KR20120027335A - Vertical wind power gernerator - Google Patents

Abstract

The present invention relates to a wind generator, and more particularly to a vertical wind generator that can increase the power generation efficiency by having a structure that the blade can be variable according to the wind speed. Vertical wind generator according to the present invention includes a rotating shaft which is formed perpendicular to the ground and rotates; A vertical blade provided on the rotating shaft and rotating the rotating shaft by wind power, the vertical blade being variable in area according to the wind speed; The rotating shaft is provided at the top vertically, and includes a power generation unit including a generator for generating electrical energy by using the rotation of the rotary shaft, and a rotation transmission means for transmitting the rotation of the rotary shaft to the generator. Accordingly, the vertical wind generator according to the present invention increases the power generation efficiency by widening the blade area in a low speed wind speed environment, and minimizes the blade area in a high speed wind speed environment to prevent mechanical failure of the generator. Have

Description

Vertical wind power gernerator

The present invention relates to a wind generator, and more particularly to a vertical wind generator that can increase the power generation efficiency by having a structure that the blade can be variable according to the wind speed.

The rapid development of the industry and consequently the increased use of fossil fuels is due to the increased cost of limited reserves of fossil fuels in industry and the formation of thick carbon dioxide layers as large amounts of carbon dioxide accumulate in the atmosphere due to the use of fossil fuels in the environment. It is causing global warming.

Accordingly, the need for alternative energy to replace fossil fuels has emerged, and research and development on wind power generators using wind power as the most viable alternative energy is expanding.

A wind generator refers to a generator that generates electricity by applying a blade to the generator rotates by the wind and converts the rotational energy into electrical energy.

These wind generators are divided into a vertical type and a horizontal type. The horizontal type generally refers to a propeller type and is used for large-scale power generation. In contrast, the vertical type refers to a generator having blades on a rotating shaft perpendicular to the ground, and generating electricity while the rotating shaft rotates by the blade, and is used for small-scale power generation. The vertical wind generator may be provided in, for example, a traffic light, a street lamp, and various electric devices provided outside.

On the other hand, the city center has a disadvantage that the wind speed due to the influence of the buildings, unlike the land, significantly lower the power generation efficiency at low speed, and can bring a lot of load on the generator itself due to excessive rotational force at high speed.

That is, at low speeds it is not possible to obtain the rotational force required for power generation, and at high speeds, the generator itself may be damaged because it brings load to the generator due to excessive rotation. Accordingly, the existing wind power generator describes the minimum wind speed for power generation at the time of shipment, and is provided with a braking device that can mechanically protect the generator by not generating power at wind speeds above the standard.

However, the addition of such a braking device increases the size of the generator itself as well as the manufacturing cost also increases, there is a disadvantage that the power generation is not made during the operation of the braking device can not provide the desired power.

In addition, the conventional wind generator used a gear to transmit the rotational force of the blade to the generator. In other words, the main method is to connect the rotating shaft and the generator through the gear. However, when the rotational force is transmitted to the generator through the gear, the mechanical noise generated through the gear is severe.

The present invention has been made to solve this problem, and to provide a vertical wind generator that can increase the power generation efficiency according to the wind speed by varying the area of the blade according to the wind speed.

Furthermore, in the low speed wind speed environment, the blade area is increased to increase the power generation efficiency, and in the high speed wind speed environment, the blade area is minimized to provide a vertical wind generator capable of preventing mechanical failure of the generator.

Furthermore, by forming a rotation transmission means capable of transmitting a rotational movement in the form of a belt instead of a gear, to provide a low noise and high efficiency vertical wind generator.

Vertical wind generator according to an aspect of the present invention described above is a vertical axis and the rotating shaft is rotated; A vertical blade provided on the rotating shaft and rotating the rotating shaft by wind power, the vertical blade being variable in area according to the wind speed; The rotating shaft is provided vertically at the top, and includes a power generator including a generator for generating electrical energy by using the rotation of the rotating shaft, and a rotation transmitting means for transmitting the rotation of the rotating shaft to the generator.

According to a characteristic aspect of the present invention, a vertical blade according to the present invention comprises: a fixed blade having one side fixed to a rotating shaft; A variable blade connected to the other side of the fixed blade by a pin and rotatably connected in one or two directions; It is provided between the fixed blade and the variable blade, characterized in that it comprises an elastic body so that the variable blade is rotated in one or two directions according to the changing wind speed and direction so that the contact area of the wind is variable.

Accordingly, the vertical wind generator according to the present invention has the advantage that the effective wing is made by varying the area of the vertical wing according to the wind speed and the wind direction.

