KR102542656B1 - Self-Elevating Crane Apparatus for Installation and Maintenance of Wind Turbine System - Google Patents

Abstract

The present invention relates to a crane device for installation and maintenance of a tower and a wind power generation system provided on top of the tower. The crane device of the present invention includes a lifting unit attached to the tower and provided to move up and down along the tower; Two crane units disposed on top of the elevating unit; It is composed of a lifting unit that is suspended and raised by two crane units and the items constituting the wind power generation system are suspended, and the two crane units are spaced apart from each other and arranged side by side with the tower in between, and the longitudinal direction in the lifting unit Two coupling points spaced apart from the center on both sides are each suspended on a crane unit, and the lifting unit moves up and down the tower or moves in the radial direction of the tower according to the operation of the crane unit, and moves the suspended items in the radial direction of the tower. And it will be able to move in a direction perpendicular to the up and down direction.

Description

Self-Elevating Crane Apparatus for Installation and Maintenance of Wind Turbine System}

The present invention relates to a self-elevating crane for installation and maintenance of a wind power generation system, and specifically, a tower installed vertically on land and a wind power generator installed on top of the tower by its own power in a wind power generation system. It relates to a crane device used to install or maintain a wind power generation system by lifting items such as towers or turbines constituting the wind power generation system while lifting the wind power generation system.

In a wind power generation system installed on land, a tower is installed vertically from the ground, a nacelle in which a wind turbine is disposed is provided on top of the tower, and blades are coupled to the turbine.

For efficient wind power generation, tower heights are increasing and blades and wind turbines are also increasing in size, so crane devices for installing wind power generation systems are also increasing in height and size.

Large cranes are limited in supply, making it difficult to construct or maintain wind tower systems in a timely manner. In particular, wind power generation systems are often installed in mountainous areas, but it is difficult to transport a high-rise large crane to mountainous areas and it is not easy to work with a large crane because sufficient working space is not secured at the site.

As a solution to this problem, a so-called self-elevating crane device has been developed.

The self-lifting crane device installs a crane on the lifting mechanism that moves along the tower of the wind power generation system, and as the lifting mechanism moves up along the tower, the crane lifts elements that make up the wind power generation system, such as tower units, blades, and nacelles, to the installation location. It is to lower the salvaged or dismantled elements.

As an invention related to such a self-elevating crane device, an invention entitled “a hoisting system for installing a wind turbine” disclosed in International Patent Publication WO2017055598 (Document 1) has been proposed.

The hoisting system of the invention of Document 1 has a configuration in which a structure for lifting is installed in a tower of a wind power generation system, and a body for lifting with a crane is used to lift the tower using the structure.

In order to use the hoisting system of the invention of Document 1, since a lifting structure must be installed on the tower, there is a problem that it cannot be used for maintenance of a wind power generation system that has been constructed and is in operation.

As another example of a self-elevating crane device, Chinese Patent Publication CN107265373A (Document 2) discloses an invention entitled "Dedicated tool for wind electricity maintenance crane arm structure".

The apparatus according to the invention of Document 2 is constructed by coupling a plurality of holding arms spaced apart in a vertical direction while surrounding a tower to a vertically extending cylinder. The holding arms are raised and lowered by cylinders and are alternately attached to the tower to provide support for the lifting movement.

The device according to the invention of Document 2 can be used without changing the structure of the tower of the wind power generation system, but since the holding arm acts to raise and lower depending on the force for gripping the tower and the crane must support the load for lifting work, holding The structure of the arm is complicated, the lifting operation is complicated, and it takes a lot of time, and it takes a lot of time to assemble and disassemble the holding arm at a work site, and the safety of the holding arm becomes a problem.

In particular, in the crane device of the invention of Document 1 and the invention of Document 2, the crane unit is attached to one side of the unit that lifts the tower, so the load of the lift unit and the crane unit and the load of the article lifted by the crane are all on one side of the tower. There is a problem that being biased imposes a significant eccentric load on the tower.

In addition, fine adjustment of the position is required when attaching the items lifted by the crane to the wind power generation system, but the cranes attached to these devices have a large load capacity for lifting the items, so that the items are leveled and fine position adjustment is made. However, there is a problem that frequent operation for fine adjustment causes failure of the crane.

Document 1: International Patent Publication WO2017055598 Document 2: Chinese Patent Publication CN107265373A

The present invention is to provide a crane device that enables installation, disassembly, and maintenance work by lifting elements constituting a wind power generation system by mounting a crane unit while lifting a tower constituting a wind power generation system by itself.

In particular, the present invention is to provide a crane device having a configuration suitable for positioning an article while minimizing the eccentricity of the load applied to the tower when the crane device is supported on a tower of a wind power generation system and lifting an article.

The problem to be solved by this invention described above is achieved by the crane device of this invention, which is for installation and maintenance of a tower and a wind power generation system provided on top of the tower.

The crane device according to the present invention,

an elevating unit attached to the tower and provided to elevate up and down along the tower; Two crane units disposed on top of the elevating unit; It is suspended by two crane units and is configured to include a lifting unit on which items constituting the wind power generation system are suspended,

The two crane units are spaced apart from each other with the tower in between and arranged side by side, and the two coupling points spaced apart from the longitudinal center on both sides of the lifting unit are suspended on the crane unit, respectively,

The lifting unit moves in the vertical direction of the tower or moves in the radial direction of the tower according to the operation of the crane unit, and can move the suspended article in directions perpendicular to the radial and vertical directions of the tower.

