KR20130136027A - Aerogenerator - Google Patents

Abstract

A wind power generator is disclosed. The wind power generator according to an embodiment of the present invention includes wind power generating bodies which are separately arranged in the longitudinal direction of a vertical structure installed on the ground and composed of a plurality of unit wind power generators to be rotated by wind power; a direction adjusting device which is connected to each unit wind power generator and which is formed to make the unit wind power generators horizontally and vertically move in the vertical structure according to a wind flowing direction; and a power generator which receives torque generated by the unit wind power generator with a power generating shaft.

Description

Wind generators {Aerogenerator}

The present invention relates to a generator using the force of the wind, and more particularly to a wind generator capable of moving the unit wind turbine according to the various directions from which the wind blows.

In general, as a method of producing electricity, wind power and photovoltaic power generation are used in addition to hydro power, tidal power, and nuclear power.

Among them, thermal power generation and nuclear power generation facilities require enormous energy, high technology, manpower and expensive high-tech equipment for operation, and cost and maintenance costs for installation. Among them, in the case of Korea, there is great interest in the development of eco-friendly, low-carbon renewable green energy using wind power or tidal power considering the rich geographic conditions of mountainous areas with good wind mobility.

In the case of renewable energy, wind turbines have been developed in the tens of kW-class commercial wind turbines since the 1980s, and since then, with active research and development, installation capacity has increased more than 10 times and has grown rapidly worldwide.

The most commonly used wind power generator so far is a so-called propeller-type wind power generator, in which a power transmission unit is mounted on an upper part of a vertically installed post, and about 3 to 4 wings are formed on one side of the power transmission unit within a predetermined diameter range. It is composed of a structure mounted vertically toward the wind blowing direction by a rotary blade disposed radially.

Such a conventional wind power generator has an irrational structure in which only one rotary blade device is vertically installed on the top of the support, such as a fan blade, and only a small amount of power generated by the rotary drive of the rotary blade can be expected. In order to increase the power generation amount of the wind power generator, a plurality of wind power generators should be installed in a vastly large place, and thus the amount of power generation that can be obtained compared to the huge installation place and investment cost was limited.

In addition, the conventional wind power generator is generated only by the wind blowing in the front, so if the direction of the wind is not the front side causes a problem that the amount of power generation is deteriorated, so urgent countermeasures were required.

Republic of Korea Patent Publication No. 10-2011-0082467 (Registration Date: July 19, 2011)

Embodiments of the present invention are to provide a wind generator capable of moving the unit wind turbine in different directions according to the direction of the wind blowing into the wind generator.

Embodiments of the present invention to provide a wind generator capable of generating power regardless of the direction of the wind.

Wind generator according to an embodiment of the present invention is a plurality of wind turbines disposed in a plurality of spaced apart in the longitudinal direction of the vertical structure installed on the ground, the rotation is made by the wind power unit; A direction controller connected to each of the unit wind turbines, the unit wind turbines being movable in a horizontal or vertical direction according to the direction in which the wind blows from the vertical structure; And a generator provided with a power generation shaft which receives the rotational force generated by the unit wind turbine.

The wind turbine is installed at the rear of the vertical structure and includes a connection structure for connecting and fixing each other when a plurality of wind turbines are installed next to each other.

The unit wind turbines are each independently movable in a horizontal or vertical direction.

The unit wind turbine is coupled to the center of the rear of the rotor blades, the rotary shaft rotates at the same time with the rotor blades; It includes a rotor guide extending horizontally toward the rear in the state in which the rotating shaft is inserted inside, the spherical housing is formed in the center.

The rotor guide has a horizontal blade formed at the rear; It includes a vertical wing perpendicular to the horizontal wing.

The direction controller may include a first universal joint connected to a rear end of the rotation shaft; One end is connected to the first universal joint, and the other end includes a second universal joint extending downward of the vertical structure via the housing.

A one way clutch may be installed between the second universal joint and the power generating shaft such that the rotational force transmitted through the second universal joint is rotated in only one direction.

The power generation shaft further includes a rotation ring installed to guide the rotation.

The vertical structure may include a round part corresponding to the housing and rounded inward; It is installed on the inside of the round portion and includes a bearing that the relative rotation is made when the rotor guide rotates in the horizontal or vertical direction.

