KR200399618Y1 - Apparatus for varying blade length of wind generator - Google Patents

Abstract

The present invention is to control the rotational speed of the blades by adjusting the blade rotation speed is short when the strength of the wind acting the blade length of the wind generator is large, long when the wind power is small, so that the power production capacity of the generator is kept constant, It relates to a wing length automatic control device of the wind power generator to prevent the wings from being damaged, the rotary device unit is installed to be rotatable on the upper end of the support pillar; A rotating shaft supported by the rotating unit; A wing part having a plurality of fixed blade parts fixedly coupled to one end of the rotating shaft and moving wing parts moving along the inner side of each fixed wing part by hydraulic pressure supplied from the outside; A hydraulic generator for supplying hydraulic pressure to the wing; And a power transmission unit for providing the rotational force generated by the wing to the hydraulic generator.

Description

Automatic control device for wind turbine blade length {Apparatus for varying blade length of wind generator}

The present invention relates to an automatic device for adjusting the blade length of a wind turbine. More specifically, the blade length is automatically adjusted according to the wind power to maintain the power productivity of the generator evenly. The present invention relates to an automatic device for adjusting the wing length of a wind turbine to prevent it from being damaged.

The wind power generator is a device that generates the necessary power by using the force of the airflow that is generated and disappears infinitely on the earth, it is provided with a wing that is rotated by lifting force by the wind.

The wind turbine is structurally composed of a wing for converting wind into rotational energy, a support structure for fixedly installing the wing at a constant ground height, and a generator for converting rotational energy generated from the wing into power.

In the wind turbine, the blades must be rotated by generating lift regardless of the strength of the wind, and must have a structure capable of continuously and smoothly rotate without being damaged by strong wind. That is, the blades of the wind turbine should be formed in a large area in order to generate lift even in weak winds, and in small areas in order not to be damaged by strong winds. As such, the wind turbine blades must satisfy both of the two conditions at the same time.

However, since the wings of the conventional wind power generator were initially developed in the form of a surface that is widely extended to receive a lot of wind, there was a problem that the wind is often broken when the wind is castrated.

In addition, if the wing length is made too small to protect the wing of the wind turbine from strong wind, the working area of the wind is reduced, so there is a problem that the power generation efficiency is lowered because it does not generate enough power.

The present invention has been devised in view of the above-mentioned problems, and when the strength of the wind acting on the blade length of the wind power generator is large, the wind power is short and the wind power is adjusted to adjust the rotational speed of the blades so that the power production power of the generator It is an object of the present invention to provide an automatic control of the blade length of the wind power generator to maintain the constant and to prevent the wings from being damaged even in the strong wind.

The present invention for achieving the above object is a rotating device installed to be rotatable on the upper end of the support pillar; A rotating shaft supported by the rotating unit; A wing part having a plurality of fixed blade parts fixedly coupled to one end of the rotating shaft and moving wing parts moving along the inner side of each fixed wing part by hydraulic pressure supplied from the outside; A hydraulic generator for supplying hydraulic pressure to the wing; And a power transmission unit for providing the rotational force generated by the wing to the hydraulic generator.

The fixed blade portion is fixed to the hydraulic cylinder which is operated by the hydraulic pressure supplied from the hydraulic generating portion inside, and the piston rod front end of the hydraulic cylinder is characterized in that the fixed to the moving blade.

The movable blade portion is provided with a driven pulley, one side is fixed to the fixed blade portion, the other side is made of a buffer wire is fixed to the moving blade portion, the buffer wire is supported by the driven pulley It is done.

The moving wing portion is characterized in that the flow prevention plate is provided with a moving hole for supporting the movement of the hydraulic cylinder and the cushioning wire to prevent the flow of the wire and provided to the inside.

The oil pressure generating unit forms a hydraulic supply unit which is connected to the hydraulic supply pipe for supplying hydraulic pressure to each hydraulic cylinder of the wing portion to the front end of the main body for generating the oil pressure by the oil, wherein the hydraulic supply unit is fixedly coupled to the rotating shaft, It is characterized in that the other side is made to be rotatable with the main body.

The rotating shaft is characterized in that the hydraulic supply pipe hole is formed is embedded with the oil supply pipe connected to the hydraulic supply.

The main body of the hydraulic generator is characterized in that it is provided with an oil return opening for returning the oil to the oil tank is opened when the internal pressure is above a predetermined.

A drive gear coupled to the power transmission unit; It is characterized in that it comprises a planetary gear connected to the drive gear for transmitting rotational force to the power generating unit and the hydraulic generating unit, respectively.

