KR101556189B1 - Blade installing system - Google Patents

Abstract

A blade installing system for a wind power generator is disclosed. The blade installing system for a wind power generator according to an embodiment of the present invention comprises a main frame connected to multiple crane cables, and lifted in the height direction; and a movable frame which accommodates a blade and relatively moves against the main frame in the joint direction of a blade formed on a hub.

Description

BLADE INSTALLING SYSTEM FOR WIND POWER GENERATOR

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a blade installation system for a wind turbine generator, and more particularly, to a blade installation system for a wind turbine generator that can shorten the time required to install a blade on a hub for a wind turbine generator.

Generally, typical types of power generation for generating electricity include thermal power generation using fossil fuel as an energy source and nuclear power generation using nuclear power.

However, thermal power generation has a problem of causing pollution due to utilization of the energy generated by the combustion of fossil fuel and a huge construction cost.

In addition, nuclear power generation is advantageous in producing a large amount of electricity, but an enormous facility cost is required to prevent radiation leakage, and a strong rebound of local residents is expected due to the risk of radiation leakage. Furthermore, There is always a risk of causing severe environmental destruction.

Therefore, researches are actively conducted to utilize natural energy such as wind power, tidal power, hydroelectric power, and solar energy as an energy source as a permanent energy source free from exhaustion problems due to firepower or nuclear power generation.

In particular, wind power generation is emerging as an alternative from the viewpoint of using clean energy sources among natural energy-based power generation. Wind power generation is easy to operate and manage, and can be operated unattended and automated. Therefore, the introduction has increased dramatically in recent years.

On the other hand, in the past, wind power generation structures were mainly located on land, but due to environmental problems caused by noise and vibration, power generation capacity has become larger, and aesthetics, As a result,

A wind turbine generator is a device for producing electric energy from wind-induced rotational energy. The wind turbine generator includes a rotor having a hub to which a plurality of blades rotated by the wind are connected, and a nacelle a nacelle cover that supports and protects the nacelle, and a tower that supports a plurality of blades, rotors, nacelles, and nacelle covers.

The blade uses aerodynamically designed geometry to generate useful aerodynamic torques in the wind energy and generates electricity by rotating the generator using aerodynamic torques.

The blade must be able to support the load induced by its shape structurally as well as aerodynamic shape is important to increase the amount of electricity generated.

The load is dominant in the aerodynamic shape, but designing a blade that is as light as possible while supporting the same load through structural optimization is another important design technique.

Meanwhile, the work of installing the blades on the hub is accomplished by gripping the blades using a blade gripping device, transferring the blade gripping device and the blade adjacent to the hub, and then inserting the blade root into the blade connecting portion provided in the hub do.

The blade root portion and the blade connecting portion are inserted into a plurality of bolt holes provided in the blade connecting portion and then bolted to each other.

However, conventionally, when connecting the blade root portion to the blade connecting portion, one blade is transferred to the hub adjacent to the hub by a crane, depending on the receiver's number on the hub side.

In this way, conventionally, since the blades are transferred and aligned one by one adjacent to the blade connection portion depending on the receiver's signal, there is a problem that a long time is required for installation of the blades.

Korean Patent Publication No. 10-2009-0083336 (Mitsubishi Chuo Kogyo Co., Ltd.) 2009.08.03 Disclosed

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a blade installation system for a wind turbine that can shorten the time required for installing a blade on a hub for a wind power generator.

According to an aspect of the present invention, there is provided an elevator system comprising: a main frame connected to a plurality of crane cables and elevated in a height direction of the tower; And a moving frame accommodating the blade therein and being moved relative to the main frame in the direction of the blade connecting portion provided in the hub, may be provided.

The main frame includes a storage space, and is provided in the storage space, and is connected to the moving frame to make the moving frame relatively movable with respect to the main frame. And a plurality of roller units disposed in the storage space and spaced apart from each other along the moving direction of the moving frame and contacting and supporting the moving frame when the moving frame is moved.

Wherein the drive unit includes: a rack gear provided in the storage space, the rack gear being disposed long along the moving direction of the moving frame; A pinion gear having one side engaged with the rack gear and the other side connected to the moving frame; And a drive motor connected to the pinion gear to provide rotational force to the pinion gear.

