KR20190001980A - Wind power generator - Google Patents

Abstract

A wind power generator according to an aspect of the present invention comprises: a first rotating unit of which rotating motion is implemented by a first wind velocity; a second rotating unit of which a rotating motion different from the rotating motion of the first rotating unit is implemented by the first wind velocity; a power generating unit which generates power using a rotary force of the first rotating unit; and a connecting unit which receives the rotary power of the first rotating unit and the second rotating unit. The connecting unit implements an identical rotating motion of the first rotating unit and the second rotating unit when wind velocity is under a predetermined reference wind velocity, and a different rotating motion of the first rotating unit and the second rotating unit when wind velocity is above a predetermined reference wind velocity.

Description

Wind power generator

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a wind power generator, and more particularly, to a wind power generator capable of generating electricity using wind power.

A wind turbine is a device that produces electricity using the wind force. Because wind power is a cheap renewable energy source, wind power generators are being used in many regions and countries today.

The wind turbine generator can be classified into vertical wind turbine generators such as Dararius type and Sabonius type and horizontal propeller type wind turbine generators according to the type of shaft. Horizontal axis wind power generators are widely used from small capacity to large capacity, and vertical axis wind power generators are widely used in wind power generators of medium capacity or below. Here, the horizontal axis wind power generation device is more efficient than the vertical axis wind power generation device, but it can receive more influence of the wind and can be broken by the wind speed and rotation. For this reason, there are various control methods for preventing the horizontal axis wind turbine from over rotating when the wind speed is strong.

As a control method for preventing the horizontal axis wind power generator from being rotated, there are typically a pitch control and a stall control. Pitch control is a control method of controlling the rotation speed of the blade by controlling the angle of the blade to control the magnitude of lift applied to the blade. Stall control is a control method that prevents the blades from rotating further when the wind speed reaches the limit wind speed. This is a method of controlling by the aerodynamic shape of the blade so that lift does not act on the blade at the limit wind speed.

Among them, the conventional pitch control measures the wind by the air volume meter and controls the angle of the blade by the electric control based on the measured wind information value. However, when the angle of the blades is adjusted by the electric control, since a large electromagnetic wave is generated inside the generator, the electric signal can not be transmitted or output properly, and the angle of the blade can not be properly adjusted.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a wind power generator in which the angle of a blade is adjusted mechanically in response to a change in wind speed to solve the above problems.

It is to be understood that the present invention is not limited to the above-described embodiments and that various changes and modifications may be made without departing from the spirit and scope of the present invention as defined by the following claims .

According to one aspect of the present invention, there is provided a wind turbine comprising: a first rotating part in which a rotating operation is realized by a first wind speed; A second rotating part that is rotated by the first wind speed to implement a rotating operation different from the rotating operation of the first rotating part; A power generating unit generating power using the rotational force of the first rotating unit; And an interlocking portion that receives the rotational force of the first rotating portion and the second rotating portion such that the first rotating portion and the second rotating portion perform the same rotating operation when the wind speed is lower than a predetermined reference wind speed So that the first rotary part and the second rotary part perform different rotational movements at a wind velocity exceeding a predetermined reference wind velocity.

The wind power generator according to the embodiment of the present invention can prevent the blades from being rotated by a strong wind speed.

The effects of the present invention are not limited to the above-mentioned effects, and the effects not mentioned can be clearly understood by those skilled in the art from the present specification and the accompanying drawings.

1 is an overall perspective view of a wind power generator according to an embodiment of the present invention;
2 is a front view of a wind turbine generator according to an embodiment of the present invention;
3 is a side view of a wind turbine generator according to an embodiment of the present invention;
4 is a partial perspective view of a wind power generator according to an embodiment of the present invention;
5 is a cross-sectional view taken along line X-X 'in Fig. 4;
6 is a view for explaining a process of controlling the angle of a blade by a wind power generator according to an embodiment of the present invention.
7 is a side view of a wind turbine generator according to another embodiment of the present invention;
8 is a partial perspective view of a wind power generator according to another embodiment of the present invention.
9 is a cross-sectional view taken along line Y-Y 'in Fig. 7;
10 is a view for explaining a process in which a wind power generator according to another embodiment of the present invention adjusts the angle of a blade.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the drawings. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the inventive concept. Other embodiments falling within the scope of the inventive concept may readily be suggested, but are also considered to be within the scope of the present invention.

The same reference numerals are used to designate the same components in the same reference numerals in the drawings of the embodiments.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a detailed description of known configurations or functions related to the present invention will be omitted when it is determined that the gist of the present invention may be blurred.

