KR20200107105A - Floating crane for installation of offshore wind turbine tower using the movable counter weight - Google Patents

Abstract

The present invention relates to a floating crane for wind turbine tower installation using a movable counter weight. The floating crane for wind turbine tower installation using a movable counter weight comprises: a boom wherein the lower end thereof is hinge-coupled to the surface of a barge, and a support with an inclination of a prescribed angle on the upper end thereof; a spreader which has a plurality of lugs on the upper and lower surfaces thereof, and horizontally ascends and descends by pulling and loosening a wire rope vertically descending from a second pulley; a lifting tool which has a holder being formed on one side thereof and allowing a wind turbine tower to be inserted thereinto to be supported thereon and a plurality of lugs on the upper and lower surfaces thereof, and is linked to the spreader; and a counter weight which is provided on the opposite side of one side of the lifting tool where the holder is formed, allows the position at the lifting tool to be moved forward and backward while being coupled to the lifting tool, and acts by the resistance against the external force when the wind turbine tower is placed on the holder to maintain the balance of the entire lifting tool. Even if the height of the wind turbine tower is higher than the height of the boom of the crane, the wind turbine tower can be lifted without using a two-boom floating crane or a large special crane. The balance of the entire lifting tool can be maintained by a movement of the counter weight at the lifting tool to stably install the wind turbine tower without overturning the wind turbine tower on the sea.

Description

{Floating crane for installation of offshore wind turbine tower using the movable counter weight}

The present invention relates to an offshore crane for installing a wind tower using a movable counter weight, and more particularly, a two boom offshore crane or a large special crane is not used at sea even if the height of the wind tower is higher than the height of the crane. Not only can the wind power tower be lifted without the need to be lifted, but also the movement of the counter weight in the lifting tool maintains the balance of the entire lifting tool so that the wind tower can be stably installed without overturning at sea. About.

In general, wind power generation is a new renewable energy, rich in resources and constantly regenerated, and is not only distributed over a wide area, but is also clean and spotlighted as an alternative energy source in preparation for depletion of fossil energy such as no emission of greenhouse gases due to power generation. Receiving.

Wind power is classified as distributed power in terms of system operation in that it generates power by using wind, which is natural energy, so when the wind blows, it always produces power regardless of demand.

The wind turbine system is divided into a mechanical system, an electric system, and a control system that controls the wind turbine. In addition, it is divided into a hub system including blades, a nutshell equipped with various mechanical, electrical, and control devices, and a tower system for supporting the weight of the upper hub system and nutshell from the ground.

Wind power generators are divided into land use and marine use depending on the installation location. In particular, offshore wind power generation enables wind power generation through the construction of a wind power generation complex in or on the water, and from the viewpoint of offshore, wind power generation in regions belonging to inland areas such as lakes, narrow rivers, and closed coastal areas is also possible. Included. Moreover, offshore wind power generation can obtain more stable and better wind speed than on land, has fewer obstacles, noise and radio interference, and can reduce transportation and installation and construction costs of large-sized wind power generators, and consumes a large amount of power. Since most of the regions are located on the coast, there is an advantage in terms of transmission cost.

Conventionally, wind turbines installed on the sea are manufactured on land, then shipped to a barge and towed by a tugboat to the installation sea area, and then the wind turbine is erected and installed on the foundation structure installed on the sea using a crane equipped with a large crane. . In addition, major components of wind power generators are directly assembled and installed at sea. In other words, it is necessary to assemble the wind tower of approximately 1-3 stages, the hub assembly, and the blade assembly at the same time or one by one, and then lift it up using a crane installed on a large crane. For this, the height of the boom is more important than the load capacity of the crane.

For the efficient power generation of wind turbines, the height of wind turbines is increasing at sea, and the length is about 80 to 130 m.To lift it, the height of the wind turbine must be lower than the height of the crane's boom. It is difficult to supply cranes equipped with large cranes that can be lifted by hand. Moreover, the installation of wind turbines in deep seas is subject to more constraints.

In addition, when moving the wind turbine while the lower part of the wind turbine is lifted using a crane, the center of gravity of the wind turbine is not located in the center of the wind turbine tower, but from the center of the tower to the direction in which the blades of the wind turbine are located. Because it is eccentric, safety is low due to the risk of overturning the wind turbine.

