KR100534020B1 - Wing Actuating Apparatus Realizing Various Motion of Wings - Google Patents

Abstract

In the present invention, a pair of symmetrical wings, a pair of reciprocating means each placed on a plane parallel to each other and intersected at a predetermined angle, the distal end of the reciprocating means and the axis of each blade It comprises a coupling for connecting, and when the force acts in the front and rear and up and down direction by the reciprocating means to the blade shaft end, the other end of the blade shaft can be rotated in an elliptical shape, the reciprocating The movement means includes a rotation drive source for generating rotational force when power is supplied, a crank shaft connected to the rotation shaft of the rotation drive source, a connecting rod connected to the crank shaft for reciprocating motion, and connected to an end of the connecting rod for reciprocation. Sliding rod for movement, and guide cylinder for guiding the reciprocating direction of the sliding rod constantly Provided is a wing drive device configured as.

According to the present invention, by connecting the movement of the two reciprocating mechanism by a coupling, it is possible to implement a wing drive device of the vehicle that can freely move forward and backward, up and down and stationary flight. In addition, according to the present invention, by forming a wing using a piezoelectric material so that the shape of the wing can be modified in accordance with the desired flight form, it is possible to achieve a great effect on the change of direction of the aircraft and the improvement of the driving force.

Description

Wing Actuating Apparatus Realizing Various Motion of Wings

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a wing drive device that implements a wing of a bird or insect. It relates to a wing drive device for implementing the three degrees of freedom of the blade.

Recently, research on small-scale aircraft commonly referred to as micro air vehicles (MAVs) has been actively conducted. Since such a vehicle may not be caught by a radar if it is made small, the possibility of using it as a spy or a surveillance vehicle as well as a toy is greatly open. The mainstream research on MAVs is to use fixed-wings, as with conventional aircraft, but the smaller wing size reduces the lift that can be made with smaller wings, making the fuselage and other components smaller and lighter. Instead of using fixed wing, research is also being conducted on aircraft that use wings to mimic the flight of insects or birds. In the case of a wing using a wing of a bird or insect, research on a method of obtaining propulsion by inducing flapping of a wing using a mechanism such as gears, belts, and links from vibration or rotational motion generated from the power source of the fuselage is mainly performed. Has been made.

However, the up and down movement of the wing implements only a part of the movement of the wing of an insect or a bird, and the up and down movement alone does not implement free flight like an actual insect or bird fly. That is, only the vertical movement of the wing can not implement the direction change, backward flight or stop flight (hovering).

There is an example in which a tail wing or propeller for changing direction is added together with a wing capable of vertical movement in order to enable the change of direction, but it is not efficient at the change of direction and has a disadvantage of lowering propulsion performance.

Therefore, in order to realize a small flying body that can be freely changed in direction and has a large propulsion force compared to the size, it is necessary for birds or insects to flap, flap, and feather the wings. Similarly, along with a wing drive that can move the wing in three degrees of freedom, there is a need to develop a wing that can be changed to suit the type of flight.

The present invention was developed to solve the above-mentioned conventional problems, and an object of the present invention is to provide a wing drive device that can freely move back and forth, up and down and maintenance flight by implementing the wing of a bird or insect.

The object of the present invention as described above is a pair of symmetrical wings, a pair of reciprocating means each placed on a plane parallel to each other and arranged to cross at a predetermined angle and the distal end of the reciprocating means It comprises a coupling connecting to the axis of the blade, when the force acts in the front and rear direction and the vertical direction to the end of the blade shaft by the reciprocating means, the other end of the blade shaft can be rotated in an elliptical shape The reciprocating means may include a rotary drive source that generates rotational force when power is supplied, a crank shaft connected to the rotary shaft of the rotary drive source, a connecting rod connected to the crank shaft to reciprocate the end, and an end of the connecting rod. A sliding rod connected to and reciprocating, and constantly guiding the reciprocating direction of the sliding rod. It is achieved by providing a vane drive consisting of a guide cylinder.

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Here, the coupling is a rod coupler to which the sliding rod of one of the two reciprocating means is inserted and fixed, a ring joint coupled to an end of the sliding rod of the other of the two reciprocating means, and A ring joint coupler rotatably inserted into the ring joint and the wing shaft inserted into and fixed to the ring joint; an end of the ring joint coupler connected to a side of the rod coupler by a pin joint, and a pin of the pin joint Is positioned in a direction perpendicular to the plane to which the coupling belongs, so that the ring joint coupler is configured to be rotatable relative to the rod coupler about the pin joint axis.