According to one aspect of the present invention, there is provided a wind turbine comprising: a first rotating part in which a rotating operation is realized by a first wind speed; A second rotating part that is rotated by the first wind speed to implement a rotating operation different from the rotating operation of the first rotating part; A power generating unit generating power using the rotational force of the first rotating unit; And an interlocking portion that receives the rotational force of the first rotating portion and the second rotating portion such that the first rotating portion and the second rotating portion perform the same rotating operation when the wind speed is lower than a predetermined reference wind speed So that the first rotary part and the second rotary part perform different rotational movements at a wind velocity exceeding a predetermined reference wind velocity.

The present invention also provides the wind power generator, wherein the interlocking portion provides an external force to the second rotating portion such that the second rotating portion performs the same rotating operation as that of the first rotating portion when the wind speed is lower than a predetermined reference wind speed .

The second rotary part overcomes an external force provided by the interlocking part at a wind speed exceeding the reference wind speed and implements a rotating operation different from the first rotary part.

The second rotary part is configured to be rotated in a direction opposite to the rotation direction of the first rotary part at an air velocity exceeding the reference wind speed.

The second rotary part is rotated in the same direction as the first rotary part at an air velocity exceeding the reference air speed but is rotated at a speed different from the rotation speed of the first rotary part. Can be provided.

Further, the interlocking portion may change the angle of the first rotating portion while allowing the first rotating portion and the second rotating portion to perform different rotating operations at the reference wind velocity exceeding the reference wind speed, .

The interlocking portion may include an auxiliary shaft connected to the second rotating portion and rotated in the same direction and speed as the second rotating portion when the second rotating portion is rotated; And a pivoting portion connected to the first rotating portion and rotated in the same direction and speed as the second rotating portion when the second rotating portion is rotated, and the pivoting portion rotates at a speed higher than a predetermined reference speed, When the second rotating part overcomes the external force provided by the interlocking part and implements a rotating operation different from the first rotating part, the second rotating part is moved on the auxiliary shaft to change the angle of the first rotating part A power generation device can be provided.

Further, the pivoting portion may slide on the auxiliary shaft in the forward or backward direction to change the angle of the first rotating portion.

Further, the auxiliary shaft forms a screw thread, and the rotating unit is screwed to the auxiliary shaft.

In addition, the pivoting portion may include: a moving portion that is moved on the sub axis; A connecting part connected to one end of the first rotating part and rotated to change an angle of the first rotating part; And a rod portion connected to the position shifting portion and the connecting portion. The rod portion is moved in correspondence with the position shifting of the position shifting portion, and the angle of the first rotating portion is changed by rotating the connecting portion Can be provided.

The power generating unit is disposed between the first rotating unit and the second rotating unit, and the cooperating unit penetrates the power generating unit to interlock the first rotating unit and the second rotating unit. Can be provided.

1 is an overall perspective view of a wind turbine generator according to an embodiment of the present invention.

Referring to FIG. 1, a wind turbine generator according to an embodiment of the present invention includes a first rotating part 100 that is rotated by a first wind speed, a second rotating part 100 that rotates the first rotating part 100 by the first wind speed, A main body 300 disposed between the first and second rotors 100 and 200 and a second rotator 200 disposed between the first rotator 100 and the second rotator 200 in a rearward direction of the first rotator 100, And the rear portion 400 and the body portion 300 are disposed to support the first rotating portion 100, the second rotating portion 200, the main body portion 300, and the rear portion 400 And may include a pillar 500 and an interlock unit 600 (see FIG. 3) that receives the rotational force of the first and second rotary units 100 and 200.

Here, the forward direction may be a direction from the first rotary part 100 to the second rotary part 200, and the rear direction may be a direction from the second rotary part 200 to the first rotary part 100 have.

In addition, the first wind speed may be the speed of all winds capable of rotating the first rotating part 100 and the second rotating part 200.

2 is a front view of a wind turbine generator according to an embodiment of the present invention.

Referring to FIG. 2, the first rotating part 100 may include a first blade 110 rotating the first rotating part 100 by the first wind speed.

The first blade 110 may have a shape such that the first rotating part 100 is rotated in a manner different from that of the second rotating part 200.

For example, the first blade 110 may include a first-first blade portion 111 and a first-second blade portion 112.

Here, the first blade 110 may be inclined from the first-second blade portion 112 toward the first-first blade portion 111.

Here, the inclination of the first blade 110 may be formed to realize a rotation operation different from the rotation of the second rotation unit 200.

For example, if the second rotary part 200 is rotated in the counterclockwise direction, the first blade 110 may be inclined so that the first rotary part 100 can be rotated clockwise.

