KR102308972B1 - A blade of wind power generator - Google Patents

Abstract

The present invention relates to a blade for a wind power generator. In accordance with the present invention, as an improvement is made in a structure of a blade including a wing part formed into a plate shape to guide wind, and a windbreak part formed at one end of the wing part to be bent in a direction to one side of the wing part to collect the wind guided to the one side of the wing part, a wind discharge hole is formed on the windbreak part and at least one vent hole, through which the wind applied to one side or the other side of the wind part passes, is formed on the surface of the wing part, and, accordingly, the wind applied to the one side or the other side of the wing part can quickly flow out to the outside of the windbreak part as well as to one side or the other side of a partition part, which is an opposite side, without stagnating in the windbreak part, and, thus, the formation of an eddy in the windbreak part is minimized to enable smooth rotation, and also, wind pressure applied to the blade is lowered to keep the rotation speed of a hub to which the blade is fixed constant, thereby improving power generation efficiency.

Description

A blade of wind power generator

The present invention relates to a blade for a wind power generator, and more particularly, when a strong wind or a gust of wind is applied to the blade according to the wind strength, it is possible to prevent damage to the blade by lowering the wind pressure, and the air can move smoothly so that the blade is fixed. It relates to a blade for a wind power generator capable of increasing wind power generation efficiency by maintaining a constant rotation speed of a hub.

Since fossil energy resources are gradually being depleted and polluting the global environment, humankind has made great efforts for a long time to develop clean alternative energy use devices that do not deplete and pollute the environment. Such clean alternative energy includes solar energy, wind energy, current energy, tidal energy, geo-thermal energy, bio-thermal energy ), etc.

On the other hand, our country, which is surrounded by the sea on three sides, is a favorable terrain for wind power generation using the power of wind. , it is classified as a vertical axis wind power generator in which the axis of rotation is installed perpendicular to the ground.

The horizontal axis wind turbine is the most common type and has the advantage of realizing high power generation efficiency, but it is difficult to generate electricity smoothly in an area where the wind direction changes frequently. Many studies are being conducted due to the advantage of easy maintenance because major parts such as gearboxes and generators are installed on the ground.

In particular, in the vertical axis wind turbine, a plurality of blades are installed around a vertical axis of rotation or a cylindrical structure, and in this case, each blade is configured to be folded or rotated according to a relative position according to the wind direction or the strength of the wind. to make the most of wind power.

As an example of such a vertical axis wind turbine, Patent Publication No. 10-2013-0048544 (Reference 1) has been proposed. This relates to a wind power generator, a rotation shaft installed perpendicular to the ground, a stator of the generator installed to surround the rotation shaft, a hub surrounding the stator and installed to rotate about the rotation shaft, and installed on the inner circumferential surface of the hub A rotor of a generator installed to face the stator, a plurality of blade support arms extending radially from an outer circumferential surface of the hub, and a blade installed at an end of the blade support arm.

By the way, the blade of Reference 1 has a concave inner surface of the front end of the rotating front end, and a windshield extending rearward from the front end and a support rib fixed to the inner surface to support the shape of the blade. Therefore, when a momentary strong wind or gust of wind occurs, the air flowing into the tip cannot be discharged quickly, so the rotation speed of the hub is irregularly variable.

In addition, in this structure, the wind cannot move from one side of the windshield part 430 to the other side, so it is difficult to quickly circulate air when an instantaneous strong wind or gusts occur, so the rotation speed of the hub to which the blade is fixed is irregularly variable, so that the power generation efficiency is increased. It has the problem of lowering.

Reference 1: Korean Patent Publication No. 10-2013-0048544

Therefore, the present invention for solving such problems of the prior art prevents the strong wind pressure due to strong wind or gust from being transmitted to the blade as it is to prevent deformation or damage of the blade and smooth air flow to rotate the hub to which the blade is fixed. An object of the present invention is to provide a blade for a wind power generator capable of maintaining a constant speed and thus increasing power generation efficiency.