Here, the wing, the wing shaft constituting the skeleton of the wing and connected to the power source; And a piezoelectric actuator coupled to the wing shaft and capable of changing the shape of the wing according to the flight type, and the piezoelectric actuator enables the wing to be deformed in the vertical direction about the wing axis. Do.

Here, the wing, it is preferable to further include a wing cover made of a light material covering the surface of the piezoelectric actuator to insulate the piezoelectric actuator from the outside.

Here, the piezoelectric actuator is in the form of a monomorph having an elastic body having a pair of fixing slots spaced parallel to the wing axis, and an EAP having a predetermined size fixed through the fixing slot on the elastic body and coupled to the elastic body. It is preferable that the electrolytic grease which forms an electrode in the front and back surfaces is applied to the said EAP, and an electrode is formed.

On the other hand, the piezoelectric actuator is formed of a bimorph having an elastic body formed with a pair of fixing slots spaced parallel to the wing axis, and the front and rear surfaces of the elastic body through the fixing slot in the elastic body, The EAP is preferably coated with a conductive grease that forms electrodes on the front and rear surfaces thereof to form electrodes.

Meanwhile, the piezoelectric actuator may include an elastic body in which a plurality of electrode slots are further formed between the pair of fixing slots and the fixing slots spaced parallel to the blade axis, and fixed through the fixing slots. Consists of an EAP of a predetermined size coupled to the elastic body, the EAP is applied to the conductive grease forming the electrode on the front and rear surfaces where the electrode slot is formed, and electrically connected between the conductive grease The conductive grease is further applied in a direction perpendicular to the slot for the electrode to connect, and the EAP surface contacting the elastic body between the electrode slots is preferably made to be attached to the elastic body with an adhesive.

Meanwhile, the piezoelectric actuator may include an elastic body in which a plurality of electrode slots are further formed between the pair of fixing slots and the fixing slots spaced parallel to the blade axis, and the elastic body of the elastic body through the fixing slot. EAP is positioned on the front and rear surfaces, and conductive greases forming electrodes are applied to the EAPs of the front and rear surfaces, respectively, where the electrodes are joined to portions where the electrode slots are formed. The conductive grease is further applied in a direction perpendicular to the slot for the electrode so as to electrically connect, and the EAP surface contacting the elastic body between the electrode slots is preferably made to be attached to the elastic body with an adhesive.

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Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the present invention.

Figures 1a to 1d shows the movement of the blade to be implemented in the aircraft according to the present invention.

As shown in FIG. 1A, when the bird flies forward at full speed, it moves its wings in an ellipse in a direction perpendicular to the direction of travel, and as shown in FIG. 1B, the bird can fly forward at normal speed. Move the wings in an ellipse that is slightly wider than when flying at full speed in the direction perpendicular to the direction of travel (Fig. 1A), and as shown in Fig. 1C, in the horizontal direction when doing Drawing an ellipse and moving the wings, as shown in Figure 1d, during the reverse flight, the body is standing up and moving the wings by drawing an ellipse inclined at an angle to the horizontal direction.

The wing of a bird, as shown in FIGS. 1A-1D, is a three degree of freedom movement of the wing defined by flapping, lagging, and feathering, and the wing itself flying. It turns out that what is deformed according to a form is combined.

Figure 2a is a schematic diagram showing an example of a wing mechanism that can implement the wing of the bird as shown in Figures 1a to 1d, Figure 2b is a perspective view of the drive means for driving the wing drive device according to the present invention 2c is an exploded perspective view of the coupling shown in FIG. 2b.

As shown in FIG. 2A, the wing mechanism 10 that implements the wing includes a pair of wings 11 which are symmetrical to each other, and the shafts 14 of the wings are inserted so that the blades can be moved forward and backward. The front and rear direction guide slots 12 and the shafts of the respective blades are inserted, and the vertical direction guide slots 13 are formed to allow movement in the vertical direction.

When the wing shaft 14 is inserted into the front and rear direction guide slot 12 and the vertical direction guide slot 13, when the force acts in the front and rear direction and the vertical direction at the end of the wing shaft 14, the wing The other end of the shaft can be rotated in an elliptical shape. At this time, by adjusting the force and displacement in the front and rear or up and down direction applied, it is possible to make the wings move while drawing a trajectory such as the trajectory of the wing of the bird or insect as shown in Figure 1a to 1d.