In other words, the first blade 110 can rotate the first rotation part 100 in a direction different from that of the second rotation part 200 if the first rotation part 100 is not interlocked with the second rotation part 200, May be inclined such that the rotation is rotated.

The second rotating part 200 may include a second blade 210 rotating the second rotating part 200 by the first wind speed.

The second blade 210 may have a shape in which the second rotating part 200 is rotated in a manner different from that of the first rotating part 100.

The second rotation unit 200 is configured to perform a rotation operation different from that of the first rotation unit 100 when the second rotation unit 200 rotates by the first rotation speed of the first rotation unit 100 It may mean that the rotation operation is implemented in the direction opposite to the direction.

The second rotating part 200 is configured such that the rotation of the first rotating part 100 is different from that of the first rotating part 100. The second rotating part 200 is rotated by the first wind speed, But it may mean that the rotation operation is implemented at a speed different from the rotation speed of the first rotation part 100. [

The second blade 210 rotates in a direction different from that of the first rotation part 100 when the second rotation part 200 is not interlocked with the first rotation part 100, And may be shaped to rotate.

As a specific example, the second blade 210 may have a first surface 211 on both sides and a second surface surrounding the first and second sides in one direction.

The first surface 211 may include a first portion 211a, a second portion 211b, a third portion 211c, and a fourth portion 211d.

The inclination of the first portion 211a may be steeper than the inclination of the second portion 211b and the first portion 211a may be connected to the second portion 211b and the third portion 211c.

The second portion 211b may be connected to the first portion 211a and the fourth portion 211d.

The second surface 213 is connected to the first portion 211a, the second portion 211b and the third portion 211c so that when the first wind speed is greater than the reference wind velocity, It is possible to provide an acceleration space 214 in which an external force transmitted by a single wind speed can be transmitted more easily.

The second blade 210 may have a protrusion 213 for receiving the external force transmitted by the first wind speed more easily when the first wind speed is higher than the reference wind speed.

As the first wind speed increases, the protrusion 213 may form a larger eddy current on the second blade 210. Accordingly, the rotational speed of the second rotary part 200 may be further increased as the first wind speed is increased.

3 is a side view of a wind turbine generator according to an embodiment of the present invention.

3, the main body 300 includes an inverter (not shown) for converting electric energy generated when the first rotary part 100 is rotated into a using current, (Not shown) for rotating the generator by shifting the rotational force to a rotational speed required by the generator, a power generator 310 generating power using the rotational force of the first rotator 100, And an electronic brake 320 for stopping the rotation of the wind turbine.

The first rotating part 100 may include a rotation driving part connected to the first blade 110 and the first blade 110 and rotating together when the first blade 110 is rotated.

In the rear direction of the second rotary part 200, a rotation driving part may be disposed.

The rear portion 400 may be positioned in a rear direction of the rotation driving portion.

The rear portion 400 may be connected to the rotation driving portion and may be positioned to rotate together with the first rotation portion 100 when the first rotation portion 100 is rotated.

The first rotating part 100 and the second rotating part 200 may be rotated in the same direction at a wind speed less than a predetermined reference wind speed.

The first and second rotary units 100 and 200 may be rotated in different rotational directions at a wind velocity exceeding a predetermined reference wind velocity.

The interlocking part 600 provides an external force to the second rotating part 200 so that the second rotating part 200 can perform the same rotating operation as the first rotating part 100 at a wind speed below a predetermined reference wind speed .

The second rotary part 200 can overcome the external force provided by the interlocking part 600 at a wind velocity exceeding the reference wind speed and implement a rotation operation different from the first rotary part 100. [

The interlocking part 600 may cause the first rotating part 100 and the second rotating part 200 to perform different rotational movements in the reference wind speed excess wind speed and to change the angle of the first rotating part 100 .

Hereinafter, embodiments for implementing the function of the interlocking unit 600 will be described.

4 is a partial perspective view of a wind turbine generator according to an embodiment of the present invention, and FIG. 5 is a sectional view taken along the line X-X 'in FIG.

4 and 5, the interlocking part 600 is connected to the second rotation part 200 so that when the second rotation part 200 is rotated, the second rotation part 200 is rotated in the same direction as the second rotation part 200 And a second rotating part connected to the first rotating part and rotated in the same direction and speed as the second rotating part when the second rotating part is rotated, And an elastic part 630 for providing an elastic force to the rotary part 620. [

The rotary part 620 includes a support 620a, an elastic fixing part 620b, a first shrinking part 620c, a compression tube 620d, a compression plate 620f, a rod part 620g, a connection part 620h, Position shifting portion 620i.

