KR20120133954A - Blade for horizontal axis wind power generation - Google Patents

Abstract

PURPOSE: A wind power blade for a horizontal-axis wind power generator is provided to minimize the damages to components as the blades are folded in strong wind. CONSTITUTION: A rotary blade unit of a wind power blade for a horizontal-axis wind power generator comprises a body, a rotary body(200), a rotary shaft(300), and a blade position control module. A blade(210) is mounted on the side of the rotary body. The rotary shaft is fixed to the side of the body, and the rotary body is rotationally embedded in the rotary shaft. The rotary shaft comprises a elongated groove(310) and a rotary space(320). A blade part of the rotary body is exposed to the outside through the elongated groove. The rotary space is formed inside the elongated groove. If the wind pressure colliding with the blade is high, the blade position control module rotates the rotary body toward a safe position. If the wind pressure colliding with the blade is low, the blade position control module reversely rotates the rotary body toward a position for wind power generation.

Description

Blade for horizontal axis wind power generation

The present invention has a means for controlling the angle of the wing to be changed according to the strength of the wind, when the wind strength is weak breeze receives more wind and when the wind strength is strong winds receive less wind resistance The present invention relates to a wind blade for a horizontal axis wind generator that minimizes damage or damage to a component including a blade even when the same strong wind blows.

In general, a wind turbine, a generator that generates electricity by rotating windmills with wind, is spotlighted as the most economical alternative energy source among fossil fuels as a natural pollution-free energy source.

As described above, wind turbines are classified into vertical shaft wind turbines such as Darius and Savonius, and horizontal shaft wind turbines of propeller according to the shape of the shaft.

First, Figure 1 is a perspective view of a typical vertical axis wind power generator (Utility Model Registration No. 20-0019653), Figure 2 is a cross-sectional view showing the state of use of the windmill blade of the configuration of FIG.

As shown in the drawing, a conventional vertical shaft wind power generator has four rotary windmills (3a) formed by rotating a plurality of rotating shafts (2) rotatably installed on a base plate (1) and a plurality of fixed shafts (2). It is connected to the windmill 3 arranged and connected by (+), the support plate P which supports the rotation shaft 2 rotatably, the rope 4 which supports and fixes the support plate P, and the rotation shaft 2 And a generator 6 for generating electricity by using the rotating part 5 to receive the rotational force from the rotating shaft 2 and the rotating force transmitted from the rotating part 5, of each surface constituting the windmill blade 3a. , The wind pressure plate (3b) is hingedly connected to the surface where the wind is contacted, and is designed to be opened to one side.

For this reason, the wind pressure plate 3b of the windmill blade 3a is opened when a strong wind or a storm storms, etc., thereby minimizing the damage of the windmill blade 3a through a simple configuration.

3 is a perspective view showing a conventional horizontal axis wind power generator.

As shown, the conventional horizontal axis wind power generator is rotated by the wind and the wing shafts 12 are fixedly installed along the side of the body 11, the wing 13 along the side of the fixed wing shaft 12 is installed. Rotation blade 10 is fixedly installed, the rotating shaft 20 fixed to the rear of the body 11, the relay rotating shaft 30 receives the rotational force from the rotating shaft 20, and the relay rotating shaft 30 from It consists of a generator (not shown) that generates electricity by the power of the rotational force transmitted.

By the way, since the wing 13 is provided along the side of the wing shaft 12 of the configuration of a conventional horizontal axis wind turbine is a fixed structure when a strong wind is transmitted during a certain weather such as storms and strong winds (10) ) Rotates too fast, the generator may be damaged or the wing 13, the wing shaft 12, etc. are damaged.

The present invention is to solve the problems of the prior art, the object of the present invention is provided with a means for controlling the angle of the wing is changed according to the strength of the wind, when the wind strength is weak breeze receives more wind When the strong wind is strong wind to provide a wind blade for the horizontal axis wind power generator to minimize the damage or damage to the components including the wing even if a strong wind, such as typhoons due to less wind resistance.