As a prior art, Republic of Korea Patent Publication No. 10-2010-0045404 (published on May 3, 2010) provides a construction device 50 for safely and smoothly constructing a float-type offshore wind power generator 10 on a deep sea. As one, the construction device 50 for constructing the offshore wind power generator 10 by the crane ship S is mounted at a working position in the vertical direction with respect to the crane ship S, and a guide member having the lower end side disposed in the sea (51) and a holding portion capable of attaching and detaching the tower portion (20) divided into a plurality of axial directions, and comprising at least one pair of arm portions (60) that slide along the guide member (51). Is being disclosed. This is not only complicated in structure, but also in terms of assembly and safety due to shaking by waves or waves by installing offshore wind power generators while assembling them at sea, and since wind power generation facilities are built by working with ordinary cranes, it is also practical for installation. There is a problem that takes a long time.

Republic of Korea Patent Publication No. 10-2010-0045404 (published on May 3, 2010): Construction method and construction device of offshore wind power generation device

The present invention is to solve the above problems, and an object of the present invention is to lift a wind tower without using a two boom offshore crane or a large special crane at sea even if the height of the wind tower is higher than the boom height of the crane. It is to provide a liftable, offshore crane for wind tower installation.

In addition, in the offshore crane of the present invention, the counterweight moves the position of the lifting tool back and forth according to the field situation in the state of being combined with the lifting tool to maintain the balance of the entire lifting tool, thereby stably preventing the wind tower from overturning at sea. We would like to provide an offshore crane for installation of a wind tower that can be installed.

In addition, it is an object of the present invention to provide an offshore crane for installing a wind tower, which can maximize the efficiency of wind power generation by allowing the height of a wind tower installed at sea to be further enhanced.

The present invention in order to achieve the above object, the present invention is a boom having a lower end hinge-coupled to the surface of the pants and a support having an inclination angle formed at an angle at the upper end; A spreader that is provided with a plurality of lugs on the upper and lower sides, and horizontally lifts and descends according to the pulling and loosening of the wire rope vertically descending from the second pulley; A lifting tool having a holder to which the wind tower is inserted and supported on one side thereof, a plurality of lugs provided on the upper and lower surfaces thereof, and interlocking with the spreader; The holder is provided on the opposite side of one side of the lifting tool, the position of the lifting tool can be moved back and forth in a state in which the lifting tool is engaged, and the lifting tool acts as a resistance force against the external force when the wind tower is seated on the holder. It characterized in that it comprises a; counter weight for maintaining the overall balance.

In addition, the present invention is a boom having a lower end hinge-coupled to the surface of the pants and a support having an inclined angle formed at an angle at the upper end; A holder to which a wind tower is inserted and supported is formed on one side, and a plurality of lugs are provided on the upper and lower surfaces thereof, and the shackle coupled to the upper lug is a lifting tool connected by a wire rope and a shackle directly coupled to the hook; The holder is provided on the opposite side of one side of the lifting tool, the position of the lifting tool can be moved back and forth in a state in which the lifting tool is engaged, and the lifting tool acts as a resistance force against the external force when the wind tower is seated on the holder. It includes; counter weight that maintains the overall balance.

In addition, the present invention pants are formed indentations; A jacket structure in which a lower leg is fixed to the trousers and a winch connected to a wire rope is fixedly installed at the upper end thereof; A spreader that is provided with a plurality of lugs on the upper and lower surfaces and horizontally lifts and descends according to the pulling and loosening of the wire rope vertically descending from the winch; A lifting tool having a holder to which the wind tower is inserted and supported on one side thereof, a plurality of lugs provided on the upper and lower surfaces thereof, and interlocking with the spreader; The holder is provided on the opposite side of one side of the lifting tool, the position of the lifting tool can be moved back and forth in a state in which the lifting tool is engaged, and the lifting tool acts as a resistance force against the external force when the wind tower is seated on the holder. It characterized in that it comprises a; counter weight for maintaining the overall balance.

In addition, the present invention pants are formed indentations; A jacket structure in which a lower leg is fixed to the trousers and a winch connected to a wire rope is fixedly installed at the upper end thereof; A holder to which a wind tower is inserted and supported is formed on one side, and a plurality of lugs are provided on the upper and lower surfaces thereof, and the shackle coupled to the upper lug is a lifting tool connected by a wire rope and a shackle directly coupled to the hook; The holder is provided on the opposite side of one side of the lifting tool, the position of the lifting tool can be moved back and forth in a state in which the lifting tool is engaged, and the lifting tool acts as a resistance force against the external force when the wind tower is seated on the holder. It includes; counter weight that maintains the overall balance.

In addition, the present invention is provided with a pair of second pulleys fixedly installed on both sides of the upper end of the support and connected by a winch and a wire rope, and the wire rope is connected through the second pulley, and ascending and descending according to the pulling and loosening of the wire rope. The third pulley is provided, and the third pulley further includes a support member for supporting the spreader, provided with a hook coupled to a lug on the upper surface of the spreader.

