KR101975794B1 - Vertical axis mid-size wind turbine - Google Patents

Abstract

The present invention provides a wind power generator generating power by rotating a rotor by the driving force of a rotary shaft rotating by a wing and effectively controlling the rotation of the rotor. According to an embodiment of the present invention, the wind power generator includes: a tower in which one end of the tower is connected to the rotary shaft connected to the wings; a generating unit including the rotor connected by enclosing a space between one end and the other end of the tower, wherein the generating unit also includes a stator enclosing the rotor by being spaced from the rotor; and a control unit storing or changing electricity generated in the generating unit. The multiple generating units are connected to be detached in the extension direction of the tower. So, the capacity of power generation can be increased and decreased.

Description

{Vertical AXIS MID-SIZE WIND TURBINE}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a wind turbine generator, and more particularly, to a wind turbine generator that generates power by rotating a blade coupled to a vertical rotary shaft, reduces noise, Type vertical wind power generators.

Unless otherwise indicated herein, the contents set forth in this section are not prior art to the claims of this application and are not to be construed as prior art to be included in this section.

Currently, generators used in vertical wind turbine generators are technical problems such as noise due to accelerator, arrangement structure of generators and boosters, vibration due to the rotating force of the blades, and control by overturn.

In the case of a vertical axis wind turbine, it is advantageous in wind speed, turbulent wind or wind blast. However, due to a structural problem, it is expensive to manufacture and commercialization of a vertical or large wind turbine is difficult due to economical problems except for a small street lamp, After solving the economic problems, a commercialization step is necessary.

Therefore, in order to commercialize a vertical-type wind turbine of medium size or more, it is necessary to solve structural problems, control devices for preventing overturning, problems of noise or vibration, arrangement structure due to accelerator, and economical problems.

Korean Patent Registration No. 10-1361042 discloses a vertical axis wind turbine and wind speed braking device, and Korean Patent Publication No. 10-1238675 discloses a blade for a vertical axis wind turbine capable of adjusting an automatic pitch.

However, the existing inventions do not disclose a technology for effectively controlling the overrun with solving the arrangement structure of the speed reducer.

Korean Patent Registration No. 10-1361042 Korean Patent Registration No. 10-1238675

The power generation unit is placed in the lower part of the wind power generator to reduce noise and vibration, to distribute the load concentrated on the tower, to relieve the fatigue transmitted to the tower,

A wind turbine that drives the tower by the driving force of the rotating shaft rotating through the rotating blades and generates electricity by driving the rotor coupled to the lower portion of the tower and effectively controls the rotation of the rotor from the overspeed or over- Generator.

Further, it is obvious that the present invention is not limited to the above-described technical problems, and another technical problem may be derived from the following description.

According to an embodiment of the disclosed subject matter, a wind turbine includes a tower that is formed to be connected to a rotating shaft, one end of which is coupled to a wing, a rotor that is surrounded and coupled between one end and the other end of the tower, And a control unit for storing or converting power generated by the power generation unit, wherein the plurality of power generation units are coupled to each other so as to be detachable from each other along the extending direction of the tower, It is possible to increase or decrease.

The power generation unit may further include ribs, one end of which surrounds the tower, is coupled to the tower, and the other end extends toward the inner side of the rotor to be coupled with the rotor.

The wind turbine further includes a disc portion formed in a cylindrical shape having one end connected to the ribs and coupled to the ribs and the other end extending in a disc shape from a lower portion of the ribs to a disc shape, have.

The apparatus may further include a brake unit which is formed so as to surround the rim of the other end of the disk unit and which is driven by hydraulic pressure or pneumatic pressure which presses the disk unit or is separated from the disk unit by driving.

The wind turbine further includes a cover portion having one end connected to a frame surrounding the stator and covering an upper portion of the power generating unit and the other end having a portion of a rim protruding upward, And a brake unit slidably moving toward the tower when electric power is generated in the power unit.

In addition, the disc portion of any one of the power generating units located at an upper portion in a state where the power generating units are laminated to each other may be disposed between the brake portion and the tower of any one of the power generating units located below.

According to the embodiment disclosed in this specification, since the rotational force of the rotating shaft rotating through the vanes is directly used as a driving force for generating power, the wind power generator has an advantage that the loss of the driving force for generating power is minimized.

In addition, the wind power generator can increase the power generation capacity by stacking a plurality of power generation units according to various environments in which a difference in wind power is generated, or use a single power generation unit, and it is possible to set a power generation capacity suitable for the environment.