In the technical spirit for achieving the present invention, the horizontal blade wind turbine wind turbine of the present invention, in the horizontal shaft wind generator for generating electricity by the power transmitted through the rotary blade portion rotated by the wind power, the rotary blade portion, Body 100; Rotor 200 with a wing 210 on the side; Being fixed to the side of the body 100, the rotating body 200 is rotatably embedded, the blade 210 of the rotating body 200 is a long groove 310 for penetrating blades to be exposed to the outside. A rotation shaft 300 having a rotating body rotating space 320 formed therein, and having a through blade rotating long groove 310 formed therein; Being provided inside the rotating shaft 300, when the wind pressure impinging on the wing 210 is counted, the rotating body 200 embedded in the rotating body rotating space 320 of the rotating shaft 300 toward the wing safety position And a wing position control module for controlling the rotating unit and controlling the rotating body 200 rotated in the rotating body rotating space 320 to the wind pressure generating position when the wind pressure impinging on the wing 210 is small. Include.

The wing position control module may include a pressing table 220 provided on the other side of the rotating body 200 embedded in the rotating body rotating space 320 of the rotating shaft 300; It is provided in the inside of the rotating shaft 300, is located on the side of the pressing table 220, the elastic body is pressed or restored to the pressing table 220 in accordance with the strength of the wind pressure; consists of.

The elastic body may use a tube 330 or a spring.

The gas filled in the tube 330 is nitrogen (N ₂ ).

The rotating body 200 is a structure provided to be separated into at least two along the rotating shaft (300).

The present invention includes a means for controlling the angle of the wing according to the strength of the wind, by receiving more wind when the wind strength is weak breeze and when the wind strength is strong wind is folded the wind resistance Even if a strong wind such as a typhoon blows less, it has an effect of minimizing damage or damage to the components including the wing.

1 is a perspective view showing a typical vertical axis wind power generator,
2 is a cross-sectional view showing a windmill blade of the configuration of FIG.
3 is a perspective view showing a conventional horizontal axis wind power generator,
Figure 4 is a side view showing a horizontal axis wind generator to which the wind vane of the present invention is applied,
5 is a front view showing a horizontal axis wind generator to which the wind vane of the present invention is applied,
6 is a main perspective view of a wind blade for a horizontal axis wind generator of the present invention;
Figure 7 is a sectional view of the main part of the wind blade for a horizontal axis wind generator of the present invention,
8 is a perspective view showing an example of the use of the tube of the wind turbine blade for the horizontal axis wind generator of the present invention,
9 is an exploded perspective view of main parts of a wind turbine blade for a horizontal axis wind generator according to the present invention;
10 to 12 are cross-sectional views of the use state showing that the angle of the wind blade for the horizontal axis wind generator of the present invention is changed according to the wind strength.

Hereinafter, with reference to the accompanying drawings, the configuration and operation of the embodiment of the present invention will be described in detail.

Figure 4 is a side view showing a horizontal axis wind generator to which the wind vane of the present invention is applied, Figure 5 is a front view showing a horizontal axis wind generator to which the wind vane of the present invention is applied, Figure 6 is a main portion of the wind blade for the horizontal axis wind generator of the present invention 7 is a sectional view of the main portion of the wind blade for the horizontal axis wind generator of the present invention, Figure 8 is a perspective view showing the use of the tube of the configuration of the wind blade for the horizontal axis wind generator of the present invention, Figure 9 is a view of the present invention It is an exploded perspective view of the main portion of the wind blade for the horizontal axis wind generator, Figure 10 to Figure 12 is a state of use showing that the angle of the wind blade for the horizontal axis wind generator of the present invention is changed according to the wind strength.

As shown, the horizontal axis wind power generator with a rotary blade of the present invention is largely powered by the rotating blade portion, the rotating shaft 20 is fixed to the rear of the rotating blade portion, and the rotational force transmitted from the rotating shaft 20 to the power. It consists of a generator (not shown) to generate.

Here, the detailed description is omitted because the rotating shaft 20 or the generator is a general technology.

Rotating blades corresponding to the present invention by changing the angle of the wind blades according to the strength of the wind, when the wind strength is weak breeze receives more wind and wind strength is strong winds receive less wind resistance Even if a strong wind such as blows the device to minimize the damage or damage to the components, including the wing.