In addition, in the present invention, the wire rope is connected through the winch, and a third pulley is provided that is raised and lowered according to the pulling and loosening of the wire rope, and the third pulley is provided with a hook that is coupled to the lug on the upper surface of the spreader. The supporting member is further configured.

In addition, in the present invention, a shackle is coupled to the lugs on the upper and lower surfaces of the lifting tool, and the shackle coupled to the lugs on the upper surface of the lifting tool is connected by a wire rope and a shackle coupled to the lug on the lower surface of the spreader. The combined shackle is connected by a wire rope to the fixture of the wind tower body, and the number of wire ropes connecting the spreader and the lifting tool is increased compared to the number of wire ropes connected to the hook to flexibly adjust the installation angle of the wire rope. The load burden of each rope can also be distributed.

In addition, in the present invention, a fender is additionally provided on the arcuate inner surface of the holder to mitigate collision with the wind power tower.

In addition, in the present invention, a separation preventing device is additionally provided on the upper surface or the lower surface of the lifting tool to prevent separation of the wind power tower inserted in the holder.

In addition, in the present invention, the separation preventing device crosses two members in a shape of a combination of a semicircle and a straight line around the hinge, and when the screw installed on the straight member side rotates, the two straight members of the separation prevention device are moved in opposite directions. To open or close the semicircular member.

In addition, in the present invention, the counter weight is loaded in a housing coupled to the lifting tool, rails are installed on both sides of the upper surface of the lifting tool, and a transporter movable above the rail is additionally provided, and the transporter is It is fixedly coupled to the housing within the bend.

In addition, in the present invention, the transporter consists of two leg members connected by a wheel and a hinge, and when the upper end of the housing is lifted, the two leg members of the transporter are unfolded, and the skirt on the side of the bent portion of the upper end of the housing is separated from the upper surface of the lifting tool. Thus, the housing is in a movable state, and when the two leg members of the transporter are folded, the upper part of the housing is lowered and the skirt on the side of the bent part of the upper part of the housing is in close contact with the upper surface of the lifting tool to fix the housing.

In addition, in the present invention, the jacket structure is made of legs, braces, and reinforcing pipes, but the braces and reinforcing pipes between the legs of the jacket structure on the indentation side are not installed so as not to interfere with the wind tower, and the upper deck is a rectangular frame and a deck in the interior thereof. It is a shape consisting of a cross-shaped reinforcement part for reinforcing the jacket structure, and each leg has a symmetrical structure based on the center point of the upper deck for stabilization of the jacket structure.

According to the present invention, even if the height of the wind power tower is higher than the boom height of the crane, it is possible to lift the wind power tower at sea without using a two boom offshore crane or a large special crane. The height of the tower can be further enhanced to maximize the efficiency of wind power generation, and the movement of the counter weight in the lifting tool maintains the balance of the entire lifting tool, allowing the wind tower to be stably installed without overturning at sea. It can have an effect.

1 is a side view showing an offshore crane for installing a wind tower as an embodiment according to the present invention.
Figure 2 is a perspective view showing the main parts of the boom and lifting tool in the offshore crane for installing a wind tower according to an embodiment of the present invention.
Figure 3 is a perspective view showing a lifting tool in the offshore crane for installing a wind tower according to an embodiment of the present invention.
Figure 4 is a view showing the plane of Figure 3 in the offshore crane for installing a wind tower according to an embodiment of the present invention.
Figure 5 is a view showing the rear of Figure 3 in the offshore crane for installing a wind tower according to an embodiment of the present invention.
Figure 6 is a view showing the step of moving the counter weight in the offshore crane for installing a wind tower according to an embodiment of the present invention.
7 is a perspective view showing an offshore crane for installing a wind tower as another embodiment according to the present invention.
Figure 8 is a side view showing an offshore crane for installing a wind tower as another embodiment according to the present invention.
9 is a plan view showing an offshore crane for installing a wind tower as another embodiment according to the present invention.

A preferred embodiment of the present invention configured as described above will be described in detail with reference to the accompanying drawings. Note that the accompanying drawings and the description with reference thereto are illustrated in order to be easily understood by those of ordinary skill in the art with respect to the present invention, and are not intended to limit the spirit and scope of the present invention. You will have to do it.

In Figures 1 to 6, in an embodiment of the present invention, the offshore crane 10 is a boom (Boom) through a winch (12) and a back tray (13) on a barge (11). ) (20) is supported and lifted by a wire rope (14). The offshore crane 10 of the present invention has a structure for more easily installing the wind tower 1 on a foundation structure (not shown) already installed on the sea. Here, the marine crane of the present invention uses one boom 20.

