KR101641625B1 - Offshore wind generators slope maintenance and calibration equipment - Google Patents

Abstract

The present invention relates to slope maintenance and calibration equipment for an offshore wind power generator, which can easily correct and maintain a slope degree of an offshore wind power generator inclined along a support structure which is inclined in any one direction by a wave, a sea current, a typhoon, ground erosion, or the like, and further, significantly reduce time and costs consumed therefor. According to the present invention, the slope maintenance and calibration equipment for an offshore wind power generator comprises: a lower flange unit; an upper flange unit; and a slope calibration unit.

Description

{Offshore wind generators for slope maintenance and calibration equipment for offshore wind power generators}

The present invention can more easily correct and maintain the slope of an offshore wind power generator inclined obliquely along a supporting structure inclined by any one direction due to waves, currents, typhoons, and ground erosion, And more particularly, to a slope maintenance and correction device for offshore wind power generators.

In general, wind power generation is a pollution-free energy source, and the maintenance and repair cost of the present alternative energy is the lowest, which is very economical.
In addition, the wind turbine generator is simple in construction and installation, easy to operate and manage, and can be operated unmanned and automated.
As a place to install a wind turbine generator, it is desirable that the wind turbine is installed at a place where the wind speed is fast and the direction is constant according to time and season. Therefore, a large scale wind turbine is constructed on the sea, In recent years, a foundation support for an offshore wind power generator that prevents a foundation support installed on a sea bed from being damaged by an external environment such as a wind load or a scour phenomenon to support an offshore wind power generator installed on an upper part is disclosed in Korean Patent Laid- 10-2012-0052678.
On the other hand, as the lower support structure (water) of the offshore wind power generator, a large diameter pile is inserted into the sea floor, and a lower support structure such as a monopile, a try pod, a jacket, And the wind power generation section is installed on the wind power generation section, and this substructure is connected to the support of the wind power generation section through a transition piece.
Here, when the lower support structure is tilted inclined in any one direction due to waves, currents, typhoons, and ground erosion, the wind power generator also tilts along the lower support structure. There is a problem.

Japanese Patent Application Laid-Open No. 10-2012-0052678

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide a wind turbine that can easily correct and maintain an inclination of an offshore wind turbine inclined along a supporting structure inclined in any one direction due to waves, currents, typhoons, And it is an object of the present invention to provide a tilting maintenance and correction device for offshore wind power generators capable of significantly reducing the time and cost required for the offshore wind power generator.

According to an aspect of the present invention, An upper flange portion provided at an upper portion of the lower flange portion and having a lower portion of the strut of the offshore wind power generator connected to the upper portion; And a plurality of inclined corrector units provided at predetermined intervals on the upper portion of the lower flange portion so as to be positioned between the upper flange portion and the lower flange portion to maintain and correct the vertical gradient of the offshore wind power generator together with the upper flange portion And an inclination maintaining and correcting device for an offshore wind power generator.
It is preferable that a wall portion extending upward in the lower flange portion is formed on an upper edge of the lower flange portion so as to be positioned in an outer direction of the tilt correction portion.
The inclination correcting portion may include a cylinder having a receiving groove formed at an upper portion of the lower flange portion at a predetermined interval and vertically extending in a lengthwise direction, the receiving groove being recessed at a predetermined depth in a downward direction of the piston rod, A member; A lower flange portion that is formed at a lower portion of the lower flange portion so as to be movable from an outer side of the upper flange portion to an inner side of the upper flange portion and that has a shape corresponding to a receiving groove of the piston rod of the cylinder member, A moving member protruding into the groove and protruding in the receiving groove direction and having a through hole formed in the center thereof; A lower portion of the piston rod of the cylinder member is fixed to an upper portion of the piston rod through a through hole of the moving member to fasten the moving member to an upper portion of the piston rod, And a fastening member formed to have a size smaller than that of the fastening member.
In addition, it is preferable that a groove, in which the head portion of the fastening member is received, is formed on the central portion of the moving member so as to communicate with the through hole of the moving member.
Further, a guide rail extending from the outer side of the upper flange portion to the inner side of the upper flange portion and having a predetermined length is formed in a lower portion of the upper flange portion, and the moving member is accommodated in the guide rail, To the inside of the upper flange portion from the outside of the upper flange portion.
Further, a support portion for supporting the upper flange portion is provided between the upper flange portion and the lower flange portion, the support portion is formed on the upper portion of the lower flange portion so as to be positioned between the inclined correction portions, A support body formed on the support body; A support wall protruding from the lower portion of the upper flange portion in a direction of the insertion groove and formed at a predetermined interval in a lower portion of the upper flange portion so as to be inserted into the insertion groove; And a plurality of support pads stacked vertically in the insertion groove in a state of being positioned between the support walls.
The upper and lower flange portions of the cylinder member are rotatably fixed by the spherical plain bearings. The upper and lower flange portions of the cylinder member are fixed to the lower flange portion, .
Preferably, the lower portion of the cylinder member and the upper portion of the lower flange portion are rotationally fixed by a spherical plain bearing.
A tilt sensor for sensing a tilt of the offshore wind turbine; And a control unit for controlling the tilt correction unit according to a detection signal of the tilt sensor.
The upper flange portion is preferably bisected.

