KR101453049B1 - Offshore Wind Power Generation Facility for Preventing Salt Damage and Doorway thereof - Google Patents

Abstract

The present invention relates to an offshore wind power generation facility with chloride attack prevention, a method, and a doorway of a tower thereof. More specifically, the present invention relates to an offshore wind power generation capable of maintaining high pressure therein relative to the atmospheric pressure of the chloride attack prevention, and a doorway having a door installed to a tower in which a user can safely open or close the door. External marine air containing chloride does not flow to the offshore wind power generation facility, thereby preventing internal parts from being corroded. The inside of the offshore wind power generation facility is maintained higher than the atmospheric pressure, thereby preventing the door from being abruptly opened due to the pressure difference between the inner pressure and the atmospheric pressure.

Description

{Offshore Wind Power Generation Facility for Preventing Salt Damage and Doorway}

More particularly, the present invention relates to an offshore wind power generation facility for maintaining a high pressure higher than atmospheric pressure for prevention of salt damage and a user installed on such a tower, And a door that is configured to be able to open and close safely.

Wind power generation is being reborn as a low-cost power source for renewable energy because of technological advances, mass production of equipment, and national support, which has been a drawback of conventional wind power generation. . At the end of 2002, the capacity of the world's wind power generation facilities reached 26,660 MW, with Germany's capacity of 12,00 MW, which is 45% of the world's. Followed by Spain, the United States and Denmark.

Generally, wind power generation facilities can be divided into offshore facilities and offshore facilities depending on the installation location. Wind power generation on the land has a limited installation site and there are problems such as landscapes and noise, and offshore wind power generation that installs a windmill on the coast of Europe is starting in Europe and is planned in the United States. Since the abundance of wind energy at sea is vast, the introduction of wind energy is rapidly promoted.

The sea is characterized by less turbulence of the wind than the land, and less change in wind speed along the elevation or direction. Such a relatively uniform supply of energy has the advantage that the power generation efficiency is higher than onshore. In addition, the wind turbines of offshore wind turbines are not limited to noise, so the speed of the wing tip is limited to 60m / s on the land, and it is advantageous to install high-speed and large wind turbines in excess of 100m / s have.

However, unlike onshore wind power generation facilities, offshore wind power generation facilities have a problem in that they can not be used for the technical and economical problems of basic construction and installation, internal parts such as corrosion protection coating, lubricating oil, internal crane structure, There are some problems to be solved such as anti-salt measures (design and material selection considering the influence of salt), failure diagnosis technology, system monitoring technology, failure prevention technology, maintenance inspection, and compensation for fishing.

Among the above-mentioned problems, the conventional technologies will be discussed with respect to the countermeasures against salting. Types of salt corrosion include galvanic corrosion, hydrogen corrosion, crevice corrosion and microbial corrosion due to salt corrosion. (1) As a measure to prevent galvanic corrosion, it is necessary to select a similar dislocation metal and to remove contaminants (oil, welding spatter, etc.) on the surface, (External power supply method) by contacting the power source from the outside by reversing the power supply, by contacting a more active third metal to the two metals of the galvanic pair (sacrificial anodic method), or by increasing the surface area of the less active metal side There is an area effect.

(2) Hydrogen corrosion can be divided into hydrogen bristling and hydrogen embrittlement. In order to prevent these, it is necessary to prevent hydrogen permeation by coating, use corrosion inhibitor, use kill steel rather than rim steel, Can be used. (3) Gap corrosion can be achieved by welding with rivets or bolts, sealing with gaps using lap joints, or by caulking. (4) Microbial corrosion The same method as above can be used.

Concrete structure design standard (2007) and concrete standard specification commentary (2009) also require countermeasures against salt corrosion in relation to the durability design standard of concrete. Concrete structure design standard explains that the structure in a highly corrosive environment condition should improve the durability by protecting the surface and the area within 10km from the coast is affected by seasonal winds and so it is recommended to take appropriate measures in accordance with it have. In the concrete standard specification commentary it is stated that the surface should be protected with suitable materials such as steels and polymer materials, or the thickness or cross section of the rebar should be increased in relation to the action.

In this connection, Korean Patent No. 10-103031 and the like provide a method for preventing the corrosion of a reinforced concrete structure.

However, countermeasures against such salt are more suitable for countermeasures related to the external surface and joints of offshore facilities, and countermeasures against internal components such as transformers, generators, etc., due to inflow of marine air containing a large amount of salt There is a limit to the need for countermeasures against internal components.

