KR20140038587A - Wind power generator - Google Patents

Abstract

A wind power generator is disclosed. According to an embodiment of the present invention, the wind power generator includes an air conditioning system which comprises an air inlet on the wind power generator to allow external air to flow into the wind power generator; a fan to take external air through the air inlet; a filter to filter out salt flowing in through the air inlet; an air outlet on the wind power generator to discharge air from the inside to the outside of the wind power generator; and a backflow prevention unit (600) to prevent external air from flowing backwards into the wind power generator through the air outlet.

Description

WIND POWER GENERATOR {WIND POWER GENERATOR}

The present invention relates to a wind power generator.

In recent years, the development of alternative energy to replace petroleum resources is in full swing to solve problems such as global warming and high oil prices. Among these alternative energy sources, wind power generation is actively researching and developing the technology because there is no pollutant emission and there is no possibility of damaging the environment.

The wind generator is installed on the top of the tower installed on the ground, and the hub installed in the nacelle rotates together with the blade by the wind blowing from the front to generate electric energy.

Wind turbines can be installed offshore. In this case, outside air containing salt is introduced into the wind turbine through an air conditioning system of the wind turbine. Salt introduced into the wind power generator has a problem of damaging various devices for operating the wind power generator.

An embodiment of the present invention is to provide a wind turbine configured to block the introduction of salt into the inside.

According to an aspect of the present invention, a wind power generator including an air conditioning system, wherein the air conditioning system, an air inlet provided in the wind generator so that the outside air flows into the inside; A fan that sucks outside air through the air inlet; A filter for filtering salt introduced through the air inlet; An air outlet provided in the wind generator so that air inside is discharged to the outside; And a backflow prevention device for preventing outside air from flowing back to the inside through the air outlet.

The filter may include a HEPA filter.

The backflow prevention device may include a rotating plate rotatable about a hinge axis within the discharge duct in which the air outlet is formed; And a protrusion protruding from an inner side surface of the discharge duct so that a part of the rotary plate is caught during the rotation of the rotary plate, and when the fan operates to flow the air along the discharge duct, the rotary plate is a pure flow of air. Direction to open the discharge duct, and when the fan stops and air flows back along the discharge duct, the rotating plate may be caught by the projection to close the discharge duct.

The cross section of the discharge duct may have a square shape, and the rotating plate may have a square shape.

The air conditioning system further includes an attachment device for attaching the rotating plate to the discharge duct, which rotates in the forward flow direction of air and approaches the inner side of the discharge duct, the attachment device comprising: a magnetic body provided on the rotating plate; And an electromagnet provided in the discharge duct so as to be attachable with the magnetic material, and when the fan is operated, power is supplied to the electromagnet, and when the fan is stopped, power can be cut off to the electromagnet.

The wind turbine is a tower; And a nacelle supported by the tower, wherein the air inlet may be located at one side of the nacelle, and the air outlet may be at least one of the tower and the nacelle.

According to the embodiment of the present invention, when the fan is operated, salt contained in the air flowing through the air inlet is removed by the filter, thereby effectively preventing the inside of the wind turbine from being damaged by the salt.

In addition, when the fan is stopped, the backflow prevention device prevents air from flowing back through the air outlet, thereby preventing the salt contained in the backflowing air from entering the wind turbine, thereby preventing the inside of the wind turbine from being damaged by the salt. Can be effectively prevented.

1 is a view schematically showing a wind power generator according to an embodiment of the present invention,
2 is a partial cutaway view of an inlet duct of an air conditioning system according to an embodiment of the present invention,
3 is a view of the inlet duct of FIG. 2 from an air outlet,
4 is a view showing a part of an air conditioning system according to another embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The present invention is capable of various modifications and various embodiments, and specific embodiments are illustrated in the drawings and described in detail in the detailed description. It is to be understood, however, that the invention is not to be limited to the specific embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. Referring to the accompanying drawings, the same or corresponding components are denoted by the same reference numerals, do.

1 is a view schematically showing a wind power generator according to an embodiment of the present invention. Referring to Figure 1, the wind turbine 10 is installed at sea. The wind turbine 10 includes a tower 100, a nacelle 200, a hub 300, a blade 400, and an air conditioning system 500.

The tower 100 may be supported on the sea bottom. In this case, the support structure 120 may be interposed between the tower 100 and the sea bottom. The tower 100 supported by the support structure 120 may be located on the sea level W. The support structure 120 may comprise a monopile or a jacket.

A nacelle 200 is installed at an upper end of the tower 100. The nacelle 200 includes a nacelle cover 210. The nacelle cover 210 provides a space in which an energy conversion device (not shown) for converting rotational energy of the hub 300 into electrical energy is accommodated. The nacelle cover 210 may be provided as a fiber reinforced plastics material, but is not limited thereto.

