KR20100131903A - Wind-acceleration type wind power generator - Google Patents

Abstract

PURPOSE: An acceleration type wind power generator is provided to implement enough generation even with a compact size by inducing and accelerating wind. CONSTITUTION: An acceleration type wind power generator comprises a frame(100), a fan(110), a plurality of wind blocking plates(120~150), a generator, and a rotary power unit. The frame is formed in the shape of a three or more angled column with four sides open. The fan is rotated around a rotary shaft in the center of the frame. The wind blocking plates rotate with a shaft installed in each corner of the frame in order to selectively open or close the open portions of the frame. The generator is connected to the rotary shaft of the fan and generates power according to the rotation of the fan. The rotary power unit rotates the wind blocking plates around a shaft.

Description

Wind-acceleration type wind power generator

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a wind power generator, which is installed on a rooftop of an apartment or a building, and generates power by wind. It relates to a wind generator.

As alternative energy sources, various natural energies such as solar, wind, hydro, tidal, etc. are being developed. Wind power generation is a typical example, which is generated by installing a fan on a high tower where wind is generated. Most of the time,

These wind power plants usually generate a large amount of power, which requires a huge amount of equipment and a large amount of investment.

In order to solve this problem, the present invention provides a miniaturized wind generator that can be installed on the roof of a building, while inducing and accelerating wind to accelerate the wind power generation to be sufficient in the miniaturized wind generator by the accelerated wind. The purpose is to provide a type wind generator.

Accelerated wind generator according to a first embodiment of the present invention for achieving the above object.

A frame having an open side and at least triangular pillars;

A fan rotatably mounted about an axis of rotation in an inner central portion of the frame;

A plurality of windshields formed in a plate shape and rotatably mounted by shafts mounted on respective inner corner portions of the frame to selectively open or close the opened portions of the frame;

A generator connected to the rotation shaft of the fan to generate power according to the rotation of the fan;

Rotation power unit for rotating the windshield around the axis;

Wind vane for detecting the direction of the wind;

And a controller for controlling the rotation of each windshield by controlling the rotational power unit based on the data on the wind direction input from the wind vane.

According to the present invention configured as described above, the amount of power generated is increased by driving a fan by accelerating a small wind. In addition, the present invention can be miniaturized and installed on a roof of a building, thereby generating power at low cost.

The present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view of an accelerated wind generator according to a first embodiment of the present invention, Figure 2 is a side cross-sectional view, Figure 3 is a view for explaining the operation process.

As shown in FIG. 1, the first embodiment of the present invention selectively opens or closes the frame 100 having side openings, the fan 110 rotating by wind, and the opened portion of the frame 100. It consists of a windshield (120, 130, 140, 150) to.

Frame 100 is a rectangular pillar shape, the sides of the four sides are opened, the upper side is covered by a roof cover, the roof cover (not shown) is omitted to show the structure inside the frame.

In addition, the frame 100 may have a shape such as a triangular or hexagonal pillar as well as a square pillar.

Such a roof cover may be in the form of a plate that simply covers the upper side of the frame.

The fan 110 is mounted on the inner center portion of the frame 100, and a plurality of windshields 120, 130, 140, and 150 are mounted on the opened portion of the frame 100 so as to rotate about an axis.

More specifically, the shaft 121 of the first windshield 120 is vertically mounted in one corner of the frame 100 so as to be rotatably mounted, and opens or closes about half of the opened portion by the rotation. Will be closed.

At this time, the fan 110 and the windshield 120, 130, 140, 150 should be installed so as not to interfere with each other.

The size of the first windshield 120 is preferably sized to block the opened portion of the frame 100 by about half, so that the other half of the windshield 130, 150 mounted on the neighboring corners is opened or closed. do.

This configuration is equally applied to the second windshield 130, the third windshield 140, and the fourth windshield 150 to selectively open or close the opened portion of the frame 100.

As the reduction gear 122 and the first motor 123 to the lower structure 160 for supporting the frame 100 in the lower portion of the frame 100 to rotate the first windshield 120 as shown in FIG. The configured rotational power unit is installed, the reduction gear 122 is mounted on the lower end of the shaft 121, the reduction gear 122 transmits the power generated from the first motor 123 to the shaft 121 and the first The windshield 120 is to rotate.

Of course, the second windshield 130 is also installed to be rotated by the reduction gear 132 and the second motor 133, and the rotational power unit of the third windshield 140 and the fourth windshield 150 are also Have the same configuration.

In addition, the generator 170 is connected to the rotating shaft 111 of the fan 110 in the lower structure 160 is configured to generate power by the rotation of the fan 110.

On the other hand, the rotation direction and angle of the windshield 120, 130, 140, 150 is controlled by receiving the data on the wind direction detected from the wind vane 180 is installed separately from the controller 181, this embodiment of the present invention The operation will be described with reference to FIGS. 3 and 4.