Korean Patent No. 10-1013031

Accordingly, the present invention has been made to solve the above-described problems.

A first object of the present invention is to provide an offshore wind power generation facility that maintains a static pressure higher than atmospheric pressure for prevention of salinization.

It is a second object of the present invention to provide an access door having a door that can be safely opened and closed by a user installed in an offshore wind power generation facility that maintains a static pressure higher than atmospheric pressure in order to prevent salt damage.

Hereinafter, specific means for achieving the object of the present invention will be described.

A first object of the present invention is to provide a turbine generator comprising a rotating portion 7 including a rotor 72 and a blade 70, a nacelle 9 housing a generator 52 generating power by rotation of the rotating portion 7, And a tower (5) installed at an upper end of the nacelle (9), wherein the nacelle (9) or the tower (5) is provided at one side of the nacelle (9) And an air conditioning unit (40) including an air intake unit for introducing the outside air of the sea into the inside of the facility through an air intake port and a filtering unit for removing salt and moisture of the outside air introduced into the facility by the air intake unit, The air conditioning means (40) is configured to maintain a static pressure higher than atmospheric pressure inside the facility and to prevent the outside air from being removed from the inside of the facility, It can be achieved by providing a stand.

A second object of the present invention is to open the inside and the outside of the offshore wind power generation facility 1 so that the air inside the offshore wind power generation facility 1 is discharged to the outside according to a user's operation, Decompression means (20); And an operating portion (22) provided on the outer surface and configured to allow the user to operate the depressurizing means (20); And a door of an offshore wind power generation facility installed on one side of the offshore wind power generation facility 1.

And a packing part provided on the outer side to seal the inside of the offshore wind power generation facility 1.

The decompression means 20 includes an exhaust port through which the air inside the offshore wind power generation facility 1 is discharged to the outside, at least one blade for controlling the opening of the exhaust port in accordance with the rotation angle, A rotary damper comprising a wing shaft; . ≪ / RTI >

The decompression means 20 includes an exhaust port through which the air inside the offshore wind power generation facility is exhausted to the outside, and a shutter that is linearly or rotationally moved in accordance with a guide provided at at least a part of the exhaust port, A slide type damper; . ≪ / RTI >

The operating portion 22 is constituted by a handle, and the handle is configured to rotate around its central portion by a rotational axis, and the pressure reducing means 20 can be adjusted by the rotational direction and the rotational speed of the handle.

The decompression means 20 may include a decompression valve having an exhaust hole connecting the inside and the outside of the offshore wind power generation facility 1 and controlling the opening of the exhaust hole according to a piston or a pressure adjusting spring.

The door 10 is provided on the outer side of the door 10 or the offshore wind power generation facility 1 and is connected to the inside of the offshore wind power generation facility 1 to detect the internal pressure, And a pressure gauge (30) for displaying on the outside of the power generation facility (1).

A third object of the present invention is to provide a gas turbine generator for a gas turbine, comprising: a packing part provided at an outer side of an offshore wind power generation facility according to claim 1 for sealing the inside of the offshore wind power generation facility; A door (10) installed at one side of the offshore wind power generation facility, including a decompression means (20) configured to open and close the inside and outside so as to be discharged to the outside so as to attenuate internal pressure. And a control unit 20 which is provided on the outer side of the offshore wind power generation facility 1 and allows a user to operate the decompression means 20 to open the inside and the outside of the offshore wind power generation facility 1 through the decompression means 20. [ And an operating unit 22 constructed as a unit for controlling the operation of the offshore wind turbine.

The decompression means 20 includes an exhaust port through which the air inside the offshore wind power generation facility 1 is discharged to the outside, at least one blade for controlling the opening of the exhaust port in accordance with the rotation angle, And a rotary damper including a wing shaft.

The decompression means 20 includes an exhaust port through which the air inside the offshore wind power generation plant 1 is discharged to the outside, a guide provided on at least a part of the outside of the exhaust port, and linear motion or rotational motion along the guide, And a slide-type damper composed of a shutter.

The decompression means 20 may include a decompression valve having an exhaust hole connecting the inside and the outside of the offshore wind power generation facility 1 and controlling the opening of the exhaust hole according to a piston or a pressure adjusting spring.

The door 10 is provided on the outer side of the door 10 or the offshore wind power generation facility 1 and is connected to the inside of the offshore wind power generation facility 1 to detect the internal pressure, And a pressure gauge 30 for indicating the outside of the power generation facility.

