KR101566523B1 - Method for building ship - Google Patents

Abstract

A ship drying method is disclosed. A method of drying a ship using a floating dock according to an embodiment of the present invention is a method of drying a ship using a floating dock, comprising: a large block preparation step of floating a first large block and a second large block having different drafts at sea; Lowering the floating dock; A large block placing step of placing the first large block and the second large block in the floating dock in ascending order of the draft while raising the floating dock; And a large block joining step of joining the first large block and the second large block together.

Description

{METHOD FOR BUILDING SHIP}

The present invention relates to a ship drying method.

In general, the shipbuilding industry, which consists of designing, building and delivering, starting with the order of the ship, is judged by the profitability of the business in the process.

At this time, one of the important factors that determine such profitability is the productivity that comes from the ship 's drying method, and all the shipbuilding industry is striving to improve the productivity of shipbuilding.

The block method first divides the hull into dozens or hundreds of blocks, assembles the divided blocks on the ground first, and then sequentially reassembles the assembled blocks into a dock (dry dock, floating dock, dock) or a barge to dry one ship.

To accomplish this, first, the block is completed in the most efficient manner in each factory according to its shape, and then a painting operation is performed on the completed block.

Thereafter, the painted blocks are combined into several blocks. The work of combining the plurality of blocks in this manner is referred to as a pre-errection (PE) operation.

Most shipyards are making a lot of effort to increase the dock turnover by making many blocks necessary for the ship first as large block through PE work, and then to transport it to the inside of the dock to dry the ship.

On the other hand, a dock is a facility built on a shipyard or a port to repair and dry a ship. The dock is largely divided into a dry dock and a floating dock.

First, dry dock is a land structure for ship construction. It can open and close a dock gate that is docked in the sea, fill water in the dock, and draw water from the inside of the dock.

On the other hand, a floating dock is a floating structure that contains a ballast tank inside a dock. When water is injected into the ballast tank, the floating dock sinks into the water, and when the water is discharged from the ballast tank, It has a floating shape in the sea.

Such a floating dock does not require site or foundation work for drying the ship, has a relatively short drying period, can reduce the drying cost, and has advantages of convenient launching of a dry ship.

Thus, drying vessels or offshore structures on floating docks can save drying costs and time compared to drying on dry land docks.

Conventionally, in a method of drying a ship in a floating dock, a large block is manufactured so as to approach a maximum capacity of a crane on the land, and then mounted on a floating dock, and the large blocks mounted are welded to each other, .

On the other hand, in order to increase the efficiency of ship drying, the blocks mounted on the dock are becoming larger and larger, and a new drying method such as a mega block method using a sea crane and a gigablock method has been developed.

This new shipbuilding method is evolving into a 'terablock' method of completing ships with only two blocks of very large size.

However, the use of marine cranes is time consuming and costly. Due to the limitation of the capacity of marine cranes, the 'Terrablock' with a weight of at least 10,000 tons is handled and mounted on the dock, This is not easy.

An embodiment of the present invention is to provide a ship drying method capable of easily mounting a plurality of large blocks on a floating dock without using a crane.

One embodiment of the present invention seeks to provide a method of drying a ship by combining a plurality of large blocks in a floating dock.

According to an aspect of the present invention, there is provided a method of drying a ship using a floating dock, comprising: preparing a large block to float a first large block and a second large block having different drafts at sea; Lowering the floating dock; A large block placing step of placing the first large block and the second large block in the floating dock in ascending order of the draft while raising the floating dock; And a large block joining step of joining the first large block and the second large block together.

At this time, the large block joining step may include an upper restraining step of joining the upper portion of the first large block and the upper portion of the second large block; Raising the floating dock to a working height; And fully combining the first large block and the second large block.

Further, before the step of lowering the floating dock, the floating dock may further include a step of providing a bogie capable of supporting the first large block and the lower portion of the second large block.

In addition, the large block seating step may include moving the first large block into the floating dock; Binding the first large block to the floating dock; Raising the floating dock so that the first large block is supported on the double helix; Moving the second large block into the floating dock; Binding the second large block to the floating dock adjacent to the first large block; And raising the floating dock so that the second large block is supported on the double helix.

The step of binding the first large block to the floating dock and raising the floating dock so that the first large block is supported on the double dock may be carried out by using the lifting means arranged on the floating dock, The position of the first large block can be controlled by winding or loosening the rope connected to one large block.

The step of binding the first large block to the floating dock and raising the floating dock so that the first large block is supported on the bifurcation may further comprise the steps of: Comparing the indicated baseline; Measuring a distance between the floating dock and the first large block; And measuring a three-dimensional coordinate value of a specific point of the first large block using a three-dimensional position measuring instrument installed in the floating dock.