According to a further aspect of the present invention, the vertical wind generator according to the present invention comprises a belt having rotation transmission means for transmitting the rotational force of the rotating shaft rotated by the vertical blade to the generator. Accordingly, it is possible to deliver a low noise as well as accurate rotational force than conventional mechanical transmission.

In addition, when adding a plurality of generators to one rotary shaft can be achieved only by the addition of a belt without the addition of a separate rotation transmission means.

Vertical wind generator according to the present invention has the advantage to increase the power generation efficiency according to the wind speed by varying the area of the blade in accordance with the wind speed.

In addition, the vertical wind generator according to the present invention increases the power generation efficiency by widening the blade area in a low speed wind speed environment, and minimizes the area of the blade in a high speed wind speed environment to prevent mechanical failure of the generator. Have

In addition, the vertical wind generator according to the present invention has the advantage that by reducing the noise, improve the efficiency by forming a belt for rotation transmission means for transmitting a rotational movement instead of a gear.

1 is a perspective view schematically showing a vertical wind generator according to an embodiment of the present invention.
2 is a schematic diagram schematically showing a rotating state of the variable blade of the vertical wind generator according to an embodiment of the present invention.
3 is a schematic diagram schematically showing a rotating state of the variable blade of the vertical wind generator according to an embodiment of the present invention.
Figure 4 is a perspective view schematically showing the inside of the power generation unit of the vertical wind generator according to an embodiment of the present invention.
5 is a perspective view schematically illustrating an interior of a power generation unit of a vertical wind generator according to another embodiment of the present invention.
6 is a perspective view illustrating a variable blade of a vertical wind generator according to another embodiment of the present invention.
7 is a plan view illustrating a variable blade of a vertical wind generator according to another embodiment of the present invention.
Figure 8 is a perspective view showing a variable blade operating structure according to another embodiment of the present invention.
<Explanation of symbols for the main parts of the drawings>
100. Vertical wind generator 110. Rotating shaft
130. Vertical Blade 131. Fixed Blade
133. Variable Blade 135. Elastic Body
137. Pin 139. Retention Guide
150. Power Generation Unit 151. Generator
153. Rotational transmission means, belts 155. Bearings
600. Vertical Wind Generators 610. (Vertical) Blades
611. Top cover 612. Bottom cover
613. Blade body portion 614. Variable blade portion
615. Variable blade connecting means

The foregoing and further aspects of the present invention will become more apparent through the preferred embodiments described with reference to the accompanying drawings. Hereinafter, the present invention will be described in detail to enable those skilled in the art to easily understand and reproduce the present invention.

1 is a perspective view schematically showing a vertical wind generator according to an embodiment of the present invention. As shown, the vertical wind generator 100 according to the present invention includes a rotating shaft 110 is formed perpendicular to the ground and rotates; A vertical blade 130 provided on the rotating shaft 110 and rotating the rotating shaft 110 by wind power, but varying according to the wind speed; The rotary shaft 110 is vertically provided at the top, the power generation including a generator for generating electrical energy using the rotation of the rotary shaft 110, and a rotation transmission means 153 for transmitting the rotation of the rotary shaft 110 to the generator. The unit 150 is included.

The rotating shaft 110 may be implemented as, for example, a rod of circular or polygonal shape, and is vertically coupled to the power generation unit 150 to stand vertically to the ground. At this time, the power generation unit 150 is buried in the ground or fixed to the ground, it can be fixed using a concrete or steel structure. In addition, a bearing 155 is added to a portion where the rotation shaft 110 and the power generation unit 150 are coupled to allow smoother rotation. The rotating shaft 110 is attached to the vertical blade 130 so as to be rotated by the wind on the outside, and transmits the rotational force generated by the blade to the generator provided in the power generation unit 150.

One side of the vertical blade 130 is fixedly coupled to the rotating shaft 110, may be formed vertically in a pair of left and right around the rotating shaft (110). The vertical blade 130 is to rotate the rotating shaft 110 by the wind, the rotating shaft 110 is to rotate as the generator is to generate electrical energy using this rotational force.

According to a characteristic aspect of the present invention, the vertical blade 130 according to the present invention changes the area that is in contact with the wind in accordance with the wind direction and wind speed to increase the area at low speed wind speed to increase the power generation efficiency, the area at high speed wind speed To avoid overloading the generator due to excessive rotation. The vertical blade 130 according to the present invention will be described in more detail with reference to FIGS.

