KR20200015020A - Passive type counter-rotating vortex generator - Google Patents

Abstract

The present invention relates to a manual counter-directional rotating type vortex generator which can increase a lift force through a stall. In particular, provided in the present invention is the manual counter-directional rotating type vortex generator which is characterized by comprising: a vortex generator main body unit including a first vortex generator main body and a second vortex generator main body; a first rotating unit and a second rotating unit which generate a rotating force to rotate the first vortex generator main body and the second vortex generator main body; a first horizontal moving unit horizontally moved by the first rotating unit; a second horizontal moving unit horizontally moved by the second rotating unit; a first link rotated by the first horizontal moving unit in order to rotate the first vortex generator main body; and a second link rotated by the second horizontal moving unit in order to rotate the second vortex generator main body in a direction opposite to the rotation direction of the first vortex generator main body.

Description

Passive type counter-rotating vortex generator

The present invention relates to a passive counter-rotating vortex generator, and more particularly to a passive counter-rotating vortex generator that can increase lift through stall delay.

When the blade is in a high angle of attack in the wind or aviation field, delamination occurs on the blade surface.

In order to prevent such peeling phenomenon, a vortex generator is installed on the surface of the blade.

The vortices generated by the vortex generator energize the boundary layer to prevent air particles in the boundary layer from falling off the blades.

However, the conventional vortex generator is fixed to the surface of the blade, there was a disadvantage that the maximum lift is fixed. Recently, many studies have been conducted on vortex generators that increase lift through stall delay.

Korean Patent Registration Publication No. 10-1497342 (Invention name: Vortex generator and wind generator including the same, Date of registration: 2015.03.12)

An object of the present invention is to solve the conventional problems, the present invention is to rotate the first vortex generating member and the second vortex generating member in the opposite direction to each other according to the operating conditions to reduce the yaw angle of each vortex generating member By adjusting simultaneously, it is possible to provide a counter-rotating vortex generator that can increase lift through stall delay even at the same angle of attack.

In order to achieve the above object of the present invention, the passive counter-rotating vortex generator according to the present invention includes a first vortex generator main body and a part of which are disposed outside the airfoil, and part of which is disposed inside the airfoil. A vortex generator body unit comprising a vortex generator body; A first rotating unit disposed on the air foil, the first rotating unit being disposed at a front side of the air foil based on a position at which the vortex generator main body unit is installed and generating a rotational force for rotating the first vortex generator main body by an external force; The second vortex generator main body disposed on the airfoil and disposed at the rear side of the air foil based on the position at which the vortex generator main body unit is installed, in the direction opposite to the rotational direction of the first vortex generator main body by external force. A second rotating unit for generating a rotating force for rotating the; A first horizontal moving unit connected to the first rotating unit and horizontally moving by the first rotating unit; A second horizontal moving unit connected to the second rotating unit and horizontally moving by the second rotating unit; A first link connected to the first horizontal moving unit and the other side connected to the first vortex generator main body to rotate the first vortex generator main body by the movement of the first horizontal moving unit; And one side is connected to the second horizontal moving unit and the other side is connected to the second vortex generator main body to move the second vortex generator in a direction opposite to the rotational direction of the first vortex generator main body by the movement of the second horizontal moving unit. And a second link for rotating the generator body.

In the passive anti-rotational vortex generator according to the present invention, the first rotating unit comprises: a first rotating member screwed to the inner wall of the air foil; And a first rotating shaft coupled to one side of the first rotating member and horizontally moving while being rotated by the rotation of the first rotating member.

In the passive anti-rotational vortex generator according to the present invention, the first horizontal moving unit, the first moving block is provided with a first receiving groove coupled to one side end of the first rotating shaft; A first moving bar coupled to one side of the first moving block and moving horizontally; And a first coupled to the outside of the first moving bar through the first slot formed in the first link and rotating along the first slot by the movement of the first moving bar. It may include a moving projection.

In the passive anti-rotational vortex generator according to the present invention, the first horizontal moving unit, the first bearing block is fixed to the inner wall of the first receiving groove in a state that one side end of the first rotating shaft is coupled; It may further include.

In the passive counter-rotating vortex generator according to the present invention, the first slot is formed to have a predetermined length along the longitudinal direction of the first link.

In the passive counter-rotating vortex generator according to the present invention, the first vortex generator body includes: a first lower body coupled to the first link; A first intermediate body extending from the first lower body and having a cross section larger than a cross section of the first lower body; And a first vortex generating member extending from the first intermediate body and exposed to the outside of the air foil.