Meanwhile, the upper confining step may include a step of joining an upper portion of the first large block and an upper portion of the second large block with a plurality of auxiliary members, or an upper portion of the first large block and an upper portion of the second large block, And the step of contacting.

The large block preparation step may include processing the first large block and the second large block so that their drafts are different from each other.

The floating dock includes a ballast tank. The floating dock is lowered by injecting seawater into the ballast tank, and the seawater of the ballast tank is discharged to the outside to raise the floating dock.

According to one embodiment of the present invention, by moving the floating dock up and down, the large block of the vessel can be mounted on the floating dock.

According to one embodiment of the present invention, the position of the large block can be adjusted while the large block of the ship is mounted on the floating dock by using the hoisting means disposed in the floating dock.

According to an embodiment of the present invention, the position of the large block of the ship can be precisely adjusted and mounted on the floating dock by using the baseline, the distance measuring device, and the three-dimensional position measuring device.

According to an embodiment of the present invention, a plurality of large blocks can be sequentially mounted on the floating dock by processing the drafts differently.

According to one embodiment of the present invention, a ship can be easily dried by sequentially mounting a plurality of large blocks to a floating dock and joining them.

1 is a view showing a state in which a plurality of large blocks are mounted on a floating dock.
2 is a flowchart illustrating a ship drying method according to an embodiment of the present invention.
FIG. 3 is a view illustrating a large block preparing step of a ship drying method according to an embodiment of the present invention.
FIG. 4 is a view illustrating a step of lowering a floating dock of a ship drying method according to an embodiment of the present invention.
FIG. 5 is a flowchart showing a large block seating step in a ship drying method according to an embodiment of the present invention.
6 to 10 are views illustrating a process of seating a first large block in a large block seating step of a ship drying method according to an embodiment of the present invention.
11 to 14 are views showing a process of seating a second large block in a large block seating step of a ship drying method according to an embodiment of the present invention.
15 to 17 are views showing a large block joining step in a ship drying method according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings, which will be readily apparent to those skilled in the art to which the present invention pertains. The present invention may be embodied in many different forms and is not limited to the embodiments described herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and the same or similar components are denoted by the same reference numerals throughout the specification.

1 is a view showing a state in which a plurality of large blocks are mounted on a floating dock 100. Fig.

Referring to FIG. 1, the floating dock 100 includes a horizontally disposed bottom 104 and a pair of outer walls 102 extending upwardly from opposite sides of the bottom 104 and disposed opposite each other.

As shown in FIG. 1, the floating dock 100 may extend in the longitudinal direction of the ship to be dried, and its cross-section may be a U-shaped.

Also, the floating dock 100 may be formed to be larger than at least a ship to be dried so that the ship to be dried can be mounted.

1, a part of the floating dock 100 is shown in a sectional view for the convenience of understanding.

In the present specification, the x direction is defined as the longitudinal direction, the y direction is defined as the width direction, and the z direction is defined as the vertical direction with reference to Fig. 1 (or Figs. 10, 14, and 17).

Thus, the longitudinal direction is the bow direction of the ship, the width direction is the left-right direction of the ship, and the up-down direction is defined as the height direction of the ship.

Referring to FIG. 1, a plurality of large blocks may be mounted on the floor 104 of the floating dock 100.

At this time, according to an embodiment of the present invention, the large block 10 may be a tera block.

At this time, the terra block is a block having a weight of 10000 tons or more, and can dry a single ship with only two terra blocks, for example, a bow block and a stern block.

Accordingly, according to one embodiment of the present invention, the plurality of large blocks may include a first large block 10 and a second large block 20, as shown in FIG.

1, the first large block 10 forms a stern block of the ship, and the second large block 20 forms a bow block of the ship.

1, the first large block 10 and the second large block 20 are connected to the outer wall 102 of the floating dock 100, respectively, May be mounted on the floor 104 of the dock 100.

At this time, since the first large block 10 and the second large block 20 each having a weight of 10,000 kg or more exceed the capacity of a general crane, a method of using a land crane or a marine crane It is very difficult to mount the robot on the floating dock 100.

Hereinafter, a ship drying method according to an embodiment of the present invention, that is, a first large block 10 and a second large block 20 having a weight of 10,000 tons or more is mounted on a floating dock 100, The method will be described in detail with reference to the drawings.

2 is a flowchart illustrating a ship drying method according to an embodiment of the present invention.

Referring to FIG. 2, the ship drying method according to an embodiment of the present invention includes four steps.

Specifically, the large block preparation step S201, the step of lowering the floating dock 100 (S202), the large block seating step S203, and the large block combining step S204 are included.

That is, according to one embodiment of the present invention, the floating dock 100 is lowered so as to be positioned lower than a plurality of large blocks that are floated (S201) while floating the manufactured plurality of large blocks in the sea (S201) S202), the floating dock 100 is raised so that a plurality of large blocks are sequentially placed on the floating dock 100 (S203), and a plurality of large blocks are placed on the floating dock 100 (S204) Can be dried.