The support table 620a may be connected to the rotation driving unit. The support table 620a may be connected to the rotation driving unit and rotated in the same direction and at the same speed as the first rotation unit 100 in correspondence with the rotation of the first rotation unit 100. [

The support base 620a may form a basic frame of the interlocking part 600. [

One end of the supporter 620a may be connected to the rotation driving unit and the other end may be connected to the elastic fixing unit 620b.

The elastic fixing portion 620b can fix one end of the compression tube 620d and the elastic portion 630, which will be described later.

The elastic fixing part 620b may form a hole to prevent the elastic part 630 from being deviated in the circumferential direction of the hole of the elastic fixing part 620b.

The elastic restricting portion 620j may be disposed on one side of the elastic fixing portion 620b.

The elastic restricting portion 620j may restrict movement of the elastic portion 630 and the compression tube 620d in the longitudinal direction of the auxiliary shaft 610. [

And a first shrinking portion 620c for fixing the auxiliary shaft 610 in the rear direction in the elastic restricting portion 620j may be disposed.

The first shrinking portion 620c is connected to one end of the auxiliary shaft 610 so as to be rotatable and can fix the auxiliary shaft 610 so as to restrict the movement of the auxiliary shaft 610.

A bearing for facilitating rotation of the auxiliary shaft 610 may be disposed between the first shrinking portion 620c and the elastic restricting portion 620j.

And the position shifting portion 620i can be moved on the sub-shaft 610. [

A thread may be formed inside the moving part 620i.

For example, the position shifting portion 620i may be a screw nut, but it is not limited thereto and may include any configuration that can be shifted on the auxiliary shaft 610 described later.

The position shifting portion 620i may be moved to move the compression tube 620d.

One end of the compression pipe 620d may be connected to the compression plate 620f and the other end may be connected to the elastic fixing unit 620b.

The elastic portion 630 may be disposed inside the compression pipe 620d.

The compression pipe 620d may contract or expand when the compression plate 620f is moved to provide an elastic force to the compression plate 620f together with the elastic portion 630. [

One side of the compression plate 620f may be connected to the compression tube 620d. The compression plate 620f can be moved when the position shifting unit 620i is slid on the support base 620a.

The restricting portion 620j may be a restriction on a distance that can be shifted in the backward direction of the compression plate 620f.

That is, in other words, the compression plate 620f can be moved to a position where the limiting portion 620j is located in the backward direction.

The restricting portion 620j may protrude from the support base 620a.

The rod portion 620g is connected to the compression plate 620f and the connection portion 620h so as to rotate the connection portion 620h in correspondence with the movement of the compression plate 620f.

One end of the rod portion 620g may be hinged to the compression plate 620f.

The other end of the rod portion 620g (hereinafter, the other end of the rod) may be hinged to the connection portion 620h.

The other end of the rod may be connected to the connection portion 620h while surrounding one end of the first blade 110. [

That is, the other end of the rod may be connected to the connecting portion 620h in a forward direction than one end of the first blade 110. [

For example, the other end of the rod may have a hook shape.

The other end of the rod provides a spacing space, and the connection portion 620h may be disposed in the spacing space.

The other end of the rod provides a claw shape and a spaced space in which the connecting portion 620h is disposed so that the connecting portion 620h is rotated at a wider angle so that the angle of the first blade 110 can be adjusted to be wide have.

The connection portion 620h may be connected to the rod portion 620g and an end portion of the first blade 110 to rotate the first blade 110 by the rod portion 620g.

The connection portion 620h may be disposed inside the sprayer driving portion.

That is, the connecting portion 620h can adjust the angle of the first blade 110 by rotating the first blade 110.

One end of the auxiliary shaft 610 may be connected to the second rotating part 200 and the other end may be connected to the first shrinking part 620c.

That is, the auxiliary shaft 610 is connected to the second rotating part 200, and when the second rotating part 200 is rotated, it can be rotated in the same direction and speed as the second rotating part 200.

Also, the auxiliary shaft 610 may be rotated by the position shifting unit 620i to rotate the second rotating unit 200, unlike the direction in which the second rotating unit 200 is to be rotated.

The auxiliary shaft 610 is connected to the second rotary part 200 and is connected to the compression plate 620f, the compression tube 620d, the elastic fixing part 620b, And may be connected to the first shrinking portion 620c through the elasticity restricting portion 620j.

A thread may be formed in a part of the auxiliary shaft 610.

The auxiliary shaft 610 may include a latching portion 611 for restricting the movement of the position shifting portion 620i in the forward direction.