According to this configuration, the crane unit is placed on the elevating unit and then raised to the working position of the tower. When the crane device other than the lifting unit reaches the working position, the lifting unit raised to the ground is suspended from the crane unit, and then the article can be suspended and lifted from the lifting unit.

Of course, with the lifting unit mounted, the crane device rises along the tower, reaches the working position, lowers the lifting unit to suspend and lift the item, but the crane device excluding the lifting unit first rises and then suspends the lifting unit. It is more efficient to do

Since the lifting unit is suspended by two crane units, it is easy to level the ground, and since the two crane units are placed side by side with the tower in between, the items suspended on the lifting unit can be lifted in alignment with the tower. there is.

Accordingly, the positioning of the article is adjusted with three degrees of freedom by the lifting and lowering of the crane unit, the movement in the radial direction, and the alignment of the article in the lifting unit.

In particular, since the two crane units are disposed across the tower, the degree of eccentricity of the load according to the weight of the crane device and the weight of the item to be lifted is very small with respect to the center of the tower, so that a large eccentric load is not applied to the tower.

As an additional feature of this invention, in the crane device of this invention,

lifting unit,

A first beam that extends in the longitudinal direction and is provided with the coupling points spaced apart from the center of the longitudinal direction to both sides; a second beam disposed under the first beam and extending in the longitudinal direction; It is coupled between the second points spaced apart from both sides of the center in the longitudinal direction of the first beam and the third points spaced apart from both sides from the center of the length direction of the second beam, and the length is stretched so that the second point and the third point leveling means configured to level the second beam by varying the distance between points; A plurality of lifting blocks spaced apart from each other along the longitudinal direction of the second beam, movably installed along the longitudinal direction of the second beam, and having suspension points on which items constituting the wind power generation system are suspended; and a positioning mechanism driven to adjust the positions of the lifting blocks in the longitudinal direction of the second beam, respectively.

According to this configuration, the first beam of the lifting unit is suspended and leveled by the crane unit, but the level or posture of the second beam can be adjusted by adjusting the posture of the second beam on which the lifting block is placed with respect to the first beam. there is.

Since the crane unit has a large load capacity to lift an article including a lifting beam, it is not easy to perform fine posture adjustment or horizontal adjustment using such a crane unit, and it may cause a failure of the crane unit.

Therefore, according to the additional feature of this invention, after the first beam is suspended by the crane unit, it is advantageous to adjust the posture of the second beam by the leveling means for fine posture adjustment.

In addition, the position of the article can be adjusted in a direction perpendicular to the vertical direction and radial direction of the tower by moving the lifting block on which the article is suspended in the longitudinal direction of the second beam.

As an embodiment of the crane device according to this additional feature,

As a leveling means, a hydraulic cylinder may be disposed at a third point of the second beam, and a piston of the hydraulic cylinder may be coupled to a second point of the first beam.

In addition, the tip of the piston of the hydraulic cylinder may be rotatably hinged to the second point of the first beam.

The position adjustment mechanism includes a drive motor and a lead screw rotated by the drive motor, and each lifting block is screwed with the lead screw to move along the longitudinal direction of the second beam according to the rotation of the lead screw so that the position is changed. It can be configured to be adjusted.

As another additional feature of this invention,

Each crane unit

A movable beam that rotates around a first point on the upper part of the lifting unit and has a suspension point at which a distance from the first point is expanded or contracted; a wire extending between the suspension point and the coupling point of the movable beam; and actuating means for stretching and retracting the length of the wire extending between the suspension point and the coupling point of the movable beam;

The lifting unit may be configured to move in the vertical direction of the tower or move in the radial direction of the tower by the rotation and contraction of the movable beam and the extension and contraction of the wire length.

Since the wire extends from the movable beam of the crane unit to the coupling point of the lifting unit, the lifting unit rises to the working position with the crane unit mounted, lowers the wire of the crane unit from the working position, and combines the lifting unit with the wire , After suspending the article on the lifting unit, the lifting beam suspended the article can rise to the position where the article is placed by pulling the wire again.

As an embodiment of this additional feature,

Each crane unit includes a hydraulic cylinder, the end of the cylinder of the hydraulic cylinder is rotatably coupled to the second point on the upper part of the lifting unit, and the piston tip is rotatably coupled to the movable beam, The movable beam may be configured to be rotatable around the second point by the telescopic operation of the hydraulic cylinder.

In addition, each crane unit may further include a lifting hook rotatably coupled to the coupling point of the lifting unit, and the lifting hook may be configured to be coupled to the front end of the wire.

As a further feature of this invention,

lift unit,

An upper base and a lower base that are configured to surround the tower and are variable in a state in which they are fixedly supported at any position of the tower and in a state in which they can be raised and lowered with respect to the tower,

A plurality of posts extending between the upper and lower bases so that the upper and lower bases are fixed to each other at positions spaced apart from each other vertically;

An elevating base configured to surround the tower, variable between a state fixedly supported at an arbitrary position of the tower and a state capable of elevating and descending with respect to the tower, and disposed to be elevating and descending along the post between the upper and lower bases, and

A drive mechanism that is disposed between the elevating base and the upper base or the lower base and changes the distance between the elevating base and the upper and lower bases by varying the length.

It is composed of,

With the upper and lower bases fixed and supported at an arbitrary position of the tower, the length of the driving mechanism is varied so that the elevating base moves up and down along the tower, and the driving mechanism in a state where the elevating base is fixed and supported at an arbitrary position of the tower. By varying the length, the upper base and the lower base move up and down along the tower, and the crane unit can be configured to be disposed on the upper base.