In particular, in the present invention, when a momentary strong wind such as a strong wind or a gust of wind blows, it is quickly discharged to move quickly from the inside or outside of the blade to the outside or the inside, thereby lowering the wind pressure to maintain a constant rotational speed of the hub to which the blade is fixed. An object of the present invention is to provide a blade for a wind turbine that can be used.

The present invention in order to solve such a technical problem;

In the blade comprising a wing portion formed in a plate shape to guide the wind, and one end of the wing portion is bent in the direction of one surface of the wing portion to collect wind guided to one surface of the wing portion, wherein the wing portion is air on the surface It provides one or more vent holes through which the wind turbine blades are formed, characterized in that the wind exhaust hole is formed on the surface of the windshield.

At this time, it is characterized in that one or more vent holes of the wing portion are formed through a rectangular or circular shape to be biased in the direction of the other end of the wing portion.

And the wind discharge hole formed in the windshield is characterized in that the opening and closing by the windshield opening and closing means.

In addition, the windshield opening/closing means includes a motor installed on one surface of the wing, a lead screw that rotates according to driving of the motor and is supported protruding in the direction of the windshield, a transfer nut screwed to the lead screw, and the transfer nut Doedoe is supported and one end is hinged to one side of the wind exhaust hole of the inner surface of the windshield and is characterized in that it comprises an opening and closing hole for opening and closing the wind exhaust hole according to the movement of the transfer nut.

At this time, a horizontal through hole through which the lead screw passes is formed through the surface of the opening and closing port, and a guide rail for guiding the horizontal movement of the transfer nut in the same direction as the horizontal through hole is provided on one surface of the opening and closing port, A first brush is provided on the front surface of the guide rail provided on one surface, and a second brush is provided on the other surface of the opening and closing hole along the horizontal through hole.

And the guide rail is made of an upper guide rail and a lower guide rail, the first brush is formed in a band shape, a first fixing part fixed to the upper guide rail, and formed as a lower part of the first fixing part, the upper guide It consists of a first brush that covers between the rail and the lower guide rail; The second brush is formed in a band shape and includes a second fixing part fixed to the upper side of the horizontal through-hole formed on the other surface of the opening and closing part, and a second brush part formed under the second fixing part to cover the horizontal through-hole. characterized by being made.

In addition, the windshield opening and closing means has one end hinged to one side of the wind exhaust hole of the inner surface of the windshield to open and close the wind exhaust hole formed in the windshield an opening and closing opening for opening and closing the wind exhaust hole, and one end of the wing portion or a windshield It is characterized in that it consists of an electric cylinder which is hinged to one side of the inner part and the other end is hinged to the opening and closing port.

In this case, the electric cylinder is composed of a cylinder body and a rod, and the rear end of the cylinder body is hinged to one side of the wing portion or one side inside the windshield, and the front end of the rod is hinged to the opening and closing port.

According to the present invention, as a wind exhaust hole is formed in the windshield and one or more vent holes through which the wind applied to one or the other surface of the wing passes is formed on the surface of the wing, the wind applied to one or the other surface of the wing is applied to the windshield. It minimizes the occurrence of vortices within the windshield and reduces the wind pressure applied to the blades by minimizing the occurrence of vortices within the windshield by allowing them to quickly move out and out of the windshield without staying on the outside as well as on the other side or one side of the bulkhead. Since the rotation speed of the hub to which the blade is fixed can be maintained constant, the power generation efficiency is improved.

In addition, according to the present invention, the wind pressure applied to the blades is constant even when a strong wind blows by automatically opening and closing the wind exhaust hole of the windshield part and the vent hole formed on the surface of the bulkhead according to the wind intensity information around the wind generator or the wind intensity information such as the weather center. In addition to preventing damage to the blade, the hub on which the blade is supported has the advantage of stably rotating at a constant speed.