In addition, the lower end of the boom 20 having a certain length is hinged to the surface of the pants 11. The first pulley 15 is fixedly installed at the upper end of the boom 20. The first pulley 15 of the boom 20 is connected to the winch 12 and the back tray 13 by a wire rope 14 and a plurality of pulleys installed on the trousers 11. Accordingly, the boom 20 is raised and lowered at a certain angle with a hinge axis at the lower end by the operation of the winch 12.

1 and 2, in the offshore crane 10 of the present invention, the support 21 is formed with an inclination angle at a predetermined angle on the upper end of the boom 20. A pair of second pulleys 23 are fixedly installed on both sides of the upper end of the support 21, and the second pulley 23 is connected to the winch 12 and the wire rope 24. In addition, a third pulley 25 is coupled to each wire rope 24. The third pulley 25 is raised and lowered according to the pulling and loosening of the wire rope 24. Hooks 26 are coupled to the third pulley 25, respectively. In the support 21 to which the second pulley 23 is coupled, through-holes are formed vertically so that the wire rope 24 is connected through. The second pulley 23, the wire rope 24, the third pulley 25, and the hook 26 are support members for supporting the spreader 30.

1 and 2, in the offshore crane 10 of the present invention, the spreader 30 has a substantially flat plate shape, and a plurality of lugs 31 and 32 are provided on the upper and lower surfaces of the spreader 30, The hook 26 of the third pulley 25 is coupled to the upper lug 31, respectively, and the shackle 33 is coupled to the lug 32 of the lower surface, and the wire descending vertically from the second pulley 23 The spreader 30 is raised and lowered horizontally without tilting along with the third pulley 25 that rises and descends according to the pulling and loosening of the rope 24.

In addition, in the offshore crane 10 of the present invention, the lifting tool 40 is also substantially in a flat plate shape, and the wind power tower 1 is inserted and supported on one side of the lifting tool 40. ) Is formed. It is preferable that the inner side of the holder 41 is formed in an arc shape in consideration of the cross section of the wind power tower 1. A fender 42 made of rubber material is provided on the inner surface of the holder 41 in an arc shape to alleviate a collision with the wind tower 1.

Here, as the wind power tower 1 is inserted into the lifting tool 40 in an upright state, the lifting tool 40 is from the point of insertion of the wind tower 1 into the holder 41 to the mechanical device of the wind turbine composed of a nutshell, a hub, and a blade. ) Of the upper part and the outside of the boom 20, so that the overall height of the wind power tower can be further enhanced.

In addition, on the upper surface or the lower surface of the lifting tool 40, a detachment preventing device 50 for preventing the detachment of the wind tower 1 inserted into the holder 41 of the lifting tool 40 is provided, the detachment preventing device (50) is a crossing of two members in the shape of a combination of a semicircle and a straight line around the hinge, and when the screw 51 installed on the straight member side rotates, the two straight members of the separation prevention device 50 are moved in opposite directions. It is to push or pull the semicircular member to open or close it. Accordingly, when the wind power tower 1 is inserted into the holder 41 and fixed, it is closed. 2 and 3 illustrate a state in which the departure prevention device 50 is open, and in FIG. 4, a state in which the separation prevention device 50 is closed.

In addition, a plurality of lugs 43 and 44 are formed on the upper and lower surfaces of the lifting tool 40. The shackle 46 and 47 are respectively coupled to the upper and lower lugs 43 and 44, and the shackle 46 coupled to the upper and lower lugs 43 of the lifting tool 40 is the spreader 30 and the lower lug 32 The shackle (47) is connected to the shackle (33) coupled to the wire rope (45), and the shackle (47) coupled to the lug (44) of the lower surface of the lifting tool (40) is the fixing tool (60) and the wire rope of the wind tower (1) body. (Or fiber rope) 61. Here, the fixture 60 is installed at a certain height of the wind power tower (1) body, and when moving the wind power tower (1) through the offshore crane 10 of the present invention, a wire rope (or fiber rope) 61 is attached to the wind power. To support the tower (1), it is a kind of trunnion.

On the other hand, when the hook 26 coupled to the third pulley 25 is directly coupled to the lug 43 on the upper surface of the lifting tool 40, the number of hooks 26 coupled to the third pulley 25 is Due to the nature of the offshore crane hook 26, the size of the lifting tool 40 is limited, and the size of the lifting tool 40 is limited, and furthermore, the connected wire rope 24 needs to come down at least vertically. The length is also limited. Therefore, this problem can be solved by using the spreader 30, compared to the limited number of wire ropes 24 connected to the hook 26 of the offshore crane 10, the spreader 30 and the lifting tool 40 While increasing the number of wire ropes 45 to be connected to suit the load or size of the offshore crane 10 and the wind tower 1, the installation angle of the wire rope 45 can be flexibly adjusted as well as each wire. The load burden of the rope 45 can also be distributed.

