KR102480406B1 - Offshore wind power plant carrier - Google Patents

Abstract

The present invention relates to a carrier for offshore wind power generation facilities, which can be easily moved regardless of the water depth, so that it can be used as a part of an offshore wind power generator not only in deep water but also in coastal ground exposed above the sea level during low tide, such as low water depth or tidal flat terrain. It is useful for transporting equipment and various facilities of the installation ship, and the hull is light, and even if the lower part of the hull is in contact with the ground, it can minimize damage to the hull by reducing friction. Provides a carrier for offshore wind power generation equipment that can continuously transport various parts and equipment for installation.

Description

Offshore wind power plant carrier { Offshore wind power plant carrier }

The present invention relates to a carrier for offshore wind power generation facilities, and more particularly, since it can be easily moved regardless of the depth of water, it is useful for transporting parts of offshore wind power generators and various facilities of installation ships in deep water as well as tidal flats. It relates to available offshore wind power plant carriers.

In general, interest in eco-friendly renewable energy is increasing due to environmental pollution such as air quality deterioration due to increased use of fossil fuels.

In particular, in order to solve the greenhouse gas problem to prevent the earth's environmental destruction, research on the development of various renewable green energy is active, and expectations for technology development and market expansion are growing. Among them, wind power generation, which is a representative green energy, is currently in operation both domestically and abroad, and global trends such as enlargement of wind turbines, expansion of complexes, and conversion to offshore wind power generation are changing according to the expansion of power generation capacity.

These wind turbines generate electricity directly by driving a wind turbine mounted on the top of a post by wind power, or generate electricity by transmitting the power of the wind turbine to a generator, and are composed of blades, nacelles, towers, foundation structures, etc. Consists of.

On the other hand, the efficiency of the wind turbine increases as the wind speed is strong and the change in wind direction is small. In the sea, since the topography that reduces wind flow is less affected, the average wind speed of the offshore wind is higher than the wind speed of the surface wind, and the wind volume of the sea wind is also greater than that of the surface wind. In particular, since offshore winds far from inland have smaller turbulence characteristics, as wind power generation is more advantageous, research to install wind power generators mainly on the sea rather than on land is being actively conducted.

In addition, when the wind turbine is installed on the ground, the place where the wind turbine can be installed is limited due to restrictions on noise and aesthetics, but when the wind turbine is installed on the sea, it is advantageous in that it is hardly subject to these restrictions.

Accordingly, as shown in FIG. 1, the wind turbine installed on the sea is equipped with the blade 10, the nacelle 20, the tower 30, and the foundation structure 40, and the ground conditions, water depth, wind load, corrosion, and wind turbine scale It is influenced by various design factors such as , wave height, and icing, and it is difficult to move and operate equipment on the sea unlike on land, requiring great expertise in construction management and quality control.

The offshore wind turbine 1 is assembled and installed at sea using a tower control derrick or the like provided on the installation ship after transporting parts of the wind turbine by a ship. As prior art related to offshore wind turbine installation ships, Registration Patent No. 10-2119024 (Reference 1) and Registration Patent No. 10-1360285 (Reference 2) have been proposed.

The offshore wind turbine installation ship of Reference 1 is a ship including a crane and a leg that is installed to move up and down on the hull deck to fix the hull to the seabed ground, and the crane is installed on the deck and a seat into which the leg is inserted. Includes a crane boom with a space, a guide stopper that is fixed inside the seating space and pressurizes and fixes the edge of the leg inserted into the seating space, and a movable stopper that is installed movably along the seating space and fixes the protrusion of the leg do.

And the offshore wind turbine installation ship of Reference 2 is a hull with receiving grooves formed from the bow and stern, respectively, toward the middle of the hull; A plurality of rigs; It is installed on the upper part of the hull in the longitudinal direction of the hull, but one side is hinged to the bow side, and a pair of first rails are installed at one end and the other end in the width direction of the hull, An elect pad with a second rail installed between the first rail in the longitudinal direction of the hull; Installed between the elect pad and the hull, so that the elect pad can be built upward around the hinge, the elect pad is a sea foundation It is composed of: a hydraulic cylinder pushing up to the ash side.