For example, when strokes in the front and rear and up and down directions of the same size are respectively applied to the end of the blade shaft 14 simultaneously in the form of a reciprocating motion, the stroke of the other end of the blade shaft 14 acts. It moves while drawing a circle of a predetermined size in proportion to the size of. By applying this, when the stroke in the vertical direction is increased and the stroke in the left and right directions is relatively small, the other end of the blade shaft 14 moves in a long elliptical trajectory in the vertical direction.

2b shows a drive means for driving a vane drive device according to the invention.

As shown in FIG. 2B, the vane driving device 30 according to the present invention is made by crossing the front and rear direction driving means 30a and the vertical direction driving means 30b, respectively, for reciprocating motion. Preferably, the crossing angle is vertical, but is not limited thereto, and may be disposed while forming an angle other than 90 degrees in order to implement a necessary wing movement. Moreover, it is preferable that the said front-back direction drive means 30a and the up-down direction drive means 30b are arrange | positioned on one plane or the parallel plane, respectively.

The front and rear direction driving means 30a and the vertical direction driving means 30b are connected to rotational drive sources 25 and 25 'such as a motor and an engine, respectively, and rotated by rotational shafts of the rotational drive sources 25 and 25'. Crank shafts 37 and 37 ', connecting rods 38 and 38' connected to the crank shafts 37 and 37 'for converting rotational movements into linear movements, and connecting rods 38 and 38'. Reciprocating motion consisting of sliding rods 39 and 39 'connected to an end for linear reciprocating motion and guide cylinders 33 and 33' for guiding the linear reciprocating motion direction of the sliding rods 39 and 39 'constantly. Means 32, 32 '.

The sliding rods 39, 39 ′ are inserted into the guide cylinders 33, 33 ′, and the sliding rods 39, 39 ′ and the guide cylinders 33, 33 ′ are relative to each other with friction. It is preferable to lubricate the inside of the guide cylinders 33 and 33 'appropriately because of the movement.

As shown in FIGS. 2B and 2C, the drive means and the vane are driven so that the power of the forward and backward drive means 30a and the vertical drive means 30b is transmitted to the vane shaft 14. A coupling 31 is used to connect the shaft 14. The coupling 31 includes a rod coupler 35 having a groove formed so that the sliding rod 39 'of the up and down driving means 30b is inserted and fixed, and the front and rear driving means 30a. Ring joint 34 coupled to the end of the sliding rod 39 of the ring joint is rotatably inserted into the ring joint 34 and the groove is formed so that the blade shaft 14 can be inserted and fixed It consists of a coupler 36. An end of the ring joint coupler 36 is connected to the side of the rod coupler 35 by a pin joint. The pin 29 of the pin joint is located in a direction perpendicular to the plane to which the coupling 31 belongs. The ring joint coupler 36 is configured to be rotatable within a 180 degree range with respect to the rod coupler 35 with respect to the pin joint axis.

Hereinafter, the principle that the power of the front-rear drive means and the vertical drive means is transmitted to the blade shaft when the coupling 31 is used.

The blade shaft 14 is inserted into and fixed to an end of the ring joint coupler 36 in the coupling 31, and the ring joint coupler 36 in the coupling 31 is in the front-rear direction. It is rotatably inserted and fixed to the ring joint 34 coupled to the end of the sliding rod 39 of the drive means 30a. The ring joint 34 is disposed in parallel with the plane in which the front and rear driving means 30a and the vertical driving means 30b are located, and a portion of the ring joint coupler 36 is connected to the ring joint 34. Inserted vertically. The sliding rod 39 'of the vertical driving means 30b is inserted into and fixed to the groove of the rod coupler 35. The rod coupler 35 is fixed between the sliding rod 39 'and the rod coupler 35 in the direction in which the sliding rod 39' is inserted, with the sliding rod 39 'as an axis. Is rotatably coupled.

When the rotary drive source 25 of the front-rear driving means 30a is rotated in the state as described above, the sliding rod 39 is linearly reciprocated in the front-rear direction, and the ring joint 34 The portion of the ring joint coupler 36 and the rod coupler 35 inserted into the pivot joint pivots at a predetermined angle about the sliding rod 39 'of the vertical drive means 30b.

When the rotary drive source 25 'of the vertical drive means 30b rotates, the sliding rod 39' of the vertical drive means 30b linearly reciprocates in the vertical direction, and the vertical drive means The ring coupler 36 fixed to the sliding rod 39 'of the 30b and the rod coupler 35 fixed in the up and down direction reciprocates in the up and down direction, and inserted into the ring joint 34. The portion is limited in movement by the ring joint 34 to pivot a predetermined angle about the axis of the pin joint.