2 and 3 are schematic diagrams schematically showing a rotating state of the variable blade of the vertical wind generator according to an embodiment of the present invention. As shown, the vertical blade 130 according to the present invention includes a fixed blade 131, one side of which is fixed to the rotating shaft 110; A variable blade 133 connected to the other side of the fixed blade 131 by a pin 137 and rotatably connected in one or two directions; It is provided between the fixed blade 131 and the variable blade 133, the variable blade 133 is rotated in one or two directions according to the changing wind speed and direction, including an elastic body 135 so that the contact area of the wind is variable It is composed.

The fixed blade 131 may be formed of a lightweight and high strength material such as, for example, reinforced plastic, and one side of the fixed blade 131 is fixedly attached to the rotating body and fixed by the fixed guide 139. The other side of the fixed blade 131 is connected to the variable blade 133 by pins 137, and the variable blade 133 is oriented from the fixed blade 131 about the pin 137 through the pin 137 connection. Or rotate in both directions.

Like the fixed blade 131, the variable blade 133 may be formed of a light and high strength material such as, for example, reinforced plastic, and is connected through a pin 137 connection. The variable blade 133 is rotated from the fixed blade 131 around the pin 137 according to the wind speed and the wind direction, wherein the variable degree is determined by the elastic force of the elastic body 135 to be described later.

The elastic body 135 may be formed of, for example, a pressure spring, and is provided between the fixed blade 131 and the variable blade 133 and is provided only on one side. The elastic body 135 rotates the variable blade 133 in one direction or in both directions from the fixed blade 131 according to the changing wind speed and direction so that the area where the wind hits is variable.

One side of the elastic body 135 is connected to the fixed blade 131, the other side thereof is connected to the variable blade 133. When the wind having the wind speed within the elastic force of the elastic body 135, the elastic body 135 is stretched by receiving the wind only when the wind direction is in the direction of the vertical blade 130, the variable blade 133 is unfolded, Increase the resistance. Thereafter, after the vertical blade 130 is rotated, the elastic force acts again to reduce the resistance by folding the variable blade 133, thereby facilitating the rotation.

However, when the wind speed is greater than or equal to the reference wind speed, that is, when the resistance of the wind is greater than the elastic force of the elastic body 135, the rotating shaft 110 is rotated more than the reference, thereby overloading the generator. Accordingly, when a wind speed equal to or greater than the elastic force of the elastic body 135 is applied, the variable blade 133 is folded in the opposite direction in which the attractive force of the elastic body 135 acts by the wind force, thereby reducing the area in contact with the wind, thereby reducing the rotational axis 110. ) Also reduces the rotation of the generator to prevent overload of the generator.

Referring to the rotation process of the variable blade 133 described above in more detail, when the wind direction is smaller than the elastic force of the elastic body 135 as shown in Figure 2 when the vertical blade 130 as shown in the rotation direction Rotate In this case, when the variable blade 133 moves to a position in contact with the wind, the variable blade 133 is spread by the resistance of the wind so that the area in contact with the wind is maximized. After the vertical blade 130 is rotated, the elastic force of the elastic body 135 acts again to fold the variable blade 133 as shown, thereby reducing the resistance during rotation, thereby facilitating the rotation. do.

If the wind speed above the reference wind speed, that is, the resistance of the wind is greater than the elastic force of the elastic body 135, as shown above, due to excessive rotation of the rotating shaft 110 may overload the generator. Accordingly, when the variable blade 133 according to the present invention moves to a position in contact with the wind, the variable blade 133 is folded as shown in FIG. 3 in a direction opposite to the folding direction by the restoring force of the elastic body 135. After the variable blade 133 is rotated, the elastic force of the elastic body 135 acts to restore the variable blade 133 in the original folding direction, so that overload of the generator due to excessive wind speed as well as continuous power generation without the braking device is achieved. It is possible.

The power generation unit 150 supports the rotating shaft 110, and the inside is provided with a generator for converting the rotational motion into electrical energy and output, the appearance may be formed in a box shape. The generator may be a generator used in a general wind generator, and receives the rotational force of the rotating shaft 110 to convert the electrical energy, according to the characteristic aspect of the present invention, the rotating shaft 110 and the generator through the belt 153 Is connected to transmit the rotational force of the rotary shaft 110 to the generator.

Figure 4 is a perspective view schematically showing the inside of the power generation unit of the vertical wind generator according to an embodiment of the present invention. As shown, the vertical wind generator 100 according to the present invention is to transmit the rotational force of the rotating shaft 110 to the generator 151 by using a belt 153 rather than the conventional gear.

Thus, when the rotational force is transmitted through the belt 153 formed of rubber or synthetic resin without using a gear, it is possible to minimize the noise due to mechanical friction and also to generate the generator 151 with a small rotational force. It can be driven so that effective development can be achieved.