The elastic portion 630 may be disposed inside the compression pipe 620d.

The elastic portion 630 may provide an elastic force to the position shifting portion 620i to provide an external force to the auxiliary shaft 610.

For example, the elastic portion 630 may be made of rubber or silicone as an elastic material, but the present invention is not limited thereto.

6 is a view for explaining a process of controlling the angle of a blade according to an embodiment of the present invention.

Below the predetermined reference wind speed, the first rotating part 100 and the second rotating part 200 perform different rotating motions, but what is actually implemented can perform the same rotating operation.

1, 2, 4, 5 and 6 (a), the first rotating part 100 tries to rotate clockwise by the first wind speed, The control unit 200 may try to rotate in the counterclockwise direction.

When the first rotation part 100 is about to rotate in the clockwise direction, the rotation part 620 may also be rotated clockwise.

That is, when the first rotation part 100 is to be rotated clockwise, the rotation driving part 120, the support 620a, the compression plate 620f, the elastic fixing part 620b, the elastic part 630b ), The elastic restricting portion 620j, and the first shrinking portion 620c may be rotated in the clockwise direction.

Also, when the second rotation part 200 is to be rotated in the counterclockwise direction, the auxiliary shaft 610 connected to the second rotation part 200 may also be rotated counterclockwise.

If the first wind speed is equal to or lower than the reference wind speed, if the second rotation part 200 is intended to rotate in the counterclockwise direction is smaller than the elastic force of the elastic part 630, It can not be rotated in the clockwise direction and can be rotated in the clockwise direction together with the first rotation part 100.

That is, the position shifting portion 620i is not moved due to the elastic force of the elastic portion 630, so that the auxiliary shaft 610 can be rotated together with the rotation portion 620.

In addition to the elastic force, the external force added to the auxiliary shaft 610 to rotate together with the rotary unit 620 is the sum of the frictional forces between the elements, that is, the frictional force between the auxiliary shaft 610 and the moving unit 620i .

At this time, the position of the moving part 620i is not moved, so that the angle of the first blade 110 may not be adjusted.

When the first wind speed becomes stronger and the first wind speed exceeds the reference wind speed, the first rotation part 100 and the second rotation part 200 can perform different rotation operations.

Referring to FIGS. 1, 2, 4, 5, and 6 (b), as the first wind speed becomes stronger, the second rotary part 200 tends to rotate counterclockwise It can be bigger.

When the first wind speed exceeds the reference wind speed, the second rotating part 200 exceeds the elastic force of the elastic part 630 and the second rotating part 200 is rotated in the counterclockwise direction, The first rotating part 100 may rotate in a different direction.

For example, the speed at which the second rotary part 200 is rotated clockwise may be slower than the speed at which the first rotary part 100 is rotated in the clockwise direction.

Alternatively, the second rotation part 200 may be rotated counterclockwise.

Alternatively, the rotation of the second rotating part 200 may be stopped.

When the second rotary part 200 rotates differently from the first rotary part 100, the thread of the position shifting part and the thread of the auxiliary shaft 610 interact with each other, As shown in FIG.

That is, the position shifting unit can be slid forward or backward on the sub axis 610.

Further, as the position shifting portion is moved, the elastic portion 630 may be gradually contracted.

The compression tube 620d and the compression plate 620f can be moved by the movement of the position shifting portion 620i.

The compression plate 620f may be slid on the support table 620a and be moved.

The rod 620g is also moved in correspondence with the movement of the compression plate 620f and the connection 620h can be rotated in response to the movement of the rod 620g.

The first blade 110 may be rotated about the longitudinal direction of the first blade 110 by the rotation of the connection portion 1620h.

Accordingly, the first blade 110 is less influenced by the first wind speed and can be prevented from being rotated by the first wind speed.

Here, the moving part 620i may be moved in the backward direction until the force of the second rotating part 200 to move in the counterclockwise direction and the elastic force of the elastic part 630 are in equilibrium.

Further, the position shifting unit can be moved in the backward direction until the compression plate 620f contacts the restriction unit 620j.

If the first wind speed changes to a wind speed less than a predetermined reference wind speed in the state where the position shifting portion 620i is moved, the position shifting portion is moved in the forward direction, 110 may also be rotated.

FIG. 7 is a side view of a wind power generator according to another embodiment of the present invention, FIG. 8 is a partial perspective view of a wind power generator according to another embodiment of the present invention, and FIG. FIG.

