along a circumference of the locking plate 500 to be rotated together with the locking plate 500. The speed detection sensor 400 is a non-contact eddy current sensor for detecting the rotational speed of the rotor 100 according to the rotation of the sensing plate (800).

Here, the sensing plate 800 is formed of iron, and a plurality of sensing holes 810 are formed through the circumference of the sensing plate 800. The reason why the sensing plate 800 is formed of iron is to enable sensing by the speed detection sensor 400.

The size (opening width) of each sensing hole 810 is smaller than the size (opening width) of each locking hole 510 formed in the locking plate 500, and the interval between the sensing holes 810 is It is preferable that the width of the locking plate 500 is narrower than that between the locking holes 510. This structure is to allow the speed detection by the actual speed detection sensor 400 to proceed through the sensing plate 800, rather than the locking plate 500 as in the prior art.

That is, even if the size of each locking hole 510 formed in the locking plate 500 is further increased due to the increase in the size of the locking plate 500 due to the increase in the size of the wind generator, By allowing the role of the speed detection performed through the locking plate 500 to be substituted, the distance between each sensing hole 810 is narrow and the quantity is high even in a relatively low speed state, so that more accurate speed detection is possible.

In particular, since the sensing plate 800 is formed to be thinner than the locking plate 500, the sensing plate 800 has an advantage of reducing material costs.

In addition, the embodiment of the present invention proposes that the sensing plate 800 is coupled to the locking plate 500 while being divided into a plurality of as shown in FIG. This structure is also intended to reduce the overall material cost, and to make the joining work as easy as possible.

The sensing plate 800 may be coupled to the locking plate 500 in various structures. In the embodiment of the present invention, the sensing plate 800 is connected to the hub by a separate fastening bracket 820. To the locking plate).

In this case, one end of the fastening bracket 820 is bolted to the sensing plate 800, and the other end is a bracket that is fastened and fixed to the hub 120 in a state bent from the one end, divided each sensing plate 800 ) Is provided in plural to fix stably.

In the following, the process for detecting the rotor rotational speed of the wind generator according to the embodiment of the present invention described above will be described.

First, when the rotor 100 is rotated due to the influence of wind in the state in which the rotor lock is released, the rotational motion force of the rotor 100 is transmitted to the nussel 200 through the rotation shaft 600.

In addition, the locking plate 500 and the sensing plate 800 coupled to the hub 120 of the rotor 100 are rotated together with the hub 120 due to the rotation of the rotor 100.

As the rotor 100 rotates as described above, the speed detection sensor 400 counts the number of the sensing holes 810 of the sensing plate 800 passing through the front surface.

In this case, the speed detection sensor 400 counts the number of each sensing hole 810, the eddy current is generated as the iron sensing plate 800 approaches the front of the speed detection sensor 400, When the part where each of the sensing holes 810 is formed passes, the eddy current disappears by sensing.

Accordingly, a signal (count signal of each sensing hole) sensed by the speed detection sensor 400 is provided to a controller (not shown) and is compared with the total number of sensing holes 810 in the controller, thereby substantially reducing the rotor ( Rotation speed 100) is detected.

In this case, the sensing holes 810 are larger than the number of the locking holes 510, and the intervals between the sensing holes 810 are narrower than the intervals between the locking holes 510. Compared to a method in which the detection sensor 400 counts the number of the locking holes 510 to detect the rotational speed of the rotor 100, an improved performance of detection can be obtained, and reliability of the detected rotational speed is improved. high.

1 is a front view showing a conventional wind generator in the related art

Figure 2 is a perspective view of the main portion shown to explain the installation structure of the configuration for detecting the rotor speed of the conventional wind generator

Figure 3 is a perspective view of the main portion shown to explain the installation structure of the configuration for the rotor speed detection according to an embodiment of the present invention

Figure 4 is a perspective view of the main portion shown to explain the structure of the sensing plate according to an embodiment of the present invention

Claims (4)

A rotor consisting of a plurality of blades and hubs; A nucelle in which various accessories are incorporated for converting rotational kinetic energy obtained by the rotation of the rotor into electrical energy; A locking plate installed at an opposite portion of the hub of the hub to be rotated together with the hub, and having a plurality of locking holes formed on a surface thereof so as to receive a rod of the locking device; A sensing plate installed along a circumference of the locking plate and rotating together with the locking plate, the sensing plate having a plurality of sensing holes formed on a surface thereof; And, A wind speed detection sensor fixedly installed at a portion corresponding to a portion where each sensing hole of the sensing plate is formed among each portion of the nussel, and detecting a rotational speed of the rotor according to the rotation of the sensing plate; generator. The method of claim 1, The sensing plate is a wind generator, characterized in that the thickness is formed thinner than the locking plate. The method of claim 1, Wind generators, characterized in that the spacing between the sensing holes formed in the sensing plate is narrower than the spacing between the locking holes formed in the locking plate. The method of claim 1, The sensing plate is divided into a plurality of wind generators, characterized in that coupled to each of the locking plate.

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