1 is a perspective view showing a blade for a wind power generator according to a first embodiment of the present invention.
2 is a view showing an example of a wind power generator to which a blade for a wind power generator according to the present invention is applied.
3 is a perspective view illustrating a blade for a wind power generator according to a second embodiment of the present invention.
4 is a perspective view showing a blade for a wind power generator according to a third embodiment of the present invention.
5 is an exploded view showing a blade for a wind power generator according to a third embodiment of the present invention.
6 is a view showing the main part of the blade for a wind power generator according to a third embodiment of the present invention from the front.
7 is a cross-sectional view showing a state in which the opening and closing the wind outlet hole formed in the windshield portion of the wind turbine blade according to the third embodiment of the present invention.
8 is a cross-sectional view showing a state in which the opening and closing opening in the wind outlet hole formed in the windshield portion of the wind turbine blade according to the third embodiment of the present invention.
9 is a cross-sectional view showing an open state of the opening in the wind outlet hole formed in the windshield portion of the wind turbine blade according to the third embodiment of the present invention.
10 is a perspective view illustrating a blade for a wind power generator according to a fourth embodiment of the present invention.
11 is a view illustrating a wind power generator to which a blade for a wind power generator according to a fifth embodiment of the present invention is applied.
12 is a view illustrating a wind power generator to which a blade for a wind power generator according to a sixth embodiment of the present invention is applied.
13 is a perspective view illustrating a blade for a wind power generator according to a seventh embodiment of the present invention.
14 is a cross-sectional view illustrating an operation process of an opening and closing opening of a blade for a wind power generator according to a seventh embodiment of the present invention.
15 is an exploded view showing a blade for a wind power generator according to an eighth embodiment of the present invention.

Hereinafter, the characteristics of the blade for a wind power generator according to the present invention will be understood by the embodiments described in detail with reference to the accompanying drawings.

Since the present invention can have various changes and can have various forms, embodiments will be described in detail in the text. However, this is not intended to limit the present invention to the specific disclosed form, it should be understood to include all modifications, equivalents and substitutes included in the spirit and scope of the present invention.

1 to 2 are views illustrating a blade for a wind power generator according to a first embodiment of the present invention.

According to this, a plurality of blades 100 for a wind power generator of the present invention are installed radially around a hub 10 installed via a bracket so as to rotate about the rotation axis of the generator 1 .

The blade 100 has a cross-section as a whole in a spar-like shape, and a wing part 110 that is formed in a plate shape to guide the wind, and one end of the wing part 110 of the wing part 110 . It is formed by bending in the direction of one side and includes a windshield unit 120 for collecting wind guided to one side of the wing unit 110 .

Hereinafter, the constitution of each part of the present invention will be described in detail.

The blade 100 can be made of various metal materials, but is preferably made of aluminum to lighten the weight.

The wing unit 110 is formed in a plate shape and is arranged to stand upright, and when wind flows into one surface of the wing unit 110 , it is guided toward the windshield unit 120 provided at one end of the wing unit 110 . .

The wing portion 110 is preferably made of a rectangular shape, but may be formed in a square or various other shapes.

At this time, the wing part 110 is formed with one or more vent holes 112 through which air passes on the surface. The vent hole 112 may be formed through various shapes such as a rectangle and a circle to be biased toward the other end of the wing unit 110 . As shown in the figure, a plurality of circular vent holes 112 vertically and continuously penetrate through the surface of the wing part 110 to be biased in the direction of the other end of the wing part 110 .

According to such a structure, the vent 112 moves in the direction of one side or the other side of the wing unit 110 without staying inside the windshield unit 120, and the wind applied to one side or the other side of the wing unit 110 can escape. Thus, it is possible to reduce the occurrence of vortices within the windshield 120 .

On the other hand, the windshield unit 120 is formed in a semi-cylindrical shape to be integrally provided at one end of the wing unit 110, one surface of the wing unit 110 is bent forward, and a wind outlet hole 122 is formed on the surface. These wind discharge holes 122 do not stay inside the windshield 120 when the wind applied to one surface or the other surface of the wing unit 110 moves to the windshield 120, but quickly in the outside direction of the windshield 120. The hub 10 to which the blade 100 is fixed by lowering the wind pressure applied to the blade 100 as well as to minimize the occurrence of vortex within the windshield 120 so as to be able to move and escape, as well as to ensure smooth rotation. The rotational speed can be kept constant, so that the power generation efficiency can be increased.