That is, a plurality of lugs 32 and 43 are formed on the left and right sides of the upper surface of the lifting tool 40 and the lower surface of the spreader 30, respectively. Therefore, the boom 20 of the offshore crane 10 of the present invention includes a first pulley 15 for adjusting the angle of the boom according to the pulling and loosening of the wire rope 14 connected to the winch 12, and the winch 12 According to the pulling and loosening of the wire rope 24 connected with the spreader 30 and the wire rope 45, the lifting tool 40 linked to the spreader 30 can be raised and lowered in a horizontal state. The second pulley 23 and the third pulley 25 are combined. Here, when the spreader 30 is not used, the shackle 33 is directly coupled to the hook 26 of the third pulley 25 and the shackle 46 coupled to the lug 43 on the upper surface of the lifting tool 40 The silver hook (26) is directly coupled to the shackle (33) and the wire rope (45) is connected.

Next, by providing a counter weight 70 on the opposite side of one side of the lifting tool 40 on which a holder 41 is formed to which the wind tower 1 is inserted and supported, the separation prevention device 50 and the fixture 60 When the wind power tower 1 is seated on the holder 41 through the back, it acts as a resistance force against the external force, thereby maintaining the balance of the lifting tool 40 as a whole. Here, it is preferable that an electronic level is attached to the lifting tool 40 so that the balance can be checked when the wind tower 1 is elevated.

The counter weight 70 is loaded in the housing 71 coupled to the lifting tool 40 as shown in FIGS. 3 to 6, and the total design weight of the counter weight 70 is the weight of the wind tower 1 , The wind tower (1) is inserted into the holder (41) by completing the assembly work to be fixed in the housing (71) in advance by calculating the eccentric distance of the center of gravity of each of the wind tower (1) and the counter weight (70). When fixed and lifted, the lifting tool 40 is kept in a horizontal state.

The counter weight 70 must be able to maintain the balance of the lifting tool 40 by moving the position of the lifting tool 40 back and forth according to the field situation in the state of being combined with the lifting tool 40. Accordingly, as shown in FIGS. 3 to 6, rails 72 are installed on both sides of the lifting tool 40 on the upper surface, and the transporter 73 can move above the rail 72, and the transporter 73 Is fixedly coupled to the housing 71 within the bent portion of the upper end portion 76 of the housing.

Here, the transporter 73 is the housing 71 in which the counter waiter 70 is loaded, and the hydraulic system is built-in as a transportation equipment for the heavy object to enable the movement of the housing 71 in which the counter waiter 70 is loaded.

In the present invention, a method of moving the housing 71 in which the counter waiter 70 is loaded and wraps the counter weight 70 using the transporter 73 will be described in detail with reference to FIGS. 5 and 6. Same as, where the transporter 73 is composed of a wheel 74 and two leg members 75 connected by a hinge.

First, when the upper housing portion 76 is lifted using a compressor (not shown), the two leg members 75 of the transporter 73 are unfolded, and the skirt 77 on the side of the bent portion of the housing upper portion 76 is a lifting tool. (40) It is in a movable state (Fig. 5b, Fig. 6b) separated from the upper surface, and in this state, the transporter 73 and the housing 71 fixedly coupled thereto are moved by driving the hydraulic system of the transporter 73 (Fig. 6c).

Next, when the housing 71 is moved to the desired position, the two leg members 75 of the transporter 73 are folded so that the upper end of the housing 76 is lowered and the side of the bent portion of the upper housing 76 The skirt 77 is fixed by being in close contact with the upper surface of the lifting tool 40 (FIG. 6D).

7 to 9 as another embodiment of the present invention shows a dedicated line for installing a wind power tower.

The offshore crane 10 ′ of FIGS. 7 to 9 has a structure in which a jacket structure 80 is fixed to a barge 11 ′ having a “C”-shaped indentation 16.

The jacket structure 80 is composed of a leg 81, a brace 82, a reinforcing pipe 83, etc., and the upper deck 84 of the jacket structure 80 is a rectangular frame and a deck for reinforcing the inside thereof. It is a shape consisting of a cross-shaped reinforcement part (田).

