KR20190125791A - External damping device for floating offshore structure - Google Patents

Abstract

The present invention provides an external force damping device for a marine floating facility, which includes: a plurality of wave absorbing pillars arranged to be vertical to a water surface in a state of having buoyancy and spaced apart from each other in a horizontal direction based on the water surface; a pair of support frames installed to be coupled to a lower end and an upper end of the plurality of wave absorbing pillars and supporting the plurality of wave absorbing pillars in a connection state; a mooring rope in which one longitudinal end is connected to the support frame and in which the other longitudinal end is fixed to the seabed so that the wave absorbing pillar floats in a state of being submerged under the water; and a wind collision roof installed on the support frame coupled to the upper end of the wave absorbing pillar so as to protrude to an upper portion of the water surface and reducing a wind load applied to a floating facility while colliding with winds moving in a direction of the floating facility.

Description

External damping device for floating offshore structure

The present invention relates to an external force damping device for an aquatic floating facility that reduces wind loads and fluid forces such as waves to stably float a floating facility floating on the water surface.

In general, offshore installations can be moored while floating at sea, and there are various types of work in the mooring state such as power generation, fossil fuel harvesting, production, stagnation, storage and / or unloading. In particular, marine floating facilities are classified into various types according to functions, structures, mooring methods, for example, semi-submersibe (SEM), tensioned leg platform (TLP), SPAR, floating, production, storage and offloading. ), There are many types of offshore installations called FSRUs or drilling rigs.

On the other hand, interest in offshore floating facilities for power generation, such as wind and solar power, has recently increased significantly for various reasons, such as site cost, limitation of installation size, and difficulty of neighboring residents.

Such a floating facility equipped with a power generation facility is provided with a mooring device to stably float on the water surface to increase power generation efficiency. Here, the mooring device connects the anchor and the floating facility with a rope while fixing the anchor to the floor below the surface of the water, but the mooring device using such a rope is a floating facility due to a change in fluid force or water level such as wind load and waves applied to the floating facility. There is a problem inherent in the risk of failure while the stress is concentrated in the rope end connected to.

Therefore, recently, the sofa facilities are installed on the surface of the sea or on the sea floor to reduce the fluid force such as waves in the floating facility. However, the conventional sofa equipment cannot be reduced with respect to the wind load, and thus there is a limit to maintaining a stable mooring state of the floating facility.

Such a technology related to the sofa device is proposed in the Republic of Korea Patent Publication No. 10-1737278 (2017.05.22).

It is an object of the present invention to provide an external force damping device for aquatic floating facilities, which reduces the fluid force such as waves and also reduces the wind load so that the floating facilities float in a stable mooring state.

The present invention is disposed vertically to the surface of the water while having a buoyancy, and installed to be coupled to the plurality of sofa pillars, a plurality of sofa pillars lower and top spaced apart from each other in the horizontal direction relative to the water, a plurality of sofa pillars A pair of support frames for supporting the connection state, one end in the longitudinal direction is connected to the support frame, the other end in the longitudinal direction is fixed to the seabed, the mooring rope floating in the submerged sofa pillar underwater, sofa protrudes above the water surface It is installed on the support frame coupled to the top of the column, to provide an external force damping device for a water floating facility including a wind impingement roof to reduce the wind load applied to the floating facility while colliding with the wind moving in the direction of the floating facility.

In addition, the wind collision roof may be made of a plate having an arcuate structure.

In addition, a plurality of sofa grooves may be formed on the outer surface of the sofa pillar to be spaced apart from each other.

The external force damping device for floating water facilities according to the present invention is located in the water locked state through a plurality of sofa poles mooring rope disposed perpendicular to the water surface by a support frame while reducing the energy of waves and waves toward the floating facilities. In addition, the wind impingement roof installed on the upper part of the sofa pillar reduces the wind load on the floating facility while causing winds to collide with the floating facility, thereby allowing the floating facility to float in a stable mooring state.