In addition, upper and lower end plate portions 123 and 124 are integrally coupled to the upper end and lower end of the windshield unit 120 . The upper and lower closing plate portions 123 and 124 are integrally fixed along the upper and lower edges of the windshield 120 by welding or the like.

The upper and lower closing plate portions 123 and 124 have their other ends extended and integrally fixed to the upper and lower sides of the other end of the wing portion, thereby also performing a function of a reinforcing bar to prevent deformation of the wing portion due to wind pressure.

At this time, one or more upper and lower through-holes 123a and 124a are formed in the upper and lower closing plate portions 123 and 124, respectively, so that when the blade 100 rotates, the wind quickly escapes to the upper and lower ends of the windshield 120. It minimizes the occurrence of vortices within the windshield 120 to ensure smooth rotation, and minimizes snow accumulation in winter to prevent the slow rotation of the blade 100 due to the weight of snow, and It can lead to the rapid discharge of rainwater.

These upper and lower through-holes 123a and 124a may be formed in a circular shape, but may be formed in a polygonal shape such as a triangle or a square, and although not shown separately, a plurality of upper and lower end plate portions 123 and 124 may be formed respectively. have.

Meanwhile, FIG. 3 is a diagram illustrating a blade for a wind power generator according to a second embodiment of the present invention.

According to this, the surface of the wing part 110 of the blade 100 for a wind power generator of the present invention is formed through a vent hole 112 of a long rectangular shape in the vertical direction. In this case, as shown on the surface of the wing part 110 , for example, the vent hole 112 is formed through a rectangular shape to be biased toward the other end direction of the wing part 110 . According to such a structure, the vent 112 moves in the direction of one side or the other side of the wing unit 110 without staying inside the windshield unit 120, and the wind applied to one side or the other side of the wing unit 110 can escape. Thus, it is possible to reduce the occurrence of vortices within the windshield 120 .

And, Figures 4 to 9 are views for explaining the blade for a wind power generator according to a third embodiment of the present invention.

According to this, the wind outlet hole 122 formed in the windshield 120 is opened and closed by the windshield opening and closing means 200 .

The windshield opening/closing means 200 includes a motor 210 installed on one surface of the wing unit 110, and a lead screw that rotates according to the driving of the motor 210 and has an end supported by protruding in the direction of the windshield 120 ( 212), the transfer nut 214 screwed to the lead screw 212, and the transfer nut 214 are supported, but one end of the wind exhaust hole 122 of the inner surface of the windshield 120 is on one side. It is hinged and consists of an opening and closing port 216 that opens and closes the wind exhaust hole 122 according to the movement of the transfer nut 214 .

Hereinafter, the windshield opening and closing means 200 will be described in detail.

First, the motor 210 is installed on one surface of the wing unit 110 and is rotated forward or reverse by a controller (not shown). In this case, the motor 210 is, for example, a stepping motor, which is also fixed to one surface and the other surface of the wing unit 110 by fastening means such as screws.

And when the lead screw 212 is connected to the rotation shaft of the motor 210 , the end of the lead screw 212 is bent forward of one surface of the wing unit 110 so that the lead screw 212 can be stably rotated. It is preferable to be supported by the support hole (121a) formed in (120). This lead screw 212 is screwed to the female thread 214a of the transfer nut 214 . At this time, the support hole 121a is installed to cross the windshield 120 and is formed in the support band 121 for supporting the opening and closing port 216 .

In this structure, when the lead screw 212 is rotated in one direction (for example, clockwise) or in the other direction (for example, counterclockwise) according to the driving of the motor 210, the transfer nut 214 is moved to the lead screw 212 ) in the longitudinal direction.

On the other hand, the windshield unit 120 is formed with a wind outlet hole 122, such a wind outlet hole 122 may be formed in a vertical long rectangular shape as shown, for example, but a square or circular shape, an oval, etc. It may be made in various shapes, and it is preferable that an opening 216 having a symmetrical shape to open and close the wind discharge hole 122 is provided.

