KR101331169B1 - Variable horizontal wing for small size wind powered generator and power control method of the same - Google Patents

Abstract

The present invention relates to a small aerogenerator, more specifically, the small aerogenerator having a variable horizontal blade and a method for controlling the output of the same. The small aerogenerator includes the horizontal blade and improves the efficiency of wind power generation by changing an angle of attack of the horizontal blade according to the speed of the blade.

Description

Variable horizontal wing for small size wind powered generator and power control method of the same}

The present invention relates to a small wind power generator, and more particularly, to a small wind power generator having a horizontal blade, the small wind having a variable horizontal blade to increase the wind power efficiency by varying the angle of attack of the horizontal blade according to the speed of the blade The present invention relates to a generator and an output control method thereof.

Wind power generators that generate electrical energy using the power of wind are being researched as an alternative energy source due to the depletion of natural resources such as oil, coal, and natural gas due to the development of industry and population growth.

Wind power generation is a technology to convert kinetic energy of air flow into mechanical energy and then to produce electric energy again. Since it uses natural wind as an energy source, it is eco-friendly without increasing cost. .

As shown in FIG. 1, the conventional wind turbine generator is rotatably installed on the top of a high-rise tower 1 standing on the ground so as to rotate the natsel 2 for supporting the rotor blades 3. 2) Inside the speed increaser, generator and control device (not shown), the rotational force of the rotor blades (3) is configured to reach the generator through the main shaft through the hub (4). On the other hand, the wind vane (5) is disposed on the upper end of the natsel (2) corresponding to the air flow wake. This is to optimally control the entire system and monitor the power generation according to the wind speed. The pitch angle of the rotor blades (3) is adjusted based on the wind direction and wind speed measured by the wind vane (5). The direction is changed to the flow direction to maximize the power generation efficiency.

The wind power generator having the above-described configuration is mainly installed in a large-capacity wind power generation system, which is uneconomical for small-capacity wind power generation systems such as simple waterworks and street lamp systems in homes and mountainous islands.

In order to economically manufacture small wind turbines, they must be manufactured without the additional parts of large capacity wind turbines. However, due to this, the wind turbine is forced to lose part of the wind energy to maintain the wind turbine's durability. As a result, as shown in FIG. 2A, the highest output is obtained at the rated wind speed (14-18 m / s), but there is a problem in that the output is lowered as the wind speed increases than the rated wind speed.

In order to solve the above problems, there has been known a method that can limit the output of the wind power generator by controlling the rotational speed of the blade even if the wind speed increases than the rated wind speed as shown in FIG. 2B using an inverter or the like. However, the method as described above may cause overheating of components due to excessive electronic brakes, and the like may further cause deformation and breakage of components.

Therefore, there is a need for development of a technology for a small wind power generator and its output control method which are excellent in power generation efficiency through stable output control and guarantee durability even when applied for a long time even when a wind speed above a rated wind speed occurs.

The present invention has been made in order to solve the above problems, an object of the present invention, having a horizontal blade in the wind power generator, by varying the angle of incidence of the wind flowing into the wind power generator through the variable angle of attack of the wind turbine It is to provide a small wind power generator having a variable horizontal blade to control the rated output of and its output control method.

Small wind power generator of the present invention, the support is built on the ground, the body is installed on the top of the support and the gearbox and the generator is installed therein, and is installed upstream of the body to rotate in the axial direction of the body A small wind turbine comprising a rotor blade and a tail blade connected to a downstream side of the body, the wind turbine comprising: a horizontal wing installed on the body such that a receiving angle with incoming air is variable; And a control unit for controlling the angle of attack of the horizontal blade; It includes, the body is hinged to the support so that the inclination angle with the ground is variable, the position of the body is variable according to the position of the horizontal blade.

At this time, the body is composed of a wing cell in which the accelerator and the generator is installed, the upstream end is connected to the natsel and the tail wing is installed at the downstream end, the horizontal wing, the tail wing on the wing frame It is installed on the upstream side of the wing frame is coupled so that the longitudinal direction and the slope of the variable.

In addition, the horizontal blade is coupled to the wing frame so as to be rotatable about a variable rotating shaft formed in the longitudinal direction, the variable rotating shaft, spaced apart from the front of the horizontal blade downstream from the front, the rear of the horizontal blade It is characterized in that the predetermined distance spaced upstream side.

