KR20160021566A - Floating structure - Google Patents

Abstract

A floating structure is disclosed. The floating structure according to an embodiment of the present invention comprises: a main body; and a cutoff member which has one side connected to the main body to be rotated, is selectively located on either the top or the bottom of a horizontal extension surface on the top surface of the main body by the rotation in the outer area of the main body, and cuts off green water flowing into the main body.

Description

{FLOATING STRUCTURE}

The following description relates to a floating structure.

A jack-up rig is a type of offshore plant that is used to drill crude oil and gas from the seabed. 1 is a view schematically showing a general jack-up league 10. Fig. As shown, the jack up league 10 may include a main body 1, legs 2, a docking station 3, a derrick 4, a cantilever 5, and the like. The jack up league 10 can be operated in a transit mode and a jackup mode. Specifically, the jack up league 10 moves to the drilling position in the voyage mode, then switches to the jack-up mode to lower the leg 2 down to the seabed, and then lifts the main body 1 along the leg 2. The jack-up rig 10 performs a drilling operation in a state where the main body 1 is spaced from the sea surface. When the drilling operation is completed, the jack-up rig 10 proceeds in the reverse order to the next drilling position. On the other hand, the jack-up league 10 can improve the efficiency of the work by the cantilever 5. The cantilever 5 provided with the derrick 4 can be moved to the outside of the jack up league 10 so that the well center can be adjusted without changing the entire position of the jack up league 10.

On the other hand, floating structures such as jack-up leagues and ships can be affected by green water when operating in the sea (when jack-up leagues are towed). Blue water refers to seawater when waves such as waves flood on the deck and sweep over the deck. Cheongpa can float on the deck at least 5m from the deck, and when the blue waves are introduced, various equipment or structures installed on the deck and deck due to the potential energy and kinetic energy of the blue waves may be damaged. In addition, blue waves can reduce the resilience of floating structures and in this case floating structures can be exposed to the risk of overturning.

In order to reduce the influence of such waves, a fixed blocking member may be provided at the edge of the deck. The stationary shut-off member is a kind of plate member, and the lower end thereof is welded on the deck to block the blue wave to prevent the introduction of the blue wave into the deck.

However, in the case of the above-described stationary blocking member, it may adversely affect the arrangement of various equipment or structures on the deck. In particular, the jack-up league includes various equipment or structures for drilling (derrick, cantilever, etc.) as compared with a general ship, so that the reduction in space utilization by the fixed shut-off member may not be a minor problem.

Also, in the jack-up rig, the cantilever must move to the outside of the body during the drilling operation, and the stationary shut-off member may interfere with the movable structure such as the cantilever. Therefore, the application of the fixed blocking member in the jack up league may be limited.

Japanese Patent Application Laid-Open No. 10-2013-0117486

The embodiment described herein is intended to provide a floating structure that is capable of blocking the introduction of a sound wave.

The floating structure according to an embodiment includes a main body and one side rotatably connected to the main body and selectively located above or below a horizontally extending surface of the upper surface of the main body by pivoting in an outer region of the main body And a blocking member for blocking a sound wave flowing into the main body.

The blocking member may be inclined upward toward the outside of the main body when the blocking member is rotated to the maximum at the main body side from the top of the extending surface.

The blocking member may be a plate-shaped member having a plurality of through holes.

The guide rail may include a guide rail and one end rotatably connected to the main body, and the other end of the guide rail may be moved along the guide rail and expanded and contracted.

A sliding unit provided at the other end of the cylinder and sliding along the guide rail, a protruding unit optionally built in the sliding unit or protruding out of the sliding unit, a controller for controlling the operation of the protruding unit, The guide rail may further include a guide wall formed on at least one side of the guide rail and extending along the extending direction of the guide rail and having a latch hole through which the protrusion unit is inserted when the protrusion unit is protruded.

In addition, when the blocking member is positioned above the extended surface, the blocking member may further include a support for providing a supporting force in the outward direction of the main body.

In addition, a wire connected to the blocking member and a winch for winding the wire and providing a tension to the wire in the inward direction of the main body by rotation may be further included.