This opening 216 is provided in close contact with the inner surface of the windshield 120 by bending a metal plate. In particular, one end of the opening 216 is provided rotatably by a hinge 218 at one end adjacent to the wing portion 110 .

At this time, a horizontal through-hole 216a through which the lead screw 212 passes is formed through the surface of the opening/closing opening 216, and a transfer nut 214 is formed in the opening/closing opening 216 in the same direction as the horizontal through-hole 216a. A guide rail 217 for guiding the horizontal movement of the At this time, the guide rail 217 has the same structure, and includes a pair of upper guide rails 217a and lower guide rails 217b.

A downward guide groove 2177a is formed in the upper guide rail 217a to support the upper side of the transfer nut 214 to prevent separation, and the lower guide rail 217b supports the lower side of the transfer nut 214. An upward guide groove 2177b for preventing separation is formed.

In addition, the transfer nut 214 has the same structure, and upper and lower shaft portions 214a and 214b having a circular cross section rotatably fitted to the downward guide groove 2177a and the upward guide groove 2177b at the upper and lower ends of the body. ) respectively protrude, and the upper and lower bearings 215a and 215b are respectively mounted.

According to this structure, when the lead screw 212 rotates in one direction (for example, clockwise) or in the other direction (for example, counterclockwise) according to the driving of the motor 210, the transfer nut 214 moves the lead screw ( The opening and closing port 216 is pushed or pulled while moving forward and backward in the longitudinal direction of 212 , and the opening and closing port 216 is rotated around the hinge 218 to open and close the wind discharge hole 122 . At this time, the position of the transfer nut 214 is varied within the guide rail 217 so that the opening 216 smoothly rotates around the hinge 218 .

And it is possible to prevent the wing portion 110 from being bent or damaged by a strong wind by integrally coupling a plurality of horizontal reinforcing bars 216b horizontally to the surface of the opening and closing port 216 . Of course, in addition to the horizontal reinforcement 216b on the surface of the opening 216, a plurality of vertical reinforcement 216c is further integrally coupled to the surface of the opening 216 to further prevent the wing portion 110 from being bent or damaged by strong wind.

According to this, the motor 210 of the windshield opening/closing means 200 is controlled to rotate forward or reverse by the controller. At this time, when the motor 210 rotates in one direction (for example, clockwise) under the control of the controller, the opening 216 closes the wind exhaust hole 122 of the windshield 120, and the motor 210 rotates in the other direction. When it rotates (for example, counterclockwise), the wind outlet hole 122 of the windshield 120 is opened.

In this case, the controller may be provided on the generator 1 or the pole of the generator. Such a controller may receive power generated by the generator 1 or use a separate driving power source.

On the other hand, a wind speed sensor (not shown) for measuring the wind strength is provided at the top of the hub or the post of the generator, and the controller receives the wind strength from the wind speed sensor in real time and controls the forward or reverse rotation of the motor 210 to control the opening/closing opening. At 216 , the wind exhaust hole 122 of the windshield 120 is opened and closed. At this time, the controller opens the wind exhaust hole 122 of the windshield 120 when the wind strength detected by the wind speed sensor exceeds the set strong wind strength value, and opens the wind exhaust hole 122 of the windshield 120 if it is less than or equal to the set strong wind strength value. (122) can be closed. Of course, the controller can also control the blade 100 to rotate at a constant speed by controlling the open area of the wind exhaust hole 122 of the windshield 120 in proportion to the wind strength detected by the wind speed sensor.

In addition, the controller receives the wind strength information from the control server (not shown) of the remote control center and controls the forward or reverse rotation of the motor 210 to open the opening 216 and the wind exhaust hole of the windshield 120 ( 122) can also be opened and closed. In this case, similarly to the control method by the wind speed sensor, the open area of the wind discharge hole 122 of the windshield 120 can be controlled. Accordingly, when the wind strength obtained by analyzing the wind strength information from the control server of the control center increases, the motor 210 is controlled so that the open area of the wind exhaust hole 122 of the windshield 120 also increases.