In another embodiment, the body is composed of a natsel cell is installed, an increaser and a generator, the upstream end is connected to the natsel and the wing frame is installed at the tail end downstream, the horizontal wing, at least one or more It is installed at the downstream end of the upstream end is hinged to the downstream end of the natsel is coupled to the angle of attack is coupled.

Output control method of the small wind turbine of the present invention, the step of detecting the rotation speed (R1) of the rotor blades; Comparing the rotation speed (R1) and the critical rotation speed (R2) of the rotor blade by a control unit; When the rotor blade rotation speed (R1) exceeds the critical rotation speed (R2), increasing the inclination angle between the body and the ground by rotating the horizontal blade through the control unit; Including, so that the rotor blade rotation speed (R1) is close to the critical rotation speed (R2).

The control method may further include reducing the inclination angle between the body and the ground by rotating the horizontal blades through the control unit when the rotor blade rotation speed R1 is less than or equal to the critical rotation speed R2; Including, so that the rotor blade rotation speed (R1) is close to the critical rotation speed (R2).

In addition, the control method, the rotor blade rotation speed (R1) is less than the critical rotation speed (R2), when the inclination angle of the body and the ground is 0 degrees, the body and the horizontal wing is horizontal; .

The small wind power generator having a variable horizontal blade and its output control method according to the present invention as described above do not apply the configuration of a large-capacity wind power generator because it can be operated while maintaining the maximum output even at high wind speeds or above the rated wind speed. There is an effect that can maximize the power generation efficiency of small wind power generators.

In particular, the wing frame connecting the natsel and the tail wing is always located in a straight line, and the durability is improved compared to the conventional wind power generator that controls the output by varying the tail wing.

1 is a perspective view of a conventional small wind power generator
Figure 2a is a graph showing the relationship between the wind speed and output power of a conventional small wind power generator
Figure 2b is a graph showing the relationship between the wind speed and output power of the small wind power generator of the present invention
3 is a perspective view of a small wind power generator according to the first embodiment of the present invention;
Figure 4a is a front view of a small wind power generator of the first embodiment of the present invention
Figure 4b is a front view when the tail wing of Figure 4a variable
5 is a perspective view of a small wind power generator according to a second embodiment of the present invention;
Figure 6a is a front view of a small wind power generator of the second embodiment of the present invention
Figure 6b is a front view when the tail wing of Figure 6a variable
7 is a flowchart illustrating a method for controlling a small wind power generator according to the present invention.

The present invention relates to a small wind power generator comprising a support, a nacelle, a rotor blade, a wing frame, a tail wing and a horizontal wing. The present invention has been invented to prevent the rotation speed of the rotor blades from rotating above the rated output even if the wind is strongly generated above the rated output. Therefore, the small wind generator of the present invention aims to keep the rotation speed of the rotor blade as close as possible to the output power rotation speed. To this end, the present invention is characterized by adjusting the rotational speed by detecting the rotational speed of the rotor blades by adjusting the inclination with the ground of the natsel according to the rotational speed of the rotor blades to vary the wind inflow area. In order to adjust the inclination of the nacelle, the present invention is coupled to the hinge to freely move on the support so that the inclination between the nacelle and the ground is adjusted, and the inclination of the nacelle is controlled by the control of a horizontal blade installed in the nacelle or the wing frame. In particular, since the present invention controls the natsel through the horizontal wing, by combining the natsel and the wing frame integrally or fixedly in a straight line, there is an advantage that can accurately detect the inflow direction of the wind through the tail wing and introduce the wind. In addition, the problem of durability deterioration due to variable wing frame can be solved.

Hereinafter, an embodiment of the present invention as described above will be described in detail with reference to the accompanying drawings.

Example 1 (Wing frame combined horizontal wing)

3 and 4, the small wind turbine having a variable horizontal wing of the present invention, the support 10, the body 20, the rotor blades 30, the tail wing 40, the horizontal wing 50 and It comprises a control unit 60.