The guide rail is formed along the longitudinal direction of the blocking member. The guide rail has a first end rotatably connected to the main body and a second end selectively moved along the guide rail or away from the guide rail. And a winch that winds the wire and provides tension to the wire in the inward direction of the body by rotation, the blocking member being movable from the bottom of the extended surface to the top of the extended surface by the cylinder The wire may be connected to the blocking member and the other end of the cylinder may be detached from the guide rail when the blocking member reaches the preset point.

The floating structure may be a jack-up structure, and the blocking member may be positioned above the extended surface when the jack-up rig is in the navigation mode, and may be located below the extended surface when the jack- .

According to the embodiment described here, it is possible to provide a floating structure that can block the inflow of blue waves.

1 schematically shows a typical jack up league;
2 is a schematic illustration of a floating structure in accordance with one embodiment;
3 is a view for explaining an operation of a blocking member;
4 is a view showing one side of the blocking member;
5 is a view showing a state in which the blocking member is rotated upward;

Hereinafter, specific embodiments for implementing the present invention will be described in detail with reference to the accompanying drawings. In the following description, well-known functions or constructions are not described in detail since they would obscure the subject matter of the present invention.

FIG. 2 is a schematic illustration of a floating structure 100 according to one embodiment. Since the floating structure 100 may have a variety of types, the edge portion of the floating structure 100 on which the blocking member 120 is installed is mainly shown.

The floating structure 100 may include a body 110. Various kinds of equipment and structures may be disposed on the main body 110. When the floating structure 100 is a jack-up rig, a relatively large number of equipment and structures can be disposed on the main body 110.

As described above, the green water flows into the upper surface of the main body 110 and sweeps the upper surface of the main body 110, thereby damaging not only the upper surface of the main body 110, but also various kinds of equipment and structures.

The floating structure 100 according to the present embodiment may include a blocking member 120 for blocking the inflow of the above-described blue wave. The blocking member 120 may be a plate-like member as shown in FIG. 2 and may be rotatably connected to the main body 110. For example, a bracket 111 may be provided on a side surface of the main body 110, and a blocking member 120 may be hinged to the bracket 111. The blocking member 120 may optionally be positioned on the horizontally extending surface of the upper surface of the body 110, above or below the extended surface, by pivoting in the outer region of the body 110 about the hinge- .

Since the blocking member 120 is rotatably connected to the main body 110 as described above, the blocking member 120 can be rotated only when the blocking of the RF wave is required and protrude to the outer region of the main body 110. [ The shielding member 120 is positioned at a point adjacent to the side surface of the main body 110 or adjacent to the side surface of the main body 110 so that the structural stability of the entire floating structure 100 Can be improved.

Further, depending on the turning operation of the blocking member 120, there may be no influence on the arrangement of various kinds of equipment and structures on the main body 110. In particular, when the floating structure 100 is a jack-up rig, a drilling facility including a derrick and the like is additionally provided, so that a space for arranging these equipment and structures can be ensured.

In addition, the blocking member 120 can be prevented from interfering with the movable structure moving in and out of the main body 110 by the rotating operation of the blocking member 120. In the case where the floating structure 100 is a jack-up rig, for example, the cantilever may protrude outside the main body 110 in order to improve the efficiency of the drilling operation. In this case, And may be located on the extended surface or the lower surface of the extended surface so as not to interfere with the movement of the cantilever. In this regard, when the floating structure 100 is a jack-up rig, the blocking member 120 is positioned below the extended surface or the extended surface when in the jack-up mode, and the interference with the movable structure, such as a cantilever, And can be located above the extended surface when the navigation mode is in effect to effectively block the blue waves.

In addition, the bracket 111 may be installed on the side of the main body 110, not on the upper side of the main body 110. Specifically, the bracket 111 may protrude from the side surface of the main body 110 to the outer region of the main body 110, and may not include the portion located above the extending surface. That is, since the bracket 111 is located at the lower side of the extended surface or the extended surface, the movable structure such as the cantilever does not affect the arrangement relationship of various kinds of equipment and structures on the main body 110, The movement of the mobile configuration may not be disturbed.