A fourth object of the present invention is to provide a method of introducing a offshore wind power generation facility (1) according to the first aspect of the present invention, wherein a user is connected to the inside of the offshore wind power generation facility (1) A pressure sensing step of sensing the inside / outside pressure difference through the pressure gauge (30) displayed on the outside of the offshore wind power generation facility (1); The control unit controls the operation unit 22 which is a constitution of the door 10 of the offshore wind power generation facility 1 according to claim 2 so that the user can open the inside and the outside of the offshore wind power generation facility 1, A pressure attenuating step of attenuating the pressure difference between the inside and the outside of the offshore wind power generation plant 1 to a predetermined pressure difference through the decompression means 20 which is a constituent of the offshore wind farm 1; And a user opening the door (10) of the offshore wind power generation facility and drawing it into the offshore wind power generation facility (1); And a method of accessing an offshore wind power generation facility including the offshore wind power generation facility.

As described above, the present invention has the following effects.

First, according to the first aspect of the present invention, it is possible to prevent corrosion of internal components by fundamentally blocking the inflow of offshore external air including salinity into an offshore wind power generation facility.

Secondly, according to the second object of the present invention, since the inside of the offshore wind power generation facility is maintained at a higher pressure than the atmospheric pressure, the operator's entrance to the facility suddenly becomes unstable due to the pressure difference between the inside air pressure and the atmospheric pressure. There is an effect of preventing the opening phenomenon.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this application, illustrate preferred embodiments of the invention and, together with the description, And shall not be interpreted.
1 is a conceptual diagram of a marine wind power generation facility according to an embodiment of the present invention,
2 is a partially enlarged view of a marine wind power generation facility according to an embodiment of the present invention;
3 is a partial cross-sectional view of an offshore wind power plant according to an embodiment of the present invention,
4 is a conceptual view of a door of a marine wind power generation facility according to an embodiment of the present invention,
FIG. 5 is a conceptual view of a doorway of an offshore wind power generation facility according to an embodiment of the present invention,
FIG. 6 is a flowchart illustrating a method of entering a marine wind power generation facility according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following detailed description of the operation principle of the preferred embodiment of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may unnecessarily obscure the subject matter of the present invention.

The same reference numerals are used for portions having similar functions and functions throughout the drawings. Throughout the specification, when a part is connected to another part, it includes not only a case where it is directly connected but also a case where the other part is indirectly connected with another part in between. In addition, the inclusion of an element does not exclude other elements, but may include other elements, unless specifically stated otherwise.

<Offshore wind power generation facility>

FIG. 1 is a conceptual diagram of a marine wind power generation facility according to an embodiment of the present invention, FIG. 2 is a partially enlarged view of a marine wind power generation facility according to an embodiment of the present invention, FIG. It is a partial cross-section of a wind power facility. 1, 2 and 3, an offshore wind power generation facility 1 according to an embodiment of the present invention includes a lower support structure 3, a tower 5, a rotation unit 7, a nacelle 9, And air conditioning means (40).

The lower support structure 3 may be formed of a mono pile, a jacket pile, a tripod pile, a suction pile, or a float depending on the depth of the sea or various conditions. (1) to be able to withstand wind waves.

The tower 5 is introduced to vertically upwardly place the rotary part 7, and the inside of the tower 5 is constituted by an empty cylinder or a semi-cone, and a ladder or an elevator Can be disposed. The lower end is coupled with the lower support structure 3 and the upper end is provided with a nacelle 9. Therefore, the entrance of the offshore wind power generation facility 1 can be provided in the tower 5. The inside of the nacelle 9 and the inside of the tower 5 may be connected to each other and the inside of the nacelle 9 and the inside of the tower 5 may be connected by the air conditioning means 40 to circulate the air.

The rotating portion 7 may be composed of a blade 70, a rotor 72, a generator, and a hub. The rotor 72 is a rotary shaft for fixing the blade, and the hub is a rotary support shaft. The blade 70 is aerodynamically constituted to obtain a rotational force by the direct airflow, and is generated by the generator 52 connected to the nacelle 9 by the rotational force.

The nacelle 9 is located at the top of the tower 5 and is of the type or gearless permanent magnet generator in which the generator 52 and the gearbox are included And it is preferable that a transformer 50 is provided, unless it is a large-scale wind farm. The interior of the nacelle 9 may be configured to be connected to the interior of the tower 5. The air may be separately circulated inside the nacelle 9, or the air may be circulated together with the tower 5 as a whole.