A hub 300 is provided in front of the nacelle 200. Hub 300 is coupled to the main shaft (not shown) protruding forward of the nacelle 200, and is connected to the energy conversion device through the main shaft. The hub 300 may be provided with a material having high strength, for example, a metal material.

A plurality of blades 400 are provided and disposed radially about the hub 300. The blade 400 is coupled to the hub 300 by a root. The blades 400 have an airfoil cross-section and are arranged to have a constant angle of attack against wind blowing from the front.

Wind blowing from the front of the wind turbine generator 10 generates a lift force as it passes over the surfaces of the blades 400. The generated lift rotates the blades 400 and the hub 300, and the rotational force is transmitted to the nacelle 200 and converted into electric energy.

A pitch bearing (not shown) may be interposed between the root of the blade 400 and the hub 300. The pitch bearing adjusts the pitch angle of the blade 400 by rotating the blade 400 relative to the hub 300 under the control of a pitch control unit (not shown).

The air conditioning system 500 includes an air inlet 510, a fan 520, a filter 530, an air outlet 540, and a backflow prevention device 600.

The air inlet 510 is provided in the wind generator 10 such that air outside the wind generator 10 flows into the wind generator 10. The air inlet 510 is formed at an outer end of the inlet duct 515 provided in the wind turbine 10. The inlet duct 515 may be disposed in the front portion of the nacelle 200 as shown in FIG. 1, but is not limited thereto.

The fan 520 sucks outside air into the inside through the air inlet 510. When the fan 520 is operated, the outside air is introduced into the wind turbine 10 through the air inlet 510, and the air inside the wind turbine 10 is pushed by the introduced air to the wind through the air outlet 540. Discharged to the outside of the generator (10).

The filter 530 filters the salt introduced through the air inlet 510. The filter 530 may include a HEPA filter 530. The HEPA filter 530 may filter out particles having a size of 0.3 μm or more. Typically, salts having a particle size of 0.5 μm or more are mostly filtered by the HEPA filter 530 in the process of being introduced into the air inlet 510 together with the outside air.

Therefore, the salt inside the wind generator 10 may be effectively prevented from being damaged by the salt introduced into the wind generator 10.

The air outlet 540 is provided in the wind power generator 10 so that air in the wind power generator 10 is discharged to the outside of the wind power generator 10. The air outlet 540 is formed at an outer end of the discharge duct 550 provided in the wind power generator 10. The discharge duct 550 may be disposed at the rear of the nacelle 200 and the lower part of the tower 100 as shown in FIG. 1, but is not limited thereto.

The backflow prevention device 600 prevents the air outside the wind turbine 10 from flowing back into the wind turbine 10 through the air outlet 540.

Figure 2 is a partial cutaway view of the inlet duct of the air conditioning system according to an embodiment of the present invention, Figure 3 is a view of the inlet duct of Figure 2 from the air outlet. 2 and 3, the backflow prevention device 600 includes a rotating plate 610 and a protrusion 620.

The rotating plate 610 is rotatable about the hinge shaft 630 in the discharge duct 550. The discharge duct 550 may be opened and closed while the rotating plate 610 rotates about the hinge shaft 630. The hinge shaft 630 may be located above the inner space of the discharge duct 550. In this case, when the air flows in the discharge duct 550, the rotating plate 610 may be lifted in the flow direction and may return to its original position by its own weight when there is no air flow.

The discharge duct 550 may have a square cross section. And the rotating plate 610 may have a square shape corresponding to the cross-sectional shape of the discharge duct (550). In this case, the rotating plate 610 may smoothly rotate in the discharge duct 550.

A portion of the rotating plate 610 is caught by the protrusion 620 while the rotating plate 610 rotates. The protrusion 620 protrudes from an inner side surface of the discharge duct 550.

The reverse flow prevention device 600 configured as described above opens the discharge duct 550 by rotating the rotating plate 610 in the forward direction when the fan 520 operates to flow the air along the discharge duct 550. When 520 stops and air flows back along the discharge duct 550, the rotating plate 610 is engaged by the protrusion 620 to operate to close the discharge duct 550. For reference, the fan 520 operates to discharge air through the discharge port, and the flow is called a forward flow, and the fan 520 stops and air flows through the discharge port is called a reverse flow.

In the wind turbine generator 10 according to the present embodiment as described above, when the fan 520 is operated, the salt contained in the air flowing through the air inlet 510 is removed by the filter 530, so that the wind power is reduced by the salt. Damage to the inside of the generator 10 can be effectively prevented.