As described above, for example, when the wing is moved in the same manner in the same way up and down and up and down at the same time, the end of the wing is rotated in a circle. In order to implement the forward flight operation as shown in Figure 1a or Figure 1b it can be made to make the elliptical wings by making the stroke of the wings in the vertical direction larger than the stroke of the wings in the front and rear direction.

3A and 3B show perspective views of the wings constituting the wing mechanism according to the present invention.

As shown in Figure 3a and 3b, in the wing mechanism according to the present invention, the wing 11 can be deformed in the vertical direction about the wing axis in accordance with the flight operation, that is, can be feathering (feathering) It is made to The wing 11 is composed of a wing shaft 14 constituting the skeleton of the wing and connected to a power source, and a wing body coupled to the wing shaft 14 and capable of varying in shape depending on the type of flight. The blade body is preferably made of a piezoelectric actuator coupled to the elastic body and the piezoelectric body can reduce the weight of the blade. In addition, the vane cover 17 is made of an elastic material that can insulate the piezoelectric actuator 16 from which a high voltage is applied to the outside and can be deformed by the piezoelectric actuator.

3C is a plan view of the first and second embodiments of the piezoelectric actuators constituting the wing mechanism according to the present invention, and FIGS. 3D to 3F show the first embodiment of the piezoelectric actuators constituting the wing mechanism according to the present invention. Cross-sectional views before and after deformation are shown.

As shown in FIGS. 3C to 3F, the piezoelectric actuator 16 of the first embodiment includes an elastic body 113 having a pair of fixing slots 15 spaced parallel to the wing axis 14, and It is composed of an EAP (Electroactive Polymer) 111 of a predetermined size is fixed through the fixing slot 15 on the elastic body 113 is coupled to the elastic body 113. The EAP 111 is coated with an energizing grease 112 for forming electrodes on the front and rear surfaces thereof. Here, EAP (Electroactive Polymer) refers to a polymer that is lengthened by compressing when a voltage is applied.

As shown in FIG. 3C, three pairs of fixing slots 15 may be provided in the longitudinal direction of the wing, or an appropriate number thereof may be formed, and each pair of fixing slots 15 may be provided. EAP 111 is installed.

In the piezoelectric actuator 16 of the first embodiment, before the EAP 111 is coupled, the elastic body 113 has a permanent deformation such that the surface on which the EAP 111 is coupled is convex, and the EAP 111 is convex. ) Is set in a state in which elastic deformation is caused to concave the surface on which the EAP 111 is installed. In this state, when voltage is applied to the electrode formed by the conductive grease 112, the EAP 111 is expanded so that the piezoelectric actuator 16 is stretched out of the elastically deformed shape. Deformation may occur until the surface on which 111 is installed becomes convex. By having such a configuration, only the piezoelectric actuator in the form of a monomorph is used to enable the feed of the wings.

3G shows a cross-sectional view of the piezoelectric actuator of the second embodiment in which the piezoelectric actuator of the first embodiment is constituted by a bimorph actuator.

As shown in FIG. 3G, the piezoelectric actuator 16 of the second embodiment uses the elastic body (B) through the fixing slot 15 in the elastic body 113 such as the elastic body constituting the piezoelectric actuator 16 of the first embodiment. The EAP 111 is positioned on the front and rear surfaces of the 113.

On both sides of the EAP 111, an energizing grease 112 is applied to both surfaces thereof, and when a voltage is applied to an electrode formed of the energizing grease 112 in the EAP 111 exposed on the front surface of the elastic body 113, the EAP 111 on the front surface. ) Is expanded so that the front surface of the elastic body 113 is convexly deformed. On the contrary, when a voltage is applied to the electrode formed of the conducting grease 112 in the EAP 111 ′ exposed to the rear side of the elastic body 113, the EAP 111 ′ of the rear side is expanded so that the elastic body 113 is convexly deformed. do.

3H shows a plan view of the third and fourth embodiments of the piezoelectric actuator constituting the vane mechanism according to the present invention, and FIGS. 3I to 3K show a third embodiment of the piezoelectric actuator constituting the vane mechanism according to the present invention. Cross-sectional views before and after deformation are shown.