Rotating blade portion for performing this function is the body 100, the rotor 200 is provided with a wing 210 on the side, and is fixed to the side of the body 100, the rotor 200 Is rotatably embedded, the blade 210 of the rotating body 200 is formed through the through blade rotation long groove 310 so that the outside is exposed to the outside, the through blade rotating long groove 310 formed inside the rotor It is provided in the rotating shaft 300 and the rotating shaft 300, the rotating space 320 is formed, and when the wind pressure impinging on the blade 210 is counted in the rotating body rotating space 320 of the rotating shaft 300 The rotor 200 is controlled to rotate toward the wing safety position, and when the wind pressure impinging on the blade 210 is small, the rotor 200 rotated in the rotor rotating space 320 is rotated back to the wind pressure generation position. It consists of wing position control module to control.

The rotating body 200 has a cylindrical shape so that the rotating body 200 can be rotated in the rotating body rotating space 320, and the rotating body rotating space 320 also has a cylindrical shape. It is provided to have a corresponding shape.

In addition, the rotor 200 and the wing 210 may be connected to each other through the connecting rod 220, so that the connecting portion 220 may be provided to be placed in the through blade rotation long groove 310 of the rotating shaft 300.

In addition, the rotating body 200 can be provided in a plurality separated along the rotating shaft 300, as described above, the reason for providing a plurality of the rotating body 200 is different from the climatic environment of the country unlike the foreign climatic environment This is because the direction of the wind is not only changed frequently, but also the intensity of the wind blowing from the upper and lower parts is different.

For this reason, the number of the rotating body 200 is separated into several, as shown in the figure, can be separated into three or provided in various numbers, such as less than two to five depending on the size of the windmill wings.

The wing position control module is to be provided in the inside of the rotating shaft 300 and the pressing table 220 provided on the other side of the rotating body 200 inherent in the rotating body rotating space 320 of the rotating shaft 300, Positioned on the side of the pressure zone 220 is made of an elastic body that is pressed or restored by pressing the pressure zone 220 according to the strength of the wind pressure.

Here, the elastic body may be provided through various embodiments, but may first be provided as a tube 330.

As such, when the tube 330 is used as an elastic body, the tube 330 may be provided in a state in which it is stored in the storage box 340 so as to be fixed to the inside of the rotating shaft 300, and the pressing table 220 may compress the tube 330. A protruding long hole is formed on one surface of the holder 340 positioned on the pressure table 220 so that a protruding portion is formed on the tube 330 so that a part of the tube 330 penetrates through the protruding long hole. It can form and provide.

Through this, the presser 220 is controlled to rotate toward the wing safety position while pressing the protrusion of the tube 330 according to the strength of the wind.

In addition, although not shown in the drawing so that the holder 340 is detachably fixed to the inside of the rotating shaft 300 may be fixed through a screw fastening or a structure that is forcibly fitted into the groove of the rotating shaft 300.

In addition, the tube 330 is filled with various gases, for example, it may be provided with nitrogen (N ₂ ) is filled.

In addition, the tube 330 may be provided as a plurality of separate and independent, like a plurality of separate rotating bodies 200, or may be provided in a communication structure to inject nitrogen at a time.

In another embodiment of the elastic body, although not shown in the drawing, it may be used as a spring such as a leaf spring or a tension spring.

As described above with reference to FIGS. 10 to 12, the angle of the wind blade is changed according to the strength of the wind through the horizontal shaft wind generator provided with the wind blade of the present invention.

First, Figure 10 is the strength of the wind (W) to the extent necessary to perform wind power generation, the strength of the wind (W) at this time is smaller than the elastic force of the tube 330 which is an elastic body inherent in the rotating shaft 300 The pressing table 220 of the rotating body 200 in the rotating body rotating space 320 of 300 is blocked from being rotated by the protruding portion of the tube 330.

At this time, the strength of the wind (W) transmitted to the rotary blade is used to rotate the blade 210 of the rotating body (200).