1 is a cross-sectional view showing the installation state of the external force damping device for floating water facilities according to an embodiment of the present invention.
FIG. 2 is an enlarged perspective view of a portion A shown in FIG. 1.
3 is a cross-sectional view showing the installation state of the external force damping device for floating water facilities according to another embodiment of the present invention.
4 is an enlarged perspective view of a portion B shown in FIG. 3.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a configuration cross-sectional view of the installation state of the external force damping device for floating water facilities according to an embodiment of the present invention, Figure 2 is an enlarged perspective view of a portion A shown in FIG. 1 and 2, the external force damping device for an aquatic floating facility according to an embodiment includes a sofa pillar 100, a support frame 200, a mooring rope 300, and a wind collision roof 400. Such an external force damping device for an aquatic floating facility of one embodiment is arranged to be spaced apart from the floating facility 10 disposed through the mooring device to float on the water surface, or the floating facility 10 through a separate connection member (not shown). Can be connected to

The sofa pillar 100 is a rod-shaped member that is made to collide with waves in a state of being locked in the water by the mooring rope 300 to be described later. In other words, the sofa pillar 100 is to reduce the energy of the waves and waves to maintain a stable mooring state of the floating facility (10). Such a sofa pillar 100 is disposed perpendicular to the surface of the water so that the collision area with the waves generated in the floating facility 10 direction is increased, and has a buoyancy force to float in the locked state. Here, the sofa pillar 100 is composed of a plurality of spaced apart from each other in the horizontal direction relative to the water surface to be able to stably reduce the energy of waves and waves generated in the floating facility 10 direction.

In addition, a plurality of sofa grooves 110 may be formed on the outer surface of the sofa pillar 100 so as to be spaced apart from each other so as to increase energy reduction efficiency of waves and waves. That is, the sofa groove 110 increases the contact area that can absorb the energy of the wave and the wave, and also serves to disperse the energy of the wave and the wave when colliding. At this time, the sofa pillar 100 may be formed to be connected to the inside and outside by the sofa groove 110 in a state formed in a tube structure provided with a space therein, then, the energy of waves and blue waves through the sofa groove 110 After being introduced into the sofa pillar 100 and discharged through the sofa groove 110 again, the energy reduction efficiency of waves and blue waves may be increased.

In addition, the outer surface of the sofa pillar 100 may be formed to protrude a sofa projection (not shown) spaced apart from each other. The sofa protrusion causes the energy of waves and blue waves to move through spaced spaces between the sofa pillars 100 to collide with each other.

The support frame 200 is a frame supporting the plurality of sofa posts 100 in a connected state. The support frame 200 maintains a plurality of sofa posts 100 spaced apart from each other in the horizontal direction on the surface of the water so as to stably absorb energy of waves and blue waves. Such, the support frame 200 is configured in a pair to be coupled to the lower and upper ends of the plurality of sofa pillars 100, respectively. Here, each of the support frame 200 is a plurality of horizontal bar member 201 and a plurality of vertical bar member (20) to ensure a stable passage of the fluid in the water while supporting the plurality of sofa pillars 100 connected ( Although 202 is shown as a combined rectangular structure, it is not limited to this, of course, may be formed in a flat structure. In this case, when each support frame 200 is formed in a flat plate structure, a plurality of through holes may be formed to be spaced apart from each other so that a stable passage of the fluid in the water can be achieved.

The mooring rope 300 is a wire member that allows the buoyancy sofa pillar 100 to float in a locked state at a certain position in the water. That is, the mooring rope 300 is connected to support floating in a fixed position in the floating facility 10 without floating down the sofa pillar 100 arranged to float in a locked state in the water. The longitudinal end of the mooring rope 300 is connected to one side of the support frame 200, more specifically, one side of the support frame 200 disposed on the lower side, and the other end of the mooring rope 300 in the longitudinal direction is subsea. Install securely on the Here, the other end in the longitudinal direction of the mooring rope 300 may be provided with a sinker 301 to be fixed to the seabed.

The wind impingement roof 400 may reduce the wind load applied to the floating facility 10 while colliding with the wind moving in the direction of the floating facility 10 to maintain a stable mooring state of the floating facility 10. The wind collision roof 400 is disposed to protrude on the surface of the water so as to collide with the wind moving in the direction of the floating facility 10, more specifically, the upper support frame coupled to the top of the sofa pillar (100) 200) to be fixedly installed. Here, the wind impingement roof 400 is formed in an arcuate structure in which the side plate portion 401 and the rear plate portion 402 are inclined downward with respect to the center portion, so that the wind collides with the side plate portion 401 primarily. In addition to the damping, a secondary damping of the wind moving toward the floating facility 10 is caused by the vortices generated in the upper side of the rear plate portion 402.