Further, the wind turbine generator is provided with a brake section for controlling the rotation of the rotor formed in each of the power generation units, so that it is possible to control the rotation effectively, and a sliding movement of a part of the brake section is possible, There are advantages.

In addition, the problem of fatigue due to the vibration generated when the power generating unit is located at the lower portion of the tower and the power generating unit is located at the upper portion is solved, and the load transmitted to the tower is reduced to secure the safety of the entire wind power generator. It is advantageous that there is no noise due to mechanical friction because a speed increasing device is unnecessary.

In addition, it is possible to obtain a maximum aerodynamic force in a wide range of wind speeds by being able to perform a variable speed operation, and to be able to continuously receive a rotational speed with respect to a fluctuating wind speed through variable speed operation.

In addition, it is possible to obtain a relatively large amount of output in comparison with the constant speed operation under the same wind speed conditions as the variable speed operation, and it is possible to provide better power quality and mechanical stress reduction.

In addition, when the mechanical brake system and the sensors of the rotational speed and the wind speed make any one of the rotational speed or the wind speed more than the proper value, the brake is operated to improve the safety and the manufacturing cost of the vertical axis type wind turbine The maintenance cost is reduced and the economical efficiency is excellent.

In addition, since the effect of the present invention described above is obviously exerted by the constitution of contents described irrespective of whether or not the inventor perceives it, the effect described above is only some effects according to the contents described, Should not be recognized.

Further, the effect of the present invention should be grasped further by the entire description of the specification, and even if it is not stated in an explicit sentence, a person having ordinary skill in the art to which the written description belongs, It should be seen as an effect described in this specification.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view of a wind turbine according to an embodiment of the present disclosure; FIG.
2 is a front view of the wind turbine generator of Fig. 1;
Fig. 3 is a perspective view of a portion of the wind turbine generator of Fig. 1; Fig.
Fig. 4 is an exploded perspective view of the power unit of the wind turbine of Fig. 1; Fig.
Fig. 5 is a state of use showing another use state of the wind power generator of Fig. 1; Fig.
FIG. 6 is an exploded perspective view of a wind turbine according to another embodiment of the disclosure of FIG. 1; FIG.

Hereinafter, configurations, operations, and effects of a wind power generator according to a preferred embodiment will be described with reference to the accompanying drawings. For reference, in the following drawings, each component is omitted or schematically shown for convenience and clarity, and the size of each component does not reflect the actual size, and the same reference numerals denote the same components throughout the specification. And reference numerals for the same components in individual drawings are omitted.

1 shows a perspective view of a wind turbine according to an embodiment of the disclosure disclosed herein. Figure 2 shows a front view of the wind turbine of Figure 1;

1 and 2, the wind power generator 100 includes a rotary shaft 200, a tower 210, a wing 220, a platform 230, a coupling 240, a structure support ring 250, A bearing 260, a structure 270, a power generation unit 400, and a control unit 700.

The wind turbine generator 100 is a vertical axis wind turbine generator in which a vertical axis wind turbine blade 220 is coupled to one end of a rotating shaft 200 located at an upper end and a lower portion of the wind turbine generator 100 is rotated Power is generated in the power generation unit 400 located in the power generation unit 400.

One end of the rotary shaft 200 is engaged with the vane 220 for the vertical axis wind turbine generator and the other end is coupled to the coupling 240 by a predetermined distance toward the lower side, And is connected to the power generation unit 400.

One end of the coupling 240 is coupled to the other end of the rotation shaft 200 and the other end is coupled to one end of a tower 210 formed at the lower end to connect the rotation shaft 200 and the tower 210 to each other, To the tower < RTI ID = 0.0 > 210. < / RTI >

The other end of the rotating shaft 200 rotates the coupling 240 and the tower 210 when the one end of the rotating shaft 200 is rotated by the rotation of the wing 220. The other end of the rotating shaft 200 rotates the coupling 240 and the tower 210, Thereby generating electric power.

One end of the tower 210 is coupled to the coupling 240 while being spaced apart from the rotation axis 200 and the other end is extended toward a lower portion where the power generation unit 400 is located and surrounds the rotation axis 200, Lt; / RTI >

The platform 230 is composed of a foot plate surrounding the outer surface of the tower 210 at a position adjacent to one end of the tower 210 and a fence surrounding the edge of the foot plate 210. When the maintenance is required, It is utilized as space.

The structure support ring 250 is coupled to the upper surface of the coupling 240 in the form of a ring surrounding the upper surface of the other end of the coupling 240 and includes a structure 260 that extends and extends obliquely downward from the upper end of the bearing 260 270) to support the shape of the structure (270).