The offshore wind turbine installation ship proposed through these references 1 and 2 is a structure that can be moved by floating on the sea, and can be easily towed to the installation site of the offshore wind turbine using a power line at sea with deep water.

However, offshore wind power generators can generate high-quality wind as the blade height increases. Since 2010, the size of the turbine has been increasing due to the global offshore wind power development plan and technological development. It reaches ~ 160 m and requires a water depth of 50 to 70 m for operation.

Accordingly, conventional offshore wind turbine installation ships have an average water depth of less than 50 m, such as the west coast of Korea, and a large tidal difference, so if the water depth of the installation site of the offshore wind turbine is low or the tidal flat topography can be exposed on the sea level, such offshore Even if a wind turbine installation ship uses its own power or uses a tugboat, it is impossible to move to a desired work place. Therefore, it is also very difficult to install an offshore wind turbine on a tidal flat in an island area with low water depth.

In addition, the conventional offshore wind turbine installation ship cannot be moved when the hull contacts the ground (or bedrock), and when the outer hull is torn in the event of a collision and seawater flows into the interior, the risk of sinking is also very high, and if it is caught on a reef, it cannot come out on its own is also impossible

On the other hand, in the case of a large offshore wind turbine, it is not possible to load all parts of the offshore wind turbine on the installation ship at once or to transport the offshore wind turbine assembled on land. have to transport

As an example of such a wind turbine carrier, it has been proposed in Patent Publication No. 10-2020-0062842 (Reference 3), but in the case of the west coast of Korea, where the water depth is low, the water depth is lowered or the tidal flat is exposed during low tide, so the carrier (park) The operation of the wind turbine is also restricted or impossible, which causes work delays when installing offshore wind turbines.

Reference 1: Registered Patent No. 10-2119024 Reference 2: Registered Patent No. 10-1360285 Reference 3: Patent Publication No. 10-2020-0062842

Therefore, as an object of the present invention to solve these problems, the present invention is an offshore wind power generation facility that can be easily moved regardless of the water depth and can be usefully used for transporting offshore wind turbine parts and facilities of installation ships in deep water as well as low seas. Its purpose is to provide carriers.

In addition, an object of the present invention is to provide an offshore wind power generation facility carrier having a structure that can be moved even on the coastal ground exposed above the sea level at low tide or on the tidal flat, as well as having a light hull and stable operation.

The present invention to solve such a technical problem;

A housing in which a deck capable of transporting offshore wind power facilities is formed and a sealed buoyancy space is formed therein, a foam material filled in the buoyancy space of the housing, and a plurality of parts installed in the buoyancy space to maintain the shape of the housing. A hull made of a reinforcing frame; Provides an offshore wind power generation facility carrier comprising a; wheel portion rotatably provided on the hull and capable of contacting the ground.

At this time, the wheel unit includes a plurality of main wheel modules continuously provided in a line on both sides of the hull; The main wheel module consists of a main wheel contacting the ground on both sides of the hull and a main wheel shaft on which the main wheel is supported, and is supported by a main damper fixed to the hull; The main wheel of the main wheel module is characterized in that it consists of a main tube made of rubber and a main filling material made of styrofoam or urethane foam filled inside the main tube.

And it is characterized in that belt-shaped track belts are mounted on the main wheels of the plurality of main wheel modules.

In addition, the wheel unit includes a plurality of auxiliary wheel modules provided in the lower part of the hull to prevent damage to the bottom surface of the hull in direct contact with the ground; The auxiliary wheel module includes an auxiliary damper fixed to the lower inside of the hull, a vertical axis rotatably provided below the auxiliary damper, a bracket eccentrically mounted at the lower end of the vertical axis, an auxiliary wheel axis fixed horizontally to the bracket, It is characterized in that it is made of an auxiliary wheel fixed to the auxiliary wheel axis and filled with an auxiliary filler made of styrofoam or urethane foam inside the auxiliary tube.

