KR101567889B1 - A Marine Structure - Google Patents

Abstract

Disclosed is a marine structure wherein a moon pool is formed in a hull. The marine structure comprises: a recess formed on a top of the moon pool; and an energy dispersion part installed to generate energy transferred in a direction reverse to the flowing direction of sea waves inside the moon pool. As such, the present invention prevents sea waves having a high height from being generated in the recess by reducing the flow of seawater inside the moon pool.

Description

{Marine Structure}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an offshore structure, and more particularly, to an offshore structure configured to disperse the offshore energy of a seawater flow occurring in a recess.

Along with the development of submarine mining technology, drilling lines have been developed with drilling facilities suitable for marginal field or deep sea oil development. Conventional submarine drilling has been mainly used for a rig ship or a rigid platform for underwater drilling that can be sailed only by another tugboat and performs submarine drilling with anchorage at one point of the sea using a mooring device. In recent years, a drill ship, which is equipped with advanced drilling equipment and manufactured in the same form as a ship, has been developed and used for deep sea drilling.

In such an offshore structure for underwater drilling, a moon pool is formed for accessing various equipment for drilling. The moon pool is a rectangular parallelepiped or cylindrical space formed so as to penetrate vertically between the deck and the bottom of the hull. to be. In addition, an offshore structure for drilling and other drilling forms an auxiliary space in the interior of the drum to temporarily lower the drilling equipment, which is called a recess.

However, in the conventional drill ship, there is a problem that the crew working on the drilling equipment or the hull installed on the top of the drum can be damaged by the seawater flow generated in the recess.

Hereinafter, referring to FIG. 1, a principle of generating a large sea water flow in the recess will be described.

1 is a cross-sectional view partially showing a drillhose in which a recess in a conventional door is formed.

Sea waves generated by the wind are always present outside the hull 1 and seawater in the interior of the hatchery 2 receives the energy from the sea waves outside the hull 1 to generate the wave 5a.

Sea waves can be classified into deep-sea waves and deep-sea waves depending on the relationship between depth and wavelength. Sea waves in the case where the water depth is deeper than one-half of the wavelength is called deep water waves and the sea depth is shallower than one- Is called a deep sea wave.

The deep-sea waves are also called longwaves, and water particles are subjected to elliptical motion by the frictional force of the seabed since they are affected by the seabed. The propagation velocity of the shallow wave is irrelevant to the wavelength and is related only to the depth of water. Therefore, the progressive velocity of the shallow wave slows down as the depth of water becomes shallower. As the propagation speed of the deep sea wave slows down, the kinetic energy that is reduced changes to the potential energy, so that as the coastal wave approaches the coast, the wavelength becomes shorter and the wave height becomes higher.

For example, in the case of a tsunami that has a characteristic of shallow waves, if a tsunami occurs with an extremely long wavelength of 100 to 200 kilometers in the distant sea due to an earthquake, However, as the tsunami approaches the shore, the depth of the tsunami becomes shallower, slowing down the process, reducing the wavelength to several kilometers, and increasing the tsunami to tens of meters.

When the wave 5a generated in the interior space 2 has a characteristic of a deep sea wave, the depth of water in the recess 3 becomes shallow, so that the sea wave 5b in the recess 3, . The wave 5b in the recess 3 having a high crest causes a large seawater flow and the wave 5b in the recess 3 rides on the inside wall surface 2a of the interior space of the recess 3, (4) damage to crew members who are working on the hull (1).

Hereinafter, the interior wall surface 2a of the interior wall means one internal wall surface of the interior wall of the interior of the door which is connected to the recess 3. [

As a technique for reducing seawater flow inside a conventionally recessed construction, there is a floating structure of Korean Patent Laid-Open No. 10-2011-0027404. The hull includes a hull having a door pool for drilling, a recess formed at a lower end of a stern side of the door pool, and a damping plate installed at a side of the stern of the door pool.

However, such a conventional floating structure does not cancel the seawater flow itself in the door, but only a structure for passively reducing the seawater flow is proposed, which limits the danger to the crew and damage to the drilling equipment there was.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a marine structure which is constructed so as not to generate a sea wave having a high wave height in a recess by canceling seawater flow itself in a door frame.