On the other hand, the angle of the blocking member 120 may be adjustable. The blocking member 120 may be positioned on the horizontally extending surface of the upper surface of the main body 110 or the lower surface of the extended surface when the blue wave flows into the upper surface of the main body 110 from a position adjacent to the main body 110. When a blue wave flows into the upper surface of the main body 110 from a position distant from the main body 110, the blocking member 120 may be positioned above the extended surface.

2, the blocking member 120 may be inclined upwards toward the outer side of the main body 110 when the blocking member 120 is rotated to the maximum in the main body 110 side. In this way, the sound wave can be prevented from flowing into the upper surface of the main body 110 across the blocking member 120. However, the rotation angle of the blocking member 120 is not limited thereto. For example, the blocking member 120 may be rotated to be perpendicular to the upper surface of the main body 110.

In addition, a plurality of through holes 121 may be formed in the blocking member 120. There is a risk that the blocking member 120 may be damaged if the blue wave hits the blocking member 120 strongly. Therefore, by forming the through-hole 121 in the blocking member 120 as in this embodiment, the pressure applied to the blocking member 120 by the sound wave can be reduced, thereby preventing the blocking member 120 from being damaged can do. The size and the number of the through holes 121 may be determined by considering the type, position, size, strength, etc. of various kinds of equipment and structures installed on the main body 110, Can be determined from this undamaged line.

Fig. 3 is a view for explaining the operation of the blocking member 120. Fig. In this embodiment, the rotation of the blocking member 120 is exemplified as being implemented by the cylinder 130. [

The cylinder 130 can be expanded and contracted in length, and the blocking member 120 can be supported and rotated through the extension and contraction of such a length. Specifically, one end of the cylinder 130 may be rotatably connected to the main body 110, and the other end may be connected to the blocking member 120. One end of the cylinder 130 is hinged to the side of the main body 110 and the other end of the cylinder 130 is moved along a guide rail (not shown) provided on the closing member 120 Explain.

First, referring to (a), the other end of the cylinder 130 may be located on the end side of the blocking member 120, and the cylinder 130 may maintain the initial length. This allows the blocking member 120 to remain substantially parallel to the side surface of the body 110. In the case where the blocking of the blue wave is not required, the blocking member may be in a state as shown in (a).

Next, referring to (b), the length of the cylinder 130 is extended, one end of the cylinder 130 rotates counterclockwise from the side of the main body 110, and the other end of the cylinder 130 is blocked The blocking member 120 can be rotated counterclockwise at the lower portion of the horizontally extending surface of the upper surface of the main body 110 by moving from the end of the member 120 toward the center side.

Finally, referring to (c), the length of the cylinder 130 is further elongated, and one end of the cylinder further rotates counterclockwise on the side of the main body 110, The blocking member 120 can be rotated in the counterclockwise direction at the upper portion of the extended surface by moving from the central portion side to the end portion side.

Also, as described above, the blocking member 120 may be inclined upward toward the outer side of the main body 110 when the main body 110 is rotated to its maximum (see (c)). When the blocking member 120 is inclined upwards toward the outer side of the main body 110 in consideration of the normal inflow angle of the sound wave, it is possible to effectively block the sound wave while reducing the impact applied to the blocking member 120, It is possible to reduce the amount of the blue wave that rides on the display 120.

4 is a view showing one surface of the blocking member 120, and a bottom surface of the blocking member 120 when the reference is made to FIG. 3 (b).

As shown in the figure, the blocking member 120 may be provided with a guide rail 122 formed along the longitudinal direction of the blocking member 120. Here, the longitudinal direction of the blocking member 120 may mean the length from one side of the blocking member 120 connected to the main body 110 to the other side of the blocking member 120 which is a free end. The sliding unit 131 may be provided at the other end of the cylinder 130 on the side of the blocking member 120. In this embodiment, the sliding unit 131 is a cloud ball which can be drawn along the guide rail 122. [ The sliding unit 131 provided at the other end of the cylinder 130 slides along the guide rail 122 and the other end of the cylinder 130 moves in the longitudinal direction of the closing member 120 Can move along.

