KR20140120539A - Buoyancy casing moving method of Semi-submersible heavy weight carrier - Google Patents

Abstract

The present invention relates to a method for moving the buoyancy casings of a semi-submersible heavy weight carrier and, more specifically, to a method for moving the buoyancy casings of a semi-submersible heavy weight carrier capable of increasing the efficiency of a loading space of a deck according to the shape of heavy weights by easily changing the position of buoyancy casings on the deck. The method for moving the buoyancy casings of a semi-submersible heavy weight in a state where the buoyancy casings are separated upward from a deck comprises a lifting device setting step of setting multiple lifting devices on the deck under the buoyancy casings in the longitudinal direction of the buoyancy casings; a buoyancy casing separating step of separating the buoyancy casings fixed on the deck; a buoyancy casing lifting step of lifting the buoyancy casings using the lifting devices arranged under the buoyancy casings; a rail assembly setting step of setting rail assemblies on the deck under the buoyancy casings; a buoyancy casing lowering step for mounting the buoyancy casings on the rail assemblies by lowering the buoyancy casings using the lifting devices; and a power cylinder operating step of operating a power cylinder to move the buoyancy casings on the rail assemblies.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a buoyancy casing moving method for semi-submersible heavy weight carriers,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a buoyancy casing moving method for semi-submersible heavy goods carriers, and more particularly, to a buoyancy casing moving method for semi-submersible heavy goods carriers, .

Due to the limitation of the weight, shape and size of the cargo to be transported, it is not possible to transport the cargo to a general cargo ship. A planned cargo carrier to carry such a cargo is a semi-submersible heavy- (semi-submersible heavy lift carrier).

Types of semi-submersible heavy goods carriers include heavy lift vessels, dock type vessels, and open deck vessels.

These semi-submersible heavy-goods carriers require the adjustment of the ballast balance so that the weight of the heavy goods does not bias the hull to one side in order to carry the heavy goods safely.

For this purpose, a semi-submersible heavy-goods carrier is equipped with a ballast balance measuring device, ie buoyancy casing.

The buoyancy casing is typically a box-like structure that is installed at the stern above the upper deck as shown in FIG. 1 to secure additional buoyancy in a semi-submersible heavy lift carrier.

At this time, the buoyancy casing (10) is installed on both sides of the stern, and is formed in a hexahedron so as to balance the sides of the hull.

At this time, the buoyancy casing 10 is fixed on the deck by welding, and all the bottom edges of the buoyancy casing 10 are fixed by welding.

Hereinafter, the heavy load shipment and load using the semi-submersible heavy-goods carrier constructed as described above will be briefly described.

First, water is injected into the ballast water tank constituting the buoyancy casing 10 of the semi-submersible heavy cargo ship to submerge the hull deck 20 below the water surface.

Next, heavy objects such as semi-articulated ships and offshore structures are shipped on the deck of semi-submersible heavy-goods carriers.

At this time, the heavy object is shipped in a space secured between the buoyancy casing 10 and the cabin 30, as shown in Fig.

Thereafter, when the loading operation for the heavy object is completed, the ballast water tank is emptied to raise the deck 20 of the semi-submerged neutralizer carrier over the sea.

That is, the buoyancy of the buoyancy casing 10 floats the deck 20 of the submerged ship over the sea.

On the other hand, when loading of the heavy object is completed, the semi-submersible heavy object carrier is operated to transport the heavy object to the destination.

Thereafter, after arriving at the destination, the buoyancy casing 10 is filled with water to lower the deck 20 of the semi-submerged neutralizer carrier in order to load the heavy object.

Thereafter, transportation of the heavy object is completed by lifting the heavy object from the semi-submerged heavy object carrier.

However, the semi-submersible heavy-goods carrier described above has the following problems.

There is a problem that efficiency of space utilization of the deck 20 for loading a heavy object is low because the buoyancy casing 10 is fixed to the stern.

In other words, various types of heavy objects can be provided, and there is a problem that heavy object loading is restricted when heavy material is required to be loaded in the longitudinal direction of the ship due to interference of the buoyancy casing 10.

Although the buoyancy casing 10 may be removed from the deck to change the position of the buoyancy casing 10, the efficiency of the heavy load may be increased. However, since the buoyancy casing 10 is welded to the deck 20 There is a problem in that workability for removing the buoyancy casing 10 is deteriorated.

Republic of Korea Publication No. 10-2010-0045886

SUMMARY OF THE INVENTION It is an object of the present invention to provide a semi-submersible pump which can increase the efficiency of space utilization of a deck according to the shape of a heavy object to be loaded, And to provide a method for moving a buoyancy casing of a heavy goods carrier.