The bearing 260 is formed between one end of the rotating shaft 200 and the coupling 240 to surround the rotating shaft 200 and connected to the tower 210 through the coupling 240 to rotate the rotating shaft 200 Stable support.

One end of the structure 270 is formed in the form of a plurality of beams or wires and is coupled to the upper end of the bearing 260. The other end of each of the beams 270 is connected to the support 270 by a plurality of beams or wires, (10).

The power generation unit 400 is coupled to the upper portion of the support portion 10, a portion of the center portion is coupled with the other end of the tower 210, and a portion of the center is rotated to start power generation as the tower 210 rotates.

The control unit 700 adjusts the rated output of the power generated by the power generation unit 400, stores the power, and converts the power into AC or DC so as to be suitable for the facility where the power is used.

The other end of the rotary shaft 200 of the wind turbine generator 100 extends to the coupling 240 and is coupled to one end of the coupling 240. The other end of the coupling 240 is connected to the tower 210 Can be extended to the lower portion to be combined with the power generation unit 400 to improve the maintenance performance of the rotary shaft 200 and the blades 220. [

Fig. 3 is a perspective view showing a part of the wind turbine generator of Fig. 1; Fig. Fig. 4 shows exploded perspective views of the power generating unit of the wind power generator of Fig. 1; Fig. Fig. 5 shows a use state diagram showing another use state of the wind power generator of Fig. 1. Fig.

3 to 5, the wind power generator 100 further includes a disc portion 500, a brake portion 520, a support 540, and a cover portion 560.

The power generation unit 400 includes ribs 410, a rotor 420, a stator 430, and a frame 440.

One end of each of the ribs 410 is coupled with the other end of the tower 210 in a state of being spaced apart from each other along the outer surface of the other end of the rotary shaft 200 at a predetermined interval, And is coupled to the inner surface of the rotor 420.

One end of the rotor 420 is coupled to the other end of each of the ribs 410 and the other end is formed to have a cylindrical shape extending outward by a predetermined distance and connecting the other ends of the ribs 410.

One end of the stator 430 is formed so as to surround the rotor 420 at a position spaced apart from the other end of the rotor 420 by a predetermined gap and the other end is formed into a cylindrical shape .

The frame 440 is formed in a ring shape in which the bottom surface of the frame 4 is engaged with the support portion 10 in a state of being in close contact with the other end of the stator 430 and stably supports the stator 430.

One end of the disk unit 500 is formed in a cylindrical shape connecting each of the ribs 410 between the rotary shaft 200 and the rotor 420 and coupled to the ribs 410, And is formed into a disc shape.

Specifically, the disc portion 500 includes a connecting unit 502 and a disc 504.

The connecting unit 502 is formed in a cylindrical shape connecting each of the ribs 410 to fix the position of each of the ribs 410 and to form the shape of the rotor 420 coupled to the other end of each of the ribs 410 .

One end of the connection unit 502 is coupled to the upper surface of each of the ribs 410 in a ring shape while the other end is coupled with each of the ribs 410 and extends toward the lower portion of the rotor 420 And the other end is located at a position spaced apart from the bottom surface of the rotor 420 by a predetermined distance.

One end of the disk 504 surrounds the other end of the connection unit 502 and is coupled to the outer surface of the connection unit 502. The other end of the disk 504 is spaced apart from the outer surface of the connection unit 502, And extends in a direction perpendicular to the direction of extension.

The brake unit 520 is a hydraulic or pneumatic disc brake apparatus in which the lower end of the rotor 420 is coupled with the support 10 and the support 540 extending from the ground at one end and the support 540 extending from the ground at the other end toward the disc unit 500 And is formed so as to surround the other end of the disk unit 500.

When the brake unit 520 is driven, the other end of the brake unit 520 simultaneously presses the upper surface and the lower surface of the other end of the rotating disk 504 in accordance with the rotation of the rotating shaft 200, 200).

The plurality of brake units 520 are disposed so as to extend toward the disc unit 500 at intervals of 120 degrees from each other with respect to the rotating shaft 200 to effectively reduce or stop the rotation of the rotating shaft 220 .

One end of the cover portion 560 is formed in the shape of a circular plate and coupled to the upper surface of the frame 440 and the other end extends a predetermined distance to cover the upper portion of the power generation unit 400.

The other end of the disk unit 500 may be integrally formed in a cylindrical shape extending from the one end of the cylindrical shape connecting each of the ribs 410 toward the lower portion of the ribs 410, A portion of the other end of the disk unit 500 located in the lower portion of the disk unit 500 is inserted between the pads of the brake unit 520 disposed so that the pad portion faces upward so that rotation of the rotation shaft 200 is reduced by driving of the brake unit 520 .