The present invention can more easily correct and maintain the inclination of an offshore wind turbine tilted along a supporting structure inclined in any one direction due to waves, currents, typhoons, and ground erosion through a warp correction unit, And the cost can be greatly reduced.

1 and 2 are perspective views schematically showing a tilting maintenance and correction apparatus for an offshore wind power generator according to an embodiment of the present invention,
3 is a perspective view schematically showing a state where an offshore wind power generator is installed on an upper part of a support structure,
4 is a partially enlarged and separated cross-sectional view schematically showing an example of the inclined corrector,
Figure 5 is a partially enlarged engaging cross-sectional view of Figure 4,
6 is a partially enlarged coupling sectional view schematically showing a state in which the movable member is inclined,
7 is a partially enlarged perspective view schematically showing a state in which a moving member is housed inside a guide rail formed at a lower portion of an upper flange portion,
8 is a partially enlarged cross-sectional view schematically showing a state in which a moving member is housed inside a guide rail formed at a lower portion of an upper flange portion,
9 is a partially cut-away side view schematically showing a state in which the slope of the offshore wind power generator is adjusted through a slope correction part,
10 is a partially enlarged coupling sectional view schematically showing another example of the inclined correcting portion,
11 is a block diagram schematically showing a control state of the control unit,
12 is a perspective view schematically showing a state in which the upper flange portion is bisected.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings. It is to be understood that the scope of the present invention is not limited to the following embodiments, and various modifications may be made by those skilled in the art without departing from the technical scope of the present invention.
1 and 2 are perspective views schematically showing a tilting maintenance and correction apparatus for an offshore wind power generator according to an embodiment of the present invention.
1 and 2, the inclination maintenance and correction device for an offshore wind power generator according to an embodiment of the present invention includes a lower flange portion 10, an upper flange portion 20, and a tilt correction portion 30 .
First, the lower flange portion 10 may be formed in an annular shape or the like.
Next, the upper flange portion 20 may also be formed in an annular shape or the like.
The upper flange portion 20 is provided at an upper portion of the lower flange portion 10.
3 is a perspective view schematically showing a state where an offshore wind power generator is installed on an upper part of a support structure.
As shown in FIG. 3, a flange 510 formed at a lower portion of the strut 51 of the offshore wind power generator 5 may be connected to the upper portion of the upper flange portion 20 by various methods such as welding or bolting.
The lower flange portion 10 may be connected to the upper portion of the transition piece 6 by various methods such as welding or bolting.
The transition piece 6 may be provided at its lower portion with a support structure 7 formed of a steel tower or the like for supporting the transition piece 20 and the marine wind power generator 5 at a predetermined height.
The lower portion of the support structure 7 may be inserted and fixed at a certain depth on the sea floor.
The inclined correcting portion 30 is provided radially at a predetermined interval on the upper portion of the lower flange portion 20 so as to be positioned between the upper flange portion 10 and the lower flange portion 20, The vertical inclination of the strut 51 of the offshore wind power generator 5 is maintained and corrected together with the flange portion 10.
Next, the inclined correcting portion 30 is securely protected and the inclined correcting portion 30 is minimized in the outward direction of the lower flange portion 10 and in the outward direction of the upper flange portion 20 1 and 2, the upper flange portion 10 and the lower flange portion 10 are vertically extended in the upper direction of the lower flange portion 10 so as to be positioned on the outer side of the inclination correcting portion 30 The wall portion 40 may be formed.
Fig. 4 is a partially enlarged sectional view schematically showing an example of the inclined correcting portion, and Fig. 5 is a partially enlarged engaging sectional view of Fig.
4 and 5, the inclination correcting unit 30 may include a cylinder member 310, a moving member 320, and a fastening member 330, for example.
The cylinder member 310 may be vertically installed on the upper portion of the lower flange portion 10 with bolts fastened at regular intervals.
As the cylinder member 310, a hydraulic cylinder may be used, but the present invention is not limited thereto, and various types of cylinders such as an air cylinder may be used.
