KR20130001363A - Floating dock device and method for building structure - Google Patents

Abstract

PURPOSE: A floating dock device and a method for constructing a structure are provided to quickly and safely construct ships and offshore structures. CONSTITUTION: A floating dock device(100) comprises a floating dock body part(110), a ballast part, and a balancing part(130). The floating dock body part is placed on one side of a dock or is floated on the sea. The ballast part is arranged in the floating dock body part to selectively draw in or out seawater. The balancing part comprises a spud device formed on the floating dock body part.

Description

Floating dock device and method for building structure

The present invention relates to a floating quay device and a method of drying the structure, and more particularly to a floating quay device and a method for drying the structure for ships and offshore structures.

In general, the apparatus and method for drying ships and offshore structures are dried on the land and moved to the sea to launch them, or they are dried on floating docks floating on the sea to inundate and launch floating docks.

However, if the construction of the above-described apparatus and method on the land is essential for launching barge for launching ships and offshore structures. Such a launch barge has a problem that the barge must be enlarged when the ship and offshore structures are enlarged. In addition, there is a time limit because the barge should be considered in order to launch the ship and the marine structure by docking the quay.

On the other hand, in the case of using the floating dock, it is difficult to move the logistics because it is difficult to access the floating dock on land. In addition, the cost of building floating docks was high, resulting in increased production costs for ships and offshore structures. Floating docks, in particular, are difficult to secure during typhoons such as typhoons.

An embodiment of the present invention is to provide a floating quay wall device and a method of building a structure that can be built quickly and safely ships and offshore structures.

One aspect of the present invention, a floating quay wall body portion floating in the ocean or seated on one side of the land quay, and a ballast portion disposed in the floating quay wall body portion to selectively inflow or outflow of sea water, and the floating quay It may include a balance maintaining portion having a spud device formed in the body portion.

In addition, the ballast portion may be introduced into the seawater when the floating quay body portion is seated on the land quay, and may flow out the seawater when floating to the sea.

The balance maintaining part may further include a wing tank installed on both sides of the floating quay wall body part to maintain the equilibrium of the floating quay wall body part by inflow or outflow of seawater from the outside.

In addition, the height of the spud device can be fixed or separated from the floating quay wall body portion to the land quay.

In addition, the spud device may include a drive unit for generating a driving force, a spur having a gear tooth formed on an outer surface thereof, and a pinion for rotating by the driving force and moving the spud in conjunction with the gear tooth.

In addition, the spud device may include a hydraulic cylinder of variable length.

In addition, the floating quay wall body portion when the floating in the sea water, the floating quay wall body portion may further include a control tower for controlling the balance maintaining portion to maintain the balance.

Another aspect of the invention the first step of drying the structure on the upper side of the floating quay device; And a second step of flowing out of the seawater to the floating quay wall body portion to the outside and floating the floating quay wall body portion to lead to the sea.

In addition, prior to the first step may further include the step of introducing the seawater into the floating quay wall body portion, and operating the balance maintaining portion to secure the floating quay wall body portion to the land quay.

The balance maintaining part may further include a third step of lowering the floating quay wall body part and seating one end of the balance keeping part on the sea floor.

The method may further include a fourth step of introducing the seawater into the floating quay-body portion to lower the sea level.

 The method may further include a fifth step of lifting the structure to separate the floating quay wall body part.

In addition, a sixth step of discharging the seawater of the floating quay wall body portion to the outside to raise the floating quay wall body portion over the sea surface.

In addition, a seventh step of raising the balance maintaining portion; may further include.

Floating quay wall device and structure drying method according to embodiments of the present invention can quickly and safely dry ship and offshore structures.

1 is a conceptual diagram showing a floating quay device according to an embodiment of the present invention.
Figure 2 is a perspective view showing an embodiment of the ballast portion installed in the floating quay wall device shown in FIG.
3 is a hydraulic circuit diagram showing the ballast part shown in FIG.
4 is a cross-sectional view illustrating an embodiment of the balance maintaining unit illustrated in FIG. 1.
5 is an operational state diagram showing a first operation of the floating quay wall device shown in FIG.
6 is an operating state diagram showing a second operation of the floating quay wall device shown in FIG.
7 is an operating state diagram showing a third operation of the floating quay wall device shown in FIG.
8 is an operating state diagram showing a fourth operation of the floating quay wall device shown in FIG.
9 is an operational state diagram showing a fifth operation of the floating quay wall device shown in FIG.
10 is an operational state diagram showing a sixth operation of the floating quay wall device shown in FIG.