Accordingly, instead of mounting a plurality of large blocks on the floating dock 100 using equipment such as a crane, the floating dock 100 can be raised and lowered in a state where a plurality of large blocks are floated on the sea, A plurality of large blocks can be easily mounted on the floating dock 100 by moving and fixing the positions of the plurality of large blocks while ballasting and deballasting the plurality of large blocks, By joining the large blocks together on the floating dock 100, the ship can be effectively dried.

Hereinafter, each step of the ship drying method according to an embodiment of the present invention will be described in detail in order.

As described above, according to the embodiment of the present invention, since the plurality of large blocks constituting the ship may include the first large block 10 and the second large block 20, The first large block 10 and the second large block 20 will be described as an embodiment of the present invention.

However, the present invention is not limited to this, and a plurality of large blocks may include two or more large blocks.

3 is a view illustrating a large block preparing step (S201) of a ship drying method according to an embodiment of the present invention.

In the first step, the large block preparation step S201 is a process of floating a plurality of large blocks in the sea, and according to an embodiment of the present invention, the first large block 10 and the second large block 20 are manufactured And processing the first large block 10 and the second large block 20 to float on the sea.

Here, the step of fabricating the first large block 10 and the second large block 20 may refer to a general block manufacturing process.

In this case, according to an embodiment of the present invention, the step of manufacturing the first large block 10 and the second large block 20 may include a step of forming a tread block for forming a bow block or stern block It can be a process of making.

Meanwhile, the step of machining the first large block 10 and the second large block 20 so as to float on the sea is performed before the produced first large block 10 and the second large block 20 are launched to the sea , The first large block 10 and the second large block 20 are machined so that the first large block 10 and the second large block 20 to be launched can be floated in the horizontal direction .

In this case, according to an embodiment of the present invention, the opening process may include closing the opening space such that water does not enter into the first large block 10 and the second large block 20 floated on the sea.

In order to prevent trim and heeling of the first large block 10 and the second large block 20 and balance the drafts, the first large block 10 and the second large block 20 20 with an additional weight or float.

According to an embodiment of the present invention, in the step of machining the first large block 10 and the second large block 20 to float on the sea, the first large block 10 and the second large block 20 Can be processed to have different drafts.

For example, when the first large block 10 is the stern block and the second large block 20 is the fore block, the first large block 10 is moved to the second large block 20 due to the propulsion of the engine or the like, The draft D1 of the first large block 10 can be made larger than the draft D2 of the second large block 20. In this case,

This is for sequentially mounting the first large block 10 and the second large block 20 on the floating dock 100 as will be described later.

According to an embodiment of the present invention, the first large block 10 and the second large block 20 can be effectively divided so that the mounting process of the first large block 10 and the second large block 20 can be effectively divided. 20) can be processed to be 600 mm or more.

As such, when the first large block 10 and the second large block 20 having been subjected to the machining step are launched into the sea, as shown in Fig. 3, they can be suspended in the sea at different drafts, It can be floated while being kept horizontal without tilting.

FIG. 4 is a view illustrating a step (S202) of lowering the floating dock 100 of the ship drying method according to an embodiment of the present invention.

The step S202 of lowering the floating dock 100 as the second stage is performed so that the floating dock 100 is positioned below the first large block 10 and the second large block 20 floating on the sea floor, (100) is increased.

According to an embodiment of the present invention, by injecting seawater into the ballast tank (not shown) provided in the floating dock 100 through the balancing process of the floating dock 100, 100) can be lowered.

At this time, the floating dock 100 can be lowered so that the large block having the largest draft among a plurality of large blocks, for example, the first large block 10 having the largest draft, is located below the large block.

4, the entirety of the floating dock 100 is not lowered until it is completely submerged below the sea surface S, but the lower portion of the outer wall 102, which can be a working space in the floating dock 100, The upper part should be exposed above the sea level (S).

Accordingly, as will be described later, the first large block 10 and the second large block 20 moved into the floating dock 100 can be handled using the equipment arranged on the outer wall 102.

Referring to FIG. 4, a bump 50 may be installed on the bottom 104 of the floating dock 100.

That is, according to an embodiment of the present invention, before the step S202 of lowering the floating dock 100, the first large block 10 and the second large block 20 to be mounted on the floating dock 100 (50) capable of supporting the lower portion.

The first large block 10 and the second large block 20 may be formed to correspond to the shape of the lower side of the first large block 10 and the second large block 20 to be mounted, May be configured with a strength and number sufficient to support the block 20.