The air conditioning means 40 is a characteristic component of the present invention and can be configured to include an intake portion and a filtering portion. The intake unit may mean a blower that sucks the outside air of the sea into the inside of the facility. At this time, the offshore outer air contains a lot of salt and moisture in the unfiltered state by the filtering unit, and there is a possibility that the internal components of the offshore wind power generation facility 1 may be salted. Accordingly, the outside air is introduced into the offshore wind power generation facility 1 in a state in which salt and moisture are removed by the filtering unit. The air conditioning means 40 can also be used for cooling the generator 52 and the transformer 50 inside the nacelle 9.

At this time, it is difficult to prevent the external air of the sea flowing through the gap existing in the outer periphery of the offshore wind power generation facility 1 without flowing into the intake portion. The salinity of the internal components of the offshore wind turbine generator 1 is also significant. The present invention is characterized in that the intake air sucks a large amount of outside air into the facility and maintains the internal static pressure of the offshore wind power generation facility 1 higher than the atmospheric pressure. And thus the outside air of the sea flowing through the gap existing in the outer side of the offshore wind power generation facility 1 is fundamentally cut off. The outside air is fundamentally cut off to fundamentally block the salinity of the internal components of the offshore wind power generation facility 1.

<Offshore wind power generation facility door >

4 is a conceptual view of a door of a marine wind power generation facility according to an embodiment of the present invention. 4, the door 10 of the offshore wind turbine according to an embodiment of the present invention may include a pressure gauge 30, a handle 12, a depressurizing means 20, and a control unit 22 have. The outer side of the door may be packed with an elastic material such as resin or rubber to form a packing part for sealing the inside of the offshore wind power generation facility.

The pressure gauge 30 is connected to the inside of the offshore wind power generation facility 1 and serves to display the internal pressure of the offshore wind power generation facility 1 on the outside. The user or the operator judges whether the door 10 can be safely opened by using the pressure indicated on the pressure gauge 30 as a measure. Whether the type of the pressure gauge 30 is an electronic pressure gauge or a mechanical pressure gauge may not be important for achieving the object of the present invention. It is desirable to use a mechanical pressure gauge for economy and non-power, and it is preferable to use an electronic pressure gauge for high accuracy, reliability, and long life.

The decompression means 20 is configured to be connected to the inside and the outside of the offshore wind power generation facility 1 so as to selectively reduce the internal and external pressure differences. After determining whether the door 10 can be safely opened by the pressure indicated on the pressure gauge 30 by the user, the user or the operator operates the pressure reducing means 20 to reduce the pressure difference between the inside and the outside of the facility to a predetermined pressure difference, The door 10 is opened.

As the decompression means 20, there is an exhaust damper or a decompression valve. Among them, a rotary damper, a slide damper, a direct operated type pressure reducing valve, a pilot type pressure reducing valve, and the like are preferable among the exhaust damper and the pressure reducing valve.

With regard to the rotary damper, it may mean a damper having at least one blade and varying degree of opening according to an angle of rotation about a blade axis. At this time, the wing axis may be configured in the lateral direction or the longitudinal direction of the wing, and may be configured at one end in the lateral direction or the longitudinal direction. It may also rotate in the same direction as the neighboring wing, or may rotate in the opposite direction. The rotary damper is simple in construction despite the drawbacks of many leaks, and can be configured so that the air inside the offshore wind power generation facility 1 discharged from the exhaust port receives a constant load, so that it is easy to control the pressure difference.

As for the slide type damper, it can be said that a wing is opened and closed along a guide like a sliding door or a curtain. At this time, there may be a rotating type slide damper and a curtain type slide damper. And includes a circular exhaust port, and a circular exhaust port is equally divided like a pie piece, and when opened, a part is opened and a part is closed. The curtain type slide damper is configured such that the wrinkle of the shutter is folded during operation like a sliding door, or the shutter is released to the side of the exhaust port and the exhaust port is opened. This is characterized by a large amount of exhaust. That is, there is an effect of achieving rapid pressure equilibrium.

The operating section 22 is a part for determining whether the decompression means 20 is opened or closed by a user's operation, and may be an electronic type or a mechanical type. At this time, the electronic type may be configured on the outer side of the door 10, on the outer side of the doorway, and the mechanical type on the outer side of the door 10. It is possible to provide a circular handle in the form of the mechanical operation portion 22. [ This has the advantage that the rotary slide damper can be configured to share a center with the center axis of the shutter and the door 10 can be closed considerably.