Wind generator according to another embodiment of the present invention is a plurality of wind turbines are spaced apart along the longitudinal direction of the vertical structure installed on the ground, consisting of a plurality of unit wind turbine to be rotated by the wind; A gear box connected to the unit wind turbine and receiving a rotational force; A rotation switching unit connected to the gear box and converting a horizontal rotational force transmitted to the gearbox into a vertical rotational force; And a generator provided with a power generation shaft which receives the rotational force transmitted through the rotation conversion unit.

The gear box may include a first gear inserted into a rotating shaft coupled to a rotor blade installed in the unit wind turbine; And a second gear meshed with the first gear at a right angle and horizontally installed inside the vertical structure.

The rotation switching unit includes a universal joint inserted in the center of the second gear and a main shaft connected to the universal joint.

The gear box includes a one-way clutch installed under the second gear.

The present invention is configured so that the unit winder can be moved in the vertical direction to the front of the wind direction regardless of the direction of the wind blowing into the wind generator, so as to look in the front of the wind direction, maximizing the power generation efficiency, stable power generation As a result, power generation efficiency can be improved.

According to the present invention, when any one wind turbine installed in the wind generator is rotated, the other wind turbines can also be rotated at the same time, so that the wind turbines can be generated with a small amount of wind. Rotation of the unit wind turbine in the direction opposite to the direction of rotation of the final generator shaft does not affect the overall rotation and has the effect of providing a wind generator that allows the highest speed unit wind turbine to contribute to raising and maintaining the total generator rotation speed. have.

1 to 2 is a view showing a wind generator according to an embodiment of the present invention.
3 is a view showing a state in which a plurality of wind generators are connected via a connection structure according to an embodiment of the present invention.
Figure 4 is a perspective view showing a one-way clutch provided in the wind power generator according to an embodiment of the present invention.
5 is a view showing a rotation state of FIG.
6 is a view showing a wind generator according to another embodiment of the present invention.
7 to 8 is an operating state diagram of a wind generator according to an embodiment of the present invention.
9 is an operational state diagram of a wind generator according to another embodiment of the present invention.
10 is a perspective view showing a form in which a unit wind turbine installed in the wind generator for rotation according to an embodiment of the present invention generates a starting torque through rotation.

A configuration of a wind generator according to an embodiment of the present invention will be described with reference to the drawings.

1 to 2, a wind generator includes a wind turbine 100 including a plurality of unit wind turbines 110 installed in a vertical structure 10, and the unit wind turbines 110 blow wind. The generator 300 includes a direction controller 200 provided to be movable along a coming direction, and a power generator shaft 310 receiving the rotational force generated from the unit wind turbine 110.

The vertical structure 10 is formed of a steel structure having a predetermined diameter and extends upward from the ground with a predetermined length, and a rectangular plate 12 having a rectangular parallelepiped shape is installed at a connection portion connected to the ground, and the rectangular plate ( A plurality of fixing bolts 15 are installed from the top of the 12 toward the ground, and include a support plate 16 for supporting between the rectangular plate 12 and the vertical structure.

The wind turbine 100 includes a plurality of unit wind turbines 110, and the unit wind turbines 110 are disposed on the lowermost side of the vertical wind turbines 110 in the longitudinal direction of the vertical structure 10. And a second wind turbine (110b) disposed above the first wind turbine (110a), and a third wind turbine (110c) disposed above the second wind turbine (110b). For reference, in the present embodiment, all three unit wind turbines 110 are illustrated, but the number of installations is variable.

The wind turbine 100 may be manufactured using the above-described first to third wind turbines 110a, 110b, and 110c as one unit, and may be installed in a state in which a plurality of individual wind turbines are connected in one direction. have.

The wind turbine 100 is installed at the rear of the vertical structure 10 and includes a connection structure 102 for connecting and fixing each other when a plurality of wind turbines 100 are installed next to each other. The connection structure 102 is provided for use in a state in which a plurality of wind generators are connected in series with each other, the connection structure 102 is a separate fixture (not shown) to be installed to maintain a stable coupling state between each other Can be.

As such, when a plurality of wind generators are connected, the number of unit wind turbines 110 is also increased, thereby improving power generation efficiency.