A receiving groove 312 may be formed in the upper portion of the piston rod 311 of the cylinder member 310 so as to be recessed into a predetermined depth in a downward direction of the piston rod 311.
The moving member 320 may be formed in a circular shape or the like.
The moving member 320 may be provided at a lower portion of the upper flange portion 20 so as to be movable from an outer side of the upper flange portion 20 to an inner side of the upper flange portion 20.
A protruding member 321 which can be formed in a shape of a circular arc so as to correspond to the receiving groove 312 of the piston rod 311 of the cylinder member 310 is inserted into the receiving groove 312, And can be accommodated in the receiving groove 312. [0051] As shown in FIG.
A through hole 322 may be formed at the center of the moving member 320 to extend vertically downward from the upper portion of the moving member 320.
The fastening member 330 has a threaded hole 313 formed at a predetermined depth in the upper center portion of the piston rod 311 of the cylinder member 310 while vertically penetrating the through hole 322 of the moving member 320. [ And a fastening bolt that is fastened in a state where the lower portion is screwed into the piston rod 311. The moving member 320 can be fastened to the upper portion of the piston rod 311. [
6 is a partially enlarged engaging sectional view schematically showing a state in which the moving member is inclined.
The inclined correcting portion 30 may be provided in the receiving groove 312 of the piston rod 311 during the process of correcting the vertical inclination of the strut 51 of the offshore wind power generator 5 together with the upper flange portion 20. [ The protruding member 321 of the accommodated moving member 320 is rotated in place so that the moving member 320 is inclined in any one of forward, backward, left and right diagonal directions of the moving member 320 as shown in FIG. To be able,
The outer diameter size (D ₁ in Fig. 4) of the fastening member 330 may be formed smaller than the inner diameter (D ₂ in Fig. 4) the size of the through-hole 322 of the movable member (320).
During the process of correcting the vertical inclination of the struts 51 of the offshore wind turbine generator 5 together with the upper flange portion 20, the moving member 320 moves the upper plan In order to prevent the head portion 331 formed on the upper portion of the fastening member 330 from acting as an obstructing element, 4, a groove 323 in which the head portion 331 of the fastening member 330 is received is formed in the central portion of the moving member 320 so as to communicate with the through hole 322 of the moving member 320 It can be recessed to a certain depth.
During the process of correcting the vertical inclination of the column 51 of the offshore wind power generator 5 together with the upper flange portion 20, the inclined correcting portion 30 moves the movable member 320 to the upper flange portion 20 The upper portion of the piston rod 311 is prevented from being damaged during the process of correcting the vertical inclination of the strut 51. As shown in FIG.
7 is a partially enlarged perspective view schematically showing a state in which a moving member is accommodated in an inner side of a guide rail formed at a lower portion of an upper flange portion and FIG. 8 is a state in which a moving member is housed inside a guide rail formed at a lower portion of the upper flange portion Fig.
7, a guide rail 210 for guiding the movement of the movable member 320, which moves from the outside of the upper flange portion 20 to the inside of the upper flange portion 20, And may be formed in the lower portion of the upper flange portion 20 in a radial manner at regular intervals.
The guide rail 210 may extend from the outer side of the upper flange portion 20 to a predetermined length in the inner direction of the upper flange portion 20.
The lower portion of the guide rail 210 is bent in the direction of the lower edge of the moving member 320 so that the moving member 320 is positioned inside the guide rail 210 The moving member 320 can move along the guide rail 210 from the outside of the upper flange portion 20 to the inside of the upper flange portion 20. [
9 is a partially cut-away side view schematically showing a state of adjusting the slope of an offshore wind power generator through a slope correction part.
The transition piece 6 and the lower flange portion 10, the upper flange portion 10, the upper flange portion 10, and the upper flange portion 10 are formed along the support structure 7 when the support structure 7 is tilted in one direction due to a wave, The upper flange portion 20 and the strut 51 of the offshore wind power generator 5 are inclined.
At this time, the length of the piston rod 311 of the cylinder member 310 of the inclined corrector 30 is extended in the vertical direction to adjust the upper flange portion 20 to a horizontal state as shown in FIG. 9, The upward and downward inclination of the column 51 of the offshore wind turbine generator 5 can be corrected so that the column 51 of the wind turbine generator 5 can assume a vertical state.