In order to achieve the above object, the present invention provides a method of moving a buoyancy casing of a semi-submersible heavy-goods carrier with a buoyancy casing spaced upward from a deck, the method comprising the steps of: A first buoyancy casing lifting step for lifting the buoyancy casing using a lifting device disposed below the buoyancy casing, a second buoyancy casing lifting step for lifting the buoyancy casing using a lifting device disposed below the buoyancy casing, a second buoyancy casing lifting step for lifting the buoyancy casing, A first buoyant casing lowering step for lowering the buoyancy casing using a lifting device to seat the buoyancy casing on the rail assembly, a power cylinder for operating the power cylinder to move the buoyancy casing on the rail assembly, Operation phase: Semi-dive consisting of It provides a buoyant casing move a heavy object carrier method.

A second buoyancy casing lifting step of lifting the buoyancy casing when it is determined that the buoyancy casing has reached the target position, and a second buoyancy casing lifting step of lifting the buoyancy casing when it is determined that the buoyancy casing has reached the target position; A second buoyancy casing lowering step of lowering the raised buoyancy casing to the deck, and a buoyancy casing fixing step of fixing the buoyancy casing to the deck, in order to disassemble the rail assembly below the buoyancy casing.

In addition, when it is determined in the target position determination step that the buoyancy casing has not reached the target position, it is preferable to perform the power cylinder recombination step in which the power cylinder is moved and rejoined to the rail assembly.

In addition, the rail assembly setting step preferably includes a plurality of rail units coupled to each other to configure various paths for moving the buoyancy casing.

In addition, the lifting device is preferably a jack-up device.

The buoyancy casing moving method of the semi-submerged heavy goods carrier according to the present invention has the following effects.

First, lifting the buoyancy casing by using a relatively simple jack-up device has the effect of increasing the convenience of moving the buoyancy casing to the rail.

Second, since a plurality of rail units can be assembled to constitute a movement path for the buoyancy casing, convenience for moving the buoyancy casing can be improved, and the moving distance of the buoyancy casing can be minimized.

Third, the buoyancy casing is fixed by a fixed support while being separated from the deck, so that the buoyancy casing can be easily fixed and separated to the deck.

That is, the fixed area between the buoyancy casing and the deck is minimized, thereby reducing the detachment operation time of the buoyancy casing to the deck, thereby reducing the manhole.

Fourth, since the cabin can be arranged in the longitudinal direction of the hull, and the position of the buoyancy casing can be arranged in various ways, the efficiency of the heavy load space with respect to the deck can be improved.

Fifth, it is effective to reduce the water storage capacity of the buoyancy casing, but to maintain the balance of the hull by installing a low-capacity buoyancy casing on the deck.

Figure 1 is a side view schematically showing a semi-submersible heavy goods carrier according to the prior art;
2 is a perspective view illustrating a semi-submersible heavy-goods carrier for a buoyancy casing moving method of a semi-submersible heavy-goods carrier according to a preferred embodiment of the present invention.
FIG. 3 is a perspective view showing main equipment of a semi-submersible heavy-goods carrier for a buoyancy casing moving method of a semi-submersible heavy-goods carrier according to a preferred embodiment of the present invention.
FIG. 4 is a side view showing a skid roller among the main equipment of a semi-submerged heavy goods carrier for a buoyancy casing moving method of a semi-submersible heavy-goods carrier according to a preferred embodiment of the present invention
5A is a plan view showing a state in which a lifting device is disposed on a bottom surface of a buoyancy casing for a method of moving a buoyancy casing of a semi-submerged heavy goods carrier according to a preferred embodiment of the present invention.
FIG. 5B is a plan view showing a state in which a buoyancy casing is seated on a rail assembly for a buoyancy casing moving method of a semi-submerged heavy goods carrier according to a preferred embodiment of the present invention.
FIG. 6 is a side elevational view showing a recess in a state in which a buoyancy casing is seated on a rail assembly for a method of moving a buoyancy casing of a semi-submerged heavy goods carrier according to a preferred embodiment of the present invention;
7A and 7B are a plan view showing examples of a state in which the buoyancy casing is moved and arranged by the buoyancy casing moving method of the semi-submerged heavy goods carrier according to the preferred embodiment of the present invention
8 is a flowchart illustrating a method of moving a buoyancy casing of a semi-submersible heavy-goods carrier according to a preferred embodiment of the present invention.