In addition, in the center of the front half of the hull, a towing bobbin in which a ship towing wire is wound, having a fixture that can be fixed to the ground at an end to be used to move the carrier to another place in case of an emergency, and to rotate the towing bobbin Characterized in that a traction motor is provided.

According to the present invention, it can be easily moved regardless of the depth of the water, so the parts of the offshore wind power generator and the wind turbine are installed at sea even in the coastal ground exposed above the sea level during low tide, such as low water depth or tidal flat terrain, as well as deep water depth It is useful for transporting various facilities of the installation ship used to do this.

In addition, the carrier according to the present invention can minimize damage to the hull by reducing friction even when the lower part of the hull is in contact with the ground while the hull is light, and can continue to operate even if part of the hull is damaged. Transport of parts and equipment can be carried out continuously.

1 is a view showing a general offshore wind power generator.
2 is a diagram showing an example of transporting structural equipment of an offshore wind turbine installation ship using an offshore wind power generation facility carrier according to an embodiment of the present invention.
3 is a diagram showing an example of transporting parts of an offshore wind power generator using an offshore wind power generation facility carrier according to an embodiment of the present invention.
4 is a longitudinal cross-sectional view of an offshore wind power generation facility carrier according to an embodiment of the present invention.
5 is a bottom view of an offshore wind power generation facility carrier according to an embodiment of the present invention.
6 is a side view of an offshore wind power generation facility carrier according to an embodiment of the present invention.
7 is a side view of an offshore wind power plant carrier according to another embodiment of the present invention.
8 is a perspective view of an offshore wind turbine installation ship and a carrier according to another embodiment of the present invention.
9 is a side view of an offshore wind power generation facility carrier according to another embodiment of the present invention.

Hereinafter, the features of the offshore wind power plant carrier according to the present invention will be understood by the detailed embodiment with reference to the accompanying drawings.

Prior to this, the terms or words used in this specification and claims should not be construed as being limited to the usual or dictionary meaning, and the inventor appropriately uses the concept of the term in order to explain his/her invention in the best way. It should be interpreted as a meaning and concept consistent with the technical idea of the present invention based on the principle that it can be defined.

Therefore, the embodiments described in this specification and the configurations shown in the drawings are only one of the most preferred embodiments of the present invention, and do not represent all the technical ideas of the present invention, so at the time of this application, they can be replaced. It should be understood that there may be many equivalents and variations.

1 to 6, the offshore wind power generation facility carrier according to the present invention includes various facilities or parts of the installation ship 100 necessary for the installation as well as the parts of the offshore wind power generator 1 to the offshore wind power generator 1 It is a transportation means that can be used to transport to the installation site.

At this time, the offshore wind turbine 1 is composed of parts such as blades 10, nacelles 20, towers 30, and foundation structures 40.

The offshore wind power generation facility of the present invention described below includes all facilities such as crane facilities of the installation ship 100 where the offshore wind power generator 1 is assembled and installed as well as parts constituting the offshore wind power generator 1 .

In addition, the foundation structure 40 may generally use a monopile, gravity type, jacket, or the like method.

More specifically, a monopile consists of a steel pipe pile with a diameter of 4 ~ 6M and a transition piece that connects the tower. The pile is installed through driving or excavation, and the transition piece ) and connected by grouting. It is known as an economical structure in the terrain of around 20M depth, and when the installation water depth is 20M or more and the turbine capacity is 5MW or more, the pile diameter exceeds 6m, so a lot of steel is required, and the securing of construction equipment such as driving and excavation is also limited. Therefore, the applicability should be reviewed together with the characteristics of the foundation ground.

And the gravity base is a structure that resists overturning moment with its own weight, and was originally applied at a low water depth (10M), but in Thornton Bank, which was opened in 2008, there is a case where it is applied to a water depth of about 30M. This type is manufactured on land and installed using an offshore crane, so the installation cost is relatively low, but the dismantling cost is high and it is difficult to install when the depth of the bedrock is deep, so the conditions of the temporary site must be considered.