According to this additional feature, the crane device of the present invention is synchronized with the extension operation of the driving mechanism installed between any one of the upper and lower bases and the elevating base, so that the upper and lower bases are fixedly supported to the tower and the elevating base is fixedly supported. By being made alternately in the state of being, the crane device is raised or lowered by the displacement of the extension operation of the drive mechanism.

Since the structure consisting of the upper and lower bases and posts is integrated with each other and surrounds the tower and raises and lowers the tower, it is stably supported by the tower without applying an eccentric load to the tower.

Therefore, the eccentric load applied to the tower is minimized not only in the lifting operation but also in the lifting operation of the article by the crane unit, and the article constituting the wind power generation system can be lifted in an aligned state with respect to the tower.

In a crane device having these additional features,

The upper and lower bases and the elevating base include a frame extending in a plane perpendicular to the extension direction of the tower, a plurality of posts extend upward through the frame of the upper base, and each crane unit includes at least two of the plurality of posts. It can be configured to be placed at the top of the post.

Therefore, since the crane unit is disposed with the tower interposed at a position spaced upward from the upper base, it is easy to install the tower unit, nacelle, or blade without interference with the tower or nacelle previously installed.

1 is a perspective view showing a state attached to a nacelle lifting jig to a crane device according to an embodiment of the present invention.
2 is a perspective view showing a state in which the crane device according to an embodiment of the present invention lifts the upper unit of the tower in a state supported by the tower of the wind power generation system.
Figure 3 is a perspective view showing a state in which the brake mechanism is installed on the upper base in the crane device according to an embodiment of the present invention.
Figure 4 is a perspective view sequentially showing an operation of the lifting unit to lift the tower in the crane device according to an embodiment of the present invention.
5 is a perspective view showing a crane unit and a lifting unit in a crane device according to an embodiment of the present invention.
6 is an enlarged perspective view of the lifting unit in FIG. 5;
7 is an enlarged side view of the lifting unit in FIG. 5 .
8 is a perspective view sequentially showing an operation of lifting a tower unit by a crane device according to an embodiment of the present invention.
9 is a perspective view showing an operation of lifting a blade by a crane device according to an embodiment of the present invention.

Hereinafter, the configuration and operation of a crane device according to one embodiment of the present invention will be described as specific details for carrying out the present invention with reference to the drawings.

Referring to Figures 1 and 2, the overall configuration of the crane device according to an embodiment will be described.

The crane device, broadly divided, is attached to the tower 1 of the wind power generation system and is configured to be vertically lifted along the tower (10 to 50), two crane units (70) disposed on top of the lift unit , It is composed of a lifting unit 80 suspended by a crane unit, lifted and lowered by the crane unit, and suspended by elements of a wind power generation system.

According to this configuration, for example, when the elevating units 10 to 50 ascend along the tower 1 in a state in which the crane unit 70 is mounted and reach the working position, the crane unit 70 lifts the lifting hook (FIG. 5). 76) is lowered close to the ground to suspend the lifting unit 80 on the lifting hook, and then elements of the wind power generation system such as tower units, nacelles or blades placed on the ground are suspended on the lifting unit 80. Next, the crane unit 70 lifts the lifting unit 80 and the elements of the wind power generation system suspended from the lifting unit are placed in place and assembled.

The overall configuration of the elevating units 10 to 50 will be described.

As an elevating unit, the upper base 10, the elevating base 30, and the lower base ( 20) is provided.

The upper base 10, the lower base 20, and the elevating base 30 are all composed of rectangular frames 11, 21, and 31 extending in a plane perpendicular to the vertical direction in which the tower 1 extends, Holes 12, 22, and 32 through which the tower 1 passes are formed at the inner centers of the frames 11, 21, and 31 so that the frames 11, 21, and 31 surround the tower 1.

Each frame 11, 21, 31 is configured to be divided and combined into two parts so that the holes 12, 22, 32 through which the tower passes are opened in a semicircular shape, so that the wind power generation system is installed or maintained in a divided state. After being transported to the repair site, they are joined together while enclosing the tower (1).

The upper base 10 and the lower base 20 are integrally formed by being fixedly coupled to each other by four posts 50 disposed at four corners of the frames 11 and 21 .

The post 50 is installed vertically, and is installed through the frames 11, 21, and 31 of the upper and lower bases and the elevating base in the vertical direction, and is fixedly coupled with the frames 11 and 21 of the upper and lower bases to post 50 ), the upper and lower bases 10 and 20 are integrated.

The elevating base 30 is placed between the upper and lower bases 10 and 20 in the vertical direction, and the post 50 penetrates the frame 31 of the elevating base, but the frame 31 is not fixedly coupled and the elevating base 30 ) and the post 50 slide.

Between the upper surface of the frame 31 of the elevating base and the lower surface of the frame 11 of the upper base, eight hydraulic cylinders 40 are disposed two by two between the posts 50 in plan view. Each hydraulic cylinder 40 has one end fixed to the upper surface of the frame 31 of the elevating base, and a piston tip coupled to the lower surface of the frame 11 of the upper base.

According to this configuration, as the hydraulic cylinder 40 expands and contracts, the elevating base 30 relatively moves up and down while the distance to the upper and lower bases 10 and 20 is varied.

The upper base 10, the lower base 20, and the elevating base 30 are each provided with a brake mechanism that allows them to be fixed and supported at an arbitrary position of the tower.

The configuration of the brake mechanism will be described with reference to FIG. 3 .

3 shows a state in which the top plate of the frame 11 of the upper base is removed, showing the brake mechanism provided inside the frame.