It is to be understood that the words or words used in the present specification and claims are not to be construed in a conventional or dictionary sense and that the inventor can properly define the concept of a term in order to describe its invention in the best possible way And should be construed in light of the meanings and concepts consistent with the technical idea of the present invention.

Hereinafter, a method of moving a buoyancy casing of a semi-submerged heavy goods carrier according to a preferred embodiment of the present invention will be described with reference to FIGS. 2 to 8 attached hereto.

First, a semi-submerged heavy goods carrier for buoyancy casing moving method will be described.

Semi-submersible heavy goods carriers have the technical feature to move the buoyancy casing over the deck.

As a result, the efficiency of securing the loading space of the deck can be improved.

Semi-submersible heavy goods carriers are comprised of a hull, a cabin 30 and mobile equipment for moving the buoyancy casing 100, as shown in FIGS. 2 and 3.

The cabin 30 is provided with a cockpit for space and navigation of crew members, and is installed at one side of the deck 20 of the hull.

At this time, it is preferable that the cabin arrangement direction on the deck 20 is installed in the longitudinal direction of the hull as shown in FIG.

This is to increase the efficiency of the deck 20 in the loading space, thereby increasing the utilization of the space for loading the heavy weight.

Next, the buoyancy casing 100 plays a role of maintaining the balance of the hull, and a plurality of buoyancy casings (100) are installed on the deck (20).

At this time, it is preferable that the buoyancy casing 100 is reduced in size by reducing the capacity for storing the ballast water, and is provided in plural.

This is for the purpose of enhancing the convenience of the movement of the buoyancy casing 100, and in order to perform balance maintenance of the hull.

On the other hand, the buoyancy casing 100 is fixed in a state of being spaced upward from the deck 20.

This is because the buoyancy casing 100 is separated from the deck 20 by minimizing the area of the fixing portion with respect to the deck 20, unlike the conventional case where the entire bottom surface of the buoyancy casing 100 is welded to the deck 20, The lifting device described later is disposed below the buoyancy casing in order to facilitate detachment and attachment with the buoyancy casing 20.

To this end, a fixed support 110 is installed at each corner of the bottom surface of the buoyancy casing 100.

The height of the fixed support 110 is preferably about 60 to 80 cm in consideration of the load and the height of the buoyancy casing 100.

At this time, it is preferable that the fixed support 110 is fixed to the deck 20 by welding or bolted.

A plurality of base members 120 are installed on the bottom surface of the buoyancy casing 100 in the longitudinal direction of the buoyancy casing 100.

The base member 120 is a portion to be coupled to an engagement pin of a skid roller which will be described later, and the base member 120 is formed with an insertion groove 121 into which the engagement pin is inserted.

Next, the equipment for moving the buoyancy casing 100 comprises a lifting device 200, a rail assembly 300, a skid roller 400, and a power cylinder 500.

The lifting device 200 generates power for lifting the buoyancy casing 100 from the deck 20, and a plurality of buoyancy casings 100 are disposed below the buoyancy casing 100.

At this time, it is preferable that the lifting device 200 is provided as a jack-up device, and it is preferable to provide about eight lifting devices, but the number is not limited.

The rail assembly 300 provides a path of movement of the buoyancy casing 100 and is mounted on the deck 20.

At this time. The rail assembly 300 is provided to couple a plurality of rail units.

Accordingly, since the coupling of the rail unit can be variously arranged, the moving distance of the buoyancy casing 100 can be minimized, and the operator can easily determine the moving position of the buoyancy casing 100.

The skid roller 400 is mounted on the rail assembly 300 as moving means for moving the buoyancy casing 100 through rolling action.

The skid roller 400 includes a body 410, a rolling member 420, and a rotary plate 430, as shown in FIGS.

The body 410 is a portion for carrying the buoyancy casing 100, and is installed in the rail assembly 300 in a rolling manner.

At this time, a coupling portion 411 for coupling with the power cylinder 500, which will be described later, is formed at one end of the body 410.

The rolling member 420 serves as a cloud for moving the body 410 along the rail assembly 300 and is installed at the lower end of the body 410.

The rolling member 420 includes a guide wheel 421 for guiding a movement path to prevent the body 410 from moving away from the rail assembly 300 and a guide rail 422 for moving the body 410 while traveling along the rail assembly 300 And a driving wheel 422 for driving.

The guide wheel 421 is installed at the front end and the rear end of the body 410 and is axially coupled so as to roll along the side surface of the rail assembly 300.

A plurality of traveling wheels 422 are installed at the lower portion of the body 410 and installed to roll along the upper surface of the rail assembly 300.