The step S202 of lowering the floating dock 100 is performed by moving the floating dock 100 so that the bumps 50 are lower than the lower sides of the first large block 10 and the second large block 20 to be mounted More specifically, the floating dock 100 can be lowered until the bumps 50 are positioned below the lower side of the first large block 10 having the largest draft.

In this case, according to the embodiment of the present invention, for safe mounting of the first large block 10, the upper end of the double leg 50 and the lower end of the first large block 10 are floated The dock 100 can be lowered.

5 is a flowchart showing a large block seating step (S203) of a ship drying method according to an embodiment of the present invention.

The third step, the large block seating step S203, is a process of placing the first large block 10 and the second large block 20 to be mounted on the floating dock 100 on the floating dock 100.

5, the first large block 10 is placed on the bobbin 50 provided on the floating dock 100, and then the second large block 10 20 can be seated on the bobbin 50 provided on the floating dock 100.

According to an embodiment of the present invention, since the first large block 10 and the second large block 20 can be seated on the floating dock 100 while the floating dock 100 is raised, The first large block 10 having a large draft can be sequentially placed in the floating dock 100 and then the second large block 20 having a small draft can be seated thereafter.

First, the process of placing the first large block 10 on the floating dock 100 will be described in detail.

6 to 10 are views showing a process of seating the first large block 10 in a large block seating step (S203) of a ship drying method according to an embodiment of the present invention.

5, the process of placing the first large block 10 includes moving the first large block 10 into the floating dock 100 (S501), moving the first large block 10 to a floating A step S502 of binding the dock 100 to the dock 100 and a step S503 of raising the floating dock 100 so that the first large block 10 is supported on the double helix 50.

The step S501 of moving the first large block 10 into the floating dock 100 is a process of moving the first large block 10 to be mounted to the upper portion of the loading position in the floating dock 100, The process is shown in Fig.

In this case, according to an embodiment of the present invention, as shown in FIG. 6, the first large block 10 can be moved into the floating dock 100 by using the tugboat 30.

At this time, a plurality of tugboats 30 can be used, and the first large block 10 is positioned between the outer walls 102 of the floating dock 100.

At this time, the position where the first large block 10 is moved may be the position close to the mounting position in the floating dock 100, that is, the upper portion of the mounting position.

The step S203 of moving the first large block 10 into the floating dock 100 is not limited to the process in which the tugboat 30 is used, It is possible.

The first large block 10 moved into the floating dock 100 in the above-described manner can then be bound to the floating dock 100.

That is, the step of binding the first large block 10 to the floating dock 100 (S502) is performed so that the first large block 10 moved into the floating dock 100 does not deviate from the position, The process of locating the movable docking station 10 in the floating dock 100 is shown in Fig.

According to an embodiment of the present invention, the step S502 of binding the first large block 10 to the floating dock 100 is performed by using the rope 150, The dock 100 can be connected to each other.

Referring to FIG. 7, the first large block 10 may be connected to the outer wall 102 of the floating dock 100 by using a plurality of ropes 150.

According to an embodiment of the present invention, a plurality of ropes 150 may be used to connect the first large block 10 and the lifting means disposed on the outer wall 102 of the floating dock 100.

According to an embodiment of the present invention, the hoisting means may include at least one of a winch 110 and a chain block 140.

The winch 110 installed on the outer wall 102 of the floating dock 100 and the binding member 14 formed on the first large block 10 are connected by the rope 150 Can be connected.

The rope 150 connected to the binding member 14 formed on the first large block 10 is connected to the chain block 140 disposed on the outer wall 102 of the floating dock 100 and the chain block 140 Can be bound to the mast 120 formed on the outer wall 102 of the floating dock 100.

Accordingly, the position of the first large block 10 can be adjusted by operating the winch 100 and the chain block 140 as lifting means.

Meanwhile, the binding member 14 formed on the first large block 10 may be a laying device such as a bollard, a bit, or the like, but is not limited thereto. The rope 150 may be used as a floating dock 100 Or may be a lug-shaped member separately formed on the first large block 10 so as to be able to engage with the first large block 10.

The winch 110, the caster 120 and the chain block 140 described above are connected to the upper surface of the outer wall 102 of the floating dock 100, that is, a deck of the outer wall 102 Quot;).

Thus, according to one embodiment of the present invention, in the deck of the outer wall 102 of the floating dock 100, the operator can use the rope 110 connected to the first large block 10 by using the winch 110 and the chain block 140 The first large block 10 can be positioned at an upper point of the mounting position in the floating dock 100, as shown in Fig.

The first large block 10 bound to the outer wall 102 of the floating dock 100 and positioned above the loading position in the manner described above is then moved to the first large block 10 by raising the floating dock 100, To the floating dock (100).

