KR20090072285A - Earth device for wind turbine - Google Patents

Abstract

A grounding apparatus of an aero-generator is provided to contact lightning stroke current and shaft current to the ground through a sliding contactor. A grounding apparatus of an aero-generator comprises a rotor blade, a set-up gear(10) which is connected to the shaft of the rotor blade, a power generator(20) which is connected to the set-up gear, a nacelle wherein the rotor blade is installed in the front end thereof and the set-up gear and power generator are formed, a tower wherein the nacelle is installed on the top thereof and which is anchored to the surface, and a sliding contactor(30) which is installed in the principal axis brake disk between the power generator and the set-up gear.

Description

Earth device for wind turbine

TECHNICAL FIELD The present invention relates to a wind turbine, and more particularly, to a grounding apparatus of a wind turbine for protecting a device from lightning and axial currents.

New / renewable energy is designated as non-petroleum, coal, natural gas and nuclear energy.

New energy is divided into three sectors: fuel cell, coal liquefaction / gasification, and hydrogen energy. Renewable energy is divided into eight sectors: solar heat, photovoltaic power generation, biomass, wind power, hydropower, geothermal, marine energy, and waste energy.

Among these, wind power has the great advantage of infinite capacity, pollution-free, eco-friendly and clean energy. Wind power generation can be obtained from aircraft systems engineering with the theoretical and technical foundations, and development costs are reduced, and operation and management are relatively simple. Easy, unmanned and automated operation, many systems are already installed and operated worldwide.

Wind power generation is mainly done by tower-type horizontal axis wind turbines. Before 2000, the mainstream was less than 750kW, but after 2003, 1.5 ~ 2.5MW class became the mainstream, and 6MW test model with a rotor diameter of 125m is also tested. It is rapidly increasing in size.

The wind turbine is composed of a rotor blade, a nussel and a tower. Inside the nussel is an accelerator, a generator, and controls, and the nussel is rotatably mounted on the upper flange of the tower.

In addition, the yawing system is applied to adjust the direction of the rotor blade according to the wind direction, and the pitch angle control system for adjusting the pitch angle of the rotor blade is also introduced.

On the other hand, wind turbines are mainly installed on mountain slopes or beaches, so there is a high risk of lightning exposure.

Lightning strikes occur mainly on the rotor blades, lightning rods installed on the upper part of the nussel, and mesh covers of the nussel, all of which are electrically connected to the nussel frame, and the nussel frame is grounded to the ground through a tower. To prevent damage to the device.

On the other hand, the double excitation induction generator is widely used as a generator. This type of generator includes an inductor and a power converter, and the axial current generated by the power converter in the induction shaft of the inductor causes damage to the equipment as well as equipment instability.

Therefore, in order to prevent this, expensive insulating bearings or insulating housings are applied.

In addition, in order to prevent the damage caused by the lightning strike of the generator is installed an insulating coupling between the gearbox and the generator.

As described above, in order to solve the problem of damage to the generator due to lightning and axial current, there is a general irrationality that merely considers the generator itself without considering the system of the entire wind power generator.

In addition, the insulating components such as the insulating bearing, the insulating housing and the insulating coupling are expensive compared to the general components, thereby increasing the installation cost.

Accordingly, the present invention has been made in view of the above, and provides a grounding device for a wind power generator capable of protecting a system from lightning and axial current without using expensive insulating bearings, insulating housings, and insulating couplings. The purpose is.

The present invention for achieving the above object,

A rotor blade, a speed reducer connected to the shaft of the rotor blades, a generator connected to the speed reducer, a nucleus in which the rotor blades are installed at the tip, and the speed reducer and the generator are built-in, and the nussel is installed on the top and fixed to the ground. In the tower wind turbine,

A sliding contactor is installed in the spindle brake disk between the speed increaser and the generator, and the sliding contactor is grounded to the nussel frame.

The sliding contactor includes a brush holder having an insertion hole, a brush inserted into the insertion hole of the brush holder and a protruding portion protruding from the insertion hole in contact with the brake disc, a support on which the brush holder is fixed, and the brush and support It includes a wire connecting the.

The brush holder is characterized in that the spring is provided to push the brush.

The wire is connected to a ground bolt fastened to the support.

A tab hole is formed in the brush holder and the support, and a fixing bolt is fastened to the tab hole, and the brush holder is fixed to the support.

The support is bolted to a support made of an insulating material, and the bolt is grounded to the nussel frame via a wire.

As described above, the sliding contactor connected to the nussel frame is installed in the main shaft sub-lake disk between the speed increaser and the generator, so that the lightning current flowing into the generator through the speed increaser in the rotor blades and the axial current generated in the generator main shaft are received through the sliding contactor. And by grounding through the tower to the ground has the effect that it is possible to protect the device from lightning current and axial current without using a large number of expensive insulating components.

Hereinafter, the present invention will be described with reference to the accompanying drawings.

1 is a view showing a part of the speed increaser and the generator, and FIG. 2 is an enlarged view of the main shaft brake part to which the present invention is applied, and the speed increaser 10 and the generator 20 are installed inside the nussel.

The speed increaser 10 serves to increase the rotational force and thrust transmitted from the rotor as a gear device to transmit the power to the generator 20.

The increaser 10 is made of a structure having a first stage planetary two-stage helical gear train because the appearance is difficult and maintenance is difficult when the number of planetary gear trains increases.

The generator 20 is a three-phase induction generator for implementing a variable speed system, the stator is directly connected to the system, and the rotor is a dual excitation induction generator that operates in conjunction with the system through an inverter.

The generator 20 is provided with a spindle brake device to adjust or stop the rotational speed of the spindle.