It is fixed to the other end of the rotating shaft is characterized in that it further comprises a tail wing for controlling the rotational movement by the wind direction of the wing.

The tail wing portion is characterized in that the triangular plate is formed symmetrically about the rotation axis.

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

1 is a schematic configuration diagram of the automatic wing length adjustment apparatus of the wind power generator according to the present invention, Figure 2 is a detailed configuration diagram of the wing in Figure 1, Figure 3 (a) is a cross-sectional view of the moving wing, ( b) is a plan view of the hydraulic cylinder flow preventing plate in FIG. 2, FIG. 4 is a detailed configuration diagram of the hydraulic generating unit and the power transmission unit in FIG. 1, FIG. 5 is a detailed configuration diagram of the hydraulic generating unit in FIG. 6 is a cross-sectional view taken along the line AA ′ of FIG. 1, and FIG. 7 is a detailed configuration diagram of the tail wing portion in FIG. 1.

The automatic wing length adjustment device of the wind power generator according to the present invention, the support pillar 80 is fixed to the ground and the rotary device portion 70 is installed to be rotatable on the upper end of the support pillar 80, the rotary device Rotating shaft 100 supported by the unit 70, the wing 10 is fixed to the rotary shaft 100 is variable in length depending on the strength of the wind, the oil pressure generating unit for supplying hydraulic pressure to the wing 10 20, the power transmission unit 30 is configured to transmit the rotational force generated by the wing unit 10 to the hydraulic generator 20.

The wing length automatic adjustment device of the wind power generator according to the present invention as described above is to adjust the wing length of the wing unit 10 according to the wind automatically, if the wind is strong so that the wing length is shortened by the wind blade It prevents the part 10 from being damaged, and if the wind power is weak, the wing length is adjusted to be long to widen the working area against the wind so that the wing part 10 receives a large amount of wind to generate more power. do.

The wing 10 is a plurality of fixed wing (10-1) that is fixedly coupled to one end of the rotating shaft 100 and the inside of each of the fixed wing (10-1) by the hydraulic pressure supplied from the outside It is made with a moving wing portion 10-2 to move along, as shown in Figure 3 (a) is formed by protruding one side to prevent the wing portion 10 is damaged by strong wind power have.

The fixed wing portion 10-1 is open at the other end so that the movable wing portion 10-2 is movable in a hollow form in a state where one end is fixed to the rotation shaft 100. The fixed wing portion (10-1) is fixed to the hydraulic cylinder (10-3) that is operated by the hydraulic pressure supplied from the hydraulic generating portion 20 inside, the hydraulic cylinder (10-3) is the hydraulic generation Hydraulic inlet (10-6) for receiving the hydraulic pressure from the unit 20 is formed in the upper end, the lower end of the hydraulic cylinder (10-3) the hydraulic pressure is installed on the lower inner peripheral surface of the fixed wing (10-1) It is fixed and supported by the cylinder support plate (10-14), the upper end of the hydraulic cylinder (10-3) to the hydraulic cylinder flow preventing plate (10-15) is installed on the lower inner peripheral surface of the moving wing (10-2) Thereby supporting the flow.

The hydraulic cylinder flow preventing plate 10-15 is installed on the inner circumferential surface of the wing portion 10 in the same shape as the cross-sectional shape of the wing portion 10, as shown in (b) of Figure 3, the hydraulic cylinder A through hole 45 through which the 10-3 can move and a through hole 46 through which the hydraulic inlet 10-6 is movable are formed, and the through holes 47a and 47b through which the buffer wire 10-8 can penetrate. Will be formed.

The hydraulic inlet 10-6 is connected to the hydraulic generator 20 through the hydraulic supply pipe 10-5, and reference numeral 10-10 denotes a lightning rod.

The hydraulic cylinder (10-3) is provided with a piston rod (10-4) is moved back and forth by the hydraulic pressure supplied through the hydraulic inlet (10-6), the front end of the piston rod (10-4) is It is fixed to the upper end of the moving blade portion 10-2 to reciprocate the moving blade portion 10-2.

The wing section 10 is provided with a buffer wire (10-8), the buffer wire (10-8) is excessively applied force to the moving wing portion 10-2 of the piston rod (10-4). As a function of buffering so as not to occur, one side is fixed to the wire fixture (10-11) of the fixed blade portion (10-1), the other side of the wire fixture (10) of the moving blade (10-2) -12), and is supported by a driven pulley (10-9) that is fixed to the inner circumferential wall surface of the moving blade (10-2).