Next, the jacket is a type originally used in the oil and gas drilling business and is applied to a large water depth environment of 20 to 80M. Assemble the jacket by welding circular steel pipes with a diameter of 5 ~ 15m, and install and fix the jacket pile and pin pile in the jacket leg. There are cases applied at Beatrice Demonstration Complex in England and Alpha Ventus in Germany. Composite pile is a type that is widely used in foundations of marine bridges and is composited by pouring concrete by filling the inside of the steel pipe after driving large-diameter steel pipe piles offshore.

The installation ship 100 for installing such an offshore wind power generator 1 on the sea includes a hull 110 that can float on the sea with buoyancy, and a wheel portion rotatably provided on the hull 110 and capable of contacting the ground ( 120), a leg part 130 for fixing the hull 110 to the seabed ground, and a crane 140 for lifting parts of the offshore wind turbine 1, so that the carrier ship 200 can stop. A work space having a vertically open structure may be provided, and an entrance through which the carrier ship 200 may enter and exit may be formed at the rear.

In addition, the carrier 200 of the present invention can transport parts such as the blade 10, the nacelle 20, the tower 30 and the foundation structure 40 of the offshore wind turbine 1 to the installation ship 100. In order to do so, it includes a hull 210 designed to float on the sea by buoyancy, and a wheel portion 220 rotatably provided on the hull 210 and in contact with the ground. At this time, the hull 210 may be further provided with a binding means 230 such as a belt or a chain to fix various parts and facilities of the installation ship 100 and parts of the offshore wind turbine 1.

Of course, in the carrier 200 of the present invention, the parts of the leg part 130 and the crane 140 constituting the hull 110 of the installation ship 100 also use the carrier 200 so that the offshore wind power generator 1 It is transported to the installation ship 100 that has moved to the area to be installed.

This is to minimize the weight of the installation ship 100 and easily move the installation ship 100 to the work area. Of course, a tower crane 160 is basically mounted on the installation ship 100 so that various parts necessary for assembling or installing the offshore wind turbine 1 can be easily moved on the deck. This tower crane 160 can rotate the jib 161 up and down as well as horizontally rotate, so that various parts can be smoothly transported to an arbitrary position on the deck of the hull 110.

In addition, the crane 160 can raise the height by raising the crane support (or mast) 162 one step at a time. In this case, the lifting crane support (or mast) 162a can be moved to the installation ship 100 through the carrier ship 200.

Hereinafter, the configuration of each part of the present invention will be described in detail.

The hull 210 of the carrier 200 can form a deck having an area capable of loading one or more of the offshore wind power generator 1 and its parts and various facilities and parts of the installation ship 100 while maintaining a low height. It consists of a housing 211 forming the outer shape of the hull 210 and a foam 212 filled in the housing 211 so as to be.

At this time, the housing 211 is formed with a closed buoyancy space 211a to generate buoyancy therein, and the buoyancy space 211a is vertically and horizontally installed to maintain the shape of the housing 211 of the hull 210. A plurality of reinforcing frames 213 are integrally fixed so as to intersect. The housing 211 is preferably made of a steel plate, but it is also possible to reduce the weight by making the housing 211 made of an aluminum alloy having a smaller specific gravity than a steel plate.

Styrofoam, urethane foam, etc. may be used as the foam 212 filling the inside of the housing 211, that is, the buoyancy space 211a. However, the material of the foam 212 is not limited thereto and can be filled with various functional urethane foam compositions capable of implementing excellent performance in terms of flame retardancy, water resistance and adhesion while implementing similar physical properties.

In particular, as the foam 212 is filled in the buoyancy space 211a of the housing 211 of the hull 210, the seawater is buoyant due to the foam 212 even if the front or side parts of the hull 210 collide with the ground or reef and are torn. It is prevented from being completely introduced into the space 211a, so that various facilities and accessories for the installation of the offshore wind power generator 1 using the carrier 200 can be continuously carried out without difficulty.

Although this hull 210 may be formed in a square shape as a whole to secure a larger deck area, the bow is moved forward at the center so as to minimize resistance with seawater or the ground when the hull 210 moves forward. It may protrude and be streamlined. The front bottom of the hull 210 is preferably formed to be inclined upward toward the front.