The driving unit may further include a driving motor encoder installed in the driving motor to measure a rotational speed of the driving motor to detect a relative moving distance of the moving frame with respect to the main frame.

Further comprising a blade posture adjusting unit provided on the main frame for adjusting the posture of the blade relative to the blade connecting portion when the moving frame is moved relative to the main frame in the direction of the blade connecting portion, A unit including a sensing unit installed in the main frame and detecting a tilt of the blade from a tilt of the main frame, the tilt of the main frame being changed as the moving frame is moved relative to the main frame; And a crane cable length adjuster installed on the main frame to adjust a length of at least one of the plurality of crane cables to adjust a slope of the blade with respect to the blade connection part.

Wherein the crane cable length adjuster includes a plurality of driving winches spaced apart from each other on the main frame and adjusting the length of the plurality of crane cables by winding and winding each of the plurality of crane cables; And a driving winch encoder installed in each of the plurality of driving winches and measuring the number of revolutions of the driving winch so as to detect a change in length of the crane cable.

Further comprising: a plurality of blade supporting units which are spaced apart from each other in the moving frame, and which support the blades, wherein the blade supporting unit comprises: a bracket provided inside the moving frame, on which the blades are mounted; And a vacuum adsorption plate provided on the upper surface of the bracket and formed in a shape corresponding to the outer shape of the blade, for adsorbing the outer surface of the blade.

In the embodiment of the present invention, the plurality of moving frames housed in the blades are moved relative to the main frame in the direction of the blade connecting portions in order to couple the blade root portions to the blade connecting portions. Thus, have.

1 is a view showing a blade installation system for a wind turbine according to an embodiment of the present invention.
2 is a perspective view illustrating a blade installation jig according to an embodiment of the present invention.
Fig. 3 is an enlarged view of part A of Fig. 2, and is a perspective view showing a blade supporting unit according to an embodiment of the present invention.
Fig. 4 is an enlarged view of part B of Fig. 2, and is a perspective view showing a roller unit and a drive unit according to an embodiment of the present invention.
5 is a flowchart illustrating a method of installing a blade for a wind power generator according to an embodiment of the present invention.
6 to 8 are operational state diagrams showing a blade installation operation according to an embodiment of the present invention.

In order to fully understand the present invention, operational advantages of the present invention, and objects achieved by the practice of the present invention, reference should be made to the accompanying drawings and the accompanying drawings which illustrate preferred embodiments of the present invention.

Hereinafter, the present invention will be described in detail with reference to the preferred embodiments of the present invention with reference to the accompanying drawings. Like reference symbols in the drawings denote like elements.

1 is a view showing a blade installation system for a wind turbine according to an embodiment of the present invention.

Referring to FIG. 1, a wind turbine generator 100 includes a plurality of blades 110 connected to a nacelle (not shown) and rotated by wind, a plurality of blades 110 rotating in accordance with rotation of the blades 110, And a tower 140 for supporting the nacelle, the rotor 120, and the blade 110. The rotor 120 includes a hub 121 to which the rotor 120 is connected.

The blade 110 is a kind of wing that is rotated by the wind to generate rotational motion. The blade 110 disposed radially with respect to the rotor 120 has a streamlined blade shape so that it can be easily rotated by the wind.

The wind turbine 100 according to the present embodiment is provided with three blades 110 so as to pursue stability while maximizing the wind characteristics. However, the present invention is not limited thereto, The scope of the rights of

The blade 110 is installed with a bidirectional type blade 110 freely rotatable in a clockwise or counterclockwise direction, and should be installed in consideration of the wind that flows toward the land in the daytime and the wind that flows toward the sea in the nighttime.

The hub 121 of the rotor 120 is a place where a plurality of blades 110 are connected.

The hub 121 has a substantially circular shape when viewed from the front, and may have a dome shape when viewed from the side.

A nacelle (not shown) is connected to one side of the hub 121 to receive the rotational motion of the blade 110 and produce electric energy. The nacelle is protected by a nacelle cover 130.