In addition, the lower end of the hydraulic cylinder (10-3) is provided with an air flow hole (10-7) is free to enter and exit the piston rod 10 by maintaining a stable state of the atmosphere inside the hydraulic cylinder (10-3) -4) can smoothly reciprocate. At this time, an elastic member for connecting the fixed wing portion 10-1 and the moving wing portion 10-2 is mounted on the inner side of the fixed wing portion 10-1. It is preferable that the length of the wing portion 10 including 2) be maximized by the elastic force of the elastic member. In addition, the elastic member allows the one side portion of the hydraulic cylinder 10-3 and the piston rod to be elastically connected to the inside of the hydraulic cylinder 10-3, so that the length of the wing portion 10 as described above is increased. It can be maximized.

On the other hand, the rotating device 70 is coupled to the upper end of the support pillar 80 and the bearing is installed to be able to rotate 360 ° so that the wing 10 can be freely rotated according to the direction of the wind Done. The housing 90 for fixing and supporting the oil tank 60 and the rotary shaft 100, the hydraulic generator 20, the power transmission unit 30, etc., the oil is stored in the upper portion of the rotary device (70). This is installed.

The rotating shaft 100 is coupled to the housing 90 formed on the upper portion of the rotating device 70 through the frame 91. As shown in FIG. 6, the bearing body 94 is formed around the rotating shaft 100. ) Is coupled, and the engaging portion 92 extending from the fixing frame 91 is coupled while surrounding the bearing body 94 so that the rotating shaft 100 is supported by the fixing frame 91 and at the same time the wing portion 10. The rotational force is transmitted to the power transmission unit 30. In addition, the hydraulic supply pipe hole 95 is formed on the outer circumferential surface of the rotating shaft 100 so that the three hydraulic supply pipes 41 are recessed and installed.

As shown in FIG. 5, the hydraulic generator 20 includes a turbine shaft 25 and a turbine 29 fixed to the turbine shaft 25, and are provided by the oil tank 60. It is to provide a predetermined pressure to the oil to be provided to each wing portion 10, the main body 24 for generating the hydraulic pressure and the hydraulic pressure supply pipe connected to each of the wing portion 10 the hydraulic pressure generated in the main body ( 41) is provided with a hydraulic supply unit 23 for providing.

The main body 24 is opened when the oil inlet 27 for receiving oil from the oil tank 60 and the internal pressure exceeds an appropriate level to return the internal oil to the oil tank 60 to adjust the internal pressure. At least one oil return port 21-1, 21-2 is provided. The oil of the oil tank 60 is supplied to the main body 24 through the oil inlet pipe 28, the oil of the main body 24 is returned to the oil tank 60 through the oil return pipe 22. .

The hydraulic supply unit 23 is one side is fixedly coupled to the rotary shaft 100, the other side is coupled through the body 24 and the bearing body 38 of the hydraulic generating unit 20 is the rotary shaft 100 It is possible to rotate simultaneously with the rotational movement of the packing member 49 is provided so that the clearance between the main body 24 and the hydraulic supply unit 23 is kept airtight. The hydraulic supply unit 23 is formed with a plurality of hydraulic outlets 39 for connecting the hydraulic supply pipe 41 connected to each wing 10, the hydraulic supply pipe 41 and the hydraulic outlet 39 is a wing It is formed to correspond to the number of sections 10. In the case of the present invention, assuming that the number of the wing parts 10 is three, three hydraulic supply pipes 41a, 41b, 41c and three hydraulic outlets 39a, 39b, 39c are formed, and the hydraulic supply pipes 41a, 41b , 41c) are also provided with three hydraulic supply holes (95a, 95b, 95c).

The oil tank 60 is fixedly coupled to the rotating device 70, and includes an oil inlet 61 for injecting oil and an oil exchange port 62 for injecting internal oil for oil exchange. Is done.

The power transmission unit 30 is connected to the drive gear 31 and the drive gear 31 fixedly coupled to the rotary shaft 100 and the first planetary gear 32 connected to the power generator unit 40. ), A second planetary gear 33 connected to the drive gear 31, a turbine gear 35 connected to the same axis as the second planetary gear and formed at one end of the turbine shaft 25; And a third planetary gear 34 connected thereto.

The power transmission unit 30 is a hydraulic pressure generating unit for generating a hydraulic pressure for adjusting the length of the wing unit 10 while transmitting the rotational force transmitted through the rotating shaft 100 to the power generation unit 40 ( 20).