In addition, the bottom of each leg 81 of the jacket structure 80 is fixed to the pants 11 ′, and the minimum number of legs 81 of the jacket structure 80 is 4, for stabilization of the jacket structure 80 Each leg 81 is manufactured in a symmetrical structure based on the center point of the upper deck 84 (the intersection of the cross-shaped reinforcement portion).

Here, the width of the indentation 16 of the pants 11 ′ where the wind tower 1 is located is when the wind tower 1 is elevated by the offshore crane 10 ′, the interference with the indentation 16 It is designed so that the wind tower 1 is standing and fixed in the vertical upward direction of the indentation 16, so that it does not interfere with the wind tower 1, the corresponding indentation 16 side jacket structure 80, leg 81 ) Between the brace 22 and the reinforcing pipe 83 should not be installed when the jacket structure 80 is initially manufactured.

7 to 9, a pair of winches 12' are fixedly installed on both sides of the upper deck 84, and the winch 12' is connected to the wire rope 24. In addition, a third pulley 25 is coupled to each wire rope 24. The third pulley 25 and the spreader 30 are raised and lowered according to the pulling and loosening of the wire rope 24 by the operation of the winch 12', and the hooks 26 are respectively coupled to the third pulley 25 have. The upper deck 84 on which the winch 12' is installed is formed with through holes up and down so that the wire rope 24 penetrates. The winch 12', the wire rope 24, the third pulley 25, and the hook 26 are support members for supporting the spreader 30.

The structure, operation, and function of the spreader 30, the lifting tool 40, and the count weight 70 in the other embodiments of the present invention are the same as those of the first embodiment, so a repetitive description will be omitted. Here, when the spreader 30 is not used, the shackle 33 is directly coupled to the hook 26 of the third pulley 25, and the shackle 46 is coupled to the lug 43 on the upper surface of the lifting tool 40. The silver hook (26) is directly coupled to the shackle (33) and the wire rope (45) is connected.

The wind tower is installed on the offshore foundation structure (not shown) by using the offshore crane for installing the wind tower according to the present invention made as described above. A brief look at the installation method is as follows.

Preferably, a plurality of towers, nutshells, hubs and blades, which are the main components of the wind tower 1 on land, are integrally assembled, and the assembled wind tower 1 is assembled. After being pulled up by a large crane installed on the land to stand, the assembled wind power tower (1) is placed on a transport barge (not shown) with a land crane, and fixed using a fixing wire for shipment. Then, the assembled wind tower 1 is towed by a tugboat for the transport barge, which is fixedly loaded, and moves it to the offshore cranes 10 and 10 ′ of the present invention in the position to install the assembled wind tower 1.

After moving the offshore crane (10,10') of the present invention toward the wind tower (1) loaded on the transport barge, the spreader (30) of the offshore crane (10) is raised or lowered by the operation of the winch (12,12') Let it. At this time, the assembled wind tower (1) body is inserted into the holder (41) of the lifting tool (40), and the wire rope (61) is wound around the fixture (60) of the wind tower (1) body to prevent separation ( 50) is used to prevent separation of the wind power tower 1 from the holder 41.

And, the spreader 30 is raised to a certain height so that the assembled wind power tower 1 is completely separated from the transportation barge, and at the same time, the wind tower 1 through the departure prevention device 50 and the fixture 60 When the counter weight 70 is mounted on the holder 41, the counter weight 70 is moved to the position of the lifting tool 40 according to the field situation in a state in which the counter weight 70 is combined with the lifting tool 40 to move the counter waiter 40 into the wind tower (1). By acting as a resistance force against the load, it is possible to maintain the balance of the lifting tool 40 as a whole, and the transport barge retreats. Accordingly, the assembled wind tower 1 is lifted and supported by the spreader 30 and the lifting tool 27 of the offshore cranes 10 and 10 ′ of the present invention.

Further, the assembled wind tower 1 is positioned and fixed on a foundation structure (not shown) already installed on the sea with the offshore cranes 10 and 10' of the present invention. At this time, the lifting tool 40 of the offshore crane (10, 10') of the present invention is positioned on the foundation structure, and the winch (12, 12') is operated to loosen or pull the wire rope (24), and the wind tower (1) You will have to make sure that the lift is controlled.

When the assembled wind tower 1 is fixed on the foundation structure, the separation prevention device 50 is opened and the wire rope 61 is released from the fixture 60 to retreat the offshore cranes 10 and 10'.

In addition, without the need to move the assembled wind tower (1) on land to a transport barge, the offshore crane (10, 10') of the present invention is moved to the quay wall, and the wind tower standing on the quay wall is transferred to the offshore crane of the present invention. (10'10') can also be carried directly.