That is, the step (S503) of raising the floating dock 100 so that the first large block 10 is supported on the bumps 50 is performed by adjusting the position of the first large block 10 bound to the floating dock 100 8 is a process of raising the floating dock 100 until the first large block 10 is supported by the bifurcation 50 while holding or holding the floating block 100. [

At this time, according to the embodiment of the present invention, the floating dock 100 is discharged to the outside through the de-ballasting process, that is, the seawater injected into the ballast tank (not shown) provided in the floating dock 100, The floating dock 100 can be raised.

8, in the step S503 of raising the floating dock 100 so that the first large block 10 is supported on the double helix block 50, the first large block 10 The spacing of the ropes 150 connecting the first large block 10 and the outer wall 120 of the floating dock 100 must be changed while the floating dock 100 is lifted.

Thus, in order to maintain the position of the first large block 10 bound to the floating dock 100 while the floating dock 100 is lifted, by operating the lifting means such as the winch 110, the chain block 140, The spacing of the ropes 150 connecting the first large block 10 and the outer wall 102 of the floating dock 100 can be adjusted.

8, the step S503 of raising the floating dock 100 so that the first large block 10 is supported on the double helix block 50 may be performed by moving the first large block 10 in the floating dock 100, But the position of the first large block 10 can be continuously changed because the second large block 10 is not supported by the bobbin 50. [

Therefore, according to an embodiment of the present invention, a position control process for raising the floating dock 100 and controlling the relative position of the first large block 10 with respect to the floating dock 100 may be included.

In this case, according to an embodiment of the present invention, the position control process is performed by winding or loosening the rope 150 connected to the first large block 10 using the winch 110, the chain block 140, The relative position of the first large block 10 relative to the floating dock 100 can be adjusted.

Accordingly, the first large block 10 can be stably mounted on the floating dock 100 at a predetermined mounting position.

More specifically, the bumps 50 disposed on the floor 104 of the floating dock 100 are arranged in a first size (the first size) when the first large block 10 is mounted at a predetermined position The first large block 10 bound to the floating dock 100 is positioned in a correct position while the floating dock 100 is lifted up for precise mounting because the first large block 10 is arranged to correspond to the shape of the lower side of the block 10 It is necessary to continually adjust the position of the first large block 10 or to continuously control the movement of the first large block 10 so that the position is maintained without departing from the normal position.

8, while the floating dock 100 is lifted in step S503 of raising the floating dock 100 so that the first large block 10 is supported by the bumps 50, When the spacing of the rope 150 connecting between the first large block 10 and the first large block 10 is loosely adjusted, due to various factors such as waves and wind, The relative position of the rope 150 may be changed or the length of the rope 150 may be shortened when the distance between the floating dock 100 and the first large block 10 is shortened. The first large block 10 may be displaced while being pulled by the rope 150 when the floating dock 100 is lifted.

Thus, according to an embodiment of the present invention, in the step S503 of raising the floating dock 100 so that the first large block 10 is supported on the bumps 50, the floating dock 100 and the first large block The first large block 10 is positioned in the correct position by using the winch 110 or the chain block 140 capable of operating the rope 150 connecting between the first large block 10 and the first large block 10, There is a need for a position control process in which the large block 10 continuously and precisely controls the movement of the first large block 10 so that the position is maintained while the floating dock 100 is ascending.

At this time, according to the embodiment of the present invention, in the above-mentioned position control process, the position of the first large block 10 is adjusted while confirming whether the first large block 10 is positioned or not by using a preset reference .

In detail, the position control process may include at least one of a longitudinal direction adjusting step, a width direction adjusting step, and a bidirectional adjusting step.

The longitudinal direction adjusting step is a step of adjusting the longitudinal position of the first large block 10 mounted on the floating dock 100.

At this time, according to the embodiment of the present invention, it is possible to confirm whether the fixed position is used by using the reference line in the longitudinal direction adjustment step.

The dock reference line 160 displayed on the floating dock 100 and the first reference line 16 displayed on the first large block 10 can be used to confirm whether or not the fixed position is correct.

9 and 10, the dock reference line 160 can be displayed in the width direction on the decks of both side outer walls 102 of the floating dock 100, and the first reference line 16 can be displayed in the first large Can be displayed on both sides of the block 10, for example, on the outer side of the left and right strings in the vertical direction.

That is, if the position of the first reference line 16 displayed on the first large block 10 is adjusted based on the dock reference line 160 displayed on the floating dock 100, for example, It is possible to confirm whether or not the one reference line 16 is arranged in a straight line based on the longitudinal direction and to determine whether the rope 150 is operated by using the winch 110 or the chain block 140, 160 and the first reference line 16 are arranged on a straight line, the longitudinal position of the first large block 10 can be adjusted.

On the other hand, the width direction adjusting step is a step of adjusting the width direction position of the first large block 10 mounted on the floating dock 100.