Next, when the cylinder member 310 of the inclination correcting unit 30 is formed of a hydraulic cylinder, even if the inflow of oil into the hydraulic cylinder constituting the cylinder member 310 is interrupted, the vertical inclination is corrected, 7, in order to allow the struts 51 of the offshore wind turbine generator 5 to be vertically continuous, the upper and lower flange portions 20, And a support portion 50 for supporting the flange portion 20 may be provided.
As shown in FIG. 7, the support 50 may include a support body 501, a support wall 502, and a support pad 503.
The support body 501 may be formed on the lower flange portion 10 so as to be positioned between the inclined corrector portions 30.
An insertion groove 504 may be formed in the upper portion of the support body 501.
The support wall 502 has a predetermined length in the lower portion of the upper flange portion 20 in the direction of the insertion groove 504 and is inserted into the insertion groove 504, And can be formed in a plurality of radial intervals.
The support pads 503 may be vertically stacked in the insertion groove 504 in a state where the support pads 503 are positioned between the support walls 502.
The upper and lower thicknesses of the plurality of support pads 503 may be different from each other and the upper and lower thicknesses of the plurality of support pads 503 may be varied from the lower portion of the upper flange portion 20 toward the insertion groove 504, The thickness can be gradually increased.
The support pad 503 may be made of various materials such as rubber. However, the support pad 503 is not necessarily limited to the rubber and may be of any material having the same physical properties as the lower flange portion 10 and the upper flange portion 20.
10 is a partially enlarged coupling sectional view schematically showing another example of the inclined correcting portion.
10, the inclination correcting unit 30 is formed of the cylinder member 310, and the upper portion of the piston rod 311 of the cylinder member 310, And the lower part of the shaft 20 can be rotationally fixed by the spherical plain bearing 60.
The lower portion of the cylinder member 310 and the upper portion of the lower flange portion 10 may be fixed by the spherical plain bearing 60.
11 is a block diagram schematically showing the control state of the control unit.
Next, as shown in FIG. 11, a tilt sensor 70 and a control unit 80 may be further provided.
The tilt sensor 70 may be provided on the outer surface of the strut 51 of the offshore wind turbine generator 5 to detect the up and down tilt of the strut 51 of the offshore wind turbine generator 5, can do.
The control unit 80 may control the cylinder member 310 of the inclination correction unit 30 according to a detection signal of the inclination sensor 70.
The control unit 80 may control the controller 80 to set a reference slope value previously set in the controller 80 and a value of the offshore wind force detected by the tilt sensor 70, It is possible to control the cylinder member 310 of the inclination correcting unit 30 by comparing the up and down inclination values of the struts 51 of the generator 5 with each other.
When the vertical slope value sensed by the slope sensor 70 is equal to the reference slope value preset in the controller 80, the control unit 80, which is supplied with power from the power supply unit 81, The cylinder member 310 of the cylinder 30 can be shut down.
When the up / down tilt value detected by the tilt sensor 70 is less than or exceeds the reference tilt value preset in the controller 80, the up / down tilt value sensed by the tilt sensor 70 is supplied to the controller 80 in advance The vertical length of the piston rod 311 of the cylinder member 310 of the inclination correcting unit 30 can be adjusted by the control of the controller 80 so as to be equal to the set reference inclination value.
12 is a perspective view schematically showing a state in which the upper flange portion is bisected.
Next, in order to allow the inclination correcting unit 30 to more accurately maintain and correct the vertical inclination of the column 51 of the offshore wind power generator 5 together with the upper flange portion 10, 12, the upper flange portion 20 includes one upper flange portion 201 formed on one side of the lower flange portion 10; And the other upper flange portion 202 formed on the other side of the lower flange portion 10 in a symmetrical state with the one upper flange portion 201.
The present invention having the above-described structure is characterized in that the offshore wind turbine (5) inclined along the support structure (7) inclined in any one direction due to waves, currents, typhoons, Can be easily corrected and maintained, and the time and cost required for the vertical support can be greatly reduced.