In the passive anti-rotational vortex generator according to the present invention, one side of the first link and the first lower body are coupled by a first fastening member.

In the passive anti-rotational vortex generator according to the present invention, in order to transmit the rotational force of the first link to the first lower body, protruding from the outside of the first link, based on the first fastening member Each of the first rotational force transmission pin is formed on both sides and is coupled to the first lower body; may further include.

As described above, the passive anti-rotational vortex generator according to the present invention rotates the first vortex generating member and the second vortex generating member in opposite directions to each other according to the operating conditions, and thus the yaw angle of each vortex generating member. By simultaneously controlling the same, there is an effect that can increase the lift force through the stall delay even at the same angle of attack.

In addition, the passive anti-rotational vortex generator according to the present invention, by transmitting the rotational force of the link to the lower body, there is an effect that can rotate the vortex generator body even if the fastening member is released from the lower body.

1 is a view schematically showing a state in which a passive counter rotating vortex generator is installed in an airfoil according to an embodiment of the present invention.
Figure 2 is a plan view schematically showing a state in which the passive anti-rotational vortex generator is installed on the airfoil according to an embodiment of the present invention.
3 is a plan view schematically illustrating a state in which a passive counter-rotating vortex generator is rotated on an airfoil according to an exemplary embodiment of the present invention.
FIG. 4 is a diagram illustrating the first vortex generator body and the second vortex generator body rotated separately according to an embodiment of the present invention.
5 is a diagram illustrating a state in which the first link and the second link are operated according to an embodiment of the present invention.
6 is a view schematically showing a state in which a passive counter-rotating vortex generator is installed in an airfoil according to another embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention in which the above-described problem to be solved may be specifically realized. In describing the present embodiments, the same name and the same reference numerals are used for the same configuration and additional description thereof will be omitted below.

1 is a view schematically showing a state in which the passive anti-rotational vortex generator is installed in the airfoil according to an embodiment of the present invention, Figure 2 is a passive anti-rotational type in the airfoil according to an embodiment of the present invention 3 is a plan view schematically showing a state in which a vortex generator is installed, and FIG. 3 is a plan view schematically showing a state in which a passive counter-rotating vortex generator is rotated on an airfoil according to an exemplary embodiment of the present invention.

4 is a diagram illustrating a state in which the first vortex generator body and the second vortex generator body are respectively rotated according to an embodiment of the present invention, and FIG. 5 is a first link according to an embodiment of the present invention. And a state in which the second link is operated separately.

4A illustrates a state in which the first vortex generator body is rotated, and FIG. 5B illustrates a state in which the second vortex generator body is rotated.

In addition, FIG. 5A illustrates a state in which the first link is operated, and FIG. 5B illustrates a state in which the second link is operated.

1 to 5, the passive counter-rotating vortex generator according to one embodiment of the present invention is a vortex generator body unit 100, a first rotating unit 200, and a second rotating unit 300. And a first horizontal moving unit 400 and a second horizontal moving unit 500, and a first link 610 and a second link 620.

The vortex generator body unit 100 may be partially disposed outside the air foil 10, and a portion thereof may be disposed inside the air foil 10.

The vortex generator main body unit 100 includes a first vortex generator main body 110 and a second vortex generator main body 120 arranged at a predetermined interval.

The structure of the first vortex generator main body 110 and the structure of the second vortex generator main body 120 are the same.

That is, the vortex generator body unit 100 may be disposed in an ecological manner in which the vortex generator bodies having the same structure are spaced at regular intervals along the longitudinal direction of the air foil 10.

As shown in FIG. 4, the first vortex generator body 110 may include a first lower body 111, a first intermediate body 112, and a first vortex generating member 113.

The first lower body 111 may be coupled to one side end of the first link 610 which will be described later, and may be rotated by the rotation of the first link 610.

The first intermediate body 112 may extend from the first lower body 111 and have a cross section larger than a cross section of the first lower body 111.

The first vortex generating member 113 may be formed to extend from the first intermediate body 112 to be exposed to the outside of the air foil 10.

The first vortex generating member 113 is disposed to have a predetermined angle of attack with respect to the wind moving along the surface of the air foil 10.

On the other hand, the air foil 10 is formed with a first recessed space portion 12 in which the first lower body 111 is accommodated.