According to an aspect of the present invention, there is provided an offshore structure having a doorpost formed on a hull, comprising: a recess formed on the doorpost; And an energy dispersing unit installed to generate energy that is transmitted in a direction opposite to the propagation direction of the sea waves in the interior of the culture pit.

Wherein the energy distribution unit comprises: a flap connected to the inner side wall surface of the recess on the recess by a hinge; And a flap driving unit for providing a driving force to the flap, wherein the flap is repeatedly folded and unfolded to generate a seawater flow in the door pool.

The flap may be connected to the recess bottom by a hinge.

The flap driving part may include a hydraulic cylinder.

The energy dispersing unit may further include an elastic member that provides an elastic force to the flap.

The interior wall surface of the door can include a recessed groove into which the flap driving portion or the elastic member can be received.

The flap driving part and the elastic member may be installed in a plurality of along the width of the recess.

Wherein the energy dispersing unit comprises: a wedge-shaped member provided so as to be in contact with the inside wall surface of the tabletop and including a side surface in the shape of a right angle triangle whose hypotenuse is downward; And a wedge-shaped member driving unit for providing a driving force to the wedge-shaped member, wherein the wedge-shaped member repeats the reciprocating motion to generate a seawater flow in the doorway.

The energy dispersing unit may further include a fixing unit for fixing the wedge-shaped member driving unit to the inside wall surface of the door.

The energy dispersing unit may further include a sliding portion formed to allow the wedge-shaped member to slide so as to reciprocate up and down.

Wherein the sliding portion includes: a sliding groove formed in the interior of the door frame; And a sliding protrusion of the wedge-shaped member, the sliding protrusion being slidably coupled to the sliding groove upwardly and downwardly.

The sliding portion may be formed along the width of the recess.

The wedge-shaped member driving unit may include a hydraulic cylinder.

The energy dispersing unit may further include an elastic member for providing an elastic force to the wedge-shaped member.

The wedge-shaped member driving unit and the elastic member may be installed along the width of the recess.

Wherein the energy dispersing unit comprises: a water jet nozzle for spraying seawater in a direction opposite to a propagation direction of the sea waves in the interior of the door frame; A water jet line for supplying seawater to the water jet nozzle; A water jet pump for applying pressure to seawater supplied to the water jet line; And a seawater inflow line for supplying inflowed seawater to the water jet pump; . ≪ / RTI >

The water jet nozzle may be installed to jet the water jet obliquely toward both side edges of the hull.

The seawater inlet line may further include a plurality of inlets connected to the recess bottom.

According to another aspect of the present invention, there is provided an offshore structure having a doorpost formed on a hull, and an energy dispersing unit installed to generate energy transmitted in a direction opposite to the propagation direction of the sea wave inside the doorpipe. An offshore structure is provided.

The energy dispersing unit may comprise a sowing machine for generating a seawater flow in the door frame.

The energy dispersing unit may include a water jet nozzle for spraying seawater in a direction opposite to the direction of propagation of the sea waves in the interior of the door.

According to the marine structure of the present invention, the flow of seawater transmitted in a direction opposite to the propagation direction of the sea wave can be generated to offset the energy itself of the sea wave. Therefore, even if the sea wave in the interior of the drum has a characteristic of a deep sea wave, the sea wave having a large wave height is not generated, and a large sea water flow in the recess causes the drilling equipment It has the effect of preventing the damage and the risk to the crew.

1 is a cross-sectional view partially showing a drillhose in which a recess in a conventional door is formed.
2 is a cross-sectional view of an offshore structure according to a first preferred embodiment of the present invention.
3 is a plan view of Fig.
4 is a cross-sectional view of an offshore structure according to a second preferred embodiment of the present invention.
5 is a plan view of Fig.
6 is a cross-sectional view of an offshore structure according to a third preferred embodiment of the present invention.
Fig. 7 is a plan view of Fig. 6. Fig.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The offshore structures of the following embodiments may be all vessels for subsea drilling in which recesses are formed in a portal, such as a league line, a drill ship, and the like. In addition, the following examples can be modified in various forms, and the scope of the present invention is not limited to the following examples.

