KR101434656B1 - Wind energy plant - Google Patents

Abstract

The wind turbine of the present invention includes a propeller rotating by wind, a nacelle for converting the rotational force of the propeller into electric power, a tower for supporting the propeller or the nacelle, and a propeller for supporting the nacelle, By including the RAP layer (Radar Absorbing Paint layer) which is applied to at least one and absorbs radio waves, the RCS of the wind power generator can be reliably lowered.

Description

WIND ENERGY PLANT

TECHNICAL FIELD [0001] The present invention relates to a wind power generator and a radio wave absorbing paint, and relates to a wind power generator with a low RCS and a radio wave absorbing coating applied to the wind power generator.

Wind turbines are widely seen as a means of generating energy in an eco-friendly manner.

The wind turbine takes the form of a tower erected and a propeller mounted on the end of the tower. This type of wind turbine reflects and interferes with various radio waves.

Such a wind turbine that affects radio waves has a problem in that it is detected by a radar used for industrial purpose or military purpose, thereby causing malfunction of radar. To solve this problem, it is necessary to lower the RCS (Radar Cross Section) of the wind power generator.

Korean Patent Laid-Open Publication No. 2002-0086606 discloses a wind turbine having a tower and a propeller, but a method of lowering the RCS is not proposed.

Korean Patent Publication No. 2002-0086606

An object of the present invention is to provide a wind power generator having a low RCS and a radio wave absorbing coating applied to the wind power generator.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are not intended to limit the invention to the precise forms disclosed. Other objects, which will be apparent to those skilled in the art, It will be possible.

The wind turbine of the present invention includes a propeller rotating by wind, a nacelle for converting the rotational force of the propeller into electric power, a tower for supporting the propeller or the nacelle, and a propeller for supporting the nacelle, And a RAP layer (Radar Absorbing Paint layer) that is applied to at least one and absorbs radio waves.

A radio wave absorbing paint of the present invention is applied to at least a part of a wind power generator and forms a RAP layer absorbing radio waves, and a radio wave absorbing material for reducing the RCS of the wind power generator, A binder for bonding and a solvent for dissolving the radio wave absorbing material.

The wind power generator of the present invention can reliably reduce RCS by including a RAP layer applied to a propeller, a nacelle, and a tower. Accordingly, the wind turbine generator of the present invention may not be detected by the radar.

1 is a schematic view showing a wind turbine generator of the present invention.
2 is a sectional view showing a blade of the wind power generator of the present invention.
3 is a schematic view showing a state in which the wind turbine generator is installed in the sea.
4 is a graph showing the RCS when RCS and RAP layers are formed when no RAP layer is formed.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The sizes and shapes of the components shown in the drawings may be exaggerated for clarity and convenience. In addition, terms defined in consideration of the configuration and operation of the present invention may be changed according to the intention or custom of the user, the operator. Definitions of these terms should be based on the content of this specification.

FIG. 1 is a schematic view showing a wind power generator of the present invention, and FIG. 2 is a sectional view showing a blade 111 of the wind power generator of the present invention. Fig. 2 shows a state in which A-A 'in Fig. 1 is cut.

The wind turbine generator shown in FIG. 1 includes a propeller 110 that rotates by wind, a nacelle 130 that converts rotational force of the propeller 110 into electric power, a propeller 110, or a nacelle 130 And a tower 150 (tower).

The wind turbine generator has a tower 150 for supporting the propeller 110 rotated by the wind, so that the wind turbine generator is protruded from the installation surface as a whole. At this time, the installation surface may be the surface of the ground, the surface of the steel, or the surface of the sea.

As described above, the wind power generator projected from the installation surface affects the radio waves. In particular, since the tower 150 supporting the propeller 110 is made of metal to provide reliable strength, the influence on the propagation is increased. Since the propeller 110 is made of FRP (glass fiber reinforced plastic) in consideration of the weight and the like, the influence on the radio wave is weakened, but the propeller 110 is large, It is hard to do.