The brake mechanism 60 is configured to selectively apply frictional force between the surface of the tower and allows the upper and lower bases and the elevating base to be fixed and supported at an arbitrary position of the tower by application of the frictional force.

Since this brake mechanism is installed in the same configuration in the upper and lower bases 10 and 20 and the elevating base 30, the brake mechanism of the upper base shown in FIG. 3 will be described below.

One brake mechanism is a block 61 disposed on the frame 11 of the upper base and sliding in the radial direction of the tower 1, a hydraulic cylinder 62 for pressing and retracting the block in the radial direction by a telescopic operation, It consists of a friction pad 63 disposed at the tip of the block and applying frictional force in contact with the surface of the tower.

A linear groove is formed in the radial direction in the frame 11 to guide the sliding operation of the block 61, and the block 61 is disposed thereto to perform the sliding operation.

The hydraulic cylinder 62 is disposed outward of the block 61 in the radial direction, and one end of the cylinder is coupled to the frame 11 and the tip of the piston is coupled to the block 61, so that the telescopic operation of the hydraulic cylinder 62 As a result, the block 61 advances inwardly or retreats outwardly in the radial direction with respect to the frame 11 .

The friction pad 63 is coupled to the diametrical tip of the block 61, and its outer surface comes into contact with the surface of the tower 1.

In a wind power generation system, towers are typically formed to taper upwards, so the tower surfaces also have such an inclination. The outer surface of the friction pad 63 of the brake mechanism 60 in contact with the tower surface is configured to have an inclination corresponding to the same inclination of the tower surface.

The inclination of the tower may be different for each wind power generation system, and the friction pad of the brake mechanism may be replaced with one suitable for the inclination.

In this embodiment, six brake mechanisms 60 having the above structure are installed in the frame 11 of the elevating base, and are spaced apart from each other in the circumferential direction of the tower. The number and arrangement of these brake mechanisms 60 can be adjusted and varied. One or two may be installed on each of the four sides of the frame 11, or may be installed at equal intervals in the circumferential direction of the tower.

With the above configuration, when the hydraulic cylinder 62 of the brake mechanism 60 is extended, the block 61 moves inward in the radial direction, which is the direction approaching the tower surface, and presses the friction pad 63 against the tower surface. . Accordingly, frictional force is applied between the surface of the tower and the friction pad 63, so that the upper base 10 can be fixedly supported at an arbitrary point of the tower 1.

When the hydraulic cylinder 62 is retracted, the block 61 moves radially outward, in the direction away from the surface of the tower, and the friction pad 63 is spaced to the surface of the tower. Accordingly, the upper base 10 is in a state in which it can rise or fall with respect to the tower 1 .

On the other hand, the wire 65 surrounds the outer surface in the radial direction of the six friction pads 63 arranged in a state surrounding the tower, that is, the back surface of the surface in contact with the surface of the tower. Two wires are arranged on the upper side of the friction pad 63 and two wires are set on the lower side.

The wire 65 is arranged so that one end is fixed to one friction pad 63 and extends in the circumferential direction of the tower 1, and is placed on the inner surface of all six friction pads 63, and the other end is placed on the frame It is coupled to the electric winch 66 provided in (11). 3, only a portion of the motorized winch 66 winding a set of wires is shown in an exposed state.

According to this configuration, when the electric winch 66 is operated to pull the wire 65, the wire 65 disposed along the circumferential direction is contracted radially inward while pressing the friction pad 63 radially inward. do.

When the operation of the electric winch 66 is stopped, the wire 65 wraps all six friction pads 63, and will remain in this state unless the electric winch 66 is operated in the reverse direction.

Due to leakage or failure of the hydraulic cylinder 62 or failure or leakage of the hydraulic supply system, the pressing force applied to the friction pad 63 by the hydraulic cylinder 62 may be reduced or lost unintentionally.

However, in this embodiment, in a state where the friction pad 63 is pressed against the surface of the tower 1 by the pressing force of the hydraulic cylinder 62, the wire 65 is wound by the winch 66 so that the friction pad 63 ) is restrained so that it does not depart radially outward, even if the pressing force of the hydraulic cylinder 62 is lost, the friction pad 63 is not separated from the surface of the tower.

Accordingly, even if the pressing force of the hydraulic cylinder 62 is reduced or lost, an accident in which the elevating base 10 unintentionally falls due to gravity is prevented.

The structures of the brake mechanism 60 and the wire 65 described above are also provided in the lower base 20 and the elevating base 30 in the same way.

For installation in the tower, the crane device is divided into several units or units at a manufacturing site or the like, transported, and assembled on the tower at the site. Since the elevating unit is manufactured in a state in which the upper and lower bases 10 and 20 and the frames 11, 21 and 31 constituting the elevating base 30 are divided into two, the upper and lower bases 10 and 20 The halves are assembled, and the post 50, the hydraulic cylinder 40 and the brake mechanism 60 can be respectively installed thereto.

The lifting unit, the two crane units, and the lifting unit of the half assembled in this way are transported to the site on a separate transportation means, and assembled on the tower using a separate crane at the site.

Referring to Fig. 4, the operation of the crane device ascending along the tower will be described.

This drawing shows a part of the process in which the crane device lifts by itself along the tower from the state in which the elements constituting the crane device of this embodiment are transported and installed at the lower end of the tower of the wind power generation system.

Figure 4 (a) shows a state in which the elements constituting the crane device are transported and installed at the lower end of the tower of the wind power generation system.