Meanwhile, FIG. 10 is a view showing a blade for a wind power generator according to a fourth embodiment of the present invention.

According to this, the windshield 120 may be formed in a shape obtained by cutting a polygonal tube in the longitudinal direction in addition to the semi-cylindrical shape. That is, the windshield unit 120 is formed by continuously bending the metal plate to form a fold line while maintaining a predetermined interval in the vertical direction.

In addition, the opening 216 provided in close contact with the inner surface of the windshield 120 may also have a shape in which a polygonal tube is cut in the longitudinal direction similar to the windshield 120 in addition to the semi-cylindrical shape. That is, the opening 216 is formed by continuously bending the metal plate to form a fold line while maintaining a predetermined interval in the vertical direction.

Meanwhile, FIGS. 11 to 12 are diagrams illustrating a blade for a wind power generator according to the fifth and sixth embodiments of the present invention.

According to this, in the wind power generator 1 of the present invention, the blade 120 supported by the hub 10 provided at the upper end of the post 2 can be manufactured in a vertical shape. In this case, one or more intermediate plate parts 125 may be further provided between the upper and lower closing plate parts 123 and 124 . That is, as shown in FIG. 11 , one intermediate plate part 125 is provided between the upper and lower closing plate parts 123 and 124 , or two intermediate plate parts are provided between the upper and lower closing plate parts 123 and 124 as shown in FIG. 12 . (125) may be provided.

13 and 14 are views illustrating a blade for a wind power generator according to a seventh embodiment of the present invention.

According to this, the windshield opening and closing means 200 for opening and closing the wind exhaust hole 122 formed in the windshield part 120 of the blade 100 has one end on one side of the wind exhaust hole 122 of the inner surface of the windshield part 120 . An opening 216 that is hinged to open and close the wind exhaust hole 122, one end is hinged to one side of the wing unit 110 or one inside the windshield 120, and the other end is hinged to the opening 216 It consists of an electric cylinder 220 to be.

At this time, the opening 216 is provided in close contact with the inner surface of the windshield 120 by bending the metal plate. In particular, one end of the opening 216 is provided rotatably by a hinge 218 at one end adjacent to the wing portion 110 .

And the electric cylinder 220 is composed of a cylinder body 221 and a rod 222, and the rod 222 protrudes forward of the cylinder body 221 or moves backward into the cylinder body 221 according to the control of the controller. will do

In this electric cylinder 220, the rear end of the cylinder body 221 is hinged to one side of the wing unit 110 or one side inside the windshield 120, and the front end of the rod 222 is hinged to the opening 216. . That is, the rear end of the cylinder body 221 is hinged to one side of the wing portion 110 or one side inside the windshield 120 by the first hinge portion 221a, and the front end of the rod 222 is the second hinge portion. It is hinged in the center of the opening 216 by the (222a).

According to this structure, when the rod 222 advances under the control of the controller of the electric cylinder 220, the opening 216 closes the wind exhaust hole 122 on the inner surface of the windshield 120, and the rod 222. When moving backward, the opening 216 may open the wind exhaust hole 122 on the inner surface of the windshield 120 .

On the other hand, Figure 15 is a view for explaining the blade for a wind power generator according to an eighth embodiment of the present invention.

According to this, a horizontal through hole 216a through which the lead screw 212 passes is formed on the surface of the opening 216, and a transfer nut 214 is formed in the opening 216 in the same direction as the horizontal through hole 216a. A guide rail 217 for guiding the horizontal movement is provided on one surface of the opening 216 . At this time, the transfer nut 214 moves horizontally along the guide rail 217. When dust accumulates on the lead screw 212 as well as the horizontal through hole 216a and the guide rail 217, the transfer nut 214 and It is difficult to smoothly move the lead screw 212 . In order to solve this problem, a first brush 2166 is provided on the front surface of the guide rail 217 provided on one surface of the opening/closing opening 216, and the second surface of the opening/closing opening 216 is provided along the horizontal through hole 216a. A brush 2167 is provided.