The unit wind turbine 110 is coupled to the center of the rear of the rotor blade 111, and rotates at the same time as the rotor blade 111 and the rotating shaft 112, the rotating shaft 112 is inserted toward the rear toward the rear The rotor guide 114 extends horizontally and has a spherical housing 115a formed at the center thereof.

The rotor blade 111 may be a blade used in a wind generator, and is not particularly limited in shape. The rotor blade 111 has a rotating shaft 112 is installed on the back, and is rotated by receiving the rotational force according to the rotation of the rotor blade 111.

The rotor guide 114 does not rotate together with the rotation of the rotation shaft 112, and guides the rotation shaft 112 without being rotated in the axial direction, and only when the rotor blade 111 is moved in the horizontal or vertical direction. The movement is made.

The rotor guide 114 according to the present embodiment may be moved in the horizontal or vertical direction by the wind, in the horizontal direction is moved in the left and right directions at a predetermined angle, and in the vertical direction is upward or at a predetermined angle. Can be downward.

The housing 115a is formed in a spherical shape, and enables the movement of the rotor blades 110 in the horizontal direction and the vertical direction in the vertical structure 10. The rotor guide 114 may be assembled after being bisected in the longitudinal direction without being manufactured integrally.

The vertical structure 10 having the rotor guide 114 installed therein corresponds to the housing 115a and has a round portion 13 formed to be rounded inward, and the rotor guide 114 is installed inside the round portion 13. Includes a bearing 14 in which relative rotation is made when rotating in the horizontal or vertical direction.

The rounded portions 13 may be formed inside the vertical structure 10 in the form of hemispheres, and flanges bent at an angle of 90 degrees toward the outer circumferential surface may be assembled to each other to maintain a spherical shape. In the round part 13, the opening hole into which the rotor guide 114 is inserted is opened at the same position to the front and the rear, respectively.

The bearing 14 enables more stable rotation when the housing 115a is rotated in the horizontal or vertical direction, and can support a part of the load due to the movement.

The rotor guide 114 includes a horizontal vane 114a formed at the rear and a vertical vane 114b. The horizontal and vertical vanes 114a and 114b may switch the moving direction of the rotor guide 114 connected to the rotor blades 111 in a horizontal or vertical direction according to a wind blowing direction. The horizontal blade 114a and the vertical blade 114b are not limited to the shapes shown in the drawings, and it is understood that changes to other shapes are possible.

A direction controller according to an embodiment of the present invention will be described.

The direction controller 200 is connected to the first universal joint 210 which is rotated together with the rotation shaft 112, one end of the first universal joint 210, and the other end of the direction controller 200 through the housing 115a. And a second universal joint 220 extending downwardly of 10). The first universal joint 210 and the second universal joint 220 enable the left and right horizontal movement of the rotor blade 111 and the up and down vertical movement, and the power generation shaft 310 to be described later. By transmitting the rotational force according to the rotation of the rotary shaft 112 to enable the power generation through the generator (300).

The first universal joint 210 is installed at the rear end of the rotary shaft 112 and simultaneously receives the rotational force of the rotary shaft 112 and the movement force according to the movement of the rotor blade 111 and transmits it to the second universal joint 220. . The second universal joint 220 receives the rotational force and the moving force of the first universal joint 210 and rotates and moves simultaneously with the first universal joint 210.

For example, when wind blows from the front of the rotor blade 111, the rotor blade 111 is rotated in a horizontal state and at the same time a rotational force is transmitted to the rotating shaft 112, the rotating shaft 112 is rotated in a horizontal state This is done. The first universal joint 210 receives the rotational force of the rotation shaft 112 as it is and transmits the rotational force to the second universal joint 220.

For example, when the wind blows from the lower side of the rotor blades 111 to the upper side, the rotor blades 111 receive the force of the wind on the horizontal blades 114a so that the wind turbine unit 110 faces the wind front direction. It can be rotated in a state where the movement is made by a predetermined angle toward the lower side of the wind in the horizontal state.

The rotor blade 111 may be rotated in a state in which the movement is made by a predetermined angle toward the upper side in a horizontal state. This is because the housing 115a is freely rotated by a predetermined angle in a state where the housing 115a is installed in the round portion 13. Therefore, the rotation shaft 112 is rotated at the same time as the rotor blade 111 is rotated, and the rotational force is transmitted to the first and second universal joints 210 and 220.