After the user 12 or the operator judges whether the door 10 can be safely opened by using the pressure indicated on the pressure gauge 30 as the scale, the handle 12 operates the decompression means 20 to change the pressure difference between the inside and the outside of the facility to a predetermined pressure And to insert the door latch so as to allow the user or the operator to open the door 10 in opening the door 10 when it is judged to be safe. It is apparent that the handle may be formed of a spherical shape, a square shape, a straight shape, a C shape or the like as shown in the drawing.

<Gateway of offshore wind power facility>

FIG. 5 is a conceptual view of an entrance of an offshore wind power generation facility according to an embodiment of the present invention. 5, the entrance of the offshore wind power generation facility according to an embodiment of the present invention may include a door 10, an operation unit 22, and a pressure gauge 30.

The door 10 may be constructed as described above.

The operation unit 22 may be constructed as described above and may be attached to the outside of the door 10 or to the outside of the tower 5 or the offshore wind power plant 1.

The pressure gauge 30 may be constructed as mentioned above and may be attached to the outside of the door 10 or to the outside of the tower 5 or the offshore wind turbine 1.

<Offshore wind power generation facility Way of entry >

FIG. 6 is a flowchart illustrating a method of entering a marine wind power generation facility according to an embodiment of the present invention. 6, the approaching method of the offshore wind power generation plant 1 according to an embodiment of the present invention may include a pressure sensing step S10, a pressure attenuation step S20, and an inlet step S30 have.

In the pressure sensing step S10, in order to prevent the door 10 from being suddenly opened before the user or the operator opens the door 10 to enter the offshore wind power generation facility 1 to deteriorate the safety of the user or the operator, The user or the operator senses the pressure displayed on the pressure gauge 30 and judges the difference between the atmospheric pressure and the risk that the door 10 is suddenly opened.

In the pressure attenuation step S20, the user or the operator operates the door 10 of the offshore wind power generation facility 1 or the operation section 22 provided on the outer side of the tower 5, The pressure reducing means 20 is operated until the pressure difference of the off-axis wind power generation facility 1 becomes equal to a predetermined pressure difference between the off-axis wind power generation facility 1 and the off-wind power generation facility 1, The predetermined pressure difference refers to a pressure difference to such an extent that the door 10 is not opened suddenly so that the risk of the user or the operator is not expected.

In step S30, the user or the operator safely opens the door 10 using the handle 12 of the door 10 and enters the tower 5 of the offshore wind power generation facility 1. [ When the user or the operator enters the inside of the offshore wind power generation facility 1 and then the door 10 is closed again, the static pressure inside the offshore wind power generation facility 1 is again returned to the high pressure by the air conditioning means 40 .

The positions and arrangements of the pressure gauge 30, the pressure reducing means 20, the operating portion 22, the air conditioning means 40, the generator and the transformer are not limited to those shown in the drawings and may be changed depending on the type of the door 10, . &Lt; / RTI &gt;

As described above, those skilled in the art will appreciate that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. It is therefore to be understood that the above-described embodiments are to be considered in all respects only as illustrative and not restrictive. The scope of the present invention is defined by the appended claims rather than the detailed description, and all changes or modifications derived from the meaning and scope of the claims and their equivalents should be construed as being included in the scope of the present invention.

1: offshore wind power generation facility
3: Lower support structure
5: Towers
7:
9: Nacelle
10: Door
12: Handle
20: Pressure reducing means
22:
30: Manometer
40: air conditioning means
50: Transformer
52: generator
70: blade
72: Rotor

Claims (14)