When the wind blows from the rear as shown in FIG. 3 (a), the controller 181 outputs a control signal to the motor driver 182 so as to be inclined to the edge portion of the fan 110 of the first windshield 120. The first motor 123 is driven, and the remaining windshields 130, 140, and 150 output a control signal to be parallel to the direction of the wind to drive the second motor 133, the third motor 143, and the fourth motor 153. .

Accordingly, the wind blowing from the rear is guided to the edge of the fan 110 by the first windshield 120 and the passage is formed by the remaining windshields 130, 140, and 150, thereby accelerating the introduced wind. Quickly rotate the rotation.

Similarly, when the wind blows from the left side as shown in FIG. 3 (b), the fourth windshield 150 guides the wind to the edge of the fan 110, and as shown in FIG. In case of blowing, the third windscreen 140 guides the wind, and when the wind blows from the right direction as shown in FIG. 3 (d), the second windscreen 130 is driven to guide the wind.

As a result, the wind is guided by the driven windshield to the edge of the fan 110, the remaining windshield is driven to be arranged in line with the wind of the wind to form an acceleration passage of the wind.

In other words, it narrows the passageway through which the wind flows and induces the wind at an angle so as to have a nozzle shape.

5 is a perspective view of an accelerated wind generator according to a second embodiment of the present invention, Figure 6 is a side cross-sectional view, Figure 7 is a simplified plan view for explaining the operation state, the frame 200 in the form of a cylinder or cylinder The fan 210 is mounted at the inner middle portion of the inner side, and the front opening 201 is formed to have an inner side and an outer side communicating with the front side 1/4 of the frame 200, and faces the front opening 201. Similarly, a rear opening 202 having a size of about 1/4 of the side surface is formed on the other side of the frame 200.

At this time, the upper side of the frame 200 is covered by a roof cover, in which the roof cover not shown is omitted to show the structure inside the frame.

On one side of the front opening 201, the wind guide plate 220 obliquely protrudes outward of the frame to guide the wind toward the front opening 201 so that the wind is accelerated and introduced into the frame 200 quickly.

A lower structure 230 for supporting the frame 200 is installed below the frame 200, and the frame 200 is installed on the upper portion of the lower structure 230 to enable rotation.

As shown in FIG. 6, the annular gear 203 is installed in the lower end of the frame 200 along the circumference thereof, and the rotational power unit including the gear 250 and the transfer motor 260 has a lower structure ( The frame 200 is rotated by the driving of the transfer motor 260 by being fixedly mounted inside the 230.

In addition, a generator 240 is installed inside the lower structure 230, and the generator 240 is connected to the rotating shaft 211 of the fan 210 to generate power in accordance with the rotation of the fan 210.

The rotation of the frame 200 is controlled by receiving the data on the wind direction detected from the wind vane 270 separately installed in the controller 271, the operation of the second embodiment of the present invention 7 and FIG. It demonstrates with reference to 8.

As shown in FIG. 7, the controller 271 outputs a control signal to the motor driver 272 so that the wind guide plate 220 may have an oblique angle of about 30 to 50 ° with respect to the direction in which the wind is blowing. ).

Accordingly, the front opening 201 of the frame 200 faces the wind blowing direction, and the wind blown by the wind guide plate 220 is guided to the edge of the fan 210 to accelerate the fan 210. The wind exiting the inside of the frame 200 while rotating the fan 210 flows out through the rear opening 202.

FIG. 9 is a variation of the second embodiment, in which the frame 200 is rotated by the power in the second embodiment, but FIG. 9 shows the frame 200 toward the direction in which the wind blows with the force of the wind direction without using the power. ) To rotate, the vertical wing portion 281 is formed on one side of the upper surface of the upper cover 280 of the frame 200, which is from the center of the upper cover 280 at a position opposite to the front opening 201 It is formed vertically outward.

Therefore, the frame 200 is rotated by the vertical wing 281 so that the front opening 201 faces the wind blowing direction.

10 is a view showing a modified embodiment of the fan applied in the present invention, the blade of the fan 310 is configured to be biased in one direction toward the center of the rotation axis 311 of the fan 310, between the wing and the wing The space of is formed to gradually narrow from the outside to the inside.

This is to allow the incoming wind to accelerate in the space between the wing and the wing.

11 is a view showing a modified embodiment of the fan 400, when the size of the fan 400 increases, it is difficult to smoothly rotate by the wind because it is bent or struck by its own weight.

In order to prevent this case, the blades 410 of the fan 400 are divided up and down, and the support plates 430 having a disc shape are formed between the divided parts so as to stably support the blades 410 of the upper and lower sides.

This means that the support plate 430 serves as a rib between the wings 410.

The proposed fan 400 may be applied to the first embodiment, the second embodiment, and the third embodiment.