FIG. 2 is a cross-sectional view of an offshore structure according to a first preferred embodiment of the present invention, and FIG. 3 is a plan view of FIG.

2 and 3, the offshore structure of the present embodiment includes a door frame 2, a recess 3, and an energy dispersing unit 10.

The door frame 2 is formed to penetrate the hull 1 in the vertical direction so as to be able to enter and exit various drilling rigs 4 for drilling operations in the seabed, and may have a rectangular parallelepiped shape or a cylindrical shape.

The recess 3 is formed in the interior of the door 2 to provide a place where the drilling rig 4 can be temporarily lowered. In general, the recess 3 is located below the aft- The position in which the recess 3 of the invention is formed is not limited to being below the aft-side sea level.

2, the energy dispersing unit 10 of the present embodiment is constituted of a sowing machine including flaps 11 and flap driving units 12, It is possible to generate a seawater flow which is transmitted in the opposite direction.

The lower end portion of the flap 11 is connected to the inside wall surface 2a of the inside cover by the hinge portion 15a. The flap 11 is folded so that all the faces of the flap 11 are in contact with the inside wall face 2a of the inside wall face 2a with the hinge portion 15a as an axis and the upper portion of the flap 11 faces the inside wall face 2a Can be repeated. The flap 11 can cancel out the sea wave energy inside the interior space 2 by repeating the folding and spreading motion to generate the sea water flow. The lower end portion of the flap 11 may be connected to the recess bottom portion 3a by a hinge portion 15a.

The upper end portion of the flap 11 is connected to the hinge portion 15b at one end of the flap driving portion 12 so that the flap 11 is repeatedly folded and stretched by the driving force supplied from the flap driving portion 12 can do.

One end portion of the flap driving portion 12 is connected to the upper end portion of the flap 11 by the hinge portion 15b and the other end portion of the flap driving portion 12 is connected to the inside side wall surface 2a of the door by the hinge portion 15c . The flap driving unit 12 includes driving means such as a hydraulic cylinder, a hydraulic motor, and a driving motor. The driving force of the driving means is transmitted to the flap 11 so that the flap 11 can be repeatedly folded and unfolded . When the driving means of the flap driving portion 12 is a hydraulic cylinder, the driving means may be constituted by a double acting cylinder and may be constituted by a plurality of single acting cylinders having different directions of applied force.

The energy dispersing unit 10 of the present embodiment may include an elastic member 13 connected between the flap 11 and the inside wall surface 2a of the interior of the interior. The elastic member 13 may be constituted by a coil spring or the like and may reduce the load of the driving means of the flap driving unit 12 during the movement of the flap 11 by providing elastic force to the flap 11, .

The concave groove 14 may be formed on the inside wall surface 2a of the door leaf of the embodiment so as to accommodate the flap driving part 12 and the elastic member 13, respectively.

3, the flap 11 of this embodiment may have a length approximately equal to the width (longitudinal direction) of the recess 3, and the flap driving portion 12 and the elastic member 13 may have a length As shown in FIG.

FIG. 4 is a cross-sectional view of an offshore structure according to a second preferred embodiment of the present invention, and FIG. 5 is a plan view of FIG.

4 and 5, the offshore structure of the present embodiment includes the platform 2, the recess 3, and the energy dispersing unit 20, as in the case of the offshore structure of the first embodiment. The energy dispersing unit 20 of the present embodiment is similar to the energy dispersing unit 10 of the first embodiment in that the energy dispersing unit 20 of the present embodiment is capable of generating seawater flowing in a direction opposite to the traveling direction of the wave 5a And destruction.

4, the sowing machine of the energy dispersing unit 20 of this embodiment is different from the sowing machine of the energy dispersing unit 10 of the first embodiment in that the wedge-shaped member 21, the wedge-shaped member driving unit 22 And a fixing portion 25. As shown in Fig.