One-way clutch and power generation shaft according to an embodiment of the present invention will be described with reference to the drawings.

1 or 4 and 5, the one-way clutch 400 is installed to receive the rotational force from the second universal joint 220 to transmit the rotational force to the power generation shaft 310 only in one direction. . The one-way clutch 400 has a ring-shaped inner ring 402 having an insertion hole 402 open at the center thereof, and an outer ring 410 surrounding the outer side of the inner ring 440 and having a predetermined diameter. ). The inner ring 440 includes a roller 420 carried by the spring 430 along the circumferential direction.

Referring briefly to the power transmission relationship in FIG. 1, when the first to third wind turbines 110a, 110b, and 110c are rotated, rotational force is transmitted to the second universal joint 220, and the second universal joint 220 is rotated. The inner ring 440 of the one-way clutch 400 coupled to the rotating, the outer ring 410 is also rotated by the rotation of the inner ring 440, the connecting shaft 304 connected to the one-way clutch 400 While rotating together, the connection gear 305 is rotated, and finally, a rotational force is transmitted to the power generating shaft 310 to operate the generator 300 connected to the power generating shaft 310.

The power generation shaft 310 is provided with a rotary ring 500, the stable rotation may be guided by the rotary ring 500. The power generation shaft 310 extends along the inner length direction of the vertical structure 10 and is rotated by receiving rotational force through the first to third wind turbines 110a, 110b, and 110c, and the rotational force to the generator 300. As it is delivered, development takes place.

Referring to FIG. 5, the one-way clutch 400 receives the rotational force of the power generation shaft 310 installed in the insertion hole 402 and the spring 430 is burnt when the inner ring 440 is rotated in the direction of the arrow. Since the roller 420 is free to rotate between the outer ring 410 and the inner ring 440, the outer ring 440 may be stably rotated toward the arrow direction shown by the solid line.

Therefore, all of the rotational force transmitted through the power generation shaft 310 may be transmitted to the generator 300 while generating power through the generator 300.

If the power generation shaft 310 is rotated in the counterclockwise direction, the rotation is performed by the spring 430 so that the power generation shaft 310 is not rotated in the reverse direction.

A wind generator according to another embodiment of the present invention will be described with reference to the drawings.

Referring to FIG. 6, a plurality of wind generators are spaced apart along the longitudinal direction of the vertical structure 10a installed on the ground, and the wind generator includes a plurality of unit wind turbines 110 ′ to be rotated by wind power. 100a, a gear box 200a connected to the unit wind turbine 110 'and receiving a rotational force, and a horizontal rotational force connected to the gear box 200a and transmitted to the gear box 200a. A rotation switching unit 400a for converting the rotation force into a vertical direction; And a generator 300a provided with a power generation shaft 310a that receives the rotational force transmitted through the rotation switching unit 400a.

The unit wind turbine 110 ′ includes a first wind turbine 111 ′ disposed at a lowermost side with respect to the longitudinal direction of the vertical structure 10 a and a first wind turbine 111 ′ disposed above the first wind turbine 111 ′. And a second wind turbine 112 'and a third wind turbine 113' disposed above the second wind turbine 112 '. For reference, in the present embodiment, all three unit wind turbines 110 ′ are installed, but the number of installations is variable.

The biggest feature of the present embodiment is that when the third wind turbine 113 'is operated, the remaining first to second wind turbines 111' and 112 'are inertial according to the rotation of the third wind turbine 113'. As the rotational force is transmitted, all of them have the feature of being able to rotate. Therefore, the third wind turbine 113 ′ may be used as a wind turbine that may cause starting and inertia of the unit wind turbine 110 ′.

The gear box 200a is coupled to the rotation shaft 112a at the center of the rear of the rotor blade 111a installed in the unit wind turbine 110 ', and the rotation shaft 112a is horizontally outward via the vertical structure 10a. It is extended so as to, the rear end of the rotary shaft 112a is provided with a vertical vane 114b so as to be movable in the left and right directions so that the unit wind turbine 110 ′ faces the wind front with respect to the wind direction. In this case, the horizontal blade 114a may be selectively installed and not necessarily installed.