That is, the guide wheel 421 is axially coupled to the rail assembly 300 in a horizontal direction, and the drive wheel 422 is axially coupled to the rail assembly 300 in a direction perpendicular to the rail assembly 300.

The rotating plate 430 is a portion where the buoyancy casing 100 is substantially seated, and is coupled to the upper portion of the body 410.

At this time, a plurality of engagement pins 431 are formed on the rotation plate 430.

The coupling pin 431 is inserted into the insertion groove 121 formed in the base member 120 of the buoyancy casing 100 and installed upward along the edge of the rotary plate 430.

That is, when the buoyancy casing 100 is mounted on the rotary plate 430, the engagement pin 431 of the rotary plate 430 is inserted into the insertion groove 121 of the base member 120, So that a stable movement can be achieved.

At this time, it is preferable that the coupling pin 431 is detachably coupled to the rotary plate 430.

Further, the rotary plate 430 is axially coupled to the upper portion of the body 410, and is rotated around the axis.

This is to allow the coupling pin 431 of the rotating plate 430 to be easily coupled to the fixed base member 120.

That is, since the rotation plate 430 can be freely rotated with respect to the insertion groove 121 of the fixed base member 120, the engagement pin 431 of the rotation plate 430 can be inserted And may be coupled to the groove 121.

Next, the power cylinder 500 serves to move the buoyancy casing 100 seated on the skid roller 400 by pushing or pulling the skid roller 400 on the rail assembly 300.

At this time, one end of the power cylinder 500 is detachably coupled to the rail assembly 300, and the other end of the power cylinder 500 is detachably coupled to the coupling portion 411 of the skid roller 400.

At this time, the other end of the power cylinder 500 refers to the end of the piston rod.

That is, the skid roller 400 is moved while the piston rod moves into and out of the cylinder body.

Hereinafter, a method of moving the buoyancy casing in a semi-submersible heavy-goods carrier constructed as described above will be described.

First, equipment for moving the buoyancy casing 100 is transported from a storage place to one side of the buoyancy casing 100 to be moved.

Since all of the above-described equipments are provided as units, they are usually disposed in a separate storage place and are carried around the buoyancy casing 100 only when the buoyancy casing 100 is moved.

5A, a lifting device 200, that is, a jack-up device is disposed below the buoyancy casing 100. In operation S10,

At this time, since the buoyancy casing 100 is separated from the deck 20 by the fixed support 110, the placement of the jack-up device 200 can be done without much difficulty.

Next, the fixed support 110 fixed on the deck 20 is separated from the deck (S20)

This results in the separation of the buoyancy casing 100 by lifting the buoyancy casing 100 from the deck 20, by loosening the bolt or releasing the welded area.

At this time, since the area of the portion fixed to the deck 20 is small, the separation operation for the buoyancy casing 100 can be easily performed.

Next, a hydraulic power unit is operated to perform a first buoyancy casing lifting step of lifting up the buoyancy casing 100 to a plurality of the jack-up units 200 (S30)

At this time, it is preferable to check the height of the jack-up device 200 to adjust the hydraulic pressure so that the load of the buoyancy casing 100 can be distributed to each of the jack-up devices 200.

Next, the rail assembly 300 is fixed to the lower deck 20 of the buoyancy casing 100 (S40)

At this time, the worker determines the moving path of the buoyancy casing 100 in advance and joins the plurality of rail units in the moving direction.

Next, as shown in FIG. 5B, a plurality of skid rollers 400 are coupled onto the rail assembly 300 (S40)

At this time, it is preferable that the skid roller 400 is installed about eight in the longitudinal direction of the rail assembly 300, and it is preferable that the skid roller 400 is installed at equal intervals.

3, the guide wheels 421 of the skid roller 400 are closely attached to both sides of the rail assembly 300 and the driving wheels 422 are brought into close contact with the upper surface of the rail assembly 300. As shown in FIG.

Next, the power cylinder 500 is coupled to the rail assembly 300.

At this time, one end of the power cylinder 500 is coupled to the rail assembly 300, and the other end of the power cylinder 500 is coupled to the coupling portion 411 of the skid roller 400.

At this time, the power cylinder 500 is not necessarily installed on all the skid rollers 400, but may be installed only at a position corresponding to the middle portion of the buoyancy casing 100.

Therefore, as shown in FIG. 5B, the power cylinder 500 is installed at about four.

Next, the first buoyancy casing descending step is performed in which the buoyancy casing 100 is gradually lowered using the jack-up device 200 lifting the buoyancy casing 100. (S50)

At this time, the buoyancy casing 100 is seated on the rotary plate 430 of the skid roller 400 disposed below, and the engagement pin 431 of the rotary plate 430 is fixed to the base member 120, As shown in FIG.