As shown in FIGS. 3H-3K, the piezoelectric actuator 16 of the third embodiment has a plurality of fixing slots 15 and a plurality of fixing slots 15 spaced parallel to the blade axis. Two electrode slots 18 are further formed, and an EAP 111 having a predetermined size fixed through the fixing slot 15 and coupled to the elastic body 113 '. A portion of the EAP 111 joined to a portion where the electrode slot 18 is formed is coated with a conductive grease 112 for forming electrodes on front and rear surfaces, and electrically connected between the conductive greases 112. The conductive grease 112 is further applied in a direction perpendicular to the electrode slot 18 so as to connect. Then, the EAP surface in contact with the elastic body other than the surface in contact with the electrode slot 18 is to be attached to the elastic body 113 with an adhesive.

Even in the piezoelectric actuator of the third embodiment, the elastic body 113 ′ has a permanent deformation such that the surface on which the EAP 111 is coupled is convex before the EAP 111 is coupled, and the EAP 111 is fixed. While engaging the EAP (111) is set in a state causing the elastic deformation so that the surface is installed concave. In this state, when voltage is applied to the electrode formed by the conductive grease 112, the EAP 111 is expanded so that the piezoelectric actuator 16 is stretched out of the elastically deformed shape. Deformation may occur until the surface on which 111 is installed becomes convex. By having such a configuration, only the piezoelectric actuator in the form of a monomorph is used to enable the feed of the wings.

FIG. 3L shows a cross-sectional view of the piezoelectric actuator of the fourth embodiment in which the piezoelectric actuator of the third embodiment is configured in bimorph form.

As shown in FIG. 3L, the piezoelectric actuator 16 of the fourth embodiment is connected to the elastic body through the fixing slot 15 in the elastic body 113 'such as the elastic body constituting the piezoelectric actuator 16 of the third embodiment. The EAP 111 is positioned on the front and rear surfaces of the 113 '.

The EAP 111 is provided with an energizing grease 112 on both sides of the surface in contact with the electrode slot 18, and is formed as an energizing grease 112 in the EAP 111 exposed on the front surface of the elastic body 113 ′. When the voltage is applied to the electrode, the front surface of the EAP 111 is expanded so that the front surface of the elastic body 113 'is convexly deformed. On the contrary, when a voltage is applied to an electrode formed of the conducting grease 12 from the EAP 111 'exposed to the rear surface of the elastic body 113', the EAP 111 'of the rear surface expands to convex the elastic body 113'. To be modified.

Unlike the first and second embodiments, in the third and fourth embodiments, even when the piezoelectric actuator 16 is bent, the elastic body 113 'is not exposed to the elastic body 113' in a bow shape. It becomes able to be attached to).

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As described above, according to the present invention, by connecting the motion of the two reciprocating mechanism by a coupling, it becomes possible to implement a vehicle that can freely move forward, backward, up and down and stationary flight.

In addition, according to the present invention, by forming a wing using a piezoelectric material so that the shape of the wing can be modified in accordance with the desired flight form, it is possible to achieve a great effect on the change of direction of the aircraft and the improvement of the driving force.

Aircraft according to the present invention can be produced to a small size to be used for various functions such as measurement, surveillance and reconnaissance in a narrow area, such as a coal mine jungle.

In the above, certain preferred embodiments of the present invention have been illustrated and described. However, the present invention is not limited to the above-described embodiments, and various modifications can be made by those skilled in the art without departing from the gist of the present invention as claimed in the claims. will be.

1a to 1d show wings of various types of birds;

2A is a schematic representation of a wing mechanism.

2b is a perspective view of a drive means according to the invention;

2C is an exploded perspective view of the coupling shown in FIG. 2B.

Figure 3a is a perspective view of the wing constituting the wing drive device according to the present invention.

3B is an exploded perspective view of the wing shown in FIG. 3A.

3C is a plan view of the first and second embodiments of the piezoelectric actuator shown in FIG. 3B.

3D to 3F are cross-sectional views taken along line C-C in FIG. 3C to illustrate the shape before and after deformation of the piezoelectric actuator.

FIG. 3G is a cross-sectional view taken along the line C-C of FIG. 3C and is a cross-sectional view of a piezoelectric actuator configured in bimorph form. FIG.

FIG. 3H is a plan view of third and fourth embodiments of the piezoelectric actuator shown in FIG. 3B; FIG.

3I to 3K are cross-sectional views taken along the line D-D in FIG. 3H to illustrate the shape before and after deformation of the piezoelectric actuator.

FIG. 3L is a cross-sectional view taken along the line D-D of FIG. 3H, and is a cross-sectional view of the piezoelectric actuator configured in the form of a bimorph.