Wind turbines that affect radio waves may interfere with the normal operation of the radar and adversely affect the laser operation policy.

3 is a schematic view showing a state in which the wind turbine generator is installed in the sea.

3, a plurality of wind power generators 100 are installed in the sea, and a radar 200 is installed on land. At this time, the wind turbine can be located within the coverage of the radar. In this case, if the wind turbine is always detected on the radar, it may be difficult to detect the object that has escaped to the vicinity of the wind turbine. In addition, due to the mirroring effect due to the characteristic problem of the radar, an object may be detected on the radar despite the absence of the actual object. This problem can be solved by lowering the RCS (Radar Cross Section) of the wind turbine.

The Radar Cross Section (RCS) is the plane area defined to reflect the amount of reflections of the object when the radio waves emitted from the radar are reflected back to the object. If the RCS is small, the radar will not detect the object. Therefore, when the RCS of the wind power generator is lowered, the wind power generator is not displayed on the radar. As a result, lowering the RCS of the wind turbine allows normal operation of the radar.

To this end, the wind power generator of the present invention includes a RAP layer (Radar Absorbing Paint layer) 170.

The RAP layer 170 is applied to at least one of the propeller 110, the nacelle 130 and the tower 150 and can remove or lower the RCS of the wind power generator by absorbing the radio waves.

The propeller 110 has a nosecone 113 forming a rotation axis and a wing 111 extending radially with respect to the rotation axis of the nosecone 113. The RCS of the wing 111 is 20%, the RCS of the nacelle 130 is 4%, the RCS of the tower 150 is 1%, the RCS of the wing 111 is 20% Is about 75%.

The RAP layer 170 may be formed on both the propeller 110, the nacelle 130 and the tower 150 constituting the wind power generator in order to reliably lower the RCS of the wind power generator. By including materials that absorb radio waves, however, the RAP layer 170 is very heavy and expensive compared to conventional paints. However, if the RAP layer 170 is formed on all the parts of the wind turbine generator, the weight of the RAP layer 170 may reach several tons.

Since the propeller 110 must be easily rotated by the wind, the lighter the wing 111 of the propeller 110, the better. Therefore, when the RAP layer 170 is formed on the wing 111 of the propeller 110, the thickness of the RAP layer 170, the formation position, and the like must be determined after carefully comparing the power generation purpose and the RCS reduction purpose.

For example, the RAP layer 170 may be applied to a curved surface or leading edge of each wing 111 constituting the propeller 110. This is because the RCS of the wing 111 is mostly generated from the curved surface portion or the leading edge portion. The curved surface portion of the blade 111 may be a portion where the shortest line connecting the arbitrary first point and the arbitrary second point on the surface of the blade 111 is curved.

The RAP layer 170 absorbs radio waves and can convert the absorbed radio waves into thermal energy, thereby destroying radio waves. At this time, the heat energy generated in the RAP layer 170 can be diverted to the atmosphere. In other words, the RAP layer 170 of the present invention directly extinguishes the absorbed radio wave without transmitting it to other objects such as the ground, and radiates heat energy generated in the process of dissipating radio waves to the contacted atmosphere without transferring it to other objects.

The RAP layer 170, which is possible due to the weight of the RAP layer 170 and the production cost, may be advantageously applied to a small area of the wind power generator. Therefore, the wind power generator of the present invention can form the RAP layer 170 only at the portion where the RCS of the propeller 110, the nacelle 130, and the tower 150 is equal to or greater than the predetermined value. The set value can be appropriately determined according to the characteristics of the rider on which the wind power generator is detected.

It is preferable that the RCS of the portion where the RAP layer 170 is applied by the wind power generator is lower than the RCS of the portion where the RAP layer 170 is excluded by 8 dBsm or more. These characteristics can lower the RCS appropriately and reliably reduce the effects on other radio waves.