1 is a conceptual diagram showing a floating quay wall device 100 according to an embodiment of the present invention.

Referring to FIG. 1, the floating quay wall device 100 includes a floating quay wall body part 110 seated on the land quay wall C. FIG. In this case, a structure (not shown) to be dried may be disposed above the quay wall body 110.

In this case, the structure may be variously formed. For example, the structure may include a vessel (not shown). In addition, the structure may include an offshore structure (not shown).

Hereinafter, for convenience of description, the structure will be described based on the case of the marine structure.

The floating quay wall body 110 may be formed of the same material as the land quay wall (C). Floating quay wall body portion 110 may be formed of concrete on the outside, it may be formed of a metal structure on the inside.

At this time, the floating quay wall body 110 may be formed to correspond to one side of the land quay wall (C). A seating portion D may be formed at one side of the land quay wall C so that the floating quay wall body 110 is seated.

The seating portion D may be formed to extend from the land quay wall C, and may be formed in multiple stages from the land quay wall C. FIG. The seating portion D may be formed below the upper surface of the land safety wall C. At this time, the seating portion (D) may be formed to be disposed below the sea surface in contact with the ocean.

In addition, when the floating quay wall body portion 110 is seated on the seating portion (D), the upper surface of the floating quay wall body portion 110 and the upper surface of the land quay wall (C) may form the same plane. Therefore, various materials used for ships and offshore structures can be easily moved from the floating quay wall (C) to the floating quay wall body (110).

On the other hand, the floating quay wall device 100 includes a ballast portion 120 (see Fig. 2) disposed inside the floating quay wall body portion 110. The ballast part 120 selectively introduces or discharges seawater from the outside or the inside of the floating quay wall body part 110.

Floating quay wall device 100 includes a balance maintaining portion 130 is fastened to one side of the floating quay wall body portion (110).

At this time, the balance maintaining unit 130 may include a wing tank (not shown, Wing tank) disposed on both sides of the floating quay wall body (110). At this time, the wing tank may maintain the balance of the floating quay device 100 by introducing sea water from the outside.

In addition, the balance maintaining unit 130 may include a spud device disposed on the floating quay wall body 110. At this time, the spud device can adjust the length to maintain the equilibrium of the floating quay device 100 similar to the wing tank. Hereinafter, for convenience of description, the at least one balance maintaining unit 130 will be described based on the case of including the spud device.

In addition, a plurality of balance maintaining unit 130 may be coupled to the floating quay wall body portion (110). The plurality of balance maintaining units 130 may be fastened to the floating quay wall body 110 so as to penetrate the floating quay wall body 110.

The plurality of balance maintaining units 130 are disposed to be spaced apart from each other by a predetermined interval. Therefore, the plurality of equilibrium maintaining parts 130 maintain the stability of the floating quay wall body 110 when the floating quay wall body 110 descends into water or rises to the surface for launching the structure.

On the other hand, the plurality of balance maintaining unit 130 may be formed so that a portion is inserted into the mounting portion (D). At this time, the plurality of equilibrium maintaining portions 130 are fixed to the seating portion (D) to fix the floating quay wall body portion (110) to the land quay wall (C).

Hereinafter, the ballast part 120 and the at least one balance maintaining part 130 will be described in detail.

FIG. 2 is a perspective view showing an embodiment of the ballast part 120 installed in the floating quay wall device 100 shown in FIG. 1. 3 is a hydraulic circuit diagram illustrating the ballast part 120 shown in FIG. 2.

2 and 3, the ballast part 120 includes a ballast tank 121. The ballast tank 121 is formed of metal and concrete to store seawater.

The ballast tank 121 may be provided in plurality, and the plurality of ballast tanks 121 may be formed to be adjacent to each other. At this time, a portion of the plurality of ballast tanks 121 may be formed with a flow hole 122 so that sea water flows with each other.

The ballast part 120 may include a seawater flow part 124 for supplying or outflowing seawater to the ballast tank 121. On the one side of the seawater flow portion 124, an on-off valve (not shown) for interrupting the seawater flow portion 124 may be disposed.

The seawater flow unit 124 may be formed in plural. The plurality of seawater flow units 124 may be formed to protrude to the inside of each ballast tank 121. Accordingly, the plurality of seawater flow units 124 supplies or discharges seawater to each ballast tank 121.