7 to 9, the linkage part 1600 is connected to the second rotation part 200 (see FIG. 1), and when the second rotation part 200 is rotated, the second rotation part 200, When the second rotating part 200 is rotated, the second rotating part 200 is rotated in the same direction and speed as the second rotating part 200, and is connected to the first rotating part 100 (see FIG. 1) And a resilient portion 1630 for providing an elastic force to the pivot portion 1620. The elastic portion 1630 may be formed of a flexible material.

The rotary unit 1620 includes a support base 1620a, an elastic fixing unit 1620b, an elasticity restricting unit 1620c, a first axial fixing unit 1620d, a moving unit 1620e, a compression tube 1620f, A compression plate 1620h, a restricting portion 1620i, a second shrinking portion 1620j, a reinforcing portion 1620k, a reinforcing bearing 1620l, a rod portion 1620m and a connecting portion 1620n.

The description may be omitted to the extent that it overlaps with the embodiment of the present invention described above.

The elastic fixing portion 1620b can fix one end of the elastic portion 1630 described later.

The elastic fixing part 1620b may form a hole to prevent the elastic part 1630 from being deviated in the circumferential direction of the hole of the elastic fixing part 1620b.

The elastic restricting portion 1620c may be disposed on one side of the elastic fixing portion 1620b.

The elastic restricting portion 1620c may restrict the movement of the elastic portion 1630 in the longitudinal direction of the auxiliary shaft 1610. [

And a first shrinking portion 1620d for fixing the auxiliary shaft 1610 in the rear direction in the elastic restricting portion 1620c may be disposed.

A bearing for facilitating rotation of the auxiliary shaft 1610 may be disposed between the first shrinking portion 1620d and the elastic restricting portion 1620c.

And the position shifting portion 1620e can be moved on the sub-shaft 1610. [

A thread may be formed inside the moving part 1620e.

For example, the position shifting portion 1620e may be a screw nut, but it is not limited thereto and may include any structure that can be shifted on the auxiliary shaft 1610 described later.

The position shifting portion 1620e may be moved to position the compression pipe 1620f.

One end of the compression tube 1620f may be connected to the position shifting portion 1620e and the other end may be connected to the compression plate 1620h.

The compression tube 1620f may be bolted to the position shifting portion 1620e.

The elastic portion 1630 may be disposed inside the compression pipe 1620f.

The compression tube 1620f may be moved by the position shifting portion 1620e to move the compression plate 1620h.

The compression tube 1620f functions to protect the elastic part 1630 and can move the compression plate 1620h in response to the movement of the position shifting part 1620e.

One end of the fixing pipe 1620g may be inserted into the compression pipe 1620f and the other end may be connected to the elastic fixing member 1620b.

The elastic portion 1630 may be disposed inside the fixing pipe 1620g. The fixing pipe 1620g may function to protect the elastic part 1630.

One side of the compression plate 1620h may be connected to the compression pipe 1620f. The compression plate 1620h may be displaced when the position shifting portion 1620e is slid on the support portion 1620a.

The restricting portion 1620i may be a restriction on the distance that can be shifted in the backward direction of the compression plate 1620h.

In other words, in other words, the compression plate 1620h can be moved to a position where the restriction portion 1620i is located in the backward direction.

The restriction portion 1620i may protrude from the support base 1620a.

The second shrinking portion 1620j can fix the auxiliary shaft 1610 so as to be rotatable.

That is, the second shrinking portion 1620j may restrict the movement of the auxiliary shaft 1610 in the circumferential direction of the auxiliary shaft 1610. [

The second shaft fixing portion may be connected to the support 1620a.

That is, the supporter 1620a may receive the external force transmitted from the second shrinking portion 1620j while supporting the auxiliary shaft 1610, and may support the second shrinking portion 1620j.

In addition, the second shrinking portion 1620j is formed so that the second moving portion 200 is rotated in the same rotational direction as the first rotating portion 100 at a wind speed less than a predetermined reference wind velocity, The elastic portion 1630 can support an external force transmitted to the position shifting portion 1620e in the process of providing an external force to the rotation portion 200. [

The reinforcing portion 1620k can support the second shrinking portion 1620j.

More specifically, the position shifting unit 1620e is moved to the second rotation unit 200 so that the second rotation unit 200 is rotated in the same rotational direction as the first rotation unit 100 at a wind speed less than a predetermined reference wind speed In the process of providing an external force, the second shaft fixing portion 1620j prevents an external force transmitted to the position shifting portion 1620e by the elastic portion 1630 from being damaged during the process of supporting the second shaft fixing portion 1620j The second shrinking portion 1620j can be supported.

The reinforcing bearing 16201 supports the position shifting portion 1620e so that the auxiliary shaft 1610 can be easily rotated.