11 shows that the strength of the wind (W) slightly exceeds the strength required to perform the wind power generation, the strength of the wind (W) at this time than the elastic force of the tube 330, which is an elastic body inherent in the rotating shaft 300 The rotor 200 is clockwise (a drawing) while the pressing table 220 of the rotor 200 embedded in the rotor rotating space 320 of the rotary shaft 300 partially compresses the protrusion of the tube 330. It has been moved to some extent.

At this time, the strength of the wind (W) transmitted to the rotary wing has a risk that can damage the wing 210 of the rotor 200 to some extent, the wing of the wing 210 of the rotor 200 is wing safety It is a state where the wind cross section is a little smaller than the wind pressure generation position with a part moved toward the position (clockwise).

Finally, FIG. 12 is a degree in which the strength of the wind (W) greatly exceeds the strength required to perform wind power generation, and the strength of the wind (W) at this time is an elastic body inherent in the rotating shaft 300 of the tube 330. The pressing table 220 of the rotating body 200 is larger than the elastic force and the pressing table 220 of the rotating body 200 embedded in the rotating body 320 of the rotating shaft 300 completely compresses the protruding portion of the tube 330. 220 is caught in the side of the holder 340, the movement is limited.

At this time, the strength of the wind (W) transmitted to the rotary blade is dangerous to damage the wing 210 of the rotor 200, the wing of the wing 210 of the rotor 200 is the wing safety position (see direction) Moved to the) side, the wind cross-section area is much smaller than the wind pressure generation position.

Then, when the strength of the wind (W) is weakened by the restoring force of the tube 330, which is an elastic body inherent in the rotating shaft 300, the projecting portion of the tube 330 is restored and the rotating body rotating space 320 of the rotating shaft 300 By moving the pressure zone 220 of the rotor 200 inherent in the wind pressure generation position (counterclockwise) to provide a rotary blade to perform wind power generation.

1: large plate 2: rotating shaft
3: windmill 3a: windmill wings
3b: Wind pressure plate 4: Rope
5: rotating part 6: generator
11,100 body 12: wing shaft
13: wing 20: axis of rotation
30: relay rotating shaft 200: rotating body
210: wing 220: pressure plate
230: connecting rod 300: rotation axis
310: long slot for penetrating blade rotation 320: rotation space of the rotating body
330 tube 340 storage box
P: support plate W: wind

Claims (6)

In the horizontal axis wind power generator for generating electricity by the power of the rotational force transmitted through the rotary blades rotated by the wind power,
The rotating blade unit
Body 100;
Rotor 200 with a wing 210 on the side;
Being fixed to the side of the body 100, the rotating body 200 is rotatably embedded, the blade 210 of the rotating body 200 is a long groove 310 for penetrating blades to be exposed to the outside. A rotation shaft 300 having a rotating body rotating space 320 formed therein, and having a through blade rotating long groove 310 formed therein;
Being provided inside the rotating shaft 300, when the wind pressure impinging on the wing 210 is counted, the rotating body 200 embedded in the rotating body rotating space 320 of the rotating shaft 300 toward the wing safety position And a wing position control module for controlling the rotating unit and controlling the rotating body 200 rotated in the rotating body rotating space 320 to the wind pressure generating position when the wind pressure impinging on the wing 210 is small. Wind blades for a horizontal axis wind generator comprising a.
The method of claim 1,
The wing position control module,
A pressing table 220 provided on the other side of the rotating body 200 embedded in the rotating body rotating space 320 of the rotating shaft 300;
Horizontal shaft wind turbine, characterized in that provided on the inside of the rotating shaft 300, positioned on the side of the pressing table 220, the elastic body is pressed or restored to the pressing table 220 in accordance with the strength of the wind pressure; Wind vanes for generators.
The method of claim 2,
The elastic body is a wind turbine blade for a horizontal axis wind generator, characterized in that the tube (330).
The method of claim 2,
Wind turbine for a horizontal axis wind generator, characterized in that the elastic body is a spring.
The method of claim 3,
The gas filled in the tube 330 is a wind blade for a horizontal axis wind generator, characterized in that nitrogen (N ₂ ).
The method according to any one of claims 3 to 5,
The rotor 200 is a wind turbine blade for a horizontal axis wind generator, characterized in that provided separately separated along at least two along the rotating shaft (300).

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