At this time, according to the embodiment of the present invention, in the width direction adjustment step, it is possible to confirm whether the fixed position is using the distance between the outer wall 102 of the floating dock 100 and the first large block 10.

For example, it is possible to confirm whether the first large block 10 is positioned in the width direction by using the distance measuring device 170 installed on the outer wall 102 of the floating dock 100.

9 and 10, the distance measuring device 170 can measure the distance in the width direction from the first large block 10 and can be installed on both outer walls 102 of the floating dock 100 .

Thus, the distance from the distance measuring device 170 provided on each outer wall 102 to the outer side surfaces of the first large block 10 (the outer side facing each outer wall) is measured, and two measured distance values It is possible to confirm whether the first large block 10 is in the forward direction or not by using the winch 110 or the chain block 140. In this way, Can adjust the position of the first large block 10 in the width direction by adjusting the position of the first large block 10 so that the distance values in the first large block 10 are the same.

At this time, according to an embodiment of the present invention, the distance measuring device 170 may be arranged to measure the distance to the point forming the plane of the left and right front outer sides of the first large block 10 for effective distance measurement have.

On the other hand, the bidirectional adjustment step is a step of adjusting both the longitudinal direction and the width direction position of the first large block 10 mounted on the floating dock 100.

At this time, according to the embodiment of the present invention, in the two-direction adjustment step, the three-dimensional position measuring device 180 can be used to confirm whether or not the position is correct.

For example, it is possible to confirm whether the first large block 10 is in a fixed position by using the three-dimensional position measuring device 180 installed on the outer wall 102 of the floating dock 100.

9 and 10, the three-dimensional position measuring device 180 provided on the outer wall 102 of the floating dock 100 is positioned at a certain point of the first large block 10, for example, The three-dimensional coordinate value of the first target 18 displayed in the block 10 can be measured.

At this time, the first target 18 can be displayed on a three-dimensional curved surface which is difficult to measure by the distance measuring unit 170 described above, and the first target (18) can be displayed on the first target 18) may be measured in advance. [0031] In this case, the three-dimensional coordinate value (defined as the reference coordinate value in this specification) may be measured in advance.

Accordingly, the three-dimensional coordinate value of the first target 18 displayed on the first large block 10 is measured by the three-dimensional position measuring device 180 provided on the floating dock 100, and the measured three- It is possible to confirm whether the first large block 10 is in the forward or reverse direction based on the width direction and the longitudinal direction by comparing the reference coordinates with the measured reference coordinate values and the rope 150 can be manipulated using the winch 110 or the chain block 140 When the position of the first large block 10 is adjusted so that the coordinate value corresponding to the longitudinal direction and the width direction among the three-dimensional coordinate values of the first target 18 measured by the method 1 is equal to the reference coordinate value, The longitudinal and lateral positions of the large block 10 can be adjusted.

As described above, according to the embodiment of the present invention, in the position adjustment step, the reference line alignment method, the method of measuring the left and right current distance values through the distance meter 170, the method of comparing coordinate values through the three- The position of the first large block 10 can be precisely adjusted.

The lower portion of the first large block 10 is seated at the correct position of the bobbin 50 provided on the bottom 104 of the floating dock 100 so that the first large block 10 is moved by the bobbin 50 Can be supported.

After the first large block 10 having a large draft is seated on the floating dock 100 through the above-described method, the second large block 20 having a small draft is seated on the floating dock 100 through a method described later .

Hereinafter, a process of placing the second large block 20 on the floating dock 100 will be described in detail.

11 to 14 are views showing a process of seating the second large block 20 in the large block seating step (S203) of the ship drying method according to the embodiment of the present invention.

5, the process of placing the second large block 20 includes moving the second large block 20 into the floating dock 100 (S504), moving the second large block 20 to a floating Step S505 of binding the dock 100 to the dock 100 and step S506 of raising the floating dock 100 so that the second large block 20 is supported on the bobbin 50. [

The process of placing the second large block 20 is substantially the same as the process of placing the first large block 10 described above and will be briefly described below. ).

11, the step (S504) of moving the second large block 20 into the floating dock 100 is performed by using the plurality of tugboats 30 to move the second large block 20 to the floating dock 100 To the upper position close to the loading position in the floating dock 100, into the interior of the floating dock 100.

12, the step (S505) of binding the second large block 20 to the floating dock 100 is performed such that the second large block 20 moved into the floating dock 100 moves out of position The second large block 20 and the outer wall 102 of the floating dock 100 are connected to each other by using the rope 150 as a process of locating the second large block 20 in the floating dock 100 The winch 100 and the chain block 140 disposed on the outer wall 102 of the second large block 20 and the floating dock 100 can be lifted up using a plurality of ropes 150 Means can be connected.

