KR100999765B1 - A Wind Power Apparatus - Google Patents

Abstract

The present invention relates to a wind turbine, and the wind turbine according to the present invention includes a nacelle frame in which a main bearing is installed on an outer surface of a front face, a rotor hub provided in front of the nacelle frame, and a rotary hub inserted into an inner side of the main bearing. It includes a connector that is attached to a custom to transmit the rotational torque generated from the rotor hub, a speed increaser connected to the rear of the connector to increase the rotational speed transmitted from the connector, and a generator connected to the rear of the speed reducer to receive the rotational torque . According to the wind power generator according to the present invention, by applying a connection between the hub and the speed increaser, the disassembling process of the speed increaser can be simplified to facilitate maintenance and repair of the speed increaser, and the speed reducer can be separately disassembled / assembled and the overall structure is simplified. Cost reduction is achieved by having a miniaturized / lightened power train.

Frame, Bearing, RotorHub, Connect, Gearhead, Torque

Description

Wind Power Apparatus {A Wind Power Apparatus}

The present invention relates to a wind turbine, and in particular, by applying a connection between the hub and the gearbox to simplify the disassembly process of the gearbox, thereby facilitating maintenance and repair of the gearbox and providing a lighter gearbox. It relates to a wind power generator.

In general, a wind power generator is to rotate a windmill by natural wind and generate power by rotating the shaft of a generator using the rotational force of the windmill.

In general, a power transmission system that transmits rotational torque to a generator using a gearbox in a horizontal wind turbine can be divided into two types.

1 and 2 show the configuration of a conventional wind power generation system.

The most common method is a system with a main shaft 14 as shown in FIG. 1, through which power from the rotor system 11 is transmitted to the speed increaser 15 attached to the nacelle frame 17. The main shaft 14 is supported by two bearings 13, which are fixed to the nacelle frame 17 to support the load transmitted from the rotor system 11, and increase the rotational torque of the gearbox. It plays a role of delivering to 15). The power transmitted through the main shaft 14 is transmitted to the generator 16 at the rear end of the speed increaser 15 by changing the rotational speed and the rotation torque from the initial state while passing through the speed increaser 15.

In the case of the conventional wind turbine generator having the power transmission system described above, the speed increaser 15 and the generator 16 may be separated and assembled separately from the main shaft 14. However, in addition to the rotational torque transmitted from the rotor system 11, thrust (wind component force), moment, and the like are transmitted and reported as a cause of damage to the accelerator 15. In order to solve this problem, it is necessary to have rigidity with respect to the above-described loads, which causes a problem that the speed increaser 15 is gradually enlarged and heavy.

Alternatively, as in the case of FIG. 2, the integrated system directly connects the rear end of the hub 22 and the front end of the speed reducer 25 of the rotor system without a main shaft. The present system manufactures an integrated gearbox 25 including a main bearing 23 and fixes the integrated gearbox 25 to the nacelle frame 27. In this case, one bearing 23 is generally used between the hub 22 and the speed increaser 25 of the rotor system, and a double row tapered roller bearing, a three-row roller bearing, or the like is used depending on the load condition.

In the case of the conventional wind power generator having the above-described power transmission system, unlike the former, the speed increaser 25 has the advantage of being able to be miniaturized / lightened, but the connection between the hub 22 and the speed increaser 25 input stage Complicated, there is a disadvantage that the disassembly / assembly of the speed increaser 25 itself is impossible due to the fastening conditions with the hub 22 and the nacelle frame 27. For this reason, it is troublesome to separate the rotor system and the entire nacelle frame 27 from the tower on which the wind turbine is installed by mobilizing a large crane necessary for the installation of the wind power generation system during disassembly / assembly for maintenance / repair of the speed increaser 25. There is a problem that follows.

The present invention has been made in view of the above, by applying a connection between the hub and the gearbox to simplify the disassembly process of the gearbox to facilitate the maintenance and repair of the gearbox and to disassemble / assemble the gearbox separately. The overall structure is simplified to provide a wind turbine generator with a miniaturized / lightened power train.

Wind turbine generator according to the present invention for achieving the above object is a nacelle frame is installed in the main bearing on the outer surface of the front; A rotor hub provided and rotated in front of the nacelle frame; A connector that is fitted to the inner side of the main bearing to transmit rotational torque generated from the rotor hub; An increaser connected to the rear of the connector to increase the rotational speed transmitted from the connector; It is characterized in that it comprises a; generator connected to the rear of the speed increaser receives a rotation torque.

The connector may include a first connector fitted to the main bearing inside the nacelle frame and connected to the accelerator cover; And a second connector fitted to the main bearing outside the nacelle frame and connected to the rotor hub.