The rod portion 1620m is connected to the compression plate 1620h and the connection portion 1620n so as to rotate the connection portion 1620n in correspondence with the movement of the compression plate 1620h.

The connection portion 1620n may be connected to the rod portion 1620m and an end portion of the first blade 110 to rotate the first blade 110 by the rod portion 1620m.

That is, the connection portion 1620n can adjust the angle of the first blade 110 by rotating the first blade 110. [

The auxiliary shaft 1610 may have one end connected to the second rotating part 200 and the other end connected to the first shrinking part 1620d.

That is, the auxiliary shaft 1610 is connected to the second rotating part 200, and when the second rotating part 200 is rotated, it can be rotated in the same direction and speed as the second rotating part 200.

Further, the auxiliary shaft 1610 may be rotated by the position shifting portion 1620e in a direction different from the direction in which the second rotating portion 200 is to be rotated, and may lead to rotation of the second rotating portion 200. [

The auxiliary shaft 1610 is connected to the second rotary part 200 and is connected to the second shrunk part 1620j, the reinforcing bearing 1620l, the moving part 1620e, And may be connected to the first shrinking portion 1620d through the compression tube 1620f, the fixing tube 1620g, the elastic fixing portion 1620b, and the elastic restricting portion 1620c.

A thread may be formed on a part of the auxiliary shaft 1610.

The elastic portion 1630 may be disposed inside the compression pipe 1620f and the fixing pipe 1620g.

The elastic portion 1630 may provide an elastic force to the position shifting portion 1620e to provide an external force to the auxiliary shaft 1610. [

For example, the elastic portion 1630 may be a spring, but the present invention is not limited thereto.

10 is a view for explaining a process of controlling the angle of a blade according to another embodiment of the present invention.

When the first wind speed is lower than the predetermined reference wind speed, the first and second rotors 100 and 200 perform different rotational motions, but what is actually implemented can perform the same rotational motions.

1, 2, 8, 9 and 10 (a), the first rotating part 100 tries to rotate clockwise by the first wind speed, The control unit 200 may try to rotate in the counterclockwise direction.

When the first rotation part 100 is about to rotate in the clockwise direction, the rotation part 1620 may also be rotated clockwise.

That is, when the first rotary part 100 is to be rotated in the clockwise direction, the rotation driving part 120, the support part 1620a, the compression plate 1620h, the compression pipe 1620f, the fixing pipe 1620g, The rotation unit 1620 such as the position shifting unit 1620e may be rotated in a clockwise direction.

Also, when the second rotary part 200 is to be rotated in the counterclockwise direction, the auxiliary shaft 1610 connected to the second rotary part 200 may also be rotated counterclockwise.

However, if the first wind speed is less than the reference wind speed, if the force to rotate the second rotation part 200 counterclockwise is smaller than the elastic force of the elastic part 1630, And can be rotated in the clockwise direction together with the first rotation part 100 without being rotated in the clockwise direction.

That is, the position shifting portion 1620e is not moved by the elastic force of the elastic portion 1630, so that the auxiliary shaft 1610 can be rotated together with the rotation portion 1620. [

In addition, the external force added to the auxiliary shaft 1610 to rotate together with the rotary unit 1620 can combine the frictional forces between the components in addition to the elastic force.

At this time, the position shifting portion 1620e is not moved and the angle of the first blade 110 may not be adjusted.

When the first wind speed becomes stronger and the first wind speed exceeds the reference wind speed, the first rotation part 100 and the second rotation part 200 can perform different rotation operations.

Referring to FIGS. 1, 2, 8, 9, and 10 (b), the second rotating part 200 tends to rotate counterclockwise as the first wind speed becomes stronger It can grow bigger.

When the first wind speed exceeds the reference wind speed, the second rotation part 200 exceeds the elastic force of the elastic part 1630 and the second rotation part 200, The first rotating part 100 may rotate in a different direction.

For example, the speed at which the second rotary part 200 is rotated clockwise may be slower than the speed at which the first rotary part 100 is rotated in the clockwise direction.

Alternatively, the second rotation part 200 may be rotated counterclockwise.

Alternatively, the rotation of the second rotating part 200 may be stopped.

When the second rotating part 200 rotates differently from the first rotating part 100, the thread of the position shifting part and the thread of the auxiliary shaft 1610 interact with each other, As shown in FIG.

That is, the position shifting unit can be slid forward or backward on the sub axis 1610.

Further, as the position shifting portion is moved, the elastic portion 1630 may be gradually contracted.