And, the wheel unit 220 is rotatably provided on the hull 210 so that the sea level is lowered due to ebb tide or the like, or it can come into contact with the ground such as tidal flats exposed on the sea level. At this time, since the ground is generally uneven due to tidal flats, etc., the wheel unit 220 may fall out and should be able to quickly escape.

The wheel unit 220 includes main wheel modules 220a provided on both sides of the hull 210. The main wheel module 220a consists of a main wheel 221 in contact with the ground on both sides of the hull 210 and a main wheel shaft 222 on which the main wheel 221 is supported, and a plurality of both sides of the hull 210 It consists of a structure arranged in a row in a row.

Of course, the main wheel module 220a is supported on the hull 210 via a main damper 223 that performs a buffering function to prevent the impact of the ground from being transmitted to the hull. That is, the main damper 223 is fixed to the hull 210 and the main wheel shaft 222 on which the main wheel 221 is supported is supported by the main damper 223 .

Of course, the main damper 223 provided in the main wheel module 220a can use a hydraulic damper using hydraulic pressure as an example, but can be replaced with a plate-type or coil-type compression spring for absorbing shock, and this degree The degree of design change of is also within the scope of the present invention.

Here, in the case where the hull 210 has a structure capable of moving using its own power, the main wheel 221 is integrally fixed to the main wheel shaft 222 of the main wheel module 220a, and the hull is powered by engine driving. (21) can be moved forward and backward, and in the case of a non-powered method such as a barge, it can be moved using a tugboat.

In addition, the main wheel 221 of the main wheel module 220a has a main tube 221a made of rubber so as to absorb shock and is light and not easily damaged, and a main filler 221b filled inside the main tube 221a. ) is made up of

Here, the main tube 221a uses synthetic rubber in which a steel wire is inserted and injected into the inside to minimize tearing or damage, and the main filler 223 is the buoyancy space of the housing 211 of the hull 210 ( Styrofoam, urethane foam, etc. can be used similarly to the foam 212 filled in 211a).

On the other hand, as shown in FIG. 6, the main wheels 221 of the plurality of main wheel modules 220a constituting the wheel unit 220 and arranged in a row on both sides of the hull, respectively, have belt-shaped track belts 224 ) can be installed to operate like a caterpillar wheel. This is useful for getting out of tidal channels, etc., where the main wheel 221 can easily fall when the track belt 224 contacts the ground and moves. In this case, the track belt 224 is made of rubber and mounted so that the plurality of main wheels 221 can be seated in the track.

Of course, the wheel unit 220 may be made by mounting a known metal endless track on both sides of the hull 21, and it is obvious that this degree of design change also falls within the scope of the present invention.

In addition to the main wheel module 220a, the wheel unit 220 further includes a plurality of auxiliary wheel modules 220b provided in the lower portion of the hull 220 to prevent damage caused by direct contact with the bottom of the hull to the ground. .

The auxiliary wheel module 220b includes an auxiliary damper 225 fixed to the inner lower side of the hull 110, a vertical shaft 226 rotatably provided below the auxiliary damper 225, and the vertical shaft 226 It consists of an auxiliary wheel axle 227 provided at the bottom and an auxiliary wheel 228 fixed to the auxiliary wheel axle 227.

At this time, the auxiliary wheel 228 is composed of an auxiliary tube 228a made of rubber to absorb shock and to be light and not easily damaged, and an auxiliary filler 228b filled in the auxiliary tube 228a. The auxiliary tube 228a and the auxiliary filler 228b of the auxiliary wheel 228 are made of the same material as the main tube 221a and the main filler 221b of the main wheel 221.

This configuration has the advantage of allowing the lower portion of the hull 210 to be easily moved while preventing contact with the ground. Furthermore, by mounting the bracket 229 eccentrically at the lower end of the vertical axis 226 and fixing the auxiliary wheel axis 227 horizontally to the bracket 229, when the auxiliary wheel 228 hits an obstacle such as a reef on the ground, the vertical axis While the 226 rotates horizontally, the auxiliary wheel 228 avoids obstacles such as reefs, so that the hull 210 can move smoothly.