In addition, the air foil 10 is recessed to form a second accommodation space 13 in which the first intermediate body 112 is accommodated.

The second vortex generator body 120 may include a second lower body 121, a second intermediate body 122, and a second vortex generating member 123.

The second lower body 121, the second intermediate body 122 and the structure of the second vortex generating member 123 is the first lower body 111 of the first vortex generator body 110, The same structure as that of the first intermediate body 112 and the first vortex generating member 113 will be omitted.

The air foil 10 is recessed to form a third accommodation space 14 in which the second lower body 121 is accommodated.

In addition, the air foil 10 may have a recessed fourth receiving space 15 in which the second intermediate body 122 is accommodated.

2 to 5, the first rotary unit 200 is disposed on the air foil 10, the front of the air foil 10 on the basis of the position where the vortex generator body unit 100 is installed Is placed on the side.

The first rotary unit 200 generates a rotational force for rotating the first vortex generator body 110 by an external force.

The first rotating unit 200 may include a first rotating member 210 and the first rotating shaft 220.

The first rotating member 210 may be screwed to the inner wall of the air foil 10 to generate a rotational force for rotating the vortex generator body unit 100.

An inner wall of the air foil 10 is provided with a first rotating member coupling space portion 16 to which the first rotating member 210 is coupled.

In this case, a first screw thread 211 is formed on the outer circumferential surface of the first rotating member 210 in order to screw the first rotating member 210 to the coupling space portion of the first rotating member 210. It is preferable that a second screw thread 16a corresponding to the first screw thread 211 is formed on the inner circumferential surface of the first rotating member coupling space 16.

On the other hand, one side of the first rotating member 210 may be provided with a wrench groove that can be coupled to a manual rotating device such as a wrench (not shown).

That is, the first rotating member 210 may be operated by the operation of the wrench.

The first rotating shaft 220 is coupled to one side of the first rotating member 210 and is moved in a horizontal direction while rotating by the rotation of the first rotating member 210.

At this time, one side end of the first rotation shaft 220 may be provided with a first rotation shaft coupling projection 221 for coupling with the first receiving groove 411 formed in the first moving block 410 to be described later.

The width of the first rotation shaft coupling protrusion 221 may be larger than the width of the first rotation shaft 220.

That is, when the wrench is rotated by coupling the wrench to the first wrench groove 212, the first rotating member 210 screwed to the first rotating member coupling space 16 is moved while rotating.

As the first rotating member 210 moves while rotating, the first rotating shaft 220 coupled to the first rotating member 210 is horizontally moved while rotating.

The second rotating unit 300 is disposed on the air foil 10, but is disposed on the rear side of the air foil 10 based on the position where the vortex generator body unit 100 is installed.

The second rotary unit 300 generates a rotational force for rotating the second vortex generator body 120 in a direction opposite to the rotational direction of the first vortex generator body 110 by an external force.

The second rotating unit 300 includes a second rotating member 310 and the second rotating shaft 320.

The structure of the second rotating member 310 and the second rotating shaft 320 is the same as the structure of the first rotating member 210 and the structure of the first rotating shaft 210 will not be described in detail.

On the other hand, the inner wall of the air foil 10 is provided with a second rotary member coupling space portion 17 to which the second rotary member 310 is coupled.

In this case, a third screw thread 311 is formed on the outer circumferential surface of the second rotating member 310 to screw the second rotating member 310 to the second rotating member coupling space 17. It is preferable that a fourth screw thread 17a corresponding to the third screw thread 311 is formed on the inner circumferential surface of the second rotating member coupling space 17.

On the other hand, one side of the second rotating member 310 may be provided with a second wrench groove 312 that can be coupled to a manual rotating device such as a wrench.

In addition, a second rotation shaft coupling protrusion 321 for coupling with the second receiving groove 511 of the second moving block 510 to be described later may be provided at one end of the second rotation shaft 320.

That is, when the wrench is coupled to the second wrench groove 312 to rotate the wrench, the second rotation member 310 screwed to the second rotation member coupling space 17 is moved while rotating.

As the second rotating member 310 moves while rotating, the second rotating shaft 320 coupled to the second rotating member 310 is horizontally moved while rotating.

The first horizontal moving unit 400 is disposed on the inner space 11 of the air foil 10.

In this case, the first horizontal moving unit 400 is connected to the first rotating unit 200 to move horizontally by the rotation of the first rotating unit 200 to rotate the first link 610 to be described later.