In addition, when the fan 520 is stopped, the backflow prevention device 600 prevents the air from flowing back through the air outlet 540 so that the salt contained in the air flowing back flows into the wind turbine 10. By blocking, the inside of the wind power generator 10 may be effectively prevented by the salt.

4 is a view showing a part of an air conditioning system according to another embodiment of the present invention. Referring to FIG. 4, the air conditioning system 500 ′ according to the present embodiment includes an air inlet (not shown), a fan (not shown), a filter (not shown), an air outlet 540, a backflow prevention device 600, and Attachment device 700.

The air inlet, the fan, the filter, the air outlet 540 and the backflow prevention device 600 according to the present embodiment are the air inlet 510, the fan 520, the filter 530, and the air outlet 540 according to the previous embodiment. ) And the same as the backflow prevention device 600 will be omitted.

The attachment device 700 rotates in the forward direction of the air when the fan 520 operates to flow the air along the discharge duct 550 to discharge the rotary plate 610 that approaches the inner side of the discharge duct 550. 550. When the rotating plate 610 is attached to the discharge duct 550, the flow of air in the forward direction is more smooth.

 The attachment device 700 according to the present embodiment detachably attaches the rotating plate 610 to the inner surface of the discharge duct 550 by using a magnetic force. The attachment device 700 includes a magnetic body 710 and an electromagnet 720. The magnetic body 710 is provided on one surface of the rotating plate 610 and the electromagnet 720 is provided in the discharge duct 550. When power is supplied to the electromagnet 720, the magnetic body 710 may be attached to the electromagnet 720.

Power supplied to the electromagnet 720 is made according to whether the fan 520 is operated. For example, when the fan 520 operates, power is supplied to the electromagnet 720, and when the fan 520 stops, power supplied to the electromagnet 720 is cut off.

When the fan 520 is operated, air flows forward through the discharge duct 550, and the rotating plate 610 rotates in the forward direction to approach the discharge duct 550. At this time, when power is supplied to the electromagnet 720, the rotating plate 610 is attached to the discharge duct 550 by a magnetic force acting between the magnetic body 710 and the electromagnet 720. In this case, the flow of air in the forward direction becomes smoother.

When the fan 520 is stopped, air may flow back along the discharge duct 550. At this time, when the power supply to the electromagnet 720 is cut off, the rotating plate 610 is separated from the discharge duct 550, and returns to the original position to close the discharge duct 550.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, many modifications and changes may be made by those skilled in the art without departing from the spirit and scope of the invention as defined in the appended claims. The present invention can be variously modified and changed by those skilled in the art, and it is also within the scope of the present invention.

10: Wind generator 100: Tower
120: support structure 200: nacelle
210: nacelle cover 300: hub
400: blade 500: air conditioning system
510: air inlet 515: inlet duct
520: fan 530: filter
540: air outlet 550: exhaust duct
600: backflow prevention portion 610: rotating plate
620: protrusion 630: hinge axis
700: attachment device 710: magnetic material
720: electromagnet

Claims (6)

In a wind turbine including an air conditioning system,
The air conditioning system,
An air inlet provided in the wind generator so that outside air flows into the inside;
A fan that sucks outside air through the air inlet;
A filter for filtering salt introduced through the air inlet;
An air outlet provided in the wind generator so that air inside is discharged to the outside; And
And a backflow prevention device for preventing outside air from flowing back to the inside through the air outlet. The method according to claim 1,
The filter includes:
A wind turbine comprising a HEPA filter. The method according to claim 1,
The backflow prevention device,
A rotating plate rotatable about a hinge axis in the discharge duct in which the air outlet is formed; And
And a protrusion protruding from an inner surface of the discharge duct so that a part of the rotating plate is caught in the rotation process of the rotating plate,
When the fan is operated so that air flows along the discharge duct, the rotating plate rotates in the forward direction of air to open the discharge duct, and when the fan stops and the air flows back along the discharge duct, And a wind turbine configured to close the discharge duct by the projection. The method of claim 3,
The cross section of the discharge duct is a rectangular shape,
The rotor has a square shape, a wind turbine. The method of claim 3,
The air conditioning system,
And an attachment device for attaching the rotating plate to the discharge duct by rotating in a forward direction of air and approaching the inner side of the discharge duct.
The attaching device includes:
A magnetic body provided on the rotating plate; And
An electromagnet provided in said discharge duct so as to be attachable with said magnetic material,
When the fan is running, power is supplied to the electromagnet,
When the fan is stopped, the power generator is cut off to the electromagnet. 6. The method according to any one of claims 1 to 5,
tower; And
Further comprising a nacelle supported by the tower,
The air inlet is located on one side of the nacelle,
The air outlet is located in at least one of the tower and the nacelle, the wind turbine.

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