In addition, in the center of the front half of the hull 210, a towing bobbin 241 around which a ship towing wire 240 is wound for use in moving the carrier ship 200 to another place in case of an emergency, and the towing bobbin 241 A traction motor 242 for rotating is provided.

At this time, a fixture 240a that can be fixed to the ground may be provided at the end of the ship towing wire 240. These fixtures (240a) can be applied to a stake as well as a conventional anchor (anchor).

Therefore, when additional power is required to move the carrier 200 of the present invention, such as when the hull 210 of the carrier 200 is stranded on a reef or a tidal channel, etc. The fixture 240a is fixed to the ground by pulling it forward in the direction of travel, and the traction motor 242 is driven by the operator's manipulation of the control panel to rotate the bobbin 241 for traction to wind and pull the wire 240 for traction. Due to this, the carrier 200 may leave the area.

Of course, the fixture 240a of the carrier 200 is dragged by a tugboat that is relatively easy to operate and fixed to the ground, or after fixing the ship traction wire 240 to the installation ship 100 used to install the offshore wind power generator, towing When the motor 242 is driven to wind the traction wire 240 around the traction bobbin 241, the carrier 200 can leave the area.

7 is a view for explaining an offshore wind power generation facility carrier according to another embodiment of the present invention. According to this, the sea level or the ground is relatively low compared to the deck of the carrier 200, and the assistive device 218 for getting on and off is provided at the rear of the hull 210 of the carrier 200 to facilitate the movement of various equipment when berthing at a coastal marina are provided

The aid for getting on and off 218 functions as a footrest and has a closed space 218a formed therein to generate buoyancy. It maintains a horizontal state when docked at a coastal dock, and can be spanned over the upper edge of the dock or supported on the ground.

This aid for getting on and off 218 has a structure that can be rotated around the hinge part 218c, and while the carrier 200 is moving, the end of the aid for getting on and off 218 is directed upward as shown in (a) of FIG. When loading or unloading various equipment on the carrier 200, the end of the getting on and off aid 218 is rotated so that it spreads in the horizontal direction as shown in (b) keep

In this case, the inlet cylinder body is fixed to the aft part of the hull 210 so that the getting on and off aid 218 rotates around the hinge part 218c, and the cylinder rod is hinged to the get on and off aid 218 It is preferable to rotate the assisting tool 218 for getting on and off about the hinge part 218c in an inlet type by combining.

These aids for getting on and off 218 function as footholds, and various equipment such as amphibious vehicles, amphibious dredging excavators, and amphibious special cranes can be directly boarded or disembarked from the carrier 200 at the coast.

Of course, the amphibious vehicle can be easily used for the movement of workers or towing of various small parts, and the amphibious dredging fork crane and amphibious special crane can be used for floor foundation work at the installation site of offshore wind power generators or installation of power line cables, etc. can be put to good use.

And Figure 8 is a perspective view of an offshore wind turbine installation ship and a carrier according to another embodiment of the present invention.

According to this, one or more bilge keels 119 are provided in the longitudinal direction of the hull 110 at the bottom or rear of the installation ship 100 used when installing the offshore wind power generator. When the installation ship 100 is sailing on the sea, the bilge keel 119 moves in a vertically straightened state to facilitate the straight movement of the installation ship 100 and to prevent the installation ship 100 from rocking. It can be prevented and stable sailing is possible. Of course, the installation ship 100 is folded horizontally to prevent damage due to contact of the bilge keel 119 to the ground in tidal flats or low water depths where it must run on the ground. let it Of course, it is preferable to control horizontal or vertical rotation of the bilge keel 119 using a hydraulic motor method or a rope winding method using a motor.