It is preferable to further include an anti-torque device attached to the side of the speed reducer to prevent rotation of the speed increaser itself.

The anti-torque device is preferably made of synthetic resin, link structure, or hydraulically operated.

In addition, it is preferable to further include a rotation preventing member provided in the insertion groove formed in the first connector to prevent the rotation of the rotor hub.

It is preferable that one side of the speed increaser is further provided with a brake for emergency braking of the rotor hub.

The speed increaser may be configured to convert a rotation speed by using a differential gear.

The generator is preferably a permanent magnet synchronous generator or a double excitation induction generator.

Coupling is further provided between the output shaft of the speed increaser and the input shaft of the generator.

It is preferable to further include a dustproof support provided on the lower portion of the generator to absorb the vibration according to the rotational movement of the generator.

It is preferable to further include a dustproof device provided between the nacelle frame and the support structure to absorb vibration according to the rotational movement of the generator.

According to the wind power generator according to the present invention, by applying a connection between the hub and the speed increaser, the disassembling process of the speed increaser can be simplified to facilitate maintenance and repair of the speed increaser, and the speed reducer can be separately disassembled / assembled and the overall structure is simplified. Cost reduction is achieved by having a miniaturized / lightened power train.

The above objects, features and other advantages of the present invention will become more apparent by describing the preferred embodiments of the present invention in detail with reference to the accompanying drawings. Hereinafter, a wind turbine generator according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

3 is a configuration diagram of a wind turbine generator according to an embodiment of the present invention, Figure 4 is a detailed side cross-sectional view of the wind turbine generator of FIG.

3 and 4, the wind turbine generator according to the present invention is provided in the front of the nacelle frame 180, the nacelle frame 180, the rotor is installed on the outer surface of the main bearing 140, the rotor that rotates The hubs 110 and the connectors 130 and 131 are fitted to the inner side of the main bearing 140 and are connected to the rear of the connectors 130 and 131 to transmit the rotational torque generated from the rotor hub 110. An increaser 150 for increasing the rotational speed transmitted from the generator, the generator 170 is connected to the rear of the increaser 150 receives the rotation torque.

The nacelle frame 180 is rotatably installed on the top of the tower, and the main bearing 140 is mounted at the front, and serves to rotatably support the rotor hub 110 installed at the front.

The rotor hub 110 is a blade is assembled on the outside, while the blade is assembled to the rotor hub 110 is rotated by the wind while the rotor hub 110 is rotated at the same time the rotational force is transmitted to the speed increaser 150.

In the present invention, the connectors 130 and 131 refer to components that connect the gearbox 150 and the rotor hub 110.

The connector is fitted to the main bearing 140 inside the nacelle frame 180 and is fitted to the main bearing 140 outside the nacelle frame 180 and the first connector 130 connected to the accelerator cover. It is composed of a second connector 131 connected to the rotor hub (110). The first connector 130 and the second connector 131 serve to transmit the rotation torque generated from the rotor hub 110 to the speed increaser 150. Due to this configuration, when the rotor hub 110 rotates, the second connector 131 and the first connector 130 also rotate, and the speed reducer cover also rotates.

The connectors 130 and 131 serve to apply a suitable load to the main bearing 140, wherein the applied load is called preload. The preload is a load derived in the design of the wind turbine, and plays an important role in increasing the fatigue life of the entire structure as well as the fatigue life of the main bearing 140 itself. The connectors 130 and 131 are assembled through an interference fit in the form of rotating in contact with the inner surface of the main bearing 140, and adjusts the preload amount by adjusting the tightening strength of the bolt.

The speed increaser 150 serves to transmit the input rotation speed to the outside after increasing the input rotational speed. 3 and 4, the cover of the speed increaser 150 rotates according to the rotation of the connectors 130 and 131, thereby increasing the rotation speed in the speed increaser 150, thereby increasing the speed of the speed increaser ( Transfer to the output shaft 153 formed on one side of 150.

Gearhead 150 can use a differential gear that can convert the rotational speed over three stages, by applying four to eight planetary gears in the first and second stages to achieve a smooth load distribution and structural stability A three-speed gearbox with a compact planetary gearbox can be used.

In this case, only the cover of the speed increaser 150 rotates and the speed increaser 150 itself does not rotate. For this purpose, the anti-torque device 155 may be provided on the side of the speed increaser 150.

The anti-torque device 155 is a device for reducing torque applied to the speed increaser 150 itself, and a material and a structure capable of absorbing the rotational force of the speed increaser 150 cover are required.

To this end, in the present invention, the anti-torque device 155 may absorb a shock by using a synthetic resin material, and the anti-torque device 155 may not be separated even if the displacement of the accelerator 150 is changed by using a link structure. In particular, it can be hydraulically operated so that the anti-torque device 155 can be attached to the speed increaser 150 by as much external force as possible.