In order to effectively lower the RCS for the radar, the RAP layer 170 can primarily absorb radio waves of a specific frequency. The specific frequency may include at least one of an L-band frequency of 1.0 to 2.0 GHz, an S-band frequency of 2.0 to 4.0 GHz, and an X-band frequency of 8.0 to 12.0 GHz mainly used in a radar. It is advantageous that the RCS of the region where the RAP layer 170 is applied for a certain frequency is lower than the RCS of the region where the RAP layer 170 is excluded by 20 dBsm or more.

4 is a graph showing RCS when RCS layer 170 is formed and RCS layer 170 is formed.

As a result, it was found that a difference of more than 8dBsm was observed depending on whether RAP layer 170 was formed or not, and a difference of more than 20dBsm was observed depending on presence or absence of RAP layer 170 in 11.0 ~ 11.2GHz, .

The RAP layer 170 may comprise a radio wave absorbing coating.

The radio wave absorbing coating material may include a radio wave absorbing material, a binder, and a solvent.

The radio wave absorbing material is applied to at least a portion of the wind power generator and forms a RAP layer 170 that absorbs radio waves and can reduce the RCS of the wind power generator.

The binder may adhere the radio wave absorbing material to the wind power generator. In addition, the binder determines the strength of the RAP layer 170.

Plastics, which is one of the materials of the wind power generation equipment which is difficult to apply to the RAP layer 170, may range from ABS, PS, PP, PPO, FRP to SMC and BMC, The nacelle 130 can be formed.

The binder should be designed to match the properties of this material and should provide the physical and chemical stability of the RAP layer 170. Otherwise, the surface is weakened by heat, and the surface is damaged from the solvent in the electromagnetic wave absorptive paint, causing cracking and crazing phenomenon, and the RAP layer 170 is deteriorated to cause peeling. Particularly, in the case of conductive electromagnetic wave absorbing material, since a large amount of metallic filler having a large specific gravity is contained, when the distance between the spray gun and the object (wind power generating device) is long, the pigment is precipitated,

Depending on the kind of the substrate and the drying conditions, a dry acrylic resin, a vinyl resin, a two-pack type acrylic modified polyurethane resin, an epoxy resin, or the like is used as the binder. It is necessary to coat the surface of the substrate to be chemically and physically activated by applying a coating having good adhesion to the substrate which is difficult to adhere to the PP.

The solvent dissolves the electromagnetic wave absorbing material, thereby facilitating the application work.

The radio wave absorbing coating material may include additives in addition to the radio wave absorbing material, the binder and the solvent. The additive can function as antioxidant, anti-settling, dispersing heavy particles of conductive absorbent material.

The electromagnetic wave absorptive paint can be formed to contain 20 to 50% of the radio wave absorbing material, 10 to 20% of the binder, 40 to 50% of the solvent, and the rest of the weight of the electromagnetic wave absorbing coating material in weight percent.

ingredient content purpose of use Kinds Radio wave absorbing material 20 to 50% Radio wave absorption Silver, copper, nickel, carbon, conductive polymer bookbinder 10 to 20% Film formation, adhesion, humidity, heat resistance, chemical resistance Acrylic, urethane, epoxy, alkyd resin additive a very small amount Anti-oxidation, anti-sedimentation, particle dispersion of radio wave absorbing material Thickener, Antioxidant, Polymer Surfactant solvent 40 to 50% Application workability Water, Alcohol

The electromagnetic wave absorbing material may include at least one of a conductive electromagnetic wave absorbing material, a dielectric wave absorbing material, and a magnetic wave absorbing material

Radio wave absorbing material is intended to reduce the reflection of radio waves. It was mainly used for the military equipment such as the submarine or the airplane is not detected in the radar at the beginning of the development, or in the radio dark room used for the antenna directivity test. However, in recent years, electronic devices using electromagnetic waves such as microwave ovens and computers have increased in the vicinity of us, and adverse effects on other electronic devices caused by them and the influence on the human body have been a problem, and they are widely used for measures against electromagnetic interference.