12 is connected to a plurality of power generators 500, 510, 520, ... that generate power by wind as the frame and fan mentioned in the first, second and third embodiments of the present invention. As a structure for generating power with greater power, gearboxes 502, 512, 522, ... are provided on each of the rotating shafts 501, 511, 512, ..., which extend from the power generators 500, 510, 520, ..., The gearboxes 502, 512, 522, ... are connected by the power transmission shafts 503, 513, ... to collect power generated from a plurality of power generators 500, 510, 520, ... to generate power. .

FIG. 13 shows an example of such a gearbox structure 502, 512, 522,..., A state in which power is transmitted by the bevel gear 504, and various other power transmission means may be applied. will be.

1 is a perspective view of an accelerated wind generator according to a first embodiment of the present invention.

2 is a side cross-sectional view.

3 is a simplified plan view for explaining an operating state.

4 is a control circuit block diagram.

5 is a perspective view of an accelerated wind generator according to a second embodiment of the present invention.

6 is a side cross-sectional view.

7 is a simplified plan view for explaining the operating state.

8 is a control circuit block diagram.

9 shows a modified form of the second embodiment;

10 shows a modified form of the fan of the second embodiment;

11 shows another variant of the fan.

12 is a view showing a structure in which power is transmitted by a plurality of rotating structures.

13 is a view showing an example of the gearbox structure of FIG.

<Description of the symbols for the main parts of the drawings>

100: frame 110: fan

111: rotating shaft 120 ~ 150: windshield

160: substructure 170: generator

200: frame 201,202: opening

203: annular gear 210: fan

211: rotating shaft 220: wind induction plate

230: substructure 240: generator

260: transfer motor 280: upper cover

281 vertical wing

Claims (13)

A frame having an open side and at least triangular pillars; A fan rotatably mounted about an axis of rotation in an inner central portion of the frame; A plurality of windshields formed in a plate shape and rotatably mounted by shafts mounted on respective inner corner portions of the frame to selectively open or close the opened portions of the frame; A generator connected to the rotation shaft of the fan to generate power according to the rotation of the fan; An accelerated wind generator, characterized in that consisting of; rotating power unit for rotating the windshield around the axis. According to claim 1, Wind vane for detecting the direction of the wind; And a controller for controlling the rotation of each windshield by controlling the rotating power unit based on the data on the wind direction input from the wind vane. According to claim 1, Accelerated wind generator comprising a lower structure for supporting the lower portion of the frame, and the rotational power unit of the reduction gear and motor for driving the generator and the windshield is installed inside the lower structure. . The accelerated wind generator according to claim 1, wherein the fan is divided up and down, and a support plate having a disc shape is formed between the divided fans. The accelerated wind generator according to claim 1, wherein a rotation shaft of the fan is extended, and a gear box is mounted on the rotation shaft and connected to a gear box of a neighboring acceleration wind generator through a power transmission shaft. A frame having a columnar shape and having an opening having a portion of a side surface and a portion of an opposite side opposite thereto; A wind guidance plate which is in the form of a plate and protrudes outwardly from one side of the opening to direct the wind toward the opening; A fan rotatably mounted about an axis of rotation in an inner central portion of the frame; A lower structure supporting the frame under the frame; A rotating power unit mounted to the lower structure to rotate the frame; Accelerated wind generators, characterized in that consisting of; generator connected to the rotating shaft of the fan for generating power in accordance with the rotation of the fan. According to claim 6, Wind vane for detecting the direction of the wind; And a controller for controlling the rotation of the frame by controlling the rotating power unit based on the data on the wind direction input from the wind vane. According to claim 6, The rotary power unit, An annular gear formed in the circumferential direction of the frame; A motor fixed inside the lower structure; And a gear connected to the shaft of the motor to transmit power of the motor to the annular gear. The accelerated wind generator according to claim 6, wherein the fan is divided up and down, and a support plate in the form of a disc is formed between the divided fans. 7. The accelerated wind generator according to claim 6, wherein a rotation shaft of the fan is extended, and a gear box is mounted on the rotation shaft and connected to a gear box of a neighboring acceleration wind generator through a power transmission shaft. A frame having a columnar shape and having a front opening formed at a side of the side and having a rear opening having a portion of the opposite side opposite to the front opening; A wind guidance plate which is in the form of a plate and protrudes outwardly from one side of the opening to direct the wind toward the opening; A fan rotatably mounted about an axis of rotation in an inner central portion of the frame; A lower structure supporting the frame under the frame; An upper cover covering an upper portion of the frame; A vertical wing portion formed on an upper surface of the upper cover and vertically formed outwardly from the center of the upper cover at a position opposite to the front opening; The generator is connected to the rotation axis of the fan for generating power in accordance with the rotation of the fan; Accelerated wind generator, characterized in that consisting of. 12. The accelerated wind generator according to claim 11, wherein the fan is divided up and down, and a support plate in the form of a disc is formed between the divided fans. 12. The accelerated wind generator according to claim 11, wherein a rotation shaft of the fan is extended, and a gear box is mounted on the rotation shaft and connected to a gear box of a neighboring acceleration wind generator through a power transmission shaft.

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