The nacelle receives mechanical components such as a main shaft (not shown), a gear box (not shown), and the like, which play an important role in driving the wind turbine generator 100, a gear box (not shown), and a generator (not shown), all of which are structurally coupled to each other.

As such, the nacelle cover 130 is coupled to the outside of the nacelle to protect the nacelle.

Since the nacelle cover 130 is exposed to the outside air and is always exposed to snow, rain, sunlight, etc., a certain degree of rigidity must be ensured. Therefore, the nacelle cover 130 is made of a non-metallic or metal composite material having excellent durability.

On the other hand, the tower 140 supports axially loads on structures such as the blades 110, the hub 121, the nacelle and the nacelle cover 130, and the like.

The tower 140 may be divided into a lower tower at the lower part and an upper tower at the upper part.

The tower 140 has a hollow pipe structure, and a cable or the like is passed through the hollow space of the tower 140. The cable may be a variety of cables, including a dedicated power cable, communication cable, and the like.

On the other hand, in the case of the wind turbine generator 100 having a small size or a small size, there is no great difficulty in installing the wind turbine generator 100. However, as in the present embodiment, the length of the tower 140 is about 100 meters The length of the large wind turbine generator 110 also has a length comparable to that of the tower 140. In the case of a large wind turbine generator 100 having a length similar to that of the tower 140, 123 is difficult to insert and fasten.

Therefore, it takes a lot of time to install the blades 110, and therefore, there is a demand for a blade installation jig 300 for a wind power generator that can shorten the working time in installing the wind power generator 100.

The blade installation system for a wind turbine according to an embodiment of the present invention includes a blade installation jig 300 in which a plurality of blades 110 are accommodated and a crane 200 for moving the blade installation jig 300 up and down. The blade installation jig 300 is connected to the crane 200 through a crane cable 210.

2 is a perspective view illustrating a blade installation jig according to an embodiment of the present invention.

The blade installation jig 300 serves to transfer a plurality of blades 110 corresponding to the number of the blade connection portions 123 provided on the hub 121 adjacent to the hub 121 at a time.

2, the blade installation jig 300 according to the present embodiment includes a main frame 310 connected to a plurality of crane cables 210, a main frame 310 housed in the main frame 310, And a moving frame 320 which is moved relative to the main frame 310 and protrudes outside the main frame 310.

In this embodiment, the main frame 310 is a skeleton supporting the movable frame 320 accommodated therein.

A plurality of storage spaces 311 are formed in the main frame 310 in the height direction and a plurality of storage spaces 311 are provided with the respective movable frames 320.

The number of the plurality of storage spaces 311 formed in the main frame 310 corresponds to the number of the blades 110 coupled to the hub 121. [

In this embodiment, when the main frame 310 is raised by the crane 200 in the vicinity of the hub 121, the moving frame 320 is moved in the direction of the blade connecting portion 123 to which the blade root portion 111 is coupled As shown in FIG.

The moving frames 320 are respectively disposed in a plurality of storage spaces 311 formed in the main frame 310 and stacked in multiple stages in the main frame 310. [ The movable frame 320 is moved relative to the main frame 310 in the direction of the blade connecting part 123.

The blade 110 is accommodated in the movable frame 320.

Accordingly, the blade installation jig 300 according to the present embodiment further includes a plurality of blade supporting units 330 which are provided to be spaced apart from each other on the moving frame 320 and support the blades 110.

Fig. 3 is an enlarged view of part A of Fig. 2, and is a perspective view showing a blade supporting unit according to an embodiment of the present invention.

3, the blade supporting unit 330 includes a bracket 331 which is provided inside the moving frame 320 and on which the blade 110 is mounted, and a blade 110 which is installed on the upper surface of the bracket 331, And a vacuum adsorption plate 333 which is formed in a shape corresponding to the outer surface of the blade 110 and adsorbs the outer surface of the blade 110.

The bracket 331 is provided inside the moving frame 320 and the blade 110 is seated on the bracket 331. A vacuum suction plate 333 for suctioning the blade 110 is installed on the upper surface of the bracket 331 to limit the movement of the blade 110.