The elevating units 10 to 50 of the crane device are installed on the tower and are fixedly supported, and the two crane units are installed on the upper base 10 of the elevating unit. The lifting unit 80 is not suspended from the crane unit 70 and is suspended from the crane unit 70 after the crane device is raised to the working position.

In the initial state shown in (a) of FIG. 4, the pistons of the hydraulic cylinders 40 between the elevating base 30 and the upper base 10 are contracted, and the elevating base 30 is between the upper and lower bases 20. is placed on

In this state, the brake mechanism operates on the upper and lower bases 10 and 20 and the elevating base 30 so that the friction pad 63 is pressed against the surface of the tower 1 to apply frictional force, and the wire 65 is driven by an electric winch ( 76) to remain in close contact with the friction pad 63. Therefore, the upper and lower bases 10 and 20 and the elevating base 30 are fixedly supported by the tower 1.

Subsequently, the hydraulic cylinder 62 of the brake mechanism contracts the upper and lower bases 10 and 20 so that the pressing force applied to the surface of the tower 1 by the friction pad 63 is lost. Accordingly, the frictional force between the friction pad 63 and the tower surface is lost, and the friction pad 63 only faces the tower surface.

Subsequently, the piston of the hydraulic cylinder 40 between the upper base 10 and the elevating base 30 is extended. Since the elevating base 30 is fixedly supported by the tower, and the upper and lower bases 10 and 20 are in a state in which the frictional force of the friction pad 63 is lost, the elevating base 30 is excluded by the extension of the hydraulic cylinder 40. And the crane device including the upper and lower bases 10 and 20 and the crane unit 70 rises along the tower.

At this time, the post 50 connecting and coupling the upper and lower bases 10 and 20 slides with respect to the frame 31 of the elevating base fixedly supported by the tower.

Since the diameter of the tower 1 decreases toward the top, the distance between the friction pads 63 of the brake mechanism of the upper and lower bases 10 and 20 and the tower surface can be widened.

However, in the crane device of this embodiment, the hydraulic cylinder 62 of the brake mechanism of the upper and lower bases 10 and 20 synchronizes with the extension operation of the hydraulic cylinder 40 between the upper base 10 and the elevating base 30. An extended and powered winch pulls the wire (65).

Accordingly, as the upper and lower bases 10 and 20 rise, the friction pad 63 rises while maintaining close contact with the surface of the tower without being spaced apart, and external force is applied to the crane device due to strong winds or other accidental factors. Even in this case, the upper and lower bases 10 and 20, which are not fixedly supported by the tower, are prevented from swinging.

After the hydraulic cylinder 40 is extended by the set length, the extension operation is stopped.

By this operation, the crane device except for the elevating base 30 is disposed at a position where the hydraulic cylinder 40 is elevated along the tower by the displacement of the extension operation.

This state is the state shown in FIG. 4(b).

Subsequently, the brake mechanism 60 of the upper and lower bases 10 and 20 operates, and the upper and lower bases 10 and 20 are fixedly supported on the tower in the raised position.

Then, as the hydraulic cylinder 62 of the brake mechanism of the elevating base 30 contracts, the frictional force between the friction pad 63 and the tower surface is lost.

Subsequently, the piston of the hydraulic cylinder 40 contracts, so that the distance between the elevating base 30 and the upper base 10 decreases, so that the elevating base 30, which is not fixed to the tower surface, rises, and the upper and lower bases ( 10, 20) are fixedly supported in place.

The hydraulic cylinder 62 of the brake mechanism installed in the elevating base 30 is also extended in synchronization with the contraction operation of the hydraulic cylinder 40 that causes the elevating base 30 to rise, and the friction pad 63 is reduced in diameter on the tower surface. to keep in contact with or adjacent to, and the wire 65 is also pulled.

When the hydraulic cylinder 40 is completely contracted, the lifting operation of the elevating base 30 is stopped, and the brake mechanism of the elevating base 30 operates, so that the elevating base 30 is also fixed and supported on the tower surface by frictional force. .

This state is the state shown in (c) of FIG. 4, and in this state, the height of the crane device has increased compared to the initial state shown in (a), and elements constituting the crane device maintain the initial state.

In this state, the above-described operation is repeated until the crane device reaches the set working height.

When the crane device rises to the working position, both the upper and lower bases 10 and 20 and the elevating base 30 are fixedly supported by the tower by the brake mechanism. Therefore, it is possible to maintain a stable support state in the work of lifting an article suspended by the crane unit 70 or the lifting unit 80.

During operation, the hydraulic cylinder 63 of the brake mechanism may not operate due to leakage or rupture of the hydraulic system, and a pressing force may not be applied to the friction pad 63.

Even if the pressing force by the hydraulic cylinder 62 of the brake mechanism is lost, the friction pad 63 remains pressed against the tower surface by the wire 65 surrounding them, so that the elevating base 30 and the upper and lower bases 10, 20), the frictional force between the friction pad 63 and the tower surface is not lost, so that the crane device does not fall to the ground due to gravity.

In the state where the pressing force by the hydraulic cylinder 62 of the brake mechanism is lost, the frictional force between the friction pad 63 and the tower surface is controlled by the elastic extension of the wire 65 or the deformation of the friction pad 63. If only frictional forces are not sufficient to hold it in position, the crane device can be lowered from the tower by gravity.

However, since the surface of the tower is inclined, when the crane device is lowered slightly, the friction pad 63 will be placed on the larger diameter part of the tower surface, but the diameter will be reduced by the wire 65 placed on the outer surface of the friction pad 63. A large pressing force acts in that direction.