Of course, one or more bilge keels in the longitudinal direction of the hull 210 even at the bottom or rear of the hull 210 of the carrier 200 that carries each part and equipment for installing the offshore wind power generator on the installation ship 100 (219) is provided. When the carrier 200 is sailing on the sea, the bilge keel 219 moves with the keel vertically extended to smooth the straight movement of the carrier 200 and prevents the carrier 200 from wobbling in a stable manner. sailing is possible Of course, the carrier 200 is folded horizontally to prevent the bilge keel 219 from contacting the ground and being damaged in tidal flats or low water depths where it must travel on the ground. Of course, it is preferable to control the horizontal or vertical rotation of the bilge keel 219 using a hydraulic motor method or a rope winding method using a motor.

And Figure 9 is a side view of an offshore wind power generation facility carrier according to another embodiment of the present invention. According to this, the carrier ship 200 is provided with a propeller 250 at the rear lower side of the hull 210 as a thrust device for providing propulsion so that it can move on the sea using its own power. The propeller 250 is connected to the engine provided in the hull 210 by a gear, receives power, rotates, and generates propulsion to move forward or backward on the sea.

Of course, the support part 252 of the propeller 250 employs a rotatable structure at the lower part of the rear of the hull 210 and moves using the wheel 221 or is damaged by contacting the propeller 250 with the ground in a low water depth In order to prevent this, the support part 252 can be rotated to rotate upwards at the rear of the hull 210. In this case, the support part 252 preferably uses a hydraulic motor method or uses a motor to control the rotation.

The above description is merely illustrative of the technical idea of the present invention, and those skilled in the art can make various modifications and variations without departing from the essential characteristics of the present invention. The protection scope of should be interpreted by the claims below, and all technical ideas within the equivalent range should be construed as being included in the scope of the present invention.

1: offshore wind turbine 10: blade
20: nacelle 30: tower
40: foundation structure 100: installation line
200: carrier 210: hull
220: wheel unit 220a: main wheel module
220b: auxiliary wheel module 224: track belt
240: wire for ship towing 240a: fixture
241: bobbin for traction 242: traction motor

Claims (5)

A housing 211 in which a deck capable of transporting offshore wind power facilities is formed and a sealed buoyancy space 211a is formed therein, and a foam 212 filled in the buoyancy space 211a of the housing 211, A hull 210 composed of a plurality of reinforcing frames 213 installed in the buoyancy space 211a to maintain the shape of the housing 211; Including; a wheel portion 220 rotatably provided on the hull 210 and capable of contacting the ground,
The wheel unit 220 includes a plurality of main wheel modules 220a continuously provided in a row on both sides of the hull 210, and the bottom surface of the hull 210 is in direct contact with the ground to prevent damage to the hull 220 ) Includes a plurality of auxiliary wheel modules (220b) provided at the bottom of;
The main wheel module 220a consists of a main wheel 221 in contact with the ground on both sides of the hull 210 and a main wheel shaft 222 on which the main wheel 221 is supported, the main fixed to the hull 210 supported by the damper 223;
The main wheel 221 of the main wheel module 220a is made of a main tube 221a made of rubber and a main filler 221b made of styrofoam or urethane foam filled inside the main tube 221a;
The auxiliary wheel module 220b includes an auxiliary damper 225 fixed to the lower inside of the hull 210, a vertical shaft 226 rotatably provided below the auxiliary damper 225, and a lower end of the vertical shaft 226 A bracket 229 eccentrically mounted on the bracket 229, an auxiliary wheel axle 227 horizontally fixed to the bracket 229, and an auxiliary wheel axle 227 fixed to the auxiliary wheel axle 227 but made of styrofoam or urethane foam inside the auxiliary tube 228a. An offshore wind power generation facility carrier, characterized in that consisting of an auxiliary wheel 228 filled with a filler (228b).
According to claim 1,
An offshore wind power generation facility carrier, characterized in that a belt-shaped track belt 224 is mounted on the main wheels 221 of the plurality of main wheel modules 220a.
According to claim 1,
In order to move the carrier ship 200 to another place in case of an emergency, the center of the first half of the hull 210 is equipped with a fixture 240a that can be fixed to the ground at the end, and a wire 240 for traction is wound around. An offshore wind power generation facility carrier, characterized in that a traction bobbin 241 and a traction motor 242 rotating the traction bobbin 241 are provided. delete delete

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