5, the wind turbine generator 100 may stack a plurality of the power generation units 400 in an upward direction according to a generated environment to increase the generating capacity of the wind turbine generator 100, ), It is possible to secure a minimum generation capacity.

The frame 440 of each of the power generation units 400 is in close contact with each other at the upper and lower portions in a state where the power generation units 400 are stacked and the rotor 420 of the power generation unit 400, And is spaced apart from the upper surface of the cover portion 560 of the power generating unit 400 located at the lower portion of the housing.

The other end of the rotary shaft 200 extends through each of the plurality of power generation units 400 and extends downward. One end of each of the ribs 410 of the power generation units 400 is coupled with the tower 210, The rotors 420 of the power generation units 400 rotate to produce electric power according to the rotation of the motors 210.

When the power generating units 400 are stacked, each of the power generating units 400 stacked on top of the power generating unit 400 excluding the power generating unit 400 located below the frame 440, 504 are separated from each other and the brake unit 520 presses the disc 504 formed in the power generation unit 400 disposed at the lowermost position in the state of being connected to the support unit 10 to perform braking drive.

Figure 6 shows an exploded perspective view of a wind turbine according to another embodiment of the disclosure of Figure 1;

The wind turbine generator 120 according to the present embodiment is substantially the same as the wind turbine generator 120 of FIGS. 1 to 5 except for the cover portion 800 and the brake portion 840, so that the same reference numerals and names are used Duplicate description will be omitted.

6, the wind power generator 120 includes a cover portion 800 and a brake portion 840. [

The wind turbine generator 120 reduces the rotation of the rotator 420 formed in each of the power generating units 400 through the break portions 840 applied to the disks 504 of the power generating units 400 stacked on each other The rotation of the rotary shaft 200 can be effectively decelerated or stopped.

One end of the cover part 800 is formed in the form of a circular plate coupled to the upper surface of the frame 430 and the other end of the cover part 800 is formed in a circular shape Grooves are formed.

One end of the brake portion 840 is coupled to the inner surface of the other end of the cover portion 800 and the other end extends a predetermined distance toward the tower 210 so that the brake portion 840 is parallel to the ground, 200 are spaced apart from each other along the inner surface of the other end of the cover portion 800 with a uniform spacing.

The disc 504 is inserted into the groove in a state where the power generation units 400 coupled with the cover unit 800 are stacked on top and bottom of each other and the other ends of the cover units 800 are the same as the disc 504 They are spaced apart from each other on the horizontal line.

The disc 504 protruding from the lower portion of the power generating unit 400 in the process of stacking the power generating units 400 coupled with the cover unit 800 is inserted into the groove without collision with the brake units 840, And is covered from the outside by the other end of the frame 800.

When the power generating units 400 are stacked on each other and the wing 220 rotates and the rotating shaft 200 rotates, each of the power generating units 400 starts to generate electricity, and the power of the pads of the brake unit 840 A portion of the disk 504 is extended toward the disk 504 in such a manner as to surround the upper and lower edges of the disk 504.

Therefore, each of the brake units 840 is disposed at a position spaced apart from each of the disks 504 inserted in the groove, so that each of the power generation units 400 can be easily stacked, The pads of the brake units 840 are slidably moved to surround the disc 504 through the power to be automatically installed.

On the other hand, the brake portion 840 can use a hydraulic or pneumatic disc brake, and is capable of sliding movement of the other end of the brake portion 840 through hydraulic pressure, pneumatic pressure or electric power.

The brake portion 840 includes a cylinder portion 841, rails 842 and 843, sliding portions 844, levers 845, an inflation portion 846, heads 847 and pads 848 .

One end of the cylinder portion 841 is coupled to the inner surface of the other end of the cover portion 800 and the other end extends in the form of a hydraulic or pneumatic cylinder by a predetermined distance toward the tower 210, So that a part thereof reciprocally slides and moves.

One end of each of the rails 842 and 843 is coupled to the inner surface of the other end of the cover portion 800 with the cylinder portion 841 interposed therebetween and the other end is formed at the other end of the cover portion 800 While being inserted into the groove, extends a predetermined distance toward the tower 210, and maintains a state spaced apart from the disk 504 by a predetermined distance.

The sliding portions 844 are formed in the shape of bar extending in the upper and lower portions and are arranged on the opposite sides of the levers 845 with the levers 845 disposed on the upper and lower sides interposed therebetween, 842 and 843 and the rails 842 and 843, respectively.