The support 10 includes a support body 11, a horizontal rotation part 12, and a vertical rotation part 13. The support body 11 may be formed in the vertical direction in the vertical direction. The lower end of the support body 11 is fixed to the ground, the horizontal rotating portion 12 may be formed on the upper end. The horizontal rotating part 12 may have an upper surface coupled to the vertical rotating part 13. The horizontal rotating unit 12 serves to rotate the body 20 in a horizontal direction on the ground, that is, the pitch (Pitch) movement relative to the axis perpendicular to the ground. The horizontal rotating part 12 may be configured to freely move the body 20 in a direction in which wind power is introduced by the tail wing 40. The vertical rotation part 13 serves to rotate the body 20 in a direction perpendicular to the ground, that is, roll movement, based on an axis horizontal to the ground. The vertical rotation part 13 may be configured to freely move the body 20 in the roll rotation direction by the horizontal blade 50.

The body 20 is composed of a natsel 21 coupled to the upper end of the support 10, and a wing frame 22 formed at the downstream end of the natsel 21. The natsel 21 is a core configuration of a small wind power generator, and is hinged to the support 10 through a horizontal rotation part 12 so as to pitch movement to optimize the position of the rotor blades 30 according to the direction of the wind. In addition, the hinge is coupled to the support 10 through the vertical rotation part 13 so as to roll in order to optimize the rotation speed of the rotor blades 30 according to the wind strength. The natsel 21 may be coupled to the rotor blade 30 so as to be rotatable on the upstream side of the rotor blade 30 as a rotation axis. Inside the natsel 21 may be provided with a speed increaser and a generator connected to the rotating shaft of the rotor blade 30. The natsel 21 may be configured such that the rotational force of the rotor blade 30 reaches the generator through the rotation shaft. On the downstream side of the natsel 21, the wing frame 22 is integrally formed or coupled. The wing frame 22 is horizontally formed on the ground in a rod shape having a predetermined length, and an upstream side is connected to the natsel 21, and a tail wing 40 may be provided on the downstream side.

The rotor blades 30 may include a rotor 31 connected to the rotation axis of the natsel 21 and a blade 32 connected radially about the rotor 31. Two or more blades 32 may be coupled to the rotor 31. Although three blades 32 are shown in the drawings, the number is not limited to three, and the number may vary depending on the capacity and use of the generator. The rotor blade 30 is a rotor blade which is typically used for a small wind power generator, so a detailed description thereof will be omitted.

Tail wing 40 may be installed upstream, downward or above and below the downstream side of the wing frame 21 perpendicular to the ground. Tail wing 40 may be installed to pitch rotate the position of the natsel 21 in the wind blowing direction.

The horizontal blade 50 is installed on the wing frame 22 so that the direction horizontal to the ground is the basic position. The horizontal wing 50 is installed on the wing frame 21 so that the inclination with the longitudinal direction of the wing frame 22 is variable. A pair of horizontal wings 50 are respectively installed on both sides of the wing frame 22, it may be installed a predetermined distance apart in the upstream side of the tail wing (40).

The horizontal blade 50 serves to roll the sickle 21 so that it can be maintained in a straight line in the air flow direction. Therefore, when the inclination of the horizontal blade 50 and the ground is variable, the horizontal blade 50 is rotated by the natsel 21 so as to match the flow direction of the air, the inclination of the ground and the sickle 21 is variable.

At this time, the horizontal blade 50 is coupled to the wing frame 22 to be rotatable around the variable rotation shaft 51 is formed in the longitudinal direction perpendicular to the wing frame 22. The variable rotation shaft 51 may be disposed at the center of the direction parallel to the wing frame 22 of the horizontal blade 50. That is, the front wing of the horizontal wing 50 may be spaced apart by a predetermined distance to the downstream side, and the rear wing of the horizontal wing 50 may be spaced apart by a predetermined distance. Through the above configuration, the load is distributed to prevent the horizontal wing 50 from being damaged even in strong wind.

4A is a front view showing the position of the horizontal blade 50 at the time when the rotor blade 30 rotates below the rated output, that is, normally. The horizontal wing 50 is maintained in parallel with the wing frame 22, accordingly, the natsel 21 is also located in parallel to the air inflow direction. Therefore, the air inflow area D1 is maximized so that the rotational force of the rotor blade 30 is maximized.