The compression tube 1620f and the compression plate 1620h can be moved by the movement of the position shifting portion 1620e.

As the compression tube 1620f is moved in the backward direction, the fixing tube 1620g can be inserted more and more into the compression tube 1620f.

The compression plate 1620h can be moved while being slid on the support base 1620a.

The rod portion 1620m is also moved in correspondence with the movement of the compression plate 1620h and the connection portion 1620n may be rotated corresponding to the movement of the rod portion 1620m.

The first blade 110 may be rotated about the longitudinal direction of the first blade 110 by the rotation of the connection portion 1620n.

Accordingly, the first blade 110 is less influenced by the first wind speed and can be prevented from being rotated by the first wind speed.

Here, the position shifting portion 1620e can be moved in the backward direction until the force of the second rotating portion 200 to move in the counterclockwise direction and the elastic force of the elastic portion 1630 are balanced.

Further, the position shifting unit can be moved in the backward direction until the compression plate 1620h is brought into contact with the restriction unit 1620i.

If the first wind speed changes to a wind speed less than a predetermined reference wind speed in a state where the position shifting portion 1620e is moved, the position shifting portion is moved in the forward direction, 110 may also be rotated.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and, together with the description, serve to explain the principles of the invention.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, It will be apparent to those skilled in the art that changes or modifications may fall within the scope of the appended claims.

100: first rotating part 200: second rotating part
300: main body part 400: rear part
500: Column

Claims (11)

A first rotating part in which a rotating operation is realized by a first wind speed;
A second rotating part that is rotated by the first wind speed to implement a rotating operation different from the rotating operation of the first rotating part;
A power generating unit generating power using the rotational force of the first rotating unit; And
And an interlocking portion that receives the rotational force of the first rotating portion and the second rotating portion,
Wherein the interlocking portion comprises:
The first rotating portion and the second rotating portion are caused to perform the same rotating operation at a wind velocity lower than a predetermined reference wind speed,
So that the first rotating part and the second rotating part can be rotated in different rotational directions at a wind speed exceeding a predetermined reference wind speed,
Wind power equipment.
The method according to claim 1,
Wherein the interlocking portion comprises:
Wherein the second rotation part provides an external force to the second rotation part such that the second rotation part performs the same rotation operation as the first rotation part at a wind speed less than a predetermined reference wind speed.
3. The method of claim 2,
The second rotating portion
Wherein the control unit overcomes an external force provided by the interlocking unit at a wind speed exceeding the reference wind speed and implements a rotation operation different from the first rotation unit.
The method of claim 3,
The second rotating portion
Wherein a rotating operation is implemented in a direction opposite to a rotating direction of the first rotating part at a wind speed exceeding the reference wind speed.
The method of claim 3,
The second rotating portion
Wherein the rotating operation is performed at a speed different from the rotating speed of the first rotating part, while rotating in the same direction as the first rotating part at the wind speed exceeding the reference wind speed.
The method of claim 3,
Wherein the interlocking portion comprises:
Wherein the first rotating part and the second rotating part implement different rotational movements and the angle of the first rotating part is changed in the reference wind speed exceeding wind speed.
The method according to claim 6,
Wherein the interlocking portion comprises:
An auxiliary shaft connected to the second rotating portion and rotated in the same direction and speed as the second rotating portion when the second rotating portion is rotated; And
And a rotation unit connected to the first rotation unit and rotated in the same direction and speed as the second rotation unit when the second rotation unit is rotated,
The pivoting portion,
When the second rotating part overcomes an external force provided by the interlocking part and implements a rotating operation different from the first rotating part at a wind speed exceeding a predetermined reference wind speed, And changes the angle of the wind turbine.
8. The method of claim 7,
The pivoting portion,
Wherein the angle of the first rotary part is changed by sliding in the forward or backward direction on the auxiliary shaft.
9. The method of claim 8,
The sub-
Forming a thread,
The pivoting portion,
And the auxiliary shaft is screwed with the auxiliary shaft.
9. The method of claim 8,
The pivoting portion,
A position shifted position on the sub axis;
A connecting part connected to one end of the first rotating part and rotated to change an angle of the first rotating part;
And a rod portion connected to the moving portion and the connecting portion,
The load unit includes:
Wherein the angle changing unit changes the angle of the first rotation unit by rotating the connection unit while being moved in correspondence with the position shifting to the position shifting unit.
The method of claim 3,
The power generation unit includes:
A second rotating part disposed between the first rotating part and the second rotating part,
Wherein the interlocking portion comprises:
And the first rotating portion and the second rotating portion are interlocked with each other through the power generation portion.

Images