The spindle brake device includes a brake disc 22 provided on the spindle 21, a friction material 23 provided on both sides of the brake disc 22, and the friction material 23 of the brake disc 22 by hydraulic pressure. And a hydraulic device 24 for press tightly contacting the surface.

Therefore, when the hydraulic device 24 is operated, both friction materials 23 are brought into close contact with the brake disc 22 and rubbed, thereby reducing the rotational speed of the main shaft 21.

Therefore, by controlling the motor operation of the pump for supplying the hydraulic pressure to the hydraulic device 24, it is possible to control the rotational speed of the generator spindle 21 by adjusting the strength of the friction braking force.

In the above structure, the present invention, the sliding contactor 30 is installed on the brake disk 22 of the main shaft 21, the sliding contactor 30 is connected to the nussel frame (electrically connected, ground means Will be

The sliding contactor 30 is bolted to the support 40 installed on the bottom surface of the nussel as shown in Figure 2 is installed to contact the lower end of the brake disk 22, or mounted on the side wall of the peripheral device as shown in FIG. Bolted to the support 41 can be installed to contact the side of the brake disk (22).

In any case, the supports 40 and 41 are made of an insulating material such as reinforced plastic and wood. In the case of a metal material, the shell may be coated with rubber or the like.

Grounding is achieved by connecting the wire 50 to bolts that fix the sliding contactor 30 to the supports 40 and 41, and the wire 50 to the nussel frame.

As shown in FIG. 4, the sliding contactor 30 includes a brush holder 31 through which a rectangular insertion hole 31a is formed, and a brush inserted into the insertion hole 31a of the brush holder 31. (32), a support (33) to which the brush holder (31) is fixed, and a wire (34) connecting the rear end of the brush (32) and the support (33).

The support 33 has a cross section of a substantially "c" (diff) shape.

Tab holes are formed in the brush holder 32 and the support 33 so that the brush holder 31 is mounted on one side of the support 33 using the fixing bolt 35.

In addition, a simple through hole is formed at the end of the support 33 of the portion where the brush holder 31 is mounted so that the ground bolt 36 is inserted and the nut is fastened and fixed to the end thereof.

The wire 34 connected to the brush 32 is connected to the ground bolt 36.

Two bolt holes 33a are formed at the other side of the support 33 to allow bolts to be fastened to the supports 40 and 41, and one of the bolts is connected to the wire of the nussel frame 50. ) Is connected.

On the other hand, the brush holder 31 is provided with a spring 35, the spring 35 pushes the rear end of the brush 32 so that the front end of the brush 32 protrudes out of the insertion hole 31a. It works.

As described above, according to the present invention, the ground path is formed through the main shaft 21 connecting the speed increaser 10 and the generator 20.

That is, the brush 32 of the sliding contactor 30 is constantly in contact with the spring 35 by the brake disc 22 formed integrally with the main shaft 21, and the brush 32 is in contact with the wire 34. It is connected to the support 33 through, the support 34 is connected to the nussel frame through the bolt and wire 50. Since the Nerssel frame is grounded through the tower, a ground path from the rotor blades to the ground via the gearbox 10 is formed.

In addition, a ground path from the main shaft 21 of the generator 20 to the ground is simultaneously formed.

Therefore, since the lightning current and the axial current are grounded from the spindle brake disk 22 to the ground through the sliding contactor 30, the nussel frame and the tower, the damage of the device by the lightning current and the axial current is prevented, so that the whole wind power generation system Normal operation of is possible.

Since the brush 32 is always in contact with the brake disc 22, wear occurs. The elastic force of the spring 35 pushes the brush 32, thereby compensating the amount of wear and maintaining a continuous contact state. .

On the other hand, by using the sliding contactor 30 as described above, by simply making a ground, it is not necessary to use expensive components such as insulation bearings and insulation housings and insulation couplings for generator protection as in the prior art, thereby reducing costs. It works.

1 is a view showing a part of the gearbox and the generator,

2 is an enlarged view of a main brake portion to which the present invention is applied;

3 is another embodiment of the present invention;

4 is a front view and a bottom view of a sliding contactor which is a main part of the present invention.

* Description of the symbols for the main parts of the drawings *

10: gearbox 20: generator

21: spindle 22: brake disc

23: friction material 24: hydraulic device

30: sliding contactor 31: brush holder

32: brush 33: support

34: wire 35: spring

40,41: Support 50: Wire

Claims (6)

A rotor blade, a speed reducer connected to the shaft of the rotor blades, a generator connected to the speed reducer, a nucleus in which the rotor blades are installed at the tip, and the speed reducer and the generator are built-in, and the nussel is installed on the top and fixed to the ground. In the tower wind turbine, A sliding contactor is installed in the spindle brake disk between the speed increaser and the generator, and the sliding contactor is grounded to the nussel frame. The brush holder of claim 1, wherein the sliding contactor includes a brush holder having an insertion hole, a brush inserted into an insertion hole of the brush holder and a protruding portion protruding from the insertion hole in contact with the brake disk, and a support on which the brush holder is fixed. And a wire connecting the brush and the support. The grounding apparatus of claim 2, wherein the brush holder is provided with a spring for pushing the brush. The grounding device of claim 2, wherein the wire is connected to a ground bolt fastened to a support. The grounding device of claim 2, wherein a tab hole is formed in the brush holder and the support, and a fixing bolt is fastened to the tab hole, and the brush holder is fixed to the support. The grounding apparatus of claim 2, wherein the support is bolt-mounted to a support made of an insulating material, and the bolt is grounded to a nussel frame through a wire.

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