And, the wind impingement roof 400 has a wind inlet (not shown) to reduce the wind load moving in the direction of the floating facility 10 while moving a portion of the wind colliding in the direction of the sofa pillar (100) It may be formed to penetrate.

As described above, the external force damping device for floating water facilities according to one embodiment, the plurality of sofa pillars 100 disposed perpendicular to the water surface by the support frame 200 is locked in the water through the mooring rope 300. Position and reduce the energy of the waves and blue waves toward the floating facility 10, the wind impingement roof 400 installed on the top of the sofa pillar 100 is to cause the wind to collide with the floating facility (10) floating facility (10) By reducing the wind load applied to), the floating facility 10 is suspended in a stable mooring state.

3 is a configuration cross-sectional view of the installation state of the external force damping device for floating water facilities according to another embodiment of the present invention, Figure 4 is an enlarged perspective view of the portion B shown in FIG. 3 and 4, the external force damping device for water floating facilities of another embodiment is provided with a sofa tube 100a, a support frame 200a, a mooring rope 300a, and a wind impingement roof 400a. Such an external force damping device for a floating water facility of another embodiment is disposed spaced apart from the floating facility 10a disposed through the mooring device so as to float on the water surface, or the floating facility 10a through a separate connection member (not shown). Can be connected to

The sofa tube (100a) is a tube member that allows the wave to flow in and out in the state that is locked in the water by the mooring rope (300a) to be described later. That is, the sofa tube (100a) is to reduce the energy of waves and waves generated in the direction of the floating facility (10a) to maintain a stable mooring state of the floating facility (10a). Such a sofa tube (100a) is arranged horizontally on the water surface so that the inflow and discharge of the wave is made, and is formed of a material having buoyancy to float in the state locked in the water. Here, the sofa tube (100a) is composed of a plurality of parallel to each other in the horizontal direction relative to the water surface to be able to stably reduce the energy of the waves and waves generated in the floating facility (10a) direction. In addition, the sofa tube 100a may be configured to be stacked in a plurality of layers in the vertical direction based on the water surface. At this time, the sofa tube (100a) is to be disposed in the same direction as the direction of the energy and the wave impacting the wave and blue waves moving in the direction of the floating facility (10a) to the floating facility (10a) to be introduced into the interior. do. That is, the open end of the sofa tube 100a into which the waves and blue energy flows is disposed facing the opposite direction to the floating facility 10a, and the opening of the sofa tube 100a into which the introduced waves and blue energy are discharged. The rear end is disposed so as to face the floating facility 10a.

In addition, the sofa tube (100a) is a plurality of sofa grooves (110a) are formed to be spaced apart from each other so as to increase the reduction efficiency for the energy of waves and waves moving in the direction of the floating facility (10a) after being introduced into the interior. Can be. That is, the sofa groove 110a is formed to connect the inside and the outside of the sofa tube 100a to disperse and discharge the energy of waves and blue waves introduced into the sofa tube 100a back into the water outside the sofa tube 100a. The energy of the waves and the waves moving in the direction of the floating facility 10a is reduced.

In addition, the outer surface of the sofa tube (100a) may be formed to protrude a sofa projection (not shown) spaced apart from each other. The sofa protrusion causes the energy of waves and blue waves to move through the spaced spaces between the sofa tubes 100a to collide with each other.

The support frame 200a is a frame that supports the plurality of sofa tubes 100a in a connected state. The support frame 200a maintains the plurality of sofa tubes 100a connected in the horizontal direction on the surface of the water, thereby stably absorbing energy of waves and blue waves. Such, the support frame 200a is configured in a pair so that the front and rear ends of the plurality of sofa tubes 100a can be coupled to each other in a connected state. Here, each of the support frame 200a is a plurality of horizontal bar member 201a and a plurality of vertical bar members (20a) to ensure a stable passage of the fluid in the water while supporting the plurality of sofa tubes (100a) connected ( Although 202a is illustrated as a combined rectangular structure, it is a matter of course that the 202a may be formed in a flat plate structure. In this case, when each support frame 200a is formed in a flat plate structure, a plurality of through holes may be formed to be spaced apart from each other so that the fluid may be introduced into the tip of the sofa tube 100a after the fluid is passed through the water.