At this time, the position of the second large block 20 can be adjusted by operating the winch 100 and the chain block 140 as lifting means, and according to an embodiment of the present invention, , The second large block 20 can be positioned so as to be adjacent to the first large block 10 which is already seated on the double helix 50.

14, the dock reference line 160 indicated on the deck of the outer wall 102 on the side of the second large block 20 on the loading dock 100 and the left and right strings of the second large block 20 A method of comparing the second reference line 26 displayed in the vertical direction on the side face and a method of measuring the distance in the width direction using the distance measuring device 170 provided on the outer wall 102 on the side of the second large block 20 on the loading dock 100 And a method of measuring a three-dimensional coordinate value of a specific point using the three-dimensional position measuring device 180 and comparing the three-dimensional coordinate value with a reference coordinate value, The longitudinal and lateral positions can be adjusted.

However, in order to prevent the second large block 20 from colliding with the first large block 10 during the ascending process, the second large block 20 is moved in the binding process of the second large block 20 20 can be adjusted to a certain distance from the first large block 10 to a certain extent.

13, step S506 of raising the floating dock 100 so that the second large block 20 is supported on the bumps 50 is performed by raising the floating dock 100 to move the second large block 20 20 can be seated on the floating dock 100.

At this time, while the floating dock 100 is lifted up, the position of the second large block 20 bound to the floating dock 100 is adjusted to the final mounting position, and the second large block 20, The floating dock 100 can be raised until the movable member 20 is supported by the bumps 50. [

The first large block 10 is supported by the bobbin 50 but the second large block 20 is coupled to the outer wall 102 of the floating dock 100, The position of the second large block 20 can be continuously changed.

 Therefore, as in the first large block 10, it is possible to include a position control process for raising the floating dock 100 and controlling the relative position of the second large block 20 relative to the floating dock 100 have.

14, the dock reference line 160 displayed on the floating dock 100 is compared with the second reference line 26 displayed on the second large block 20, The longitudinal position can be adjusted and controlled.

14, the width direction position of the second large block 20 can be adjusted and controlled by using the distance measuring device 170 provided on the outer wall 102 of the floating dock 100. [

14, by using the three-dimensional position measuring device 180 provided on the outer wall 102 of the floating dock 100, the three-dimensional position measuring device 180 of the second target 28, which is displayed on the second large block 20, By measuring the dimension coordinate values, the longitudinal and lateral positions of the second large block 20 can be adjusted and controlled.

Through such a process, the large block mounting step S203 is completed by sequentially supporting the first large block 10 and the second large block 20 on the double helix block 50, S204).

15 to 17 are views showing a large block joining step (S204) of a ship drying method according to an embodiment of the present invention.

15 to 17, the large block joining step S204 is a process of joining a plurality of large blocks seated on the floating dock 100 to each other, according to an embodiment of the present invention, Raising the floating dock 100 to the working height, and fully engaging the plurality of large blocks.

At this time, the upper confining step is a step of joining the plurality of large blocks seated on the floating dock 100, for example, the upper portion of the first large block 10 and the second large block 20.

This is because in order to join the first large block 10 and the second large block 20 to each other, the upper surface of the floor 104 of the floating dock 100 is positioned above the sea level S, The floating dock 100 is deflected by the weight of the mounted first large block 10 and the second large block 20 while the floating dock 100 is lifted The hogging of the first large block 10 and the second large block 20, that is, the center portion of the ship, may be bent due to the upward force, (10) and the second large block (20).

Here, the 'work height' means that the bottom surface of the floating dock 100 is positioned above the sea surface S, so that the operator can easily work on the bottom surface of the floating dock 100, Height.

In the present specification, the upper side of the bottom 104 of the floating dock 100 is defined as a " bottom surface ".

Meanwhile, according to an embodiment of the present invention, the upper confining step may combine the upper portion of the first large block 10 and the upper portion of the second large block 20 with a plurality of auxiliary members 40.

15, a plurality of auxiliary members 40 may be disposed between the upper portion of the first large block 10 and the upper portion of the second large block 20, and the auxiliary member 40 may be welded or the like The first large block 10 and the second large block 20 can be coupled to each other through the method of FIG.

At this time, the auxiliary member 40 may be in the form of a flat plate, but it is not limited thereto, and any member capable of connecting the first large block 10 and the upper portion of the second large block 20 to each other may be included.

Meanwhile, according to an embodiment of the present invention, the upper confining step may make the upper portion of the first large block 10 and the upper portion of the second large block 20 abut each other.

That is, the first large block 10 and the second large block 20 can be fixed by abutting the upper portion of the engaging portions of the first large block 10 and the second large block 20. [

Thus, the upper portion of the first large block 10 and the upper portion of the second large block 20 are constrained, and then the floating dock 100 is raised to the working height.

15, since the first large block 10 and the second large block 20 are positioned below the sea surface S in the upper confining step, the first large block 10, And the second large block 20, the floating dock 100 must be raised to the working height.