Therefore, the present invention can lift the wind tower at sea without using a two boom offshore crane or a large special crane, even if the height of the wind tower is higher than the boom height of the crane. It is possible to maximize the efficiency of wind power generation by allowing the height to be further enhanced, and the counter weight is combined with the lifting tool to move the position of the lifting tool back and forth depending on the site situation to maintain the balance of the entire lifting tool. The wind power tower can be installed stably without overturning at sea.

1: wind tower 10,10': offshore crane 11,11': pants 12,12': winch 13: back tray 14,24,45,61: wire rope 15: first pulley 16: indentation
20: boom 21: support 23: second pulley 25: third pulley 26: hook 30: spreader 31, 32, 43, 44: lug 33, 46, 47: shackle 40: lifting tool 41: holder 42: fender 50: Separation prevention device 51: screw 60: fixture 70: counter weight
71: housing 72: rail 73: transporter 74: wheel 75: leg member
76: upper part of the housing 77: skirt 80: jacket structure 81: leg
82: brace 83: reinforcement pipe 84: deck

Claims (13)

A boom 20 having a support 21 having a lower end portion hinged to the surface of the trousers 11 and having an inclined angle formed at an upper end portion thereof;
The upper and lower surfaces are provided with a plurality of lugs (31, 32), the spreader 30 horizontally rising and lowering according to the pulling and loosening of the wire rope 24 descending vertically from the second pulley 23;
A holder 41 is formed on one side of which the wind tower 1 is inserted and supported, and a plurality of lugs 43 and 44 are provided on the upper and lower surfaces thereof, and a lifting tool 40 interlocks with the spreader 30;
The holder 41 is provided on the opposite side of one side of the lifting tool 40, the position of the lifting tool 40 can be moved back and forth in a combined state with the lifting tool 40, and the wind power tower 1 is a holder ( 41) When seated on the counterweight (70) that acts as a resistance force against the external force to maintain the balance of the lifting tool (40); characterized in that comprising, a wind tower using a movable counter weight Offshore crane for installation.
A boom 20 having a support 21 having a lower end portion hinged to the surface of the trousers 11 and having an inclined angle formed at an upper end portion thereof;
A holder 41 is formed on one side to which the wind tower 1 is inserted and supported, and a plurality of lugs 43 and 44 are provided on the upper and lower sides, and the shackle 46 coupled to the lug 43 on the upper surface is a hook ( A lifting tool 40 connected by a shackle 33 and a wire rope 45 directly coupled to 26);
The holder 41 is provided on the opposite side of one side of the lifting tool 40, the position of the lifting tool 40 can be moved back and forth in a coupled state with the lifting tool 40, and the wind power tower 1 is a holder ( 41) When seated on the counter weight 70 to maintain the balance of the lifting tool 40 by acting as a resistance force against the external force; characterized in that the wind tower using a movable counter weight Offshore crane for installation.
Trousers 11' in which the indentation 16 is formed;
A jacket structure 80 formed with a deck 84 having a lower leg 81 fixed to the trousers 11 ′ and a winch 12 ′ connected to the wire rope 24 fixedly installed at the upper end;
The upper and lower surfaces are provided with a plurality of lugs (31, 32), the spreader 30 horizontally rising and lowering according to the pulling and loosening of the wire rope 24 descending vertically from the winch (12');
A holder 41 is formed on one side of which the wind tower 1 is inserted and supported, and a plurality of lugs 43 and 44 are provided on the upper and lower surfaces thereof, and a lifting tool 40 interlocks with the spreader 30;
The holder 41 is provided on the opposite side of one side of the lifting tool 40, the position of the lifting tool 40 can be moved back and forth in a combined state with the lifting tool 40, and the wind power tower 1 is a holder ( 41) When seated on the counterweight (70) that acts as a resistance force against the external force to maintain the balance of the lifting tool (40); characterized in that comprising, a wind tower using a movable counter weight Offshore crane for installation.
Trousers 11' in which the indentation 16 is formed;
A jacket structure 80 formed with a deck 84 having a lower leg 81 fixed to the trousers 11 ′ and a winch 12 ′ connected to the wire rope 24 fixedly installed at the upper end;
A holder 41 is formed on one side by which the wind power tower 1 is inserted and supported, and a plurality of lugs 43 and 44 are provided on the upper and lower sides, and the shackle 46 coupled to the lug 43 on the upper surface is a hook ( A lifting tool 40 connected by a shackle 33 and a wire rope 45 directly coupled to 26);
The holder 41 is provided on the opposite side of one side of the lifting tool 40, the position of the lifting tool 40 can be moved back and forth in a combined state with the lifting tool 40, and the wind power tower 1 is a holder ( 41) When seated on the counterweight (70) that acts as a resistance force against the external force to maintain the balance of the lifting tool (40); characterized in that comprising, a wind tower using a movable counter weight Offshore crane for installation.