In the entire system, the anti-torque device 155 serves to effectively transmit the rotational torque transmitted from the rotor hub 110 to the generator 170 via the speed increaser 150.

In the wind turbine generator according to the present invention may be additionally applied by changing the design to have a separate input shaft (not shown) for proper load distribution.

The brake unit 165 may be further provided on one surface of the speed increaser 150 toward the generator 170 for emergency braking of the rotor hub 110 during an operation of the wind power generator. The brake unit 165 may be formed of a synthetic resin or a material resistant to friction as a device for sudden braking.

Generator 170 is a device for producing electricity, the generator 170 in the present invention is provided with an input shaft 163 to be connected to the output shaft 153 provided in the speed increaser 150, the input shaft 163 is an output shaft At the same time as the rotation of the 153 is rotated, the electricity is produced inside the generator 170 in which the input shaft 163 is installed.

As the generator 170, a permanent magnet synchronous generator or a double excitation induction generator may be used.

A coupling 160 may be further provided between the output shaft 153 of the speed increaser 150 and the input shaft 163 of the generator 170 to effectively transmit the rotational force.

Referring to FIG. 4, a pedestal 195 may be further provided below the generator 170 to absorb vibrations of the generator 170, and the generator 170 may include the rotor hub 110 and the speed increaser 150. The support structure 190 may be installed below the generator 170 to be installed horizontally. The pedestal 195 also serves to prevent the vibration caused by the rotational movement of the generator 170 is transmitted to the nacelle frame 180 or the tower. The pedestal 195 in FIG. 4 is installed on the lower surface of the generator 170 to absorb shocks.

5 is a detailed side cross-sectional view illustrating a state in which a dustproof support 185 is added to the wind power generator of FIG. 4, and FIG. 6 illustrates a state in which the support structure 190 is changed to the wind power generator of FIG. 4. It is a detailed side sectional drawing, and FIG. 7 is a detailed side sectional view which shows the state which added the dustproof apparatus 195 with respect to the wind power generator of FIG.

In the case of FIG. 5, in the wind power generator of FIG. 4, the pedestal 195 is removed, and the generator 170 and the dustproof support 185 having a sandwich plate structure are provided between the support structure 190 and the generator 170. ) Can be fixedly attached.

In the case of FIG. 6, in the wind power generator of FIG. 4, the pedestal 195 may be removed and the support structure 190 may be designed as a sandwich plate structure to attach the generator 170 to the support structure 190.

In the case of FIG. 7, the vibration isolator between the support structure 190 and the nacelle frame 180 when the pedestal 195 is removed and the support structure 190 is fixed to the nacelle frame 180 in the wind power generator of FIG. 4. 195 may be provided to secure the generator 170 to the support structure 190.

5 to 7, the dustproof part 185, the support structure 190, and the dustproof device 195 play an important role for safety because they play a role of absorbing vibration generated inside the wind turbine.

8 is a configuration diagram of a wind turbine generator according to another embodiment of the present invention. The wind power generator according to FIG. 8 includes a nacelle frame 280 in which a main bearing 240 is installed on an outer surface of the front surface, a rotor hub 210 rotating in front of the nacelle frame 280, and a main bearing 240. An increaser that is attached to the inner side of the connector and connected to the rear of the connectors 230 and 231 to transmit the rotational torque generated from the rotor hub 210 and to increase the rotational speed transmitted from the connectors 230 and 231. 250, the generator 270 is connected to the rear of the speed increaser 250 to receive the rotation torque.

The connector is fitted to the main bearing 240 inside the nacelle frame 280 and fitted to the main bearing 240 outside the nacelle frame 280 and the first connector 230 connected to the increaser 250 cover. The second connector 231 is configured to be attached to the rotor hub 210. The first connector 230 and the second connector 231 serve to transmit the rotational torque generated from the rotor hub 210 to the speed increaser 250.

An insertion groove 237 is formed in the first connector 230 of the wind turbine shown in FIG. 8, and the insertion groove 237 for controlling the rotor hub 210 when it is necessary to prevent rotation of the rotor hub 210. The anti-rotation member 235 can be installed on the.

Specifically, in comparison with the wind turbine shown in FIG. 4, the wind turbine of FIG. 8 includes an output shaft 253 and a generator 270 behind the speed increaser 250 to prevent rotation of the rotor hub 210. The brake unit 265 is installed between the front input shafts 263. When disassembling / assembling for maintenance / repair of the speed increaser 250, the brake unit 265 normally prevents the rotation of the rotor hub 210. It becomes impossible. Therefore, in addition to the brake unit 265, the rotation preventing member 235 for preventing the rotation of a separate rotor hub 210 is required. When the anti-rotation member 235 is used, rotation of the rotor hub 210 may be prevented during independent maintenance / repair of all components of the power transmission system of the wind turbine.