Accordingly, the crane device is maintained in place without further descending, preventing a fall accident, and in this state, it is possible to repair the hydraulic system or the hydraulic cylinder.

On the other hand, when the work by the crane device is completed or the crane device descends from the tower due to the need for work, the above-described operation is reversed.

In the state shown in FIG. 4(c), when the hydraulic cylinder 40 between the elevating base 30 and the upper base 10 is extended, the elevating base 30 that is not fixed to the tower descends and is fixed to the tower. and becomes the state shown in (b).

Subsequently, the hydraulic cylinder 40 contracts in a state in which the elevating base 30 is fixed to the tower and the fixed state of the upper and lower bases 10 and 20 is released. Accordingly, the upper and lower bases 10 and 20 and the crane unit 70 mounted therein descend.

In this way, the crane device descends to the ground, is sequentially disassembled, and is loaded onto a transport vehicle by a separate crane.

In this embodiment, the hydraulic cylinder 40 is installed between the upper base 10 and the elevating base 30, but may be installed between the lower base 20 and the elevating base 30 conversely.

In the lifting operation of the crane device configured as described above, the hydraulic cylinders are extended while the upper and lower bases are fixed to the tower to raise the lifting base, and the hydraulic cylinders are contracted while the lifting base is fixed to the tower to raise the upper and lower bases. do.

In the lowering operation, the hydraulic cylinders are extended while the elevating base is fixed to the tower to lower the upper and lower bases, and the hydraulic cylinders are extended and the elevating base is lowered while the upper and lower bases are fixed to the tower.

In addition, in this embodiment, the piston tip of the hydraulic cylinder is coupled to the upper base and the cylinder is coupled to the elevating base, but conversely, the piston tip is coupled to the elevating base and the cylinder is coupled to the upper base or lower base. You may. Even in such a configuration, the operation is performed in the same manner.

Next, the configuration of the crane unit 70 will be described with reference to FIG. 5 .

The upper end of the post 50 penetrates the frame 11 of the upper base and extends upward, and a reinforcing frame 51 is connected between the upper ends of the two posts 50 .

One crane unit 70 is installed on the upper end of the two posts 50 connected to each other by the reinforcing frame 41, and the crane units 70 are installed side by side with the tower interposed therebetween.

Each crane unit 70 has one end of the first and second movable beams 71 and 72 rotatably coupled to the hinge 711 provided at the top of one post 50 and the other post ( 50), a hydraulic cylinder 73 having an end rotatably coupled to a hinge 731 provided at the top, and a roller 721 provided at the front end of the second movable beam 72 An electric winch (not shown) It is composed of a wire 75 wound by and a lifting hook 76 suspended from the wire.

The first movable beam 71 is rotatably coupled to the hinge 711 provided at the top of the post 50, and the second movable beam 72 is coaxial with the first movable beam 71 ), and is extended and protruded from the first movable beam by hydraulic pressure, or retracted into the first movable beam 71 by contraction. Accordingly, while the first and second movable beams 71 and 72 rotate about the hinge 711, the length between the hinge and the front end is expanded and contracted.

The hydraulic cylinder 73 has an end of the cylinder coupled to a hinge 731 provided at an upper end of the post 50 and a front end of the piston 731 provided in the middle of the first movable beam 71 Hinge 731 It is coupled to, and the movable beams 71 and 72 rotate about the hinge 711 by the extension operation of the hydraulic cylinder 73.

Two rollers 721 are wound around the tip of the second movable beam 72 . The roller 721 forms a suspension point, and a wire 75 is wound around the roller 721 and passes through it, and a lifting hook 76 is attached to the front end of the wire. The remaining part of the wire 75 passes through the roller 721 and is wound around an electric winch (not shown) to be pulled or released so that the lifting hook 76 attached to the front end of the wire goes up and down.

The lifting unit 80 is suspended from the lifting hook 76.

The lifting unit 80 is a unit for lifting elements of the wind power generation system, but can be used as needed, and can be lifted by directly suspending an item on the lifting hook 76 of the crane unit 70 without using a lifting unit. there is.

Since the two crane units 70 are installed side by side, the goods can be suspended and lifted from the lifting hooks 76 of the two crane units, and only one crane unit 70 can be used depending on the installation position or weight of the goods. You can also use it to lift.

The lifting unit 80 is not installed together when the crane device is installed on the tower, and after installing the lifting units 10 to 50 and the crane unit 70 excluding the lifting unit on the tower 1, the elements of the wind power generation system are removed. When lifting from the ground to the installation location of the wind power generation system, the lifting hook 76 of the crane unit 70 is lowered close to the ground, and the lifting unit 80 can be suspended and used on the lifting hook.

The configuration of the lifting unit 80 in a suspended state on the crane unit 70 and the configuration in which the lifting unit 80 is suspended on the crane unit 70 will be described using FIGS. 6 and 7 .

6 and 7 are enlarged views of a state in which the lifting unit 80 is suspended from the crane unit 70 in FIG. 5 .

The lifting unit 80 includes a first beam 81 extending long and a second beam 82 disposed below the first beam and extending long generally parallel to the first beam.

Hinges 811 are provided at both ends spaced apart from the center in the longitudinal direction of the first beam 81 to both sides. The lifting hook 76 of each crane unit 70 is coupled to the hinge 811 by a pin 812, so that the first beam 81 is suspended by the two crane units 70.

The second beam 82 is composed of a channel having a rectangular cross section, and a hydraulic cylinder 83 is disposed inside the channel as a leveling means at both ends spaced apart on both sides from the center in the longitudinal direction of the second beam 82. there is.