The first horizontal moving unit 400 may include a first moving block 410, a first moving bar 430, and a first moving protrusion 440.

The first moving block 410 may be provided with a first accommodating groove 411 in which the first rotation shaft coupling protrusion 221 is coupled and accommodated.

Meanwhile, according to the present embodiment, the first horizontal movement unit 400 may further include a first bearing block 420.

The first bearing block 420 is fixed to the inner wall of the first receiving groove 411 in a state in which the first rotation shaft coupling protrusion 221 is coupled.

That is, as the first bearing block 420 is installed on the first accommodating groove 411, the first rotation shaft coupling protrusion 221 is formed on the first accommodating groove 411. 411 may be rotated without interference.

The first moving bar 430 is horizontally coupled to one side of the first moving block 410.

At this time, the thickness of the first moving block 410 is preferably formed larger than the thickness of the first moving bar 430.

That is, the thickness of the first moving block 410 should be formed to have a thickness that can be accommodated on the first receiving shaft 411, the first rotating shaft coupling projection 221.

On the other hand, since the first moving bar 430 only needs to rotate the first link 610, the first moving bar 430 need not be formed as large as the thickness of the first moving block 410.

Therefore, it is preferable that the thickness of the first moving block 410 is greater than the thickness of the first moving bar 430.

In this case, although the first moving block 410 and the first moving bar 430 may be manufactured integrally, the first moving block 410 and the first moving bar 430 may be manufactured separately. The first bolts B1 may be coupled to each other.

When the first moving block 410 and the first moving bar 430 are coupled to each other by the first bolt B1, the strengths of the portions joined to each other may be increased.

The first moving protrusion 440 may be coupled to the outside of the first moving bar 430 by passing through the first slot 611 formed in the first link 610 to be described later.

The first moving protrusion 440 rotates the first link 610 while being moved along the first slot 611 by the movement of the first moving bar 430.

The second horizontal moving unit 500 is disposed on the inner space 11 of the air foil 10.

In this case, the second horizontal moving unit 500 is connected to the second rotating unit 300 to move horizontally by the rotation of the second rotating unit 300 to rotate the second link 620 to be described later.

The second horizontal moving unit 500 may include a second moving block 510, a second moving bar 530, and a second moving protrusion 540.

The structures of the second moving block 510, the second moving bar 530, and the second moving protrusion 540 are the first moving block 410 and the first moving bar 430. And the same as the structure of the first moving protrusion 440, detailed description thereof will be omitted.

The second moving block 510 may be provided with a second receiving groove 511 in which the second rotation shaft 320 and the coupling protrusion 321 are accommodated.

Meanwhile, according to the present embodiment, the second horizontal moving unit 500 may further include a second bearing block 520. At this time, the second bearing block 520 is the same as the structure of the first bearing block 420 described above, and a detailed description thereof will be omitted.

Each of the second moving block 510 and the second moving bar 530 may be manufactured to be coupled to each other by a separate second bolt B2.

The first link 610 is disposed on the inner space 11, and is rotated by the operation of the first horizontal moving unit 400.

One side of the first link 610 is coupled to the first vortex generator body 110, and the other side thereof is connected to the first moving bar 430 via the first moving protrusion 440.

At this time, one side of the first link 610 is coupled to the first lower body 111 through the first fastening member (C1).

Meanwhile, a first slot 611 through which the first moving protrusion 440 is installed may be provided at the other side of the first link 610.

The first slot 611 may be formed to have a predetermined length along the longitudinal direction of the first link 610 so that the first moving protrusion 440 is moved on the first slot 611. .

That is, the first link 440 is moved along the first slot 611 by the movement of the first bar 430 in the state installed through the first slot 611, the first link One side of 610 is rotated.

When one side of the first link 610 is rotated, the first vortex generator body 110 is rotated, and as a result, the first vortex generating member 113 is rotated.

Meanwhile, the upper end portion of the first moving protrusion 440 may be screwed by the first nut N1 in a state where the first moving protrusion 440 penetrates through the first slot 611.

That is, since the first moving protrusion 440 is coupled to the first nut N1, even if vibration occurs in the air foil 10 due to an external impact, the first moving protrusion 440 is the first moving protrusion 440. Departure from the slot 611 can be prevented.

The second link 620 is disposed on the inner space 11, and is rotated by the operation of the second horizontal moving unit 500.

Since the structure of the second link 620 is the same as that of the first link 610, a detailed description thereof will be omitted.