Thus, the buoyancy casing 100 can be stably mounted on the skid roller 400 without large flow.

Next, the jack-up device 200 disposed below the buoyancy casing 100 is pulled out so that the buoyancy casing 100 can be smoothly moved.

Next, the hydraulic system is operated to push the power cylinder 500 to push the skid roller 400. (S60)

The skid roller 400 is rotated along the rail assembly 300 and the buoyancy casing 100 seated on the skid roller 400 is moved by the withdrawal length of the piston rod of the power cylinder 500.

Thereafter, a target position determination step is performed to determine whether the position of the buoyancy casing 100 moved by the operation of the power cylinder 500 is a desired position (S70). [

When the buoyancy casing 100 is not positioned at the desired position, the power cylinder 500 is separated from the rail assembly 300, and the rail assembly 300 at the position where the skid roller 400 is moved, (S80).

At this time, since the power cylinder 500 is detachably coupled to the coupling portion 411 of the skid roller 400 and the rail assembly 300, it is understandable that such a series of operations can be carried out without difficulty .

Next, the above-described series of processes is repeated to move the buoyancy casing 100 to a desired position.

When the movement of the buoyancy casing 100 is completed at a desired position, a plurality of the jack-up devices 200 are disposed below the buoyancy casing 100, and then the jack-up device 200 is moved to the buoyancy casing 100 The second buoyancy casing lifting step of lifting the second buoyancy casing upward is performed (S90)

Next, equipment such as the rail assembly 300 and the skid roller 400 disposed below the buoyancy casing 100 are dismantled (S100)

Next, the second buoyancy casing lowering step of gradually lowering the buoyancy casing 100 using the jack-up device 200 is performed (S110)

 Next, when the fixed support 110 of the buoyancy casing 100 touches the deck 20, the buoyancy casing 100 is moved by welding or bolts to complete the movement of the buoyancy casing 100 (S120).

Through such a series of processes, all the buoyancy casings 100 on the deck can be moved to different positions and their arrangement can be changed according to the type of the object to be loaded on the deck 20, as shown in FIGS. 7A and 7B And the like.

As described above, since the semi-submersible heavy-goods carrier according to the present invention can easily change the position of the buoyancy casing, there is a technical feature that it is possible to increase the efficiency of the loading space of the deck according to the shape of the heavy object to be loaded.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art.

100: Buoyancy casing 110: Fixed support
120: base member 121: insertion groove
200: lifting device 300: rail assembly
400: skid roller 410: body
411: engaging portion 420: rolling member
421: Guide wheel 422: Driving wheel
430: rotating plate 431: engaging pin
500: Power cylinder

Claims (5)

A method of moving a buoyancy casing of a semi-submersible heavy goods carrier with a buoyancy casing spaced upward from a deck,
A lifting device setting step of setting a plurality of lifting devices in the longitudinal direction of the buoyancy casing on the lower deck of the buoyancy casing;
A buoyancy casing separation step of separating the buoyancy casing fixed to the deck;
A first buoyancy casing lifting step of lifting the buoyancy casing using a lifting device disposed below the buoyancy casing;
A rail assembly setting step of setting the rail assembly on the lower deck of the buoyancy casing;
A first buoyancy casing lowering step of lowering the buoyancy casing using a lifting device and seating the buoyancy casing on a rail assembly;
Operating the power cylinder to move the buoyancy casing over the rail assembly. ≪ Desc / Clms Page number 20 > The method according to claim 1,
After the power cylinder actuation step,
A target position determining step of determining whether the buoyancy casing has reached a target position;
A second buoyancy casing lifting step of lifting the buoyancy casing when it is determined that the buoyancy casing has reached the target position;
A disassembly step of disassembling the rail assembly under the buoyancy casing;
A second buoyancy casing lowering step of lowering the raised buoyancy casing to the deck;
And a buoyancy casing fixing step of fixing the buoyancy casing to the deck. 3. The method according to claim 1 or 2,
And when the buoyancy casing is determined not to reach the target position in the target position determination step, the power cylinder re-combination step of moving the power cylinder and rejoining the power cylinder to the rail assembly is performed. 3. The method according to claim 1 or 2,
Wherein the rail assembly setting step includes combining a plurality of rail units to form a variety of moving paths of the buoyancy casing. 3. The method according to claim 1 or 2,
Wherein the lifting device is a jack-up device. ≪ RTI ID = 0.0 > 8. < / RTI >

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