In addition, when manufacturing a larger capacity wind turbine, if it is impossible to rotate the gearbox 250 cover due to supply and demand of bearings, an additional flat plate shaft 225 is installed at the rear of the second connector 231 and used. To transmit the rotational torque to the increaser 250.

The wind power generator described above is mainly installed and operated at sea, and a separate cooling device (not shown) is further provided so that the air flowing inside the nacelle frame does not come into contact with the outside air and the inside air flows and is cooled in a closed circuit. Of course, it can also be provided.

According to the wind turbine generator according to the present invention, a connector is provided between the rotor hub and the speed increaser to enable separate disassembly / assembly, thereby improving durability, reliability, and convenience of maintenance / repair of the product. In addition, by connecting the rotor hub and the speed increaser directly by using a connector, the main shaft, which is the input terminal of the speed increaser, disappears, thereby simplifying the nacelle frame, reducing the weight, and providing a lighter speed increaser. This will of course reduce the production cost of the wind turbine.

While preferred embodiments of the present invention have been described above, the present invention is not limited to the above-described specific embodiments. That is, those skilled in the art to which the present invention pertains can make many changes and modifications to the present invention without departing from the spirit and scope of the appended claims, and all such appropriate changes and modifications are possible. Equivalents should be considered to be within the scope of the present invention.

1 is a configuration diagram of a conventional wind power generation system,

2 is a configuration diagram of another conventional wind power generation system,

3 is a configuration diagram of a wind turbine generator according to an embodiment of the present invention;

4 is a detailed side cross-sectional view of the wind power generator of FIG. 3;

FIG. 5 is a detailed side cross-sectional view illustrating a state in which a dustproof support 185 is added to the wind power generator of FIG. 4.

6 is a detailed side cross-sectional view showing a state in which the support structure 190 is changed with respect to the wind power generator of FIG.

7 is a detailed side cross-sectional view showing a state in which the vibration isolator 195 is added to the wind power generator of FIG.

8 is a configuration diagram of a wind turbine generator according to another embodiment of the present invention.

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

110, 210: Rotor hub 130, 230: 1st connector

131, 231: Second connector 140, 240: Main bearing

150, 250: Gearheads 153, 253: Output shaft

160, 260: coupling 163, 263: input shaft

170, 270: generator 180, 280: nacelle frame

190: support structure 195: pedestal

225: flat plate shaft 235: rotation preventing member

237: Inserting Groove

Claims (12)

Nacelle frame in which the main bearing is installed on the outer surface of the front surface; A rotor hub provided and rotated in front of the nacelle frame; A connector that is fitted to the inner side of the main bearing to transmit rotational torque generated from the rotor hub; A speed reducer connected to the rear of the connector and including an speed increaser cover which rotates according to the rotation of the connector, the speed increaser increasing the rotation speed transmitted from the connector; And And a generator connected to the rear of the speed increaser to receive a rotation torque. The connector, A first connector fitted to the main bearing inside the nacelle frame and connected to the speed reducer cover; And And a second connector fitted to the main bearing at an outer side of the nacelle frame and connected to the rotor hub. Wind power generation device. delete The method of claim 1, And an anti-torque device attached to the side of the speed increaser to prevent rotation of the speed increaser itself. The method of claim 3, wherein The anti-torque device is a wind turbine, characterized in that the synthetic resin material. The method of claim 3, wherein The anti-torque device is a wind turbine generator, characterized in that the link structure, or hydraulically operated. The method of claim 1, Insertion grooves are formed in the first connector, The insertion groove is provided with a rotation preventing member that can prevent the rotation of the rotor hub, Wind power generation device. The method of claim 1, The wind turbine generator, characterized in that one side of the speed increaser is further provided with a brake for emergency braking of the rotor hub. The method of claim 1, The speed increaser is a wind turbine generator, characterized in that for converting the rotational speed by using a differential gear. The method of claim 1, The generator is a wind power generator, characterized in that the permanent magnet synchronous generator or dual excitation induction generator. The method of claim 1, And a coupling further provided between the output shaft of the speed increaser and the input shaft of the generator. The method of claim 1, The wind turbine generator, characterized in that the lower portion of the generator further comprises a dustproof support for absorbing vibrations in accordance with the rotational movement of the generator. The method of claim 1, And a dustproof device provided between the nacelle frame and the support structure to absorb vibrations according to the rotational movement of the generator.

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