At this time, the step of raising the floating dock 100 to the working height is shown in Fig.

16, in the step of raising the floating dock 100 to the working height, in a state where both the first large block 10 and the second large block 20 are supported by the boss 50, The floor dock 100 is raised until the upper side (bottom surface) of the bottom 104 of the floor 100 is positioned above the sea level S.

At this time, as described above, the hogging phenomenon of the ship due to the deformation of the floating dock 100 can be effectively prevented through the upper confining step.

After the floating dock 100 is raised to the working height, the plurality of large blocks can be fully engaged.

At this time, according to an embodiment of the present invention, all portions of the coupling portion between the first large block 10 and the second large block 20 can be welded and combined.

At this time, the auxiliary member 40 used in the upper confining step can be separated.

Alternatively, the welded portion may be fully welded in the upper constraining step.

The first large block 10 and the second large block 20 may be connected to the floating dock 100 before or after joining all the connection portions between the first large block 10 and the second large block 20. [ The rope 150 that has been bound to the outer wall 102 of the main body 100 can be separated.

In this way, by completely joining the first large block 10 and the second large block 20, the completed vessel can be completed.

As described above, in the ship drying method according to an embodiment of the present invention, the floating dock 100 can be used to mount and connect large blocks of 10,000 tons or more to dry the ship.

At this time, according to one embodiment of the present invention, a method of raising and lowering the floating dock 100 can be used to mount the large block on the floating dock 100 without using a crane.

At this time, according to the embodiment of the present invention, by using the lifting means disposed in the floating dock 100, it is possible to adjust the positions of the plurality of large blocks.

In this case, according to an embodiment of the present invention, the position of a plurality of large blocks can be precisely adjusted by using a reference line, a distance measuring device, and a three-dimensional position measuring device.

Further, according to the embodiment of the present invention, a plurality of large blocks can be sequentially mounted on the floating dock 100 in the descending order of the draft by processing the plurality of large blocks at different drafts.

According to an embodiment of the present invention, it is possible to prevent deformation of a plurality of large blocks by restricting the upper portions of a plurality of large blocks sequentially mounted.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

10 first large block 14 binding member
16 first reference line 18 first target
20 second large block 26 second reference line
28 second target 30 tugboat
40 Auxiliary member 50 Boss
100 floating dock 102 outer wall
104 floor 110 winch
120 caster 140 chain block
150 rope 160 dock baseline
170 Distance Measuring Machine 180 3D Position Measuring Machine
S sea level

Claims (9)

A method of drying a ship using a floating dock,
A large block preparing step of floating a first large block having a large draft and a second large block having a draft smaller than that of the first large block, respectively, on the sea;
Lowering the floating dock so as to be positioned below the first large block having a large draft;
Placing a first large block having a large draft in the floating dock while raising the floating dock, and then sequentially placing the second large blocks having a small draft; And
And joining the first large block and the second large block seated on the floating dock to each other. The method according to claim 1,
The large block combining step includes:
An upper restraining step of assembling the upper portion of the first large block and the upper portion of the second large block;
Raising the floating dock to a working height; And
And fully engaging the first large block and the second large block. The method according to claim 1,
Further comprising the step of providing a bogie capable of supporting the first large block and the bottom of the second large block to the floating dock prior to the step of lowering the floating dock. The method of claim 3,
The large block seating step comprises:
Moving the first large block into the floating dock;
Binding the first large block to the floating dock;
Raising the floating dock so that the first large block is supported on the double helix;
Moving the second large block into the floating dock;
Binding the second large block to the floating dock adjacent to the first large block; And
And raising the floating dock so that the second large block is supported on the double helix. 5. The method of claim 4,
Coupling the first large block to the floating dock, and raising the floating dock to support the first large block in the bifurcation,
Wherein the lifting means disposed in the floating dock is used to wind or loosen the rope connected to the first large block to control the position of the first large block. 6. The method of claim 5,
Coupling the first large block to the floating dock, and raising the floating dock to support the first large block in the bifurcation,
Comparing a reference line displayed on the floating dock with a reference line displayed on the first large block;
Measuring a distance between the floating dock and the first large block; And
And measuring a three-dimensional coordinate value of a specific point of the first large block using a three-dimensional position finder installed in the floating dock. 3. The method of claim 2,
Wherein the upper confining step comprises:
And joining the upper portion of the first large block and the upper portion of the second large block with a plurality of auxiliary members or abutting the upper portion of the first large block and the upper portion of the second large block to each other, Way. delete 8. The method according to any one of claims 1 to 7,
The floating dock includes a ballast tank,
The floating dock is lowered by injecting seawater into the ballast tank,
And the seawater of the ballast tank is discharged to the outside to raise the floating dock.

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