4B is a front view showing the position of the blade 50 when the rotor blade 30 rotates above the rated output, that is, when strong wind is generated. The horizontal blade 50 is rotated in a counterclockwise direction when viewed in the drawings inclined at a predetermined angle with the wing frame 22, the horizontal blade 50 is positioned in a straight line in the air flow direction by the wind force (21) Rotate the roll. The inlet area D2 is reduced by the nacelle 21 roll-rotated at an angle to the air flow direction, and the rotational force of the rotor blade 30 is reduced to induce the rotor blade 30 to rotate at the rated output. Done.

The controller 60 may be provided on the outer circumferential surface of the support 10. The controller 60 detects the rotation of the rotor blade 30 and controls the roll rotation of the horizontal blade 50 according to the wind speed. Although the control unit 60 is shown to be provided in the support 10, it is obvious that the installation can be installed anywhere on the wind turbine not limited to the operation of the control unit 60.

Example 2 (natcell combined horizontal wing)

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

5 and 6, the small wind turbine having a variable horizontal wing of the present invention is a support 10, the body 20, the rotor blades 30, the tail wing 40, the horizontal wing 500 and It comprises a control unit 60.

The support 10 includes a support body 11, a horizontal rotation part 12, and a vertical rotation part 13. The support body 11 may be formed in the vertical direction in the vertical direction. The lower end of the support body 11 is fixed to the ground, the horizontal rotating portion 12 may be formed on the upper end. The horizontal rotating part 12 may have an upper surface coupled to the vertical rotating part 13. The horizontal rotating unit 12 serves to rotate the body 20 in a horizontal direction on the ground, that is, the pitch (Pitch) movement relative to the axis perpendicular to the ground. The horizontal rotating part 12 may be configured to freely move the body 20 in a direction in which wind power is introduced by the tail wing 40. The vertical rotation part 13 serves to rotate the body 20 in a direction perpendicular to the ground, that is, roll movement, based on an axis horizontal to the ground. The vertical rotation part 13 may be configured to freely move the body 20 in the roll rotation direction by the horizontal blade 50.

The body 20 is composed of a natsel 21 coupled to the upper end of the support 10, and a wing frame 22 formed at the downstream end of the natsel 21. The natsel 21 is a core configuration of a small wind power generator, and is hinged to the support 10 through a horizontal rotation part 12 so as to pitch movement to optimize the position of the rotor blades 30 according to the direction of the wind. In addition, the hinge is coupled to the support 10 through the vertical rotation part 13 so as to roll in order to optimize the rotation speed of the rotor blades 30 according to the wind strength. The natsel 21 may be coupled to the rotor blade 30 so as to be rotatable on the upstream side of the rotor blade 30 as a rotation axis. Inside the natsel 21 may be provided with a speed increaser and a generator connected to the rotating shaft of the rotor blade 30. The natsel 21 may be configured such that the rotational force of the rotor blade 30 reaches the generator through the rotation shaft. On the downstream side of the natsel 21, the wing frame 22 is integrally formed or coupled. The wing frame 22 is horizontally formed on the ground in a rod shape having a predetermined length, and an upstream side is connected to the natsel 21, and a tail wing 40 may be provided on the downstream side.

The rotor blades 30 may include a rotor 31 connected to the rotation axis of the natsel 21 and a blade 32 connected radially about the rotor 31. Two or more blades 32 may be coupled to the rotor 31. Although three blades 32 are shown in the drawings, the number is not limited to three, and the number may vary depending on the capacity and use of the generator. The rotor blade 30 is a rotor blade which is typically used for a small wind power generator, so a detailed description thereof will be omitted.

Tail wing 40 may be installed upstream, downward or above and below the downstream side of the wing frame 21 perpendicular to the ground. Tail wing 40 may be installed to pitch rotate the position of the natsel 21 in the wind blowing direction.

The horizontal blade 500 is installed at the downstream end of the natsel 21 so that the direction horizontal to the ground is the basic position. The horizontal blade 500 is installed in the natsel 21 so that the inclination with the longitudinal direction of the wing frame 22 is variable. The horizontal blade 500 may be installed on both sides of the downstream surface of the natsel 21 with a pair of wings frame 22 therebetween.