One side of the second link 620 may be coupled to the second vortex generator body 120, and the other side thereof may be connected to the second moving bar 530 via the second moving protrusion 540.

Meanwhile, a second slot 621 through which the second moving protrusion 540 is installed may be provided at the other side of the second link 620.

That is, the second linking protrusion 540 is moved along the second slot 621 by the movement of the second moving bar 530 in the state installed through the second slot 621, the first link. One side of the second link 620 is rotated in a direction opposite to the rotation direction of 610.

When one side of the second link 620 is rotated, the second vortex generator main body 120 is rotated, and as a result, the second vortex generating member (in the opposite direction of rotation of the first vortex generating member 113) 123 is rotated.

Meanwhile, the upper end portion of the second moving protrusion 540 may be screwed by the second nut N2 in a state where the second moving protrusion 540 penetrates through the second slot 621.

Hereinafter, the operation of the passive counter-rotational vortex generator according to an embodiment of the present invention will be described.

First, the operator rotates the first rotating member 210 and the first rotating member 210 at the same time in order to adjust the yaw angle (φ) of each vortex generating member.

At this time, the first rotating member 210 and the second rotating member 310 is rotated through a manual rotating device such as a wrench from the outside.

When the first rotating member 210 is moved while rotating, the first rotating shaft 220 is horizontally moved while rotating.

At the same time, when the second rotating member 310 is moved while rotating, the second rotating shaft 320 is horizontally moved while rotating.

When the first rotating shaft 220 is horizontally moved, the first moving bar 430 together with the first moving block 410 is horizontally moved.

At the same time, when the second rotating shaft 320 is horizontally moved, the second moving bar 530 moves together with the second moving block 510.

When the first moving bar 430 is moved, the first moving protrusion 440 rotates one side of the first link 610 while moving on the first slot 611.

At the same time, when the second moving bar 530 is moved, the second moving protrusion 540 is moved on the second slot 621 while being opposite to the rotation direction of the first link 610. Rotate one side of 620.

 When the first link 610 is rotated, the first vortex generator body 110 is rotated.

At the same time, when the second link 620 is rotated, the second vortex generator main body 120 is rotated opposite to the rotation direction of the first vortex generator main body 110.

As a result, as the first vortex generator main body 110 and the second vortex generator main body 120 rotate in opposite directions, the first vortex generating member 113 and the second vortex generating member 123 are rotated. Is rotated in the opposite direction to each other by adjusting the yaw angle (φ) of each vortex generating member, it is possible to increase the lift through the stall delay even at the same angle of attack.

6 is a view schematically showing a state in which a passive counter-rotating vortex generator is installed in an airfoil according to another embodiment of the present invention. With reference to FIG. 6, a passive counter rotating vortex generator according to another embodiment of the present invention will be described.

Referring to Figure 6, the structure of the passive counter-rotational vortex generator according to another embodiment of the present invention is the same as the structure of the passive counter-rotational vortex generator according to an embodiment of the present invention. However, in another embodiment of the present invention, it is shown that the first rotational force transmission pin 710 and the second rotational force transmission pin 720 are further included.

The first rotational force transmission pin 710 may protrude from the outside of the first link 610.

In this case, the first rotational force transmission pins 710 may be formed on both sides of the first fastening member C1 to be coupled to the first lower body 111.

The first rotational force transmission pin 710 may be coupled to the first lower body 111 by an interference fit method, bonding adhesion, welding, or the like.

That is, the first rotational force transfer pin 710 allows the rotational force of the first link 610 to be transmitted to the first lower body 111.

More specifically, if the rotation of the first link 610 is repeated, the first link coupled to the first link 610 to the first lower body 111 by the rotation of the first link 610. The fastening member C1 can be released.

For this reason, the rotational force of the first link 610 may not be transmitted to the first lower body 111.

At this time, since the first rotational force transmission pin 710 is coupled to the first lower body 111, the rotation of the first link 610 is repeated so that the first fastening member C1 is released. The rotational force of the first link 610 may be transmitted to the first lower body 111.

The second rotation force transmission pin 720 may protrude from the outside of the second link 620.

In this case, the second rotational force transmission pins 710 may be formed on both sides of the second fastening member C2 to be coupled to the second lower body 121.

The structure of the second torque transmission pin 720 is the same as the structure of the first torque transmission pin 710 and a detailed description thereof will be omitted.