On the other hand, the ballast portion 120 may include a flow pipe 125 is fastened to the seawater flow portion 124. In this case, when the plurality of seawater flow units 124 are disposed, the flow pipe 125 may be coupled to each seawater flow unit 124.

Hereinafter, for convenience of description, the seawater flow unit 124 will be described based on a plurality of cases.

The flow pipe 125 supplies the seawater flowing in from the outside to each seawater flow unit 124. In addition, the flow pipe 125 guides the seawater supplied from each ballast tank 121 to each seawater flow unit 124 to the outside.

The ballast part 120 may include a ballast pump 123 fastened to the flow pipe 125. The ballast pump 123 may apply pressure so that the seawater flows to the flow pipe 125. The ballast pump 123 may rotate in the forward or reverse direction according to the flow direction of the seawater to flow in and out of the seawater into each ballast tank 121.

Hereinafter, for convenience of description, when the ballast pump 123 rotates forward, the description will be given based on a case where seawater flows into each ballast tank 121.

As described above, the ballast part 120 allows seawater to flow into or out of the floating quay wall body part 110. Accordingly, the ballast portion 120 can easily float or submerge the floating quay wall body portion 110 as needed.

4 is a cross-sectional view showing an embodiment of the balance maintaining unit 130 shown in FIG.

Referring to FIG. 4, the balance maintaining unit 130 may be formed in various ways. The balance maintaining unit 130 may include a spud device as described above. In addition, the balance maintaining unit 130 may include a hydraulic system (not shown).

When the balance maintaining unit 130 includes the spud device, the spud device may include spuds 131 and spud. Spud 131 is formed long in one direction may be formed with a plurality of gears (not shown) on one surface. The plurality of gear teeth may be formed in the longitudinal direction of the spud 131.

The spud device may include a pinion 132 fastened to one side of the spud 131. At this time, one side of the pinion 132 is engaged with the plurality of gear teeth is fastened.

The spud device may include a driver 133 for driving the pinion 132. The driving unit 133 is engaged with the pinion 132 to drive the pinion 132.

In this case, the driving unit 133 may include a motor (not shown) and a chain (not shown) fastened to the motor and pinion 132.

On the other hand, the driving unit 133 may rotate the pinion 132 by forward or reverse rotation. At this time, the spud 131 may move up and down by the rotation of the pinion 132.

On the other hand, when the balance holding unit 130 is formed by the hydraulic system, the balance holding unit 130 may include a hydraulic cylinder (not shown). In addition, the balance maintaining unit 130 may include a hydraulic supply unit (not shown) for supplying a fluid to the hydraulic cylinder.

At this time, when the hydraulic supply unit supplies the fluid to the hydraulic cylinder, the hydraulic cylinder can rise. On the other hand, when the hydraulic supply unit recovers the fluid of the hydraulic cylinder, the hydraulic cylinder can be lowered.

In addition, when the balance maintaining unit 130 is formed as the wing tank as described above, the wing tank is partially present on the water surface when the floating quay wall body 110 descends below the water surface. Therefore, the wing tank can achieve stability during operation of the floating quay wall body (110).

At this time, the balance maintaining unit 130 is not limited to the above. The balance maintaining unit 130 may include any device having a variable length in addition to the hydraulic system and the spud device.

Meanwhile, the floating quay wall device 100 may include a control tower 140 for controlling the balance maintaining unit 130. In this case, the control tower 140 may control the balance maintaining unit 130 to maintain the equilibrium of the floating quay wall body portion 110 when the floating quay wall body portion 110 is floating in seawater.

For example, when the balance maintaining unit 130 includes the wing tank, the control tower 140 may control the amount of seawater flowing into the wing tank to maintain the equilibrium of the floating quay wall body 110. have.

In addition, when the balance maintaining unit 130 includes the hydraulic cylinder or the spud device, the control tower 140 of the floating quay wall body part 110 by varying the length of the hydraulic cylinder or the spud device. Equilibrium can be maintained. In this case, since the method of varying the length is similar to that described above, a detailed description thereof will be omitted.

5 is an operating state diagram showing a first operation of the floating quay wall device 100 shown in FIG.

Referring to Figure 5, the floating quay device 100 is seated on the seating portion (D) of the land quay (C). The floating quay wall body 110 is formed at the same height as the top of the land quay wall (C).