According to an additional aspect of the present invention, the vertical wind generator 100 according to the present invention may be provided with a plurality of vertical blades 130 coupled to the rotating shaft 110. As shown in FIG. 1, in accordance with an additional aspect of the present invention, a pair of vertical blades 130 may be provided in multiple stages above and below. For example, when two pairs of vertical blades 130 are formed up and down, the pair of vertical blades 130 formed at the top and the pair of vertical blades 130 provided at the bottom are attached to each other at a 90 ° angle to each other. Make effective progress.

According to a further aspect of the present invention, the vertical wind generator 100 according to the present invention includes a plurality of generators 151 to increase the amount of power generated under the same conditions. 5 is a perspective view schematically illustrating an interior of a power generation unit of a vertical wind generator according to another embodiment of the present invention. As shown, the generator 151 may be added to the top, bottom, left and right about the rotation shaft 110 of the vertical wind generator 100 according to the present invention.

6 and 7 are respectively a perspective view and a plan view from above showing a vertical wind generator according to another embodiment of the present invention.

As illustrated in FIGS. 6 and 7, the vertical wind generator 600 may include a pair of blades 610, a rotation shaft 620, and a power generator (not shown).

The pair of blades 610 may be fixed to be spaced apart from each other by 180 ° angle, the top cover 611, the bottom cover 612, the blade body portion 613, the variable blade portion 614 and variable blade connecting means And 615.

The top cover 611 and the bottom cover 612 preferably has a semi-circular shape as shown, but may be manufactured in various forms such as a trapezoidal shape according to the shape of the blade body portion 613. In addition, the upper cover 611 and the lower cover 612 confines the wind into the blade body portion so that the wind pressure can be strongly transmitted to the inner surface of the blade body portion 613 by the wind speed.

The blade body 613 is preferably formed so that the inner surface is concave to confine the wind efficiently, it is preferable that a hole (hole) is formed therein so that the variable blade portion 614 can be coupled. As shown, it is preferable that the variable blade connecting portion is formed at one end of the hole of the blade body 613 so that the variable blade portion 614 can be coupled by the variable blade connecting means 615.

On the other hand, the blade 610 is provided with a rotation speed adjusting means (not shown). If the wind speed is excessively fast beyond a certain speed, the blade rotates at an excessively high speed may reduce the efficiency of wind power. Therefore, even when a strong wind is blown over a certain level, it is preferable that the blade 610 is prevented from rotating above a certain speed by the rotation speed adjusting means so that efficient wind power generation can be achieved.

To this end, the variable blade connecting means 615 preferably includes elastic means. When the wind speed is maintained at a constant speed or less so as not to bring a load on the generator, the variable blade portion 614 completely seals the hole of the blade body portion 613 to allow the blade 610 to rotate efficiently by the wind pressure. do. However, when the wind speed is large enough to bring a load to the generator, a pressure greater than the elastic force of the elastic means is applied by the strong wind pressure, so that the variable blade portion 614 is opened at a predetermined angle as shown in FIG. 6. When the variable blade unit 614 is opened, a portion of the wind passes through the hole formed in the blade body 613 to automatically rotate the rotational speed of the blade 610 so that the rotational speed of the blade 610 does not increase beyond a certain speed. To adjust.

In addition, as shown in FIG. 1, the plurality of blades 610 may be installed in different heights and angles. That is, when n pairs of blades 610 are coupled to the rotation axis, the angle between each pair of blades is preferably formed at (180 / n) ° which is a uniform angle to each other.

In another embodiment, the three blades can be installed in one group by making 120 ° angles to each other as a group. In this case, when installing blade groups including additional three blades in different layers, the angles formed by the blade groups installed in each layer with the blade groups in other adjacent layers are equal to each other (120 / n) °. It is preferable to form.

On the other hand, even when a strong wind of more than 104 km / h (65 mph), it is preferable to set the size of the variable blade portion and the elastic force of the elastic means so that the blade of the conventional structure does not exceed the blade rotation speed when rotating at a wind speed of 104 km / h. . Experimentally, when the conventional blade rotates in a strong wind of 104km / h or more because there is a problem that the generator is overheated and the wind turbine is a problem.

According to another embodiment of the present invention, when the angle between the variable blade portion and the blade body portion is greater than the angle formed when the strong wind of 104 km / h wind blowing, the rotation ratio (or gear ratio) between the rotating shaft and the generator is automatically adjusted. It is possible to further include a rotation ratio adjustment control means for controlling the generator so as not to overheat. To this end, when the rotation speed exceeds the preset reference speed (preferably 104 km / h) by using the rotation speed sensor, the rotation ratio adjustment control means controls to adjust the rotation ratio to prevent the generator from overheating, or the variable blade and the blade. When the angle between the main body portion is greater than the preset angle may be built-in switch is turned on (On) to adjust the rotation ratio.