The upper surface of the bracket 331 is formed to have a curved surface in a shape corresponding to the outer shape of the blade 110 so that the outer surface of the blade 110 is seated and the vacuum attracting plate 333 is also formed on the outer surface of the blade 110 The blade 110 is formed to have a curved surface in a shape corresponding to the shape, so that the blade 110 can be attracted. However, the present invention is not limited to this, and the vacuum suction plate 333 provided on the upper surface of the bracket 331 may have a curved surface shape corresponding to the outer shape of the blade 110.

The blade 110 is fixed to the inside of the moving frame 320 while being attracted to the vacuum attracting plate 333 and is conveyed toward the blade connecting portion 123. The blade root portion 111 is connected to the blade connecting portion 123 And the blade 110 is separated from the moving frame 320 after the vacuum of the vacuum attracting plate 333 is released.

Fig. 4 is an enlarged view of part B of Fig. 2, and is a perspective view showing a roller unit and a drive unit according to an embodiment of the present invention.

4, the blade installation jig 300 according to the present embodiment includes a storage space 311 (not shown) so that the movable frame 320 accommodating the blade 110 can be moved relative to the main frame 310, A driving unit 350 connected to the moving frame 320 to make the moving frame 320 relatively movable with respect to the main frame 310 and a driving unit 350 provided in the receiving space 311, And a plurality of roller units 340 spaced apart from each other along the moving direction of the moving frame 320 and contacting and supporting the moving frame 320 when the moving frame 320 is moved.

The driving unit 350 serves to make the moving frame 320 relatively movable with respect to the main frame 310. [

The drive unit 350 includes a rack gear 351 which is provided in the storage space 311 so as to be long along the moving direction of the moving frame 320 and a rack gear 351 which is meshed with the rack gear 351 on one side, A pinion gear 353 connected to the moving frame 320 and a driving motor 355 connected to the pinion gear 353 and providing a rotational force to the pinion gear 353.

The pinion gear 353 is rotated with the pinion gear 353 engaged with the rack gear 351 by the rotation of the drive motor 355 so that the moving frame 320 can move relative to the main frame 310. [

The driving unit 350 is provided in the driving motor 355 to detect the relative moving distance of the moving frame 320 with respect to the main frame 310. The driving unit 350 includes a driving motor encoder 355 for measuring the number of revolutions of the driving motor 355, (encoder) (not shown).

In this embodiment, the plurality of roller units 340 are spaced apart from each other by a predetermined distance along the moving direction of the moving frame 320 in the storage space 311.

The plurality of roller units 340 contact the moving frame 320 to roll when the moving frame 320 is moved relative to the main frame 310 in order to minimize friction with the moving frame 320.

On the other hand, when the movable frame 320 is moved relative to the main frame 310 to couple the blade root 111 to the blade connecting portion 123, the weight of the blade 110 and the movable frame 320 The main frame 310 itself may be inclined.

The blade installation system for a wind turbine according to an embodiment of the present invention is provided with a main frame 310 in which a moving frame 320 is moved relative to the main frame 310 in the direction of the blade connection part 123 And a blade posture adjusting unit 400 for adjusting the posture of the blade 110 with respect to the blade connecting portion 123.

Referring to FIG. 2, the blade posture adjusting unit 400 includes a blade posture adjusting unit 400, which is installed on the main frame 310, and which moves from the inclination of the main frame 310, which is changed as the moving frame 320 is moved relative to the main frame 310 At least one of a plurality of crane cables 210 installed on the main frame 310 to adjust the inclination of the blades 110 with respect to the blade connecting part 123, a sensing part 430 for detecting the inclination of the blade 110, And a crane cable length adjuster 410 that adjusts one length.

When the movable frame 320 is moved relative to the main frame 310 in the direction of the blade connection part 123, the weight of the blade 110 and the movable frame 320 is concentrated, Loses. The sensing unit 430 includes a sensor for detecting the inclination and detects the inclination of the blade 110 from the inclination of the main frame 310 installed in the main frame 310.

In order to adjust the inclination of the blade 110 detected by the sensing unit 430, the crane cable length adjuster 410 according to the present embodiment includes a plurality of crane cables 210 connected to the main frame 310 And adjusts the inclination of the blade 110 with respect to the blade connecting portion 123 by adjusting at least one of the lengths.