One end of each of the levers 845 is engaged with each of the upper portion and the lower portion of the expanding portion 846 and the central portion extends from the one end toward the rotating shaft 200 to be rotatable on the upper and lower portions of the sliding portions 844 And the other end is coupled to each of the heads 847 in a rotatable manner.

The expanding portion 846 is formed between one ends of each of the levers 845 and is engaged with one end of each of the levers 845 and expands or contracts in accordance with pneumatic pressure to separate one end of each of the levers 845 from each other Pull to adjoin.

One end of each of the heads 847 is coupled to both sides of the other end of the lever 845 located at the upper portion thereof so as to be rotatable and the other end is extended and extends downward to be inserted into a groove formed at the other end of the cover portion 800 And to the pads 848 formed to be parallel to the substrate 504.

One end of each of the heads 847 is rotatably coupled to both sides of the other end of the lever 845 located at a distance apart from the disk 504 by a distance greater than the thickness of the disk 504, And pads 848 formed to be parallel to the disk 504 inserted in the groove formed at the other end of the cover portion 800.

Accordingly, when the disk 504 is inserted into the groove of the cover part 800, the cylinder part 841 is driven to slide the expansion part 846 toward the tower 210 by a predetermined distance And the edge of the disk 504 is disposed between each of the pads 848.

Further, when the rotary shaft 200 is over-rotated to stop the rotation or to stop the rotation, each of the pads 848 presses the upper surface and the lower surface of the disk 504 by the driving of the expansion portion 846, 200 is decelerated.

In another embodiment, the brake portion 850 includes a motor 851, a drive shaft 852, wheels 853 and 854, a chain 855, and a fixed portion 856.

The motor 851 is disposed inside the other end of the cover portion 800. The drive shaft 852 is formed at a position adjacent to one end of the rail 842 formed at one side and the wheel 853 is coupled to the drive shaft 852 .

The wheel 854 is formed inside the other end of the rail 842 and the chain 855 surrounds the wheels 853 and 854 and is coupled with the wheels 853 and 854 so that, (853, 854).

A portion of the chain 855 is coupled to the protruding portion protruding outward of the sliding portion 844 through the fixing portion 856 and the sliding portion 844 is moved toward the tower 210 by the rotation of the driving shaft 852 And moves toward the inner surface of the cover portion 800. [

Each of the pads 848 of the brake portion 850 is disposed adjacent to the inner surface of the cover portion 800 when the disk 504 is inserted into the groove formed at the other end of the cover portion 800, And the motor 851 is driven by the generated electric power to move the pads 848 toward the upper and lower edges of the disk 504 when the power generation unit 400 generates electricity .

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken in conjunction with the present invention. It is to be understood that various equivalents and modifications may be substituted for those at the time of the present application. It is to be understood, therefore, that the above description is intended to be illustrative, and not restrictive, and that the scope of the present invention will be defined by the appended claims rather than by the foregoing description, All changes or modifications that come within the scope of the equivalent concept are to be construed as being included within the scope of the present invention.

100: wind turbine generator 200: rotary shaft
400: power generation unit

Claims (6)

A tower, one end of which is configured to be connected to a rotational axis associated with the wings;
A stator which surrounds the rotor and surrounds the tower and is coupled to the tower, and the other end is connected to the inner surface of the rotor, And a rib that extends toward the rotor and is configured to engage with the rotor; And
And a controller for storing or converting power generated in the power generating unit,
Wherein the power generation unit is stacked with the power generation unit such that the power generation unit is detachably attached to the power generation unit along the extending direction of the tower so that the power generation capacity can be increased.
delete The method according to claim 1,
And a disc part formed in a cylindrical shape connecting one end of the ribs and coupled with the ribs and the other end extending in a disc shape from the lower part of the ribs to the outside, generator.
The method of claim 3,
And a braking portion which is formed so as to surround the rim of the other end of the disk portion and which is driven by hydraulic pressure or pneumatic pressure to press the disk portion or to separate from the disk portion according to driving.
The method of claim 3,
A cover part connected to a frame surrounding the stator and covering an upper part of the power generating unit, a groove formed at the center, and a part of the frame protruding toward the upper part; And
And a brake unit coupled to the tower on an inner side of the cover unit located in the groove and slidably moving toward the tower when power is generated in the power unit.
6. The method of claim 5,
Wherein when a power generating unit of the same type as that of the power generating unit is further stacked on top of the power generating unit, the disc portion of the power generating unit located at the upper portion is inserted into the groove of the cover portion located at the lower portion. .

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