The horizontal blade 500 serves to roll the sickle 21 so that it can be maintained in a straight line in the air flow direction. Therefore, when the inclination of the horizontal blade 500 and the ground is variable, the horizontal blade 500 is rotated by the natsel 21 to match the flow direction of the air is the slope of the ground and the sickle 21 is variable.

At this time, the horizontal blade 500 is coupled to the natsel 21 so as to be rotatable about the variable rotation shaft 510 is formed to be horizontal to the ground and perpendicular to the longitudinal direction of the natsel 21. The variable rotation shaft 510 is formed on an upstream side of the horizontal wing 500, and may be imparted on a downstream side of the natsel 21. Since the horizontal blade 500 is installed in the natsel 21, there is an advantage that the control of the natsel 21 can be changed more quickly and reliably.

FIG. 6A is a front view showing the position of the horizontal blade 500 at the time when the rotor blade 30 rotates below the rated output, that is, normally. The horizontal blade 500 is kept parallel to the wing frame 22, accordingly, the natsel 21 is also located in parallel to the air inflow direction. Therefore, the air inflow area D1 is maximized so that the rotational force of the rotor blade 30 is maximized.

FIG. 6B is a front view showing the position of the blade 500 when the rotor blade 30 rotates above the rated output, that is, when strong wind is generated. The horizontal blade 500 is rotated in a counterclockwise direction when viewed in the drawing inclined at a predetermined angle with the wing frame 22, the horizontal blade 50 is positioned in a straight line in the air flow direction by the wind power (21) Rotate the roll. The inlet area D2 is reduced by the nacelle 21 roll-rotated at an angle to the air flow direction, and the rotational force of the rotor blade 30 is reduced to induce the rotor blade 30 to rotate at the rated output. Done.

The controller 60 may be provided on the outer circumferential surface of the support 10. The controller 60 detects the rotation of the rotor blade 30 and controls the roll rotation of the horizontal blade 500 according to the wind speed. Although the control unit 60 is shown to be provided in the support 10, it is obvious that the installation can be installed anywhere on the wind turbine not limited to the operation of the control unit 60.

Hereinafter, a variable tail wing control method for a small wind turbine according to the present invention configured as described above will be described with reference to the accompanying drawings.

7 is a flowchart illustrating a method for controlling a small wind power generator according to the present invention.

First, after power is supplied, the controller 60 detects the rotational speed R1 of the generator through the output voltage and frequency of the wind power generator, and detects the position TP of the horizontal wings 50 and 500. Proceed with the first step (S1). Here, the rotation speed (R1) means the revolutions per minute of the rotor blades 30, the position (TP) of the horizontal wings (50, 500) is the longitudinal axis of the wing frame 22, the horizontal wings (50, 500) It can be represented by the longitudinal inclination (θ) of the wing frame 22 of. In addition, the initial position of the horizontal wings (50, 500) means that the horizontal side (50, 500) is in a straight line with the longitudinal axis of the wing frame 22, the side inclination (θ) is 180 degrees. In addition, the roll rotation of the horizontal blades (50, 500) by the control unit 60, the inclination (θ) formed by the longitudinal axis of the wing frame 22, the horizontal blades (50, 500) 1 ~ 1 operation 10 degrees can be defined as increasing or decreasing.

As a result of the detection of the first step S1, the second step S2 of comparing whether the rotation speed R1 is higher than the set rotation speed R2 is performed.

The reason why the set speed R2 is not defined by the numerical value is that the optimized speed R2 is different according to the capacity and configuration of the wind power generator. Therefore, the set rotation speed R2 may be defined according to the intention of those skilled in the art.

As a result of the comparison of the second step (S2), if the rotor blade (30) rotation speed (R1) is greater than the set rotation speed (R2) the horizontal blades (50, 500) by rolling the roll and the longitudinal axis of the wing frame 22 The third step S3 of rotating the horizontal blades 50 and 500 is rolled so that the inclination θ formed by the horizontal blades 50 and 500 can be reduced by 1 to 10 degrees.

That is, when the rotor blades 30 rotational speed R1 is greater than the set rotational speed R2, the load on the rotor blades 30 increases and the output decreases, thereby varying the horizontal blades 50 and 500 so that the sickle 20 can be used. To move the position of the rotor blades 30 to reduce the area receiving wind energy to adjust the rotation speed.