The crane cable length adjusting unit 410 includes a plurality of crane cable length adjusting units 410 spaced apart from each other in the main frame 310 and wound around and winding up a plurality of crane cables 210 to adjust a length of the plurality of crane cables 210 A drive winch 411 and a drive winch encoder (not shown) installed in the drive winch 411 for measuring the number of revolutions of the drive winch 411 so as to detect a change in length of the crane cable 210.

When the main frame 310 is tilted obliquely according to the relative movement of the movable frame 320, the sensing unit 430 may be rotated in the direction of the relative movement of the movable frame 320, Detects the inclination of the blade 110 from the inclination angle of the main frame 310.

At least one of the plurality of crane cables 210 connected to the main frame 310 based on the inclination of the main frame 310 and the blades 110 detected by the sensing unit 430 And the tilt of the main frame 310 and the blade root portion 111 is adjusted so as to face the blade connecting portion 123. [

The change in the length of the crane cable 210 wound around the drive winch 411 to adjust the tilt of the main frame 310 and the blade root 111 is controlled by the drive winch 411 using a drive winch encoder, Can be determined by measuring the number of revolutions.

A method of installing a blade for a wind turbine according to an embodiment of the present invention will now be described.

FIG. 5 is a flowchart illustrating a method of installing a blade for a wind turbine according to an embodiment of the present invention, and FIGS. 6 to 8 are operational state diagrams illustrating a blade installation operation according to an embodiment of the present invention.

Referring to FIG. 5, first, the main frame 310 is raised adjacent to the hub 121 by using the crane 200 (S100).

6, the moving frame 320 is moved relative to the main frame 310 in the direction of the blade connecting portion 123 so that the blade root portion 111 is coupled to the blade connecting portion 123 S200).

The relative movement of the moving frame 320 is performed by moving the pinion gear 353 connected to the moving frame 320 to the rack gear 351, which is arranged in the main frame 310 along the moving direction of the moving frame 320, So as to move the movable frame 320 relative to the main frame 310.

At this time, the blade connecting portion 123 is in a fixed state. As the moving frame 320 is moved toward the blade connecting portion 123, the weight is biased and the main frame 310 and the blade 110 are inclined at an angle.

Therefore, the blade root portion 111 and the blade connecting portion 123 should be aligned (S300).

That is, the blade root portion 111 and the blade connecting portion 123 are connected by a plurality of bolts (not shown) provided in the blade root portion 111 to a plurality of bolt holes (not shown) provided in the blade connecting portion 123 Should be inserted. Therefore, the blade root portion 111 and the blade connecting portion 123 should be aligned with the blade root portion 111 approaching the blade connecting portion 123.

(Not shown), laser point (not shown) or the like, and the blade root portion 111 is connected to the blade connecting portion 123 ), It can be confirmed with the naked eye.

In this embodiment, the alignment of the blade root portion 111 and the blade connecting portion 123 is as follows.

First, when the movable frame 320 is moved relative to the main frame 310, the weight is biased and the main frame 310 is inclined at an angle. The inclination of the blade 110 from the inclination of the main frame 310 which is changed as the movable frame 320 is moved relative to the main frame 310 by using the sensing unit 430 installed in the main frame 310, (S310).

The length of at least one of the plurality of crane cables 210 connected to the main frame 310 is adjusted based on the inclination of the detected blade 110 to adjust the inclination of the blade 110 with respect to the blade connecting portion 123 (S330).

For example, when the movable frame 320 is moved in the direction of the blade connecting portion 123, the front portion of the main frame 310 facing the blade connecting portion 123 is inclined downward. At this time, the crane cable 210 is wound on the driving winches 411 provided at the upper part of the front part of the main frame 310 to lift the front part of the main frame 310 upward, ) Can be adjusted.

The blade root portion 111 is moved relative to the main frame 310 while the movable frame 320 is moved relative to the main frame 310 until the blade root portion 111 accommodated in the movable frame 320 approaches the blade connecting portion 123, And the blade connecting portion 123 can be repeated.

Then, the blade root portion 111 is coupled to the blade connecting portion 123 (S400).