A rotary section 7 including a rotor 72 and a blade 70; a nacelle 9 housing a generator 52 generating power by rotation of the rotary section 7; And a tower (5) on which a wind turbine (9) is installed,
An intake part provided at one side of the nacelle (9) or the tower (5) for introducing marine external air of high humidity and high saltiness into the inside of the facility through an intake port, and an intake part And an air conditioning means (40) including a filtering section for removing salt and moisture from the air,
The air conditioning means (40) is configured to maintain a static pressure higher than atmospheric pressure in the facility and to prevent the outside air from being removed from the inside of the facility, Power generation facilities.
The door of the offshore wind power plant according to claim 1,
Decompression means (20) configured to open and close the inside and the outside of the offshore wind power generation facility (1) so that the air inside the offshore wind power generation facility (1) is discharged to the outside according to a user operation; And
An operating portion (22) provided on the outer surface and configured to allow the user to operate the depressurizing means (20);
Lt; / RTI &gt;
A door of an offshore wind power generation facility installed on one side of the offshore wind power generation facility (1).
3. The method of claim 2,
A packing part provided on the outer side to seal the inside of the offshore wind power generation facility 1;
And a door for the wind turbine.
3. The method of claim 2,
The decompression means (20)
At least one wing plate whose opening degree of the exhaust port is adjusted according to the angle of rotation, and a wing axis which becomes a rotation axis of the wing plate, A damper;
Of the offshore wind turbine.
3. The method of claim 2,
The decompression means (20)
A slide type damper having an exhaust port through which the air inside the offshore wind power generation facility is discharged to the outside and a shutter which is linearly or rotationally moved in accordance with a guide provided on at least a part of the outside of the exhaust port and opened and closed;
Of the offshore wind turbine.
6. The method of claim 5,
Wherein the handle (22) is configured as a handle, and the handle is configured to rotate around a central axis of rotation of the handle, and the decompression means (20) is adjusted by the rotational direction and the number of rotations of the handle.
3. The method of claim 2,
The decompression means (20)
A pressure reducing valve having an exhaust hole connecting the inside and the outside of the offshore wind power generation plant 1 and controlling the opening degree of the exhaust hole according to a piston or a pressure adjusting spring;
Of the offshore wind turbine.
3. The method of claim 2,
The door 10 is provided on the outer side of the door 10 or the offshore wind power generation facility 1 and is connected to the inside of the offshore wind power generation facility 1 to detect the internal pressure, A pressure gauge (30) for displaying on the outside of the power generation facility (1);
And a door for the wind turbine.
An entrance of an offshore wind power generation facility according to claim 1,
A decompression means 20 for decompressing the internal pressure by opening the inside and outside of the packing to cover the inside of the offshore wind power generation facility 1 so that the inside air is discharged to the outside according to a user's operation, A door (10) installed at one side of the offshore wind power generation facility; And
The wind power generation system according to any one of claims 1 to 3, wherein the offshore wind power generation facility (1) is provided on the outside of the offshore wind power generation facility (1) and a user operates the decompression means (20) (22);
Of the offshore wind power plant including
10. The method of claim 9,
The decompression means (20)
At least one wing plate whose opening degree of the exhaust port is adjusted according to the angle of rotation, and a wing axis which becomes a rotation axis of the wing plate, A damper;
Of the offshore wind power plant including
10. The method of claim 9,
The decompression means (20)
A slide type damper configured by an exhaust port through which the air inside the offshore wind power generation facility 1 is discharged to the outside, a guide provided on at least a part of the outside of the exhaust port, and a shutter that is linearly or rotationally moved along the guide, ;
Of the offshore wind power plant including
10. The method of claim 9,
The decompression means (20)
A pressure reducing valve having an exhaust hole connecting the inside and the outside of the offshore wind power generation plant 1 and controlling the opening degree of the exhaust hole according to a piston or a pressure adjusting spring;
Of the offshore wind power plant including
10. The method of claim 9,
The door 10 is provided on the outer side of the door 10 or the offshore wind power generation facility 1 and is connected to the inside of the offshore wind power generation facility 1 to detect the internal pressure, A pressure gauge (30) for displaying on the outside of the power generation facility;
Of the offshore wind turbine.
A method of introducing an offshore wind power generation plant (1) according to claim 1,
A user is connected to the inside of the offshore wind power generation facility 1 to sense the internal pressure and the detected pressure is transmitted to the inside and outside through the pressure gauge 30 displayed on the outside of the offshore wind power generation facility 1. [ A pressure sensing step of sensing a pressure difference;
The control unit controls the operation unit 22 which is a constitution of the door 10 of the offshore wind power generation facility 1 according to claim 2 so that the user can open the inside and the outside of the offshore wind power generation facility 1, A pressure attenuating step of attenuating the pressure difference between the inside and the outside of the offshore wind power generation plant 1 to a predetermined pressure difference through the decompression means 20 which is a constituent of the offshore wind farm 1; And
A user opening the door (10) of the offshore wind power generation facility and drawing it into the offshore wind power generation facility (1);
Of the offshore wind power generation facility.

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