At this time, the guide rail 217 has the same structure and includes a pair of upper guide rails 217a and lower guide rails 217b.

In addition, the first brush 2166 is formed in a band shape and is formed with a first fixing part 2166a fixed to the upper guide rail 217a, and a lower part of the first fixing part 2166a, and the upper guide rail 217a. ) and a first brush portion 2166a that covers between the lower guide rail 217b.

In addition, the second brush 2167 is formed in a band shape and includes a second fixing part 2167a fixed to the upper side of the horizontal through-hole 216a formed on the other surface of the opening/closing opening 216, and the second fixing part 2167a. ) formed under the second brush portion 2166a to cover the horizontal through-hole 216a.

The first brush 2166 and the second brush 2167 prevent external dust or foreign substances from flowing into the horizontal through-hole 216a and the guide rail 217 as well as the surface of the lead screw 212. It is possible to remove (or wash) foreign substances adhering to the screw thread, so that the transfer nut 214 and the lead screw 212 move smoothly along the horizontal through hole 216a and the guide rail 217 during the opening and closing operation of the opening 216. and thus the opening/closing operation of the opening/closing opening 216 may be smoothly controlled.

Although the embodiment of the present invention has been described in detail as described above, the scope of the present invention is not limited thereto, and the scope of the present invention extends to the scope of substantially equivalent to the embodiment of the present invention.

1: Generator 10: Hub
100: blade 110: wing
112: vent 120: windshield
122: wind exhaust hole 200: windshield opening and closing means
210: first motor 212: first lead screw
214: first transfer nut 216: first opening and closing port
220: electric cylinder 221: cylinder body
222: load

Claims (8)

The wing part 110 made of a plate shape to guide the wind, and one end of the wing part 110 is bent in the direction of one surface of the wing part 110 so that the wind guided to one surface of the wing part 110 is formed. In the blade 100 including the gathering windshield 120,
One or more vent holes 112 through which air passes are formed on the wing portion 110, and the wind exhaust hole 122 is formed on the surface of the windshield 120, and the wind exhaust hole 122. is opened and closed by the windshield opening and closing means 200;
The windshield opening/closing means 200 includes a motor 210 installed on one surface of the wing part 110, and a lead screw that rotates according to the driving of the motor 210 and has an end supported by protruding in the direction of the windshield 120 ( 212), a transfer nut 214 screwed to the lead screw 212, and the transfer nut 214 are supported, but one end of the wind outlet hole 122 of the inner surface of the windshield 120 is on one side. It is hinged and consists of an opening and closing port 216 for opening and closing the wind exhaust hole 122 according to the movement of the transfer nut 214;
A horizontal through hole 216a through which the lead screw 212 passes is formed through the surface of the opening 216, and the transfer nut 214 is formed in the opening 216 in the same direction as the horizontal through hole 216a. A guide rail 217 for guiding horizontal movement is provided on one surface of the opening 216,
A first brush 2166 is provided on the front surface of the guide rail 217 provided on one surface of the opening 216, and the second brush 2167 is provided on the other surface of the opening 216 along the horizontal through hole 216a. A blade for a wind power generator, characterized in that it is provided.
The method of claim 1,
The vent 112 of the wing part 110 is a blade for a wind power generator, characterized in that one or more penetrating rectangular or circular shapes to be biased in the direction of the other end of the wing part 110 .
The method of claim 1,
The guide rail 217 is composed of an upper guide rail 217a and a lower guide rail 217b,
The first brush 2166 is formed in a band shape and is formed with a first fixing part 2166a fixed to the upper guide rail 217a, and a lower part of the first fixing part 2166a, and the upper guide rail 217a. and a first brush portion 2166a that covers between the and the lower guide rail 217b,
The second brush 2167 is formed in a band shape and includes a second fixing part 2167a fixed to the upper side of the horizontal through-hole 216a formed on the other surface of the opening/closing opening 216, and the second fixing part 2167a. A blade for a wind power generator, characterized in that it is formed under the second brush portion (2166a) to cover the horizontal through-hole (216a).
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