The hydraulic cylinder 83 is fixedly coupled to the second beam 82 and a hinge 832 is attached to the piston tip 831, and the hinge 832 is spaced apart from the center of the first beam 81 on both sides. It is coupled with a pin 833 penetrating the position of the end.

According to this configuration, the distance between the point where the first beam 81 is coupled with the pin 833 and the second beam 82 is adjusted by the telescopic operation of the hydraulic cylinder 83 . Since the first beam 81 and the second beam 82 are coupled to the hydraulic cylinder 83 at the ends spaced apart from the center in the longitudinal direction to both sides, according to the distance adjustment according to the expansion and contraction of the hydraulic cylinder 83, the first beam The attitude of the second beam 82 relative to 81 is adjusted.

The first beam of the lifting unit 80 ( 81) can be adjusted to be level with the ground.

The crane unit 70 is configured to operate while supporting a large load, so that the hydraulic cylinder 73 for rotating the first movable beam 71 and the electric winch for winding the wire 75 have a large capacity. . Therefore, it is not appropriate to operate the hydraulic cylinder 73 and the electric winch of the crane unit 70 for fine leveling of the first beam 81 of the lifting unit, and in particular, frequent operations for fine leveling are these mechanisms. can do damage to

However, in this embodiment, after the first beam 81 is suspended from the crane unit 70 so as to be in a near-horizontal state, the hydraulic cylinder 83 of the lifting unit is used to lift the second beam 81 to the first beam 81. The posture of the beam 82 can be adjusted so that the second beam 82 is level with the ground or has a desired posture.

The second beam 82 is provided with two lifting blocks 84 disposed on the second beam and having variable positions along the length direction of the second beam.

Each lifting block 84 is configured to have a rectangular cross-section surrounding the second beam 82 as a whole and is configured to slide and move in the longitudinal direction of the second beam 82, and form a wind power generation system on the side. A pin 841 around which a sling 85 on which a lifting jig ( 86 in FIG. 5 ) suspended an element is suspended protrudes.

A lead screw 85 forming a position adjustment mechanism for adjusting the longitudinal position of the lifting block is coupled to a portion of the lifting block 84 placed above the second beam 82 .

The lead screw 85 extends in the longitudinal direction of the second beam 82, and one end receives rotational force from a drive motor 86 equipped with a speed reducer. The longitudinal position of the lifting block 84 on the second beam 82 is adjusted by the rotation of the lead screw 85 .

Accordingly, the sling 85 wound around the pin of the lifting block 84 can be placed at the position where the sling is wound on the item to be lifted, and the position of the lifting block 84 is adjusted even after the item is wound with the sling 85. By doing so, the position of the article in the longitudinal direction of the second beam 82 can be adjusted.

The process of lifting an article by the crane device having the above configuration will be described.

FIG. 8 sequentially illustrates the process of installing the lower part of the tower on the ground and installing the tower unit 2 constituting the tower on the lower part of the installed tower during the process of constructing the wind power generation system.

When the trailer (4) loaded with the tower unit (2) is towed by the tractor (3) and arrives at the construction site of the wind power generation system, a separate crane device (5) removes the tower unit (2) from the trailer (4). Lift up.

The crane device of this embodiment is installed at the bottom of the tower 1 through the process described with reference to FIG. Lower the lifting hook close to the ground on one side.

The lifting unit 80 is suspended on two lifting hooks, and the hydraulic cylinder 83 of the lifting unit 80 adjusts the lifting unit 80 to a horizontal position.

A jig (86 in FIG. 5) suitable for suspending the tower unit 2 is suspended from the sling 85 provided on the lifting block of the lifting unit 80, and the tower unit 2 is fixed to the jig 86. It is suspended on the lifting unit 80.

This state is shown in Fig. 8(a).

As shown in (b) of FIG. 8, in the crane device of this embodiment, as the wire 75 of the two crane units 70 is synchronously wound with each other, the lifting unit 80 and the tower unit 2 suspended therein ) is generally parallel to the tower (1) and the center line of the tower unit (2) is lifted upwards in a state aligned with the center line of the tower (1).

The two crane units 70 are arranged side by side with the tower 1 interposed therebetween on the upper side of the upper base 10 installed to surround the tower 1, and the lifting unit 80 has two crane units at both ends. Since it is suspended on 70, the tower unit 2 suspended on the lifting unit 80 can be lifted while aligned with the center line of the tower 1.

When the tower unit 2 is located above the installed tower 1, the hydraulic cylinder 73 of the crane unit 70 extends while the movable beams 71 and 72 rotate, as shown in FIG. 8(c). As described above, the tower unit 2 first moves to a position concentric with the installed tower.

The tower unit 2 moves the tower 1 by the operation of the movable beam 71 of the crane unit 70 and the movement of the lifting block 84 in the lifting unit 80 relative to the second beam 82. and the position is matched, and assembly work can be performed.

In the above operation, the crane unit 70 for lifting the tower unit 2 is spaced apart from each other on both sides from the center line of the tower 1, so that the eccentricity of the load applied to the tower 1 is minimized, especially the tower unit In a state where (2) is located substantially above the tower (1), the weight of the tower unit (2) and the crane device of this embodiment installed on the tower are eccentric and do not act on the tower (1).

In addition, the operation of coupling the tower unit 2 to the top of the tower 1 requires a very fine operation, such an operation minimizes the operation of the crane unit 70 and the lifting unit in the lifting unit 80 ( 84).