The other end of the rotating shaft 100 is fixed to the tail wing 50 is installed so that the wing 10 moves in the direction of the wind blowing. The tail wing 50 is formed symmetrically about the rotating shaft 100 penetrating the center portion is fixedly coupled to the rotating shaft 100 through the coupling portion 53. The tail wing portion 50 is a triangular plate shape, the direction keys 51 and 52 are formed at the rear end so as to perform an accurate operation with respect to the direction of the wind.

Next, the operation of the automatic wing length adjustment device of the wind power generator according to the present invention will be described.

First, the rotary unit 70 is rotatably installed at the upper end of the support pillar 80 fixed to the ground, the oil tank 60 and the housing 90 is installed. The rotating shaft 100 is coupled to the housing 90, one end of the rotating shaft 100 is coupled to the wing 10, and the other end of the tail wing 50 is coupled to the housing 90.

The wing unit 10 is rotated in accordance with the increase and decrease of the rotational force in proportion to the strength of the wind, the rotational force by the wing unit 10 is transmitted to the power transmission unit 30 through the rotation shaft 100, power transmission The unit 30 is to transmit the rotational force to the power generation unit 40.

In addition, the power transmission unit 30 is to transmit the rotational force to the turbine shaft 25 of the hydraulic generating unit 20, according to which the turbine 29 of the hydraulic generating unit 20 is rotated to hydraulic pressure by oil Will be generated. The oil pressure generated by the oil pressure generating unit 20 is supplied to each wing 10 through the hydraulic supply pipe 41, each wing 10 is length by the oil pressure supplied from the oil pressure generating unit 20 Will be adjusted.

On the other hand, when the strength of the wind is increased, the rotational speed of the rotating shaft 100 is increased, the rotational force transmitted to the power transmission unit 30 is increased, the rotational force of the hydraulic generator 20 received the rotational force from the power transmission unit 30 The turbine 29 rotates at a higher speed to generate stronger hydraulic pressure and supplies the hydraulic cylinder 10-3 of each wing 10 through the hydraulic supply pipe 41. By this hydraulic pressure, the moving blade part 10-2 moves to the inside of the fixed blade part 10-1, and from the rear of the fixed blade part 10-1 to the tip of the moving blade part 10-2. The overall length of the wings will be shortened. When the length of the wing portion 10 is shortened, the working area caused by the wind is reduced to reduce the rotational force of the wing portion 10, and the reduced rotational force is transmitted to the power transmission unit 30 as it is.

Subsequently, the power transmission unit 30 performs the operation as described above to transfer the rotational force of the rotary shaft 100 to the hydraulic generator 20, the rotational speed of the turbine 29 is reduced by this weakened rotational force To generate a smaller hydraulic pressure, and the hydraulic pressure acting on the movable wing portion 10-2 of the wing portion 10 is weakened by the hydraulic pressure, so that the movable wing portion 10-2 is fixed blade portion 10. -1) stop moving inward and move outward.

The reciprocating movement of the wing 10-2 of the wing 10 is performed by the centrifugal force due to the rotation of the wing 10 and the oil pressure supplied from the oil pressure generating unit 20. If larger, the moving wing section 10-2 moves outward, and if the hydraulic pressure is greater than the centrifugal force, the moving wing section 10-2 moves inward.

Thus, the automatic wing length adjustment device of the wind power generator according to the present invention will be able to properly adjust the wing length according to the wind strength.

As described above, the automatic control of the wing length of the wind turbine according to the present invention prevents the wings from being damaged by adjusting the length of the wings shortly when the wind strength is strong, and by adjusting the length of the wings long when the wind strength is weak. By expanding the wind's working area, it is possible to produce enough power.

The above-described embodiment is described with respect to the most preferred example of the present invention, the present invention is not limited to the above embodiment, various modifications are possible within the scope without departing from the spirit of the present invention.

The wing length automatic control device of the wind power generator according to the present invention as described above has the effect that the wing length is automatically adjusted according to the wind power so that the wing length is shortened when the wind is castrated.

In addition, the present invention has an effect that can be generated enough power even in the weak wind power by allowing the wing length to be adjusted by the centrifugal force generated as the blade rotates when the wind power is weak.

1 is a schematic configuration diagram of a wing length automatic adjustment device of a wind turbine according to the present invention.

FIG. 2 is a detailed configuration diagram of the wing portion in FIG. 1. FIG.