At this time, the ballast pump 123 introduces seawater into each ballast tank 121 from the outside. When seawater is stored inside the plurality of ballast tanks 121, the floating quay wall body 110 is submerged. The floating quay wall body 110 is flooded and seated in the seating portion (D).

On the other hand, when the ballast pump 123 operates, the drive unit 133 of the balance maintaining unit 130 is operated. The driver 133 rotates the pinion 132 to lower the spud 131. The spud 131 may be lowered and inserted into a fastening hole (not shown) of the seating part D. At this time, the fastening hole is formed to be drawn in from the upper surface of the seating portion can be inserted and fixed to the spud 131. Therefore, the floating quay wall body portion 110 may be firmly fixed to the seating portion (D).

On the other hand, the floating quay wall body portion 110 may be in a state seated on the seating portion (D) without undergoing the above-described process. That is, the floating quay wall body 110 may be a state in which a spud 131 is fastened to the fastening hole, and seawater flows into the floating quay wall body 110.

Therefore, the user can dry the marine structure (S) and the like at the top of the floating quay wall body (110).

6 is an operating state diagram showing a second operation of the floating quay wall device 100 shown in FIG.

Referring to FIG. 6, when the floating quay device 100 is seated on the seating portion D as described above, the marine structure S is dried.

At this time, since the floating quay wall body portion 110 forms the same height as the land quay wall (C) can dry the marine structure (S) in the same manner as the dry land method.

In addition, while the marine structure (S) is drying, the floating quay wall body portion 110 is firmly fixed to the seating portion (D) by its own weight or by the spud (131). Therefore, the floating quay wall body portion 110 is prevented from rocking by the blue.

7 is an operating state diagram showing a third operation of the floating quay wall device 100 shown in FIG.

Referring to FIG. 7, when the drying of the marine structure S is completed, the spud 131 is raised. In this case, the spud 131 is separated from the fastening hole by leaving the fastening hole.

In addition, even when the spud 131 is separated from the fastening hole, the floating quay wall body part 110 is maintained in the seated part (D). At this time, the ballast pump 123 pumps the seawater of each ballast tank 121 to the outside.

When the sea water is pumped to the outside, the air is filled in the inside of each ballast tank (121). At this time, the floating quay wall body portion 110 by the air buoyancy occurs.

The ballast pump 123 continuously pumps the seawater to the floating quay wall body part 110 so as to be spaced apart from the seating part D by a predetermined distance.

When the above process is completed, the floating quay wall body portion 110 is separated from the seating portion (D) to float. At this time, the floating quay wall body portion 110 is connected to the tugboat (not shown) to guide the floating quay wall device 100 to the sea.

Therefore, the floating quay wall body portion 110 can be easily separated from the seating portion (D). In addition, it is possible to reduce the time required by not having to move the marine structure (S) to a separate barge.

8 is an operating state diagram showing a fourth operation of the floating quay wall device shown in FIG.

Referring to FIG. 8, when a worker tows the floating quay device 100 to the tugboat and reaches a sea of a predetermined depth, the worker lowers each spud 131.

At this time, when each drive unit 133 is operated, each pinion 132 is rotated. Each pinion 132 rotates to lower each spud 131. One end of each spur 131 continues to descend and settles on the sea floor. At this time, the plurality of descending spuds 130 as described above is fixed to the bottom of the sea.

The plurality of spuds 130 are lowered to a predetermined depth to fix the floating quay wall body 110. In addition, the plurality of spuds 130 may ensure the stability of the floating quay wall body 110 so that the floating quay wall body 110 does not flow.

Therefore, even when the blue is formed from the outside floating body wall portion 110 does not move. In addition, it is possible to ensure the safety of the marine structure (S) disposed on the top of the floating quay wall body portion (110).

9 is an operational state diagram showing a fifth operation of the floating quay wall device 100 shown in FIG.

Referring to FIG. 9, the floating quay wall device 100 is fixed as described in FIG. 8 by a plurality of spuds 130.

At this time, the ballast pump 123 operates to introduce seawater back into each ballast tank 121. Seawater is introduced into each ballast tank 121 to discharge the air inside.

When predetermined seawater flows into each ballast tank 121, the floating quay-wall body part 110 submerges again. When the floating quay wall body portion 110 is submerged below a predetermined level, the marine structure (S) at the top is floating.