At least one side of the guide rail 122 may be provided with a guide wall 123 extending along the extending direction of the guide rail. In FIG. 4, guide walls 123 are provided on both sides of the guide rails 122 and are provided as a pair. The guide wall 123 may have a plurality of engagement holes 124 formed along the extending direction thereof. The sliding unit 131 may be provided with a protruding unit 132. The protruding unit 132 can optionally be embedded inside the sliding unit 131 or protrude to the outside of the sliding unit 131. In the case of this embodiment, the protruding unit 132 as described above is illustrated as being in the form of a pin. The protruding unit 132 is protruded to the outside of the sliding unit 131 after the blocking member 120 is rotated according to the expansion and contraction of the cylinder 130 and the sliding on the guide rail 122 of the sliding unit 131, (Not shown). The position of the sliding unit 131 of the cylinder 130 on the guide rail 122 can be fixed. When further rotation of the blocking member 120 is required, the protruding unit 132 can again be operated to be built into the sliding unit 131. [ A controller (not shown) may be provided for the operation of the protruding unit 132 as described above.

5, the protruding unit 132 is housed inside the sliding unit 131, and the length of the cylinder 130 is shortened, so that the sliding unit 131 can be separated from the guide rail 122 So that the cylinder 130 can no longer support the blocking member 120.

5 is a view showing a state in which the blocking member 120 is rotated upward.

The floating structure 100 according to the present embodiment may include a support 140 that provides the blocking member 120 with a supporting force in the outward direction of the main body 110. The support 140 may include at least a portion protruding into the outer region of the body 110 as shown and the blocking member 120 may be disposed on the upper portion of the horizontally extending surface of the body 110 The support member 140 may contact the blocking member 120 to provide a rightward bearing force to the blocking member 120 with reference to FIG. Referring to FIG. 5, a blue wave applies a force to the blocking member 120 in the left direction. By providing the supporting member 140 as described above, damage to the blocking member 120 and the bracket 111 can be prevented.

When the blocking member 120 is rotated to some extent, the supporting member 140 and the blocking member 120 are separated from each other by a protrusion or a groove formed in the supporting member 140, And may be automatically engaged with each other while being contacted with each other. The contact between the blocking member 120 and the support 140 may occur when the blocking member 120 is rotated to the maximum in the main body 110 side.

Meanwhile, the floating structure 100 according to the present embodiment may include a wire 150 and a winch 151. The winch 151 may be provided on the upper surface of the main body 110, and the wire 150 may be wound on the winch 151.

5, the wire 150 is connected to the ring 129 formed at the other end (free end portion) of the blocking member 120. The wire 150 may be connected to the blocking member 120, do. Another part of the wire 150 connected to the blocking member 120 can be wound on the winch 151 provided in the main body 110. When the support 140 described above is provided, the wire 150 may extend along a portion of the support 140, wherein at least one point of the support 140 may be provided with at least one pulley.

The winch 151 can provide tension to the wire 150 in the inward direction of the main body 110 by rotating it. Therefore, the blocking member 120 connected to the wire 150 can also receive a force inward of the main body 110, thereby maintaining the rotating state.

The rotation of the blocking member 120 can be realized by the cylinder 130 described above and the turning state of the blocking member 120 can be realized by the wire 150 and the winch 151. [ Specifically, when the blocking member 120 is rotated in the upward direction from the bottom, the cylinder 130 rotates the blocking member 120 through extension and rotation of the length thereof as described with reference to FIG. 3 Can support. The wire 150 wound on the winch 151 at one end can be connected to the blocking member 120 when the blocking member 120 is rotated to a predetermined point on the upper surface of the horizontally extending surface of the upper surface of the main body 110 At the same time, the cylinder 130 may no longer support the blocking member 120. 4, as the protruding unit is built into the sliding unit and the length of the cylinder 130 is shortened, the sliding unit is separated from the guide rail, so that the cylinder 130 is separated from the blocking member 120 It can be.