The wedge-shaped member 21 is provided so as to be in contact with the inside wall surface 2a of the tabletop. The side surface of the wedge-shaped member 21 is in the shape of a right triangle with a hypotenuse facing downward. The wedge-shaped member 21 is connected to the sliding portion, and the sliding portion is composed of the sliding protrusion 23 and the sliding groove 24.

The sliding protrusion 23 is a protruding portion of the wedge-shaped member 21, and is slidably coupled to the sliding groove 24 in an up-and-down direction. The sliding grooves 24 may be formed in the interior of the door frame 2, and the sliding protrusions 23 may be coupled to slide up and down.

The wedge-shaped member 21 repeats upward and downward reciprocating motion along the sliding portion to generate a seawater flow, thereby canceling the sea wave energy in the interior of the interior space 2. [

The upper end of the wedge-shaped member driving unit 22 is connected to the fixing unit 25 and the lower end of the wedge-shaped member driving unit 22 is connected to the wedge-shaped member 21. The wedge-shaped member driving unit 22 includes driving means such as a hydraulic cylinder, a hydraulic motor, and a driving motor. The driving force of the driving means is transmitted to the wedge-shaped member 21, .

The fixing portion 25 is provided on the inside wall surface 2a of the tabletop for fixing the wedge-shaped member driving portion 22 and the lower end portion of the fixing portion 25 is connected to the upper end portion of the wedge-

The energy dispersing unit 20 of the present embodiment may be provided with an elastic member 13 between the wedge-shaped member driving unit 22 and the wedge-shaped member 21. [ The elastic member 13 may be constituted by a coil spring or the like and is provided with elastic force to the wedge-shaped member 21 so that the wedge- Reduce the load.

5, the wedge-shaped member 21 of this embodiment can have a length substantially equal to the width (longitudinal direction) of the recess 3, and the wedge-shaped member driving portion 22, the elastic member 13, The sliding portion may be provided in a plurality of along the width of the recess 3. [

FIG. 6 is a cross-sectional view of an offshore structure according to a third preferred embodiment of the present invention, and FIG. 7 is a plan view of FIG.

6 and 7, the offshore structure of the present embodiment includes a platform 2, a recess 3, and an energy dispersing unit 30, as in the case of the offshore structures of the first and second embodiments.

6, the energy dispersing unit 30 of the present embodiment differs from the energy dispersing units 10 and 20 of the first and second embodiments in that the waves 5a in the interior of the interior 2 are progressed A water jet line 31, a water jet line 32, a water jet pump 33, and a seawater inflow line 34. The water jet nozzle 31,

The water jet nozzle 31 is installed on the surface of the inside wall surface 2a of the inside of the inside of the image forming apparatus and is connected to the water jet line 32. The water jet nozzle 31 receives the seawater from the water jet line 32 and injects seawater in a direction opposite to the traveling direction of the sea wave 5a inside the sea water pool 2 to cancel the sea water flow itself in the sea water pool 2.

One end of the water jet line 32 is connected to the water jet nozzle 31 and the other end of the water jet line 32 is connected to the water jet pump 33. The seawater supplied to the water jet nozzle 31 through the water jet pump 33 is supplied to the water jet nozzle 31 along the water jet line 32.

The water jet pump 33 is connected between the water jet line 32 and the seawater inflow line 34. The seawater introduced into the seawater inflow line 34 is moved to the water jet pump 33 and is pressurized by the water jet pump 33. The seawater pressurized by the water jet pump 33 is supplied to the water jet nozzle 31 through the water jet line 32 and is injected at a high pressure from the water jet nozzle 31.

The seawater inflow line 34 is formed below the recess bottom surface 3a. One end of the seawater inflow line 34 is connected to the recess bottom portion 3a and the other end of the seawater inflow line 34 is connected to the water jet pump 33. The seawater inlet line 34 may include a plurality of inlets 35 connected to the recess bottom surface 3a.

The seawater in the door frame 2 flows into the seawater inflow line 34 through the seawater inflow line 34 and the inflow port 35 connected to the recess bottom portion 3a and flows into the seawater inflow line 34 The seawater is supplied to the water jet pump 33.