The first gear 201a is installed at the rear end of the rotation shaft 112a, and the second gear 202a is horizontally installed inside the vertical structure 10a in a state where the first gear 201a is crossed at right angles to the first gear 201a. .

The gear box 200a includes a one-way clutch 203a installed below the second gear 202a. Since the description of the one-way clutch 203a has already been described above, it will be omitted.

The rotation switching unit 400a includes a universal joint 410a and a main shaft 410b installed at the center of the second gear 202a, and the universal joint 410a is along the longitudinal direction of the vertical structure 10a. A plurality of extension parts may receive the rotational force transmitted from the wind turbine 100a and transmit the received rotational force to the power generation shaft 310a. The inertia rotational force according to the rotation of the third wind turbine 113 'may be the first to second wind turbines. Transmitted to the universal joint located at (111 ', 112') to inertial rotation, thereby rotating the power generation shaft (310a) it is possible to perform the power generation of the generator (300a). The main shaft 410b may connect the universal joint 410a to each other. Here, the rotation of the unit wind turbine having the highest rotational speed contributes to the rotation of the final power generation shaft by the one-way clutch of the unit wind turbine 110 'having the highest rotation speed.

Although the rotation switching unit 400a according to an embodiment of the present invention has been described as being limited to the universal joint 410a, a worm and a worm wheel capable of converting the rotational force in the horizontal direction transmitted through the rotation shaft 112a in the vertical direction. Note that it is also possible to change to a configuration such as

A state of use of the wind power generator according to an embodiment of the present invention configured as described above will be described with reference to the drawings.

Referring to FIG. 7, in the state where the wind generator is installed, the wind may be blown in various directions instead of always blowing toward the front of the wind generator. For example, when the wind from the lower side of the wind generator toward the upper side blows into the second wind generator 110b, the wind is applied to the horizontal vane 114a and lift force is applied to lift the horizontal vane 114a upward. The horizontal vanes 114a are moved about the housing 115a toward the upper side in the horizontal state, and the rotor blades 111 are moved downward.

The rotor blades 111 are rotated at a predetermined speed by wind, and the rotational force of the rotor blades 111 is transmitted as it is through the first and second universal joints 210 and 220 via the rotation shaft 112. Then, the rotational force of the second universal joint 220 is transmitted through the one-way clutch 400, and the power generation shaft 310 is rotated to generate power through the generator 300.

Referring to FIG. 8, the first wind generator 110a installed at the lower side of the second wind generator 110b has a vertical vane 114b when the wind is blown from the front and the direction of the wind is changed to the right horizontal direction. The rotor guide 114 is rotated in the horizontal direction as the wind is switched to the direction), but is stably supported by the bearing 14 while being rotated in the horizontal direction, thereby moving.

Even after the position of the second wind generator 110b is changed, the rotor blades 111 are rotated at a predetermined speed by the wind, and the power generation shaft 310 is rotated via the rotation shaft 11 and the first and second universal joints 210 and 220. As the rotational force is transmitted to the generator, stable power generation is achieved through the generator 300.

Therefore, even when the wind blows from different directions based on the location where the wind generator 100 is installed, stable power generation is possible, and power generation efficiency can be improved accordingly.

An operating state of a wind generator according to another embodiment of the present invention will be described with reference to the drawings.

Referring to FIG. 9, in the wind generator 100a, the rotor blade 111a installed in the third wind turbine 113 ′ is rotated by the wind blown into the unit wind turbine 110 ′, and the rotating shaft 112 a is rotated. At the same time, the rotational force of the rotating shaft 112a is transmitted to the universal joint 410a connected to the main shaft 410b after the direction of rotational force is changed while passing through the first gear 201a and the second gear 202a. .

The universal joint 410a generates the rotational force for starting the unit wind turbine 110 'by the rotational force transmitted through the second gear 202a, and simultaneously generates the rotational force according to the inertia, thereby generating the second to the first wind turbines. Causing inertial rotation of the universal joint extending toward groups 112 'and 111'. Accordingly, the second to first wind turbines 112 ′ and 111 ′ may rotate at a predetermined speed by the inertial force of the universal joint 410 a even when the wind does not blow, thereby enabling the power generation of the generator 300 a. Can be. Here, the rotation of the unit wind turbine having the highest rotational speed contributes to the rotation of the final power generation shaft by the one-way clutch of the unit wind turbine 110 'having the highest rotation speed.