At this time, the ballast pump 123 continues to operate to immerse the floating quay wall body 110 so that the marine structure (S) is completely separated from the floating quay wall body (110).

On the other hand, when the marine structure (S) is completely separated from the floating quay wall body portion 110, guides the marine structure (S) to the sea through the tugboat.

Accordingly, the marine structure S can be easily separated from the floating quay wall body 110.

FIG. 10 is an operational state diagram showing a sixth operation of the floating quay device 100 shown in FIG. 1.

Referring to FIG. 10, when the above process is completed, the ballast pump 123 is operated again. At this time, when the ballast pump 123 is operated, seawater stored in each ballast tank 121 is discharged to the outside of the floating quay wall body portion 110.

Due to the discharge of sea water, spaces are generated again in the respective ballast tanks 121. Due to the space, the floating quay wall body 110 generates buoyancy. Therefore, the floating quay wall body portion 110 floats above the sea surface by the buoyancy.

On the other hand, while operating the ballast pump 123, each drive unit 133 is operated. Each drive unit 133 rotates each pinion 132. Each pinion 132 raises each spur 131 while rotating.

As each spur 131 rises, each spur 131 separates from the sea floor. At this time, if the ballast pump 123 continues to operate as described above, the floating quay wall body portion 110 is completely floating above the sea level.

On the other hand, when the above process is completed, the worker tows the floating quay wall body portion 110 back to the land quay wall (C) through the tugboat.

When the floating quay wall body 110 is towed to the land quay, the operator operates the spud 131 and the ballast pump 123 as described above with reference to FIG. 5.

Therefore, the floating quay wall device 100 is formed almost similar to the land quay wall (C) can dry the marine structure (S) quickly and easily.

In addition, since the floating quay device 100 is formed almost the same as the land quay wall (C), the manufacturing cost is reduced, and the manufacturing time can be shortened.

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 embodiments, but, on the contrary, 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.

100: floating quay device
110: floating quay wall body
120: ballast part
121: ballast tank
123: ballast pump
124: Seawater Flow Department
130: equilibrium maintaining part

Claims (14)

Floating quay wall body portion floating in the ocean or seated on one side of the land quay,
A ballast part disposed on the floating quay wall body part to selectively inflow or outflow of sea water;
Floating quay wall device comprising a balance holding unit having a spud device formed in the floating quay wall body portion. The method of claim 1,
The ballast portion is floating floating wall device that allows the floating seawall body portion to be introduced into the land quay, the seawater when flowing into the sea, and outflowing seawater. The method of claim 1,
The balance retaining unit further comprises a wing tank (Wing tank) is installed on both sides of the floating quay wall body portion to maintain the balance of the floating quay wall body portion by inflow or outflow from the outside. The method according to claim 1,
The spud device is a variable height of the floating quay wall device for fixing or separating the floating quay wall body portion to the land quay. The method of claim 1,
The spud device,
A driving unit generating a driving force,
Spurd gear is formed on the outer surface,
Floating quay wall device having a pinion to rotate by the drive force, the pinion to move the spud in conjunction with the gear. The method of claim 1,
The spud device is a floating quay device comprising a hydraulic cylinder of variable length. The method according to any one of claims 1 to 6,
And a control tower configured to control the balance maintaining unit to maintain the equilibrium of the floating quay wall body portion when the floating quay wall body portion floats in seawater. A first step of drying the structure on the upper side of any one of the floating quay device of claim 1; And
And outflowing the seawater to the outside of the floating quay wall body portion and floating the floating quay wall body portion to lead to the sea. 2. The method of claim 8,
The method of claim 1, further comprising the step of introducing the seawater into the floating quay wall body portion prior to the first step, by operating the balance maintaining portion to secure the floating quay wall body portion to the land quay. The method of claim 8,
And operating the balance holding unit to lower the floating quay wall body and to mount one end of the balance maintaining unit on the sea floor. The method of claim 8,
And a fourth step of introducing the seawater into the floating quay-walled body portion and lowering it below the sea surface. The method of claim 11,
And a fifth step of lifting the structure to separate the floating quay wall body portion. 13. The method of claim 12,
And a sixth step of discharging the seawater of the floating quay wall body portion to the outside to raise the floating quay wall body portion over the sea surface. The method of claim 13,
And a seventh step of raising the equilibrium maintaining portion.

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