Figure 3 (a) is a cross-sectional view of the moving wing, (b) is a plan view of the hydraulic cylinder flow preventing plate in FIG.

4 is a detailed configuration diagram of the hydraulic generating unit and the power transmission unit in FIG.

5 is a detailed configuration diagram of the hydraulic generator in FIG. 4.

6 is a cross-sectional view taken along the line AA ′ of FIG. 1.

7 is a detailed configuration diagram of a direction key in FIG. 1;

* Description of the symbols for the main parts of the drawings *

10. Wings 10-1. Fixed wing

10-2.Moving Wing Part 10-3.Hydraulic Cylinder

10-4.Piston rod 10-5.Hydraulic supply line

10-6.Hydraulic inlet 10-7.Air flow hole

10-8.Shock wire 10-9.Following pulley

Lightning rod 10-11, 10-12.

10-13.Hydraulic supply pipe hole 10-14.Hydraulic cylinder support plate

10-15.Hydraulic cylinder flow preventing plate 20.Hydraulic generator

21. Oil return 22. Oil return

23. Hydraulic supply 24. Main body

25.Turbine shaft 26.Frame

27..Oil inlet 28..Oil inlet

30. Power transmission unit

31..Drive Gear 32..First Planetary Gear

33. 2nd planetary gear 34. 3rd planetary gear

35.Turbine Gear 40.Generator

41. Hydraulic feed pipe 50. Tail wing

51, 52. Arrow keys 53. Joint

60..oil tank 61..oil inlet

62..Oil exchange exit 63..Oil return exit

Oil outlet 70. Rotator

71. Bearing 80. Support pillar

90. Housing 91. Fixed frame

92. Coupling part 94. Bearing body

95. Supply pipe hole 100. Shaft

Claims (10)

A rotating device unit rotatably installed at an upper end of the support pillar; A rotating shaft supported by the rotating unit; A wing part having a plurality of fixed blade parts fixedly coupled to one end of the rotating shaft and moving wing parts moving along the inner side of each fixed wing part by hydraulic pressure supplied from the outside; Hydraulic generating unit for generating and supplying hydraulic pressure to the wing; And a power transmission unit for transmitting the rotational force generated by the wing to the hydraulic generator. The method of claim 1, A hydraulic cylinder operating by the hydraulic pressure supplied from the hydraulic generator is fixedly installed on the fixed blade portion of the wing, and the piston rod end portion of the hydraulic cylinder is fixedly installed on the moving blade portion. Automatic wing length adjustment of generator. The method of claim 2, The moving wing portion is provided with a driven pulley, One side is fixed to the fixed blade, the other side is made of a buffer wire is fixed to the moving blade, The buffer wire is automatically adjusted by the wing length of the wind turbine, characterized in that supported by the driven pulley. The method of claim 3, wherein The wing blade automatic adjustment device of the wind regulator is characterized in that the hydraulic cylinder flow preventing plate is provided with a moving hole for providing a moving path while supporting to prevent the flow of the hydraulic cylinder and the buffer wire in the inner side. . The method according to claim 1 or 2, The oil pressure generating unit forms a hydraulic supply unit which is connected to the main body for generating oil pressure by the oil and the hydraulic supply pipe for supplying the hydraulic pressure to each hydraulic cylinder of the wing portion at the front end of the main body, The hydraulic supply unit is one side is fixedly coupled to the rotary shaft, the other side is the automatic wing length adjustment device of the wind turbine, characterized in that the coupling is made to be rotatable with the main body. The method of claim 5, The rotation shaft is automatic adjustment of the wing length of the wind turbine generator, characterized in that the hydraulic supply pipe hole is formed is embedded in the hydraulic supply pipe connected to the hydraulic supply. The method of claim 5, The main body of the hydraulic generator is open when the internal pressure is above a predetermined length of the wind turbine generator, characterized in that it comprises an oil return for returning the oil to the oil tank. The method of claim 1, A drive gear coupled to the power transmission unit; Wing automatic control device of the wind turbine generator characterized in that it comprises a planetary gear connected to the drive gear for transmitting a rotational force to the hydraulic generator. The method of claim 1, It is fixed to the other end of the rotary shaft is the wing length automatic adjustment device of the wind turbine, characterized in that further comprising a tail wing for controlling the rotational movement by the wind direction of the wing. The method of claim 9, The tail wing portion is a triangular plate-shaped wing length automatic adjustment device, characterized in that is formed symmetrically around the rotation axis.