As described above, according to another embodiment of the present invention, as each rotation force transfer pin transmits the rotational force of each link to each lower body, the vortex generator body can be rotated even if each fastening member is released from each lower body. do.

While the preferred embodiments of the present invention have been described with reference to the drawings as described above, those skilled in the art will appreciate that the present invention may be modified in various ways without departing from the spirit and scope of the invention as set forth in the claims below. Can be modified or changed.

10: airfoil 11: interior space
12: first accommodating space part 13: second accommodating space part
14: third receiving space 15: fourth receiving space
16: first rotating member engaging space portion 16a: second thread
17: second rotating member coupling space 17a: fourth thread
100: vortex generator body unit 110: the first vortex generator body
111: first lower body 112: first intermediate body
113: first vortex generating member 120: second vortex generator main body
121: second lower body 122: second intermediate body
123: second vortex generating member 200: first rotating unit
210: first rotating member 211: first thread
212: first wrench groove 220: first rotating shaft
221: first rotating shaft coupling protrusion 300: second rotating unit
310: second rotating member 311: third thread
312: second wrench groove 320: second rotating shaft
321: second rotating shaft coupling projection 400: the first horizontal moving unit
410: first moving block 411: first receiving groove
420: first bearing block 430: first moving bar
440: the first moving projection 500: the second horizontal moving unit
510: second moving block 511: second receiving groove
520: second bearing block 530: second moving bar
540: second moving projection 610: first link
611: first slot 620: second link
621: second slot 710: first rotational force transfer pin
720: second torque transmission pin
B1: first bolt B2: second bolt
N1: first nut N2: second nut

Claims (8)

A vortex generator body unit comprising a first vortex generator body and a second vortex generator body, some of which are disposed outside the airfoil, and some of which are disposed inside the airfoil;
A first rotating unit disposed on the air foil, the first rotating unit being disposed at a front side of the air foil based on a position at which the vortex generator body unit is installed, and generating a rotational force for rotating the first vortex generator body by an external force;
The second vortex generator main body disposed on the airfoil and disposed on the rear side of the air foil based on the position at which the vortex generator main body unit is installed, in the direction opposite to the rotational direction of the first vortex generator main body by external force. A second rotating unit for generating a rotating force for rotating the;
A first horizontal moving unit connected to the first rotating unit and horizontally moving by the first rotating unit;
A second horizontal moving unit connected to the second rotating unit and horizontally moving by the second rotating unit;
A first link connected to the first horizontal moving unit and the other side connected to the first vortex generator main body to rotate the first vortex generator main body by the movement of the first horizontal moving unit; And
One side is connected to the second horizontal moving unit and the other side is connected to the second vortex generator main body by the movement of the second horizontal moving unit the second vortex generator in a direction opposite to the rotation direction of the first vortex generator main body And a second link for rotating the main body. The method of claim 1,
The first rotating unit,
A first rotating member screwed to the inner wall of the air foil; And
And a first rotating shaft coupled to one side of the first rotating member and horizontally moving while being rotated by the rotation of the first rotating member. The method of claim 2,
The first horizontal moving unit,
A first moving block provided with a first receiving groove in which one side end of the first rotation shaft is coupled and received;
A first moving bar coupled to one side of the first moving block and moving horizontally; And
A first movement coupled to an outer side of the first moving bar through a first slot formed in the first link, and moving along the first slot by the movement of the first moving bar to rotate the first link; Passive anti-rotational vortex generator characterized in that it comprises a projection. The method of claim 3,
The first horizontal moving unit,
And a first bearing block fixed to an inner wall of the first receiving groove in a state in which one side end of the first rotation shaft is coupled. The method of claim 3,
The first slot,
Passive counter-rotating vortex generator characterized in that it is formed to have a predetermined length along the longitudinal direction of the first link. The method of claim 1,
The first vortex generator body,
A first lower body coupled to the first link;
A first intermediate body extending from the first lower body and having a cross section larger than a cross section of the first lower body; And
And a first vortex generating member extending from the first intermediate body and exposed to the outside of the airfoil. The method of claim 6,
One side of the first link and the first lower body is a passive counter-rotating vortex generator, characterized in that coupled by a first fastening member. The method of claim 7, wherein
In order to transmit the rotational force of the first link to the first lower body, protruding from the outside of the first link, respectively formed on both sides with respect to the first fastening member is coupled to the first lower body Passive anti-rotational vortex generator characterized in that it further comprises; 1 rotation force transmission pin.

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