Fatigue can accumulate in the cylinder 130 if the cylinder 130 continues to support the blocking member 120 while the blocking member 120 is located above the extended surface and this can lead to damage to the cylinder 130 . Therefore, in the present embodiment, the cylinder 130 is utilized only for rotating the blocking member 120, and the blocking member 120 is maintained in the rotated state through the wire 150 and the winch 151. [

The time when the wire 151 is connected to the blocking member 120 and the cylinder 130 no longer supports the blocking member 120 may be the time when the blocking member 120 and the supporting body 140 are in contact with each other.

When the blocking member 120 is rotated by the wire 150 and the winch 151 without being further supported by the cylinder 130, the wire 150 is rotated through the rotation of the winch 151 somewhat, It is possible to adjust the magnitude of the tension acting on the belt. For example, when the blocking member 120 is kept at the maximum rotation state by maximizing the tension, damages to the blocking member 120 and the bracket 111 due to the strong vibration of the blocking member 120 May occur. Accordingly, the wire 150 is given a tension that is somewhat looser than the above-described state through the rotation of the winch 151, and when the blue wave collides against the blocking member 120, until the blocking member 120 contacts the supporting body 140 It is possible to rotate the bracket 111 toward the main body 110 side. That is, it is possible to give a kind of flexibility to the blocking member 120 and the bracket 111. At this time, a separate cushioning member may be provided at a junction between the blocking member 120 and the support 140.

It is to be understood that the embodiments described above are merely illustrative of some examples of the technical idea and the scope of the technical idea is not limited to the illustrated embodiments, It will be understood that various changes, substitutions, and alterations may be made therein without departing from the spirit and scope of the invention.

100: Floating structure 110: Body
111: bracket 120: blocking member
121: through hole 122: guide rail
123: side wall 124:
130: cylinder 131: sliding unit
132: protruding unit 140:
150: Wire 151: Winch

Claims (9)

main body; And
And a shielding member for shielding a sunflower flowing into the main body, the shielding member being located at an upper portion or a lower portion of a horizontally extending surface of the upper surface of the main body selectively by pivoting in an outer region of the main body, A floating structure comprising a member. The method according to claim 1,
Wherein the blocking member is inclined upward toward the outside of the main body when the main body rotates to the maximum at the upper side of the extended surface. The method according to claim 1,
Wherein the blocking member is a plate-shaped member having a plurality of through holes formed therein. The method according to claim 1,
A guide rail formed along the longitudinal direction of the blocking member; And
Wherein the one end portion is rotatably connected to the main body and the other end portion is moved along the guide rail and the length is expanded and contracted. 5. The method of claim 4,
A sliding unit provided at the other end of the cylinder and sliding along the guide rail;
A protruding unit selectively housed inside the sliding unit or protruding outside the sliding unit;
A controller for controlling an operation of the protruding unit; And
And a guide wall extending along at least one side of the guide rail and extending along the extending direction of the guide rail and having a locking hole through which the protruding unit is inserted when the protruding unit is protruded. The method according to claim 1,
Further comprising a support for providing an outward bearing force of the body to the blocking member when the blocking member is located above the extended surface. The method according to claim 1,
A wire connected to the blocking member; And
Further comprising a winch that winds the wire and provides tension in the inward direction of the body to the wire by rotation. The method according to claim 1,
A guide rail formed along the longitudinal direction of the blocking member;
A cylinder having one end rotatably connected to the main body and the other end selectively moving along the guide rail or away from the guide rail;
wire; And
Further comprising a winch that winds the wire and provides tension in the inward direction of the body to the wire by rotation,
The blocking member is rotated by the cylinder from a lower portion of the extended surface to a predetermined point on the upper portion of the extended surface,
Wherein the wire is connected to the blocking member when the blocking member reaches the predetermined point and the other end of the cylinder is detached from the guide rail. The method according to claim 1,
The floating structure is a jack up league,
Wherein the blocking member is positioned above the extended surface when the jack-up rig is in the navigation mode and is located below the extended surface when the jack-up lever is in the jack-up mode.

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