Figure 8 is a perspective view showing a variable blade operating structure according to another embodiment of the present invention.

The vertical wind generator may further include blade tilt adjusting means.

As shown, when the wind speed exceeds the preset reference wind speed, that is, the reference speed is recognized by the speed sensor or the angle between the variable blade unit and the blade main body (or the variable blade and the fixed blade) is greater than the preset angle. If it becomes large, it is necessary to further reduce the area where the wind touches the blade. At this time, the blade tilt adjusting means may control the rotational speed of the wind generator by changing the inclination of the entire vertical blade in the direction of the arrow to reduce the area where the wind abuts the entire blade. Of course, if the wind speed decreases again, the inclination of the vertical blade can be restored to its original position.

1 to 8, the concave portion of the variable blade is defined as the front of the variable blade and the convex portion of the variable blade is defined as the rear of the variable blade. In addition, when the variable blade is folded inward, it means that the front of the variable blade and the fixed blade or the variable blade portion and the blade body portion is folded in the direction in contact with each other.

The vertical wind generator according to the present invention uses a belt to transmit the rotational force of the rotating shaft to the generator 151. In the case of using the belt, unlike the gear system, the power generation capability can be improved by simply adding the generator 151 and the belt, and the installation also has a simple advantage. In addition, since the noise can be significantly reduced compared to the gear system, even when a plurality of generators 151 are added, there is an advantage of less noise.

Claims (13)

A rotating shaft formed perpendicular to the ground and rotating;
A vertical blade coupled to the rotating shaft and rotating the rotating shaft by wind power, the vertical blade being in contact with the wind according to the wind speed;
And a power generator including a generator for generating electrical energy by using the rotation of the rotary shaft and a rotational force transmitting means for transmitting the rotational force of the rotary shaft to the generator. The method of claim 1 wherein the vertical blade is:
A fixed blade having one side fixed to the rotation shaft;
A variable blade connected to the other side of the fixed blade by a pin and rotatably connected in one or two directions;
And a fixed body provided between the fixed blade and the variable blade, the variable blade being rotated in one direction or two directions according to the changing wind speed and direction, and including an elastic body for varying the area of the wind. The method of claim 2,
The vertical wind generator, characterized in that the rotation transmission means is a belt. The method of claim 2,
The variable blade is configured to expand when the wind direction toward the front of the variable blade, folded inward when the wind direction toward the rear of the variable blade is configured to reduce the resistance,
If the wind speed is greater than the elastic force of the elastic body vertical wind turbine generator characterized in that the variable blade is folded outward to adjust the rotational speed of the rotating shaft by reducing the area that the variable blade is in contact with the wind. The method of claim 4, wherein
At least two pairs of the vertical blades are provided on the rotating shaft, and each vertical blade pair is disposed vertically spaced apart from each other at a uniform angle. The generator of claim 5 wherein the generator is:
Vertical wind generator, characterized in that provided with a plurality around the axis of rotation. The method of claim 1 wherein the vertical blade is:
A blade main body having one side fixed to the rotation shaft and a hole through which wind passes;
A variable blade part which is connected to the blade body part and rotates according to wind speed to open and close a hole formed in the blade body part; And
Vertical wind generator comprising a variable blade connecting means for connecting the blade main body and the variable blade. The method of claim 7, wherein the variable blade connecting means,
Vertical wind generator further comprises a rotation speed adjusting means for adjusting the rotation speed of the rotating shaft so that the generator is not overheated even if the wind speed is high speed. The method of claim 8, wherein the power generation unit,
When the angle between the variable blade portion and the blade body portion is greater than a predetermined angle vertical wind power, characterized in that it further comprises a rotation ratio adjustment control means for controlling the rotation ratio between the rotating shaft and the generator to prevent overheating of the generator generator. The method of claim 9,
The elastic body and the rotational speed control means is a vertical wind generator, characterized in that made of a spring. The method of claim 7, wherein the vertical blades,
The vertical wind generator further comprises a top cover and a bottom cover to confine the wind into the blade body portion. The method of claim 7, wherein
At least two pairs of the vertical blades are provided on the rotating shaft, and each vertical blade pair is disposed vertically spaced apart from each other at a uniform angle. The method according to any one of claims 1 to 12,
Vertical wind generator further comprises a blade inclination adjustment means for adjusting the rotational speed by adjusting the inclination of the vertical blade.

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