The method of claim 1,
A pair of second pulleys 23 are fixedly installed on both sides of the upper end of the support 21 and connected by a winch 12 and a wire rope 24, and a wire rope 24 through the second pulley 23 ) Is connected and is provided with a third pulley 25 that is raised and lowered according to the pulling and loosening of the wire rope 24, and the third pulley 25 has a hook 26 coupled to the lug 31 on the upper surface of the spreader 30 ) Is provided, characterized in that the support member for supporting the spreader 30 is additionally configured, the offshore crane for installation of a wind tower using a movable counter weight.
The method of claim 3,
The wire rope 24 is connected through the winch 12 ′, and a third pulley 25 is provided which is raised and lowered according to the pulling and loosening of the wire rope 24, and the spreader 30 on the third pulley 25 An offshore crane for installation of a wind tower using a movable counter weight, characterized in that a support member for supporting the spreader 30 is further configured, provided with a hook 26 coupled to the upper lug 31.
The method of claim 1 or 3,
Shackles 46 and 47 are respectively coupled to the lugs 43 and 44 on the upper and lower surfaces of the lifting tool 40, and the shackle 46 coupled to the lugs 43 on the upper and lower surfaces of the lifting tool 40 is the spreader 30 The shackle 33 coupled to the lower lug 32 and the wire rope 45 are connected, and the shackle 47 coupled to the lower lug 44 of the lifting tool 40 is a fixture of the wind power tower (1) body. It is connected with 60 and wire rope 61,
The installation angle of the wire rope 45 is flexibly adjusted by increasing the number of wire ropes 45 connecting the spreader 30 and the lifting tool 40 compared to the number of wire ropes 24 connected to the hook 26 And the wire rope 45, characterized in that it is possible to distribute the load burden of each, the offshore crane for installing a wind tower using a movable counter weight.
The method according to any one of claims 1 to 4,
An offshore crane for installing a wind tower using a movable counter weight, characterized in that a fender 42 is additionally provided on the arcuate inner surface of the holder 41 to alleviate a collision with the wind tower 1.
The method according to any one of claims 1 to 4,
Using a movable counter weight, characterized in that a departure prevention device 50 for preventing separation of the wind tower 1 inserted in the holder 41 is additionally provided on the upper or lower surface of the lifting tool 40 Offshore crane for installing wind towers.
The method of claim 9,
The separation prevention device 50 crosses two members in a shape of a combination of a semicircle and a straight line around the hinge, and when the screw 51 installed on the straight member side rotates, two straight members of the separation prevention device 50 An offshore crane for installing a wind tower using a movable counter weight, characterized in that the semicircular member is opened or closed by pushing or pulling in opposite directions.
The method according to any one of claims 1 to 4,
The counter weight 70 is loaded in a housing 71 coupled to the lifting tool 40, and rails 72 are installed on both sides on the upper surface of the lifting tool 40, and the transporter is movable above the rail 72 (73) is additionally provided, wherein the transporter (73) is fixedly coupled to the housing (71) within the bent portion of the upper end portion (76) of the housing (76), a marine crane for installing a wind tower using a movable counter weight.
The method of claim 11,
The transporter 73 is composed of a wheel 74 and two leg members 75 connected by a hinge, so when the upper end portion 76 of the housing is lifted, the two leg members 75 of the transporter 73 are unfolded. The skirt 77 on the side of the bent portion of the housing upper portion 76 is spaced apart from the upper surface of the lifting tool 40 so that the housing 71 is in a movable state, and the two leg members 75 of the transporter 73 are folded. A movable counterweight, characterized in that the housing 71 is fixed by allowing the skirt 77 on the side of the bent portion of the housing upper portion 76 to be in close contact with the upper surface of the lifting tool 40 together with the lowering of the lower housing upper portion 76 Offshore crane for installing a wind tower using a.
The method according to claim 3 or 4,
The jacket structure 80 is composed of a leg 81, a brace 82, and a reinforcing pipe 83, but between the indentation 16 side jacket structure 80 and the leg 81 so as not to interfere with the wind tower 1 The brace 22 and the reinforcing pipe 83 are not installed, and the upper deck 84 is a shape consisting of a square frame and a cross-shaped reinforcement part for reinforcing the deck 84 therein, and the jacket structure 80 For stabilization, each leg 81 is of a symmetrical structure based on the center point of the upper deck 84 for stabilization. An offshore crane for installation of a wind tower using a movable counter weight.

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