The mooring rope (300a) is a wire member that allows the buoyancy sofa (100a) to be floating in the locked state in a certain position in the water. That is, the mooring rope 300a is connected and supported to float at a predetermined position adjacent to the floating facility 10a without floating down the sofa tube 100a arranged to float in the submerged state. The longitudinal end of the mooring rope 300 is connected to one side of the support frame 200a, more specifically, the lower end side of the support frame 200a, and the other end of the mooring rope 300a in the longitudinal direction is fixed to the seabed. Install. Here, the other end in the longitudinal direction of the mooring rope (300a) may be provided with a sinker (301a) coupled to be fixed to the seabed.

The wind impingement roof 400a reduces the wind load applied to the floating facility 10a while colliding with the wind moving in the direction of the floating facility 10a, thereby maintaining a stable mooring state of the floating facility 10a. The wind impingement roof 400a is disposed to protrude on the surface of the water so as to collide with the wind moving in the direction of the floating facility 10a. More specifically, the wind impinging roof 400a is coupled to the front and rear ends of the sofa tube 100a, respectively. Install to be fixed to the top of the (200a). Here, the wind impingement roof 400a is formed in an arcuate structure in which the side plate portion 401a and the rear plate portion 402a are inclined downward with respect to the center portion, so that the wind collides with the side plate portion 401a and primarily. In addition to the damping, a secondary damping of the wind moving toward the floating facility 10a is caused by the vortex generated in the upper side of the rear plate portion 402a.

And, the wind collision roof (400a) is a wind inlet (not shown) to reduce the wind load moving in the direction of the floating facility (10a) while moving a portion of the wind colliding in the direction of the sofa tube (100a) It may be formed to penetrate.

As described above, in the external force damping device for water floating facilities according to another embodiment, the sofa tube 100a having a plurality of open ends disposed horizontally on the water surface by the support frame 200a is underwater through the mooring rope 300a. Located in the locked state to reduce the energy of the waves and waves toward the floating facility (10a), the wind impingement roof 400a installed on the upper portion of the sofa tube (100a) while the wind toward the floating facility (10a) collide By reducing the wind load on the floating facility 10a, the floating facility 10a is suspended in a stable mooring state.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

10,10a: floating facility 100: sofa pillar
100a: sofa tube 200,200a: support frame
300,300a: mooring load 400,400a: wind collision roof

Claims (6)

A sofa pole disposed vertically to the surface of the water while having buoyancy and provided with a plurality of spaced apart from each other in a horizontal direction based on the surface of the water;
A pair of support frames installed to be coupled to the lower and upper ends of the plurality of sofa columns to support the plurality of sofa columns in a connected state;
A mooring rope connected to the support frame in one longitudinal direction and the other end in the longitudinal direction to be suspended in the submerged sofa pillar while being fixed to the sea floor; And
Installed on the support frame coupled to the top of the sofa pillar to protrude to the upper surface of the water, the wind impact roof to reduce the wind load applied to the floating facility while colliding with the wind moving in the direction of the floating facility; Damping device. The method according to claim 1,
The wind impingement roof is an external force damping device for water floating facilities made of a plate having an arched structure. The method according to claim 1,
External force damping device for a water floating facility formed with a plurality of sofa grooves spaced apart from each other on the outer surface of the sofa pillar. A sofa tube having a plurality of horizontally arranged on the water surface in a state of having buoyancy and having a structure in which both ends in the longitudinal direction are opened so that the fluid is introduced and discharged;
A pair of support frames installed to be coupled to the front and rear ends of the plurality of sofa tubes to support the plurality of sofa tubes in a connected state;
A mooring rope connected to the support frame in one longitudinal direction and the other end in the longitudinal direction to be suspended in the submerged sofa while being fixed to the sea floor; And
An external force damping device for aquatic floating facilities comprising a; wind installation roof coupled to the top of the support frame to protrude above the water surface, to reduce the wind load applied to the floating facilities while colliding with the wind. The method according to claim 4,
The sofa tube is an external force damping device for a water floating facility formed so that the inner diameter becomes smaller toward the other end in the longitudinal direction where the fluid is discharged from the longitudinal end where the fluid is introduced. The method according to claim 4,
The wind impingement roof is an external force damping device for water floating facilities made of a plate having an arched structure.

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