In the present embodiment, the vertical wing 114b is attached to the embodiment of the present invention, but the vertical wing 114b may also be omitted, and the unit wind turbine 110 'may be installed vertically by installing only the horizontal wing 114a. Can be moved. In the present embodiment, the unit wind turbine (110 ') has been described mainly around the horizontal axis wind power generator, it can be replaced by a vertical axis wind power generator, it will be found that it can be configured and applied to a combination of the horizontal axis and vertical axis.

In the wind power generator according to an embodiment of the present invention, a unit wind turbine 1110 having a shape as shown in FIG. 10 may be used to generate a starting torque required for rotation, and the unit wind turbine 1110 may be used. The plurality of blades 1114 between the disk 1112 installed on the upper and lower may be made of a configuration installed with the disk 1112 concentric circles. The blade 1114 extends with a predetermined length in the vertical direction and is rounded in the circumferential direction, so that the blade 1114 may be more easily transmitted when the wind blows.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit of the invention as set forth in the appended claims. The present invention can be variously modified and changed by those skilled in the art, and it is also within the scope of the present invention.

10: vertical structure
100: wind turbine
111: rotor blade
112: rotation axis
114: rotor guide
115a: housing
110: unit wind turbine
200: direction controller
210, 220: First and second universal joint
300: generator
310: development axis
400: one-way clutch
500: rotating ring

Claims (13)

A plurality of wind turbines are spaced apart along the longitudinal direction of the vertical structure installed on the ground, consisting of a plurality of unit wind turbine to be rotated by the wind;
A direction controller connected to each of the unit wind turbines, the unit wind turbines being movable in a horizontal or vertical direction according to the direction in which the wind blows from the vertical structure; And
Wind generator comprising a generator having a power generating shaft for receiving the rotational force generated in the unit wind turbine. The method according to claim 1,
The wind power generator,
And a connection structure installed at a rear of the vertical structure and connected to each other to fix each other when a plurality of wind power generators are installed next to each other. The method according to claim 1,
The unit wind turbine,
Wind generator, characterized in that each independently movable in the horizontal or vertical direction. The method according to claim 1,
The unit wind turbine,
A rotating shaft coupled to the rear center of the rotor blade and rotating simultaneously with the rotor blade;
And a rotor guide extending horizontally toward the rear with the rotary shaft inserted therein and having a spherical housing formed in the center thereof. 5. The method of claim 4,
The rotor guide,
Horizontal wings formed at the rear;
A wind generator comprising a vertical wing perpendicular to the horizontal wing. The method according to any one of claims 1 to 4,
The direction adjuster,
A first universal joint connected to a rear end of the rotation shaft;
And a second universal joint having one end connected to the first universal joint and the other end extending downward of the vertical structure via the housing. The method of claim 6,
And a one way clutch installed between the second universal joint and the power generating shaft such that the rotational force transmitted through the second universal joint is rotated in only one direction. The method according to claim 1,
In the development axis,
A wind generator further comprising a rotating ring installed to guide the rotation. The method according to any one of claims 1 to 4,
The vertical structure,
A round part corresponding to the housing and rounded inwardly;
And a bearing installed inside the round part and configured to rotate relative to the rotor guide in a horizontal or vertical direction. A plurality of wind power generators spaced apart along the longitudinal direction of the vertical structure installed on the ground, the plurality of unit wind turbines being rotated by wind power;
A gear box connected to the unit wind turbine and receiving a rotational force;
A rotation switching unit connected to the gear box and converting a horizontal rotational force transmitted to the gearbox into a vertical rotational force; And
Wind generator comprising a generator having a power generation shaft that receives the rotational force transmitted through the rotation conversion unit. The method of claim 10,
The gear box includes:
A first gear inserted into a rotating shaft coupled to a rotor blade installed in the unit wind turbine;
And a second gear meshed with the first gear at a right angle and horizontally installed inside the vertical structure. The method according to any one of claims 10 to 11,
The rotation switching unit,
A universal joint inserted in the center of the second gear;
A wind generator comprising a main shaft connected to the universal joint. 12. The method of claim 11,
The gear box includes:
A wind generator comprising a one-way clutch installed under the second gear.

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