When the rotor blade 30 has a rotational speed R1 smaller than the set rotational speed R2, the position 60 of the horizontal blades 50 and 500 is controlled by the controller 60 to be the initial position, that is, the horizontal blades 50 and 500. And the fourth step S4 of determining whether the inclination θ formed by the longitudinal axis of the wing frame 22 is 180 degrees.

As a result of the comparison in the fourth step S4, when the tilt θ is not 180 degrees, the horizontal wings 50 and 500 are roll-rotated to form the longitudinal axes of the wing frames 22 and the horizontal wings 50 and 500. The fifth step S5 of rotating the horizontal blades 50 and 500 is rolled so that the inclination θ may increase by 1 to 10 degrees.

That is, when the rotation speed R1 of the rotor blade 30 is smaller than the set rotation speed R2, the inclination θ formed between the longitudinal axis of the wing frame 22 and the horizontal wings 50 and 500 is increased, but the horizontal If wings 50 and 500 reach their initial position, further rotation is limited.

The technical idea should not be construed as being limited to the above-described embodiment of the present invention. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. Accordingly, such modifications and changes are within the scope of protection of the present invention as long as it is obvious to those skilled in the art.

10: support 11: support body
12: horizontal rotating part 13: vertical rotating part
20: body 21: natsel
22: wing frame
30: rotor blade 31: rotor
32: Blade
40: tail wing
50, 500: horizontal wing 51, 510: variable rotation shaft

Claims (7)

A support standing on the ground, a body installed at an upper end of the support, on which an increaser and a generator are installed, a rotor blade installed on an upstream side of the body to rotate in an axial direction of the body, and a downstream of the body. In the small wind turbine comprising a tail wing connected to the side,
Horizontal wings installed on the body so that the angle of attack with the incoming air is variable; And
Control unit for controlling the angle of attack of the horizontal blade; Including;
The body is hinged to the support so that the inclination angle with the ground is variable, the position of the body is variable according to the position of the horizontal blade, a small wind turbine having a variable horizontal wing.
The method of claim 1,
The body,
It consists of a natsel cell in which a speed reducer and a generator are installed, and an upstream end is connected to the natcell and a wing frame is installed at the tail end at a downstream end thereof.
The horizontal wing is installed on the upstream side of the tail wing on the wing frame, the small wind turbine having a variable horizontal wing, coupled so that the longitudinal direction and the inclination of the wing frame is variable.
The method of claim 2,
The horizontal wing,
Is coupled to the wing frame to be rotatable about a variable rotating shaft formed in the longitudinal direction,
The variable rotation shaft is spaced apart by a predetermined distance to the downstream side in front of the horizontal blade, a small wind turbine having a variable horizontal blade, characterized in that the predetermined distance spaced from the rear side of the horizontal blade.
The method of claim 1,
The body,
It consists of a natsel cell in which a speed reducer and a generator are installed, and an upstream end is connected to the natcell and a wing frame is installed at the tail end at a downstream end thereof.
The horizontal wing, at least one or more installed in the downstream end of the Naksel, the upstream end is hinged to the downstream end of the Naksel is coupled to the variable angle of attack, a small wind turbine having a variable horizontal wing.
Detecting the rotation speed R1 of the rotor blades;
Comparing the rotation speed (R1) and the critical rotation speed (R2) of the rotor blade by a control unit;
When the rotor blade rotation speed (R1) exceeds the critical rotation speed (R2), increasing the inclination angle between the body and the ground by rotating the horizontal blade through the control unit; Including,
A control method for a small wind turbine with a variable horizontal blade, wherein the rotor blade rotation speed (R1) is close to the critical rotation speed (R2).
6. The method of claim 5,
In the control method,
Reducing the inclination angle of the body and the ground by rotating the horizontal blades through the control unit when the rotor blade rotation speed R1 is less than or equal to the critical rotation speed R2; Including,
A control method for a small wind turbine with a variable horizontal blade, wherein the rotor blade rotation speed (R1) is close to the critical rotation speed (R2).
6. The method of claim 5,
In the control method,
When the rotor blade rotation speed (R1) is less than or equal to the critical rotation speed (R2) and the inclination angle between the body and the ground is 0 degrees, the body and the horizontal wing forming a level; Including, a small wind turbine control method having a variable horizontal wing.

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