7, the energy dispersing unit 30 of the present embodiment can be installed in a plurality of along the width of the recess 3, and the water jet nozzle 31 of the present embodiment is arranged in the water jet nozzle 31 The water jets 36 are slanted obliquely toward both side edges of the hull 1, that is, toward the port and starboard directions of the hull 1, so as to prevent the drilling rig 4 from being damaged by the jetted water jet 36. [ As shown in FIG.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention. It is.

1: Hull 2:
2a: Inner wall face of the interior wall 3:
3a: recess bottom 4: drilling rig
5a, 5b: wave 10, 20, 30: energy dispersing unit
11: flap 12: flap driving part
13: elastic member 14: concave groove
15a, 15b, 15c: a hinge portion 21: a wedge-
22: wedge-shaped member driving part 23: sliding protrusion
24: sliding groove 25:
31: water jet nozzle 32: water jet line
33: Water jet pump 34: Seawater inflow line
35: inlet 36: water jet

Claims (20)

As an offshore structure in which a door grass is formed on the hull,
A recess formed on the upper surface of the door frame; And
And an energy dispersing unit installed to generate energy to be transmitted in a direction opposite to a propagation direction of the sea waves in the interior of the door,
The energy dispersing unit includes:
A flap connected to the inside wall surface of the interior of the recess by a hinge portion; And
And a flap driving part for providing a driving force to the flap,
Wherein the flap is repeatedly folded and unfolded to create a seawater flow in the door frame and is connected by a hinge to the recess bottom. delete delete The method according to claim 1,
Wherein the flap driver comprises a hydraulic cylinder. The method according to claim 1 or 4,
Wherein the energy dispersing unit further comprises an elastic member provided between the flap and the inner side wall of the door so as to connect the flap to the inner side wall of the door,
Wherein the elastic member provides an elastic force to the flap while the flap is being folded and unfolded. The method of claim 5,
Wherein the interior wall surface of the door includes a recessed groove into which the flap driving portion or the elastic member can be received. The method of claim 5,
Wherein the flap driving portion and the elastic member are installed in a plurality of along the width of the recess. As an offshore structure in which a door grass is formed on the hull,
A recess formed on the upper surface of the door frame; And
And an energy dispersing unit installed to generate energy to be transmitted in a direction opposite to a propagation direction of the sea waves in the interior of the door,
The energy dispersing unit includes:
A wedge-shaped member installed to be in contact with the inner side wall surface of the tabletop, the wedge-shaped member including a side surface in the shape of a right angle triangle whose hypotenuse faces downward; And
And a wedge-shaped member driving unit for providing a driving force to the wedge-shaped member,
Wherein said wedge-shaped member repeatedly reciprocates up and down to generate a seawater flow in said door frame. The method of claim 8,
Wherein the energy dispersing unit further comprises a fixing part for fixing the wedge-shaped member driving part to the inside wall surface of the door. The method of claim 8,
Wherein the energy dispersing unit further comprises a sliding part formed to allow the wedge-shaped member to slide so as to reciprocate up and down,
The sliding portion includes:
A sliding groove formed in the interior of the door frame; And
A protrusion of the wedge-shaped member, the sliding protrusion being slidably coupled to the sliding groove;
. ≪ / RTI > The method of claim 10,
Wherein the sliding portion is formed in a plurality of along the width of the recess. The method of claim 8,
Wherein the wedge-shaped member drive comprises a hydraulic cylinder. The method according to any one of claims 8 to 12,
Wherein the energy dispersing unit further comprises an elastic member provided between the wedge-shaped member driving unit and the wedge-shaped member and connecting the wedge-shaped member driving unit and the wedge-shaped member,
Wherein the elastic member provides an elastic force to the wedge-shaped member while the wedge-shaped member is reciprocating up and down. 14. The method of claim 13,
Wherein the wedge-shaped member driving portion and the elastic member are installed in a plurality of along the width of the recess. delete delete delete delete delete delete

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