10; A lower flange portion, 20; An upper flange portion,
30; Inclined correction.

Claims (10)

A lower flange portion;
An upper flange portion provided at an upper portion of the lower flange portion and having a lower portion of the strut of the offshore wind power generator connected to the upper portion;
And a plurality of inclined corrector units provided at predetermined intervals on the upper portion of the lower flange portion so as to be positioned between the upper flange portion and the lower flange portion to maintain and correct the vertical gradient of the offshore wind power generator together with the upper flange portion Lt; / RTI >
Wherein the inclination correcting portion includes a cylinder member vertically provided at an upper portion of the lower flange portion and having a receiving groove recessed at a predetermined depth in a downward direction of the piston rod at an upper portion of the piston rod extending in the vertical direction, ;
A lower flange portion that is formed at a lower portion of the lower flange portion so as to be movable from an outer side of the upper flange portion to an inner side of the upper flange portion and that has a shape corresponding to a receiving groove of the piston rod of the cylinder member, A moving member protruding into the groove and protruding in the receiving groove direction and having a through hole formed in the center thereof;
A lower portion of the piston rod of the cylinder member is fixed to an upper portion of the piston rod through a through hole of the moving member to fasten the moving member to an upper portion of the piston rod, And an engaging member formed to be smaller than a size of the engaging member.
A lower flange portion;
An upper flange portion provided at an upper portion of the lower flange portion and having a lower portion of the strut of the offshore wind power generator connected to the upper portion;
A plurality of inclined corrector units provided at predetermined intervals on the upper portion of the lower flange portion so as to be positioned between the upper flange portion and the lower flange portion to maintain and correct a vertical gradient of the offshore wind power generator together with the upper flange portion;
And a support portion provided between the upper flange portion and the lower flange portion and supporting the upper flange portion,
A support body formed on an upper portion of the lower flange portion so as to be positioned between the inclined corrector portions and having an insertion groove formed thereon;
A support wall protruding from the lower portion of the upper flange portion in a direction of the insertion groove and formed at a predetermined interval in a lower portion of the upper flange portion so as to be inserted into the insertion groove;
And a plurality of support pads stacked vertically in the insertion groove in a state of being positioned between the support walls.
A lower flange portion;
An upper flange portion provided at an upper portion of the lower flange portion and having a lower portion of the strut of the offshore wind power generator connected to the upper portion;
And a plurality of inclined corrector units provided at predetermined intervals on the upper portion of the lower flange portion so as to be positioned between the upper flange portion and the lower flange portion to maintain and correct the vertical gradient of the offshore wind power generator together with the upper flange portion Lt; / RTI >
Wherein the inclination correcting portion comprises a cylinder member vertically disposed at an upper portion of the lower flange portion,
Wherein an upper portion of the piston rod of the cylinder member and a lower portion of the upper flange portion are rotatably fixed by a spherical plain bearing.
A lower flange portion;
An upper flange portion provided at an upper portion of the lower flange portion and having a lower portion of the strut of the offshore wind power generator connected to the upper portion;
And a plurality of inclined corrector units provided at predetermined intervals on the upper portion of the lower flange portion so as to be positioned between the upper flange portion and the lower flange portion to maintain and correct the vertical gradient of the offshore wind power generator together with the upper flange portion Lt; / RTI >
Wherein the upper flange portion is divided into two halves.
5. The method according to any one of claims 1 to 4,
And a wall portion extending upward in the lower flange portion is formed on an upper edge of the lower flange portion so as to be positioned in an outer direction of the inclined correcting portion.
The method according to claim 1,
Wherein a groove is formed in the central portion of the moving member so as to communicate with a through hole of the moving member to receive a head portion of the coupling member.
The method according to claim 1,
A guide rail extending from the outer side of the upper flange portion to the inner side of the upper flange portion is formed at a lower portion of the upper flange portion,
Wherein the moving member is moved from the outside of the upper flange portion to the inside of the upper flange portion along the guide rail while being accommodated in the inside of the guide rail.
The method of claim 3,
Wherein a lower portion of the cylinder member and an upper portion of the lower flange portion are rotatably fixed by a spherical plain bearing.
5. The method according to any one of claims 1 to 4,
A tilt sensor for sensing a tilt of the offshore wind turbine;
And a control unit for controlling the tilt correction unit according to a detection signal of the tilt sensor. delete

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