That is, when it is determined that the plurality of bolts provided in the blade root portion 111 and the blade connecting portion 123, specifically, the blade root portion 111 and the plurality of bolt holes provided in the blade connecting portion 123 are aligned, (111) is inserted into the blade connecting portion (123) and engaged.

When the blade root portion 111 is coupled to the blade connecting portion 123, the movable frame 320 is moved relative to the main frame 310 such that the movable frame 320 is accommodated in the main frame 310 . That is, the moving frame 320 is restored to its original state (S500).

Specifically, as shown in Fig. 7, the movable frame 320 provided at the lowermost end of the main frame 310 is returned to its original state.

Then, as shown in Fig. 7, the hub 121 is rotated to couple the second blade root portion 111 to the blade connection portion 123. [ The movement of the movable frame 320 with the second blade 110 relative to the main frame 310 in the direction of the blade connecting part 123 is repeated while repeating the above- And is connected to the connection part 123.

Then, as shown in FIG. 8, the hub 121 is rotated to couple the third blade root portion 111 to the blade connection portion 123. The movement of the movable frame 320 with the third blade 110 relative to the main frame 310 in the direction of the blade connecting part 123 is repeated while repeating the above- And is connected to the connection part 123.

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 or scope of the invention. Accordingly, such modifications or variations are intended to fall within the scope of the appended claims.

100: Wind power generator 110: Blade
111: blade root portion 123: blade connection portion
200: Crane 210: Crane cable
300: blade installation jig 310: main frame
311: storage space 320: moving frame
330: blade support unit 331: bracket
333 Vacuum suction plate 340:
350: drive unit 351: rack gear
353: Pinion gear 355: Drive motor
400: blade posture control unit 410: crane cable length control unit
411: driving winch 430: sensing part

Claims (7)

A main frame connected to a plurality of crane cables and lifted and raised in a height direction of the tower;
A moving frame accommodating a blade therein and being moved relative to the main frame in a direction of a blade connecting portion provided in the hub; And
And a blade posture adjusting unit provided on the main frame for adjusting the posture of the blade relative to the blade connecting portion when the moving frame is moved relative to the main frame in the direction of the blade connecting portion,
The blade posture adjusting unit includes:
And a crane cable length adjuster installed in the main frame for adjusting a length of at least one of the plurality of crane cables so as to adjust a tilt of the blade relative to the blade connection part. The method according to claim 1,
Wherein the main frame includes a storage space,
A driving unit coupled to the moving frame, the driving unit being disposed in the receiving space, the driving unit moving the moving frame relative to the main frame; And
Further comprising a plurality of roller portions disposed in the storage space and spaced apart from each other along the moving direction of the moving frame and contacting and supporting the moving frame when the moving frame is moved. 3. The method of claim 2,
The driving unit includes:
A rack gear provided in the storage space and arranged long along the moving direction of the moving frame;
A pinion gear having one side engaged with the rack gear and the other side connected to the moving frame; And
And a drive motor connected to the pinion gear to provide rotational force to the pinion gear. The method of claim 3,
The driving unit includes:
Further comprising a drive motor encoder installed in the drive motor for measuring a rotation speed of the drive motor to detect a relative movement distance of the movable frame with respect to the main frame. The method according to claim 1,
The blade posture adjusting unit includes:
Further comprising a sensing unit installed in the main frame for detecting a tilt of the blade from a slope of the main frame that changes as the movable frame moves relative to the main frame. 6. The method of claim 5,
Wherein the crane cable length adjuster comprises:
A plurality of driving winches spaced apart from each other on the main frame, each of the plurality of crane cables being wound and wound to adjust a length of the plurality of crane cables; And
And a drive winch encoder installed in each of the plurality of drive winches for measuring the number of revolutions of the drive winch to detect a change in length of the crane cable. The method according to claim 1,
Further comprising a plurality of blade support units spaced apart from each other in the moving frame, the blade support units supporting the blades,
The blade supporting unit includes:
A bracket provided inside the moving frame, on which the blade is mounted; And
And a vacuum suction plate installed on the upper surface of the bracket and formed in a shape corresponding to an outer shape of the blade and adapted to suction the outer surface of the blade.

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