Next, with reference to FIG. 9, the operation of coupling or disassembling the blade 8 to the wind power generation system by the crane device of this embodiment will be described.

In the operation shown in FIG. 9 , the blades 8 are installed on the hub 9 provided in the nacelle 7 with only two crane units 70 without using the lifting unit 80 .

The blade 8 is lifted in a state where the ends coupled to the turbine shaft 9 are suspended on two crane units 70.

The blade 8 can maintain a vertical state by adjusting the length of the wire 75 of the two crane units 70, and, of course, the rotation angle of the movable beams 71 and 72 of the two crane units 70 and By adjusting the length, the angle and position can be adjusted so that the end of the blade 8 can be assembled to the turbine shaft 9.

Above, the configuration and operation of the self-elevating crane device according to the present invention has been described. The present invention is not limited to these embodiments, and various modifications and variations and addition of components are possible within the scope described in the claims, and the crane device to which such various modifications and variations are made and components are added is the object of this invention. belong to the range

1: tower 10: upper base
20: lower base 30: lifting base
40: hydraulic cylinder 50: post
60: brake mechanism 70: crane unit
80: lifting unit

Claims (10)

delete A crane device for installation and maintenance of a tower and a wind power generation system provided at the top of the tower,
an elevating unit attached to the tower and provided to elevate up and down along the tower;
Two crane units disposed on top of the elevating unit;
A lifting unit that is suspended and raised by two crane units, and the items constituting the wind power generation system are suspended.
It is composed of,
The two crane units are spaced apart from each other with the tower in between and arranged side by side, and the two coupling points spaced apart from the longitudinal center on both sides of the lifting unit are suspended on the crane unit, respectively,
lifting unit,
In accordance with the operation of the crane unit, it is moved in the vertical direction of the tower or in the radial direction of the tower, and is configured to move the suspended item in a direction perpendicular to the radial and vertical directions of the tower,
A first beam that extends in the longitudinal direction and is provided with the coupling points spaced apart from the center of the longitudinal direction to both sides; a second beam disposed under the first beam and extending in the longitudinal direction; It is coupled between the second points spaced apart from both sides of the center in the longitudinal direction of the first beam and the third points spaced apart from both sides from the center of the length direction of the second beam, and the length is stretched so that the second point and the third point leveling means configured to level the second beam by varying the distance between points; A plurality of lifting blocks spaced apart from each other along the longitudinal direction of the second beam, movably installed along the longitudinal direction of the second beam, and having suspension points on which items constituting the wind power generation system are suspended; and a position adjustment mechanism driven to adjust the positions of the lifting blocks in the longitudinal direction of the second beam, respectively. The method of claim 2,
A crane device, wherein a hydraulic cylinder is disposed at a third point of the second beam as a leveling means, and a piston of the hydraulic cylinder is coupled to a second point of the first beam. The method of claim 3,
The crane device, wherein the tip of the piston of the hydraulic cylinder is rotatably hinged to the second point of the first beam. The method of claim 2,
The position adjustment mechanism includes a drive motor and a lead screw rotated by the drive motor, and each lifting block is screwed with the lead screw to move along the longitudinal direction of the second beam according to the rotation of the lead screw so that the position is changed. The crane device, which is to be adjusted. The method of claim 2,
Each crane unit includes a movable beam that rotates around a first point on the upper part of the lifting unit and has a suspension point at which a distance from the first point is expanded and contracted; a wire extending between the suspension point and the coupling point of the movable beam; and actuating means for stretching and retracting the length of the wire extending between the suspension point and the coupling point of the movable beam;
The lifting unit is a crane device that is moved in the vertical direction of the tower or moved in the radial direction of the tower by the rotation and extension of the movable beam and the extension and contraction of the wire length. The method of claim 6,
Each crane unit includes a hydraulic cylinder, the end of the cylinder of the hydraulic cylinder is rotatably coupled to the second point on the upper part of the lifting unit, and the piston tip is rotatably coupled to the movable beam, A crane device capable of rotating the movable beam around the second point by the telescopic operation of the hydraulic cylinder. The method of claim 7,
Each crane unit further comprises a lifting hook rotatably coupled to the coupling point of the lifting unit, and the lifting hook is coupled to the front end of the wire, the crane device. In any one of claims 2 to 8,
lift unit,
An upper base and a lower base that are configured to surround the tower and are variable in a state in which they are fixedly supported at any position of the tower and in a state in which they can be raised and lowered with respect to the tower,
A plurality of posts extending between the upper and lower bases so that the upper and lower bases are fixed to each other at positions spaced apart from each other vertically;
An elevating base configured to surround the tower, variable between a state fixedly supported at an arbitrary position of the tower and a state capable of elevating and descending with respect to the tower, and disposed to be elevating and descending along the post between the upper and lower bases, and
A drive mechanism that is disposed between the elevating base and the upper base or the lower base and changes the distance between the elevating base and the upper and lower bases by varying the length.
It is composed of,
With the upper and lower bases fixed and supported at an arbitrary position of the tower, the length of the driving mechanism is varied so that the elevating base moves up and down along the tower, and the driving mechanism in a state where the elevating base is fixed and supported at an arbitrary position of the tower. By varying the length, the upper base and the lower base move up and down along the tower, and the crane unit is disposed on the upper base. The method of claim 9,
The upper and lower bases and the elevating base include frames extending in a plane perpendicular to the extension direction of the tower,
A plurality of posts extend upward through the frame of the upper base,
A crane device, wherein each crane unit is disposed on top of at least two posts among a plurality of posts.

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