Conductive electromagnetic wave absorbing material is a material that absorbs radio waves by the current flowing through a resistor, a resistance wire, and a resistance film. It is important to select a material having an appropriate resistance value at the time of use, and it is important to use an electromagnetic wave absorbing material Can be obtained.

The conductive electromagnetic wave absorbing material may include at least one of a conductive organic polymer including silver, copper, iron, nickel, aluminum, tin, zinc and gold, and polyacetylene, polypyrrole, polythiophene and polyaniline.

Silver is mainly used as a flake, and exhibits a low electric resistance and a high attenuation rate of about 60 dB, which is very effective as an electromagnetic wave shielding material, but is expensive. Copper has problems such as oxidation. Recently, however, the use of copper has been increasing due to the release of antioxidant products on the surface. The resistance is somewhat higher than silver, but costs about 1/5. Silver and copper are often used in combination to improve performance.

Nickel is a metal which is more easily oxidized than silver, but can be stabilized by a combination of an oxidation preventing treatment and a binder, so that there is no practical problem.

The dielectric wave absorbing material may include at least one of carbon, foamed urethane, and expanded polystyrene. In order to obtain broadband characteristics with this type of absorber, it is necessary to reduce the attenuation near the surface by making the multilayer structure and increase attenuation as it enters the inside. How to do the attenuation distribution of each layer is important.

The magnetic wave-absorbing material may include ferrite. A ferrite plate with a metal plate added exhibits good radio wave absorption characteristics over a relatively wide frequency range. In addition, rubber ferrite powder mixed with rubber is flexible, and the matching frequency can be changed by adjusting the mixing ratio of ferrite to rubber.

Further, the radio wave absorbing material may include iron oxide heating powder.

The above-mentioned electromagnetic wave absorbing material vibrates and rubs the molecules due to a change in the direction of the electric field due to the absorbed electromagnetic wave, thereby generating heat energy, and in this process, the electromagnetic wave is extinguished.

The above-described wind power generation apparatus can minimize the influence on the radio wave by applying a paint absorbing radio waves of a specific frequency to the outer surface.

While the invention has been shown and described with reference to certain preferred embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention as defined by the appended claims. Accordingly, the true scope of the present invention should be determined by the following claims.

100 ... Wind power generator 110 ... Propeller
111 ... wing 113 ... nozkon
130 ... Nacelle 150 ... Tower
170 ... RAP floor 200 ... radar

Claims (14)

A propeller rotating by wind;
A nacelle for converting the rotational force of the propeller into electric power;
A tower for supporting the propeller or the nacelle; And
And a RAP layer (Radar Absorbing Paint layer) applied to at least one of the propeller, the nacelle, and the tower and absorbing radio waves,
The RAP layer absorbs radio waves of a specific frequency,
The RCS of the region where the RAP layer is applied to the specific frequency is lower than the RCS of the region where the RAP layer is excluded by 20 dBsm or more,
The specific frequency is an X band frequency of 8.0 to 12.0 GHz,
Wherein the RAP layer includes a radio wave absorbing material for absorbing the radio wave, a binder for adhering the radio wave absorbing material to at least one of the propeller, the nacelle and the tower, and a solvent for dissolving the radio wave absorbing material,
Wherein the RAP layer comprises 20 to 50% by weight of the radio wave absorbing material, 10 to 20% of the binder, 40 to 50% of the solvent, and the remaining weight of additives in order to absorb the specific frequency.
delete delete delete delete The method according to claim 1,
Wherein the RAP layer is applied to a portion where the RCS of the propeller, the nacelle, and the tower is equal to or greater than a set value.
The method according to claim 1,
Wherein the RAP layer is applied to a curved surface or a leading edge of each wing constituting the propeller.
delete delete The method according to claim 1,
The radio wave absorbing material may be a conductive organic polymer including copper, iron, nickel, aluminum, tin, zinc and gold, And an iron oxide heating powder. delete delete delete delete

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