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<Explanation of symbols for main parts of the drawings>

1: aircraft 10: wing mechanism

10a: left wing mechanism 10b: right wing mechanism

11: wing 12: front and rear direction guide slot

13: up and down direction guide slot 14: wing shaft

15: fixing slot 16: piezo actuator

17: wing cover 18: slot for electrode

19: Grease 31: Coupling

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32: reciprocating means 33: guide cylinder

34: ring joint 35: coupler for rod

36: Coupler for ring joint 37: Crankshaft

38: connecting rod 39: sliding rod

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111, 111 ': EAP 112: energized grease

113, 113 ': elastomer

Claims (19)

A pair of wings symmetrically; A pair of reciprocating means disposed on planes parallel to each other and arranged to cross at a predetermined angle; And A coupling connecting the distal end of the reciprocating means with the axis of each of the vanes, When a force is applied to the blade shaft end by the reciprocating means in the front-back direction and the vertical direction, the other end of the blade shaft can be rotated in an elliptical shape, The reciprocating means, A rotation drive source generating a rotational force when power is supplied; A crank shaft connected to the rotation shaft of the rotation drive source; A connecting rod connected to the crankshaft to reciprocate in an end thereof; A sliding rod connected to an end of the connecting rod to reciprocate; And Blade drive device, characterized in that consisting of a guide cylinder for guiding the reciprocating direction of the sliding rod constantly. delete delete The method of claim 1, wherein the coupling, A rod coupler to which the sliding rod of one of the two reciprocating means is inserted and fixed; A ring joint coupled to an end of the sliding rod of the other of the two reciprocating means; And A ring joint coupler rotatably inserted into the ring joint and the wing shaft inserted into and fixed to the ring joint; an end of the ring joint coupler connected to a side of the rod coupler by a pin joint, and a pin of the pin joint Is located in a direction perpendicular to the plane to which the coupling belongs, so that the ring joint coupler is configured to be rotatable relative to the rod coupler about the pin joint axis. The method of claim 1, wherein the wing, A wing axis that constitutes the skeleton of the wing and is connected to a power source; And It is composed of a piezoelectric actuator coupled to the wing shaft and capable of changing the shape of the wing according to the flight shape, characterized in that the feeder is deformable in the vertical direction about the wing axis by the piezoelectric actuator is enabled Wing drive. The method of claim 5, wherein the wing, And a wing cover made of a light material covering the surface of the piezoelectric actuator to insulate the piezoelectric actuator from the outside. The piezoelectric actuator of claim 5, wherein the piezoelectric actuator is provided with an elastic body having a pair of fixing slots spaced parallel to the wing axis, and an EAP having a predetermined size fixed through the fixing slot on the elastic body and coupled to the elastic body. It is configured in the form of a monomorph, the wing drive device, characterized in that the electrode is applied to the EAP is applied to the conductive grease forming the electrode on the front and rear surfaces. 6. The piezoelectric actuator of claim 5, wherein the piezoelectric actuator has an elastic body having a pair of fixing slots spaced parallel to the blade axis, and an EAP is positioned on the front and rear surfaces of the elastic body through the fixing slot in the elastic body, thereby forming a bimorph. And an electroconductive grease which forms electrodes on the front and rear surfaces thereof, to form the electrodes on the EAP. 6. The piezoelectric actuator of claim 5, wherein the piezoelectric actuator includes a pair of fixing slots spaced parallel to the blade axis and a plurality of electrode slots formed between the fixing slots, and the fixing slots. It consists of an EAP of a predetermined size fixed and coupled to the elastic body, the EAP is applied to the conductive grease to form the electrode on the front and rear surfaces of the junction where the electrode slot is formed, between the conductive grease The conductive grease is further applied in a direction perpendicular to the slot for the electrode so as to electrically connect the electrode, and an EAP surface contacting the elastic body between the electrode slots is made to be attached to the elastic body with an adhesive. 6. The piezoelectric actuator of claim 5, wherein the piezoelectric actuator includes a pair of fixing slots spaced parallel to the blade axis and a plurality of electrode slots formed between the fixing slots, and the fixing slot. EAP is positioned on the front and rear surfaces of the elastic body, and the conductive grease forming the electrodes is applied to the front and rear surfaces of the EAP on the front and rear surfaces, respectively, where the electrode slots are formed. An electrically conductive grease is further applied in a direction perpendicular to the slot for the electrode so as to electrically connect the electrodes, and an EAP surface contacting the elastic body between the electrode slots is made to be attached to the elastic body with an adhesive. Device. delete delete delete delete delete delete delete delete delete