KR101291260B1 - Floating structure - Google Patents

Abstract

The present invention relates to a floating structure.
According to one aspect of the invention, the hull is submerged below sea level; A plurality of modules provided on an upper portion of the hull; A first support part supporting one side of the module such that one side of the module does not move in one direction with respect to the hull; And a second support part supporting the other side of the module such that the other side of the module is moved in the one direction.

Description

{Floating structure}

The present invention relates to a floating structure.

Floating Production Storage Offloading (FPSO) or Floating LNG Production Storage (LNG FPSO) is a floating structure that extracts and refines crude oil or LNG from deep sea and stores it. Installed in medium and large wells, they are configured to operate for decades.

The hull of the floating structure may include a lifting module, a refining module, and a storage tank for extracting crude oil or the like from an oil well. In addition, the hull may further include a thruster (thruster) for position control.

However, the above conventional technology has the following problems.

Since the floating structure has a large hull fluctuation due to the influence of waves and tidal currents, since the high power thruster must be used for position control, energy consumption is severe.

In particular, in an oil well in an ice-sea region such as the polar region, the floating structure is pushed to the drift ice, so the position control is very difficult. Therefore, the use area of the floating structure is limited.

In addition, since it has only a function of simply extracting and refining crude oil and storing it, there is a problem that a separate drilling line is required for the actual oil well development. In this case, it is very inefficient in terms of cost to operate small wells.

Embodiments of the present invention, to provide a floating structure with low fluctuations caused by waves and tides.

In addition, to provide a floating structure that can be operated in the sea ice.

In addition, to provide a floating structure including a drilling function with the production and storage of crude oil or liquefied natural gas.

According to an embodiment of the present invention, a hull submerged beneath the sea surface; A plurality of modules provided on an upper portion of the hull; A first support part supporting one side of the module such that one side of the module does not move in one direction with respect to the hull; And a second support part supporting the other side of the module such that the other side of the module is moved in the one direction, wherein the first support part and the second support part are provided with the hull and the module so that the module is positioned above the sea level. Floating structures that are spaced apart may be provided.

In addition, the first support and the second support may provide a floating structure characterized in that it has a circular cross section.

It is provided between the hull and the module, it may provide a floating structure, characterized in that it further comprises a thruster for generating a thrust for position control of the hull.

In addition, one side of the module may be rotatably fixed to the first support, the other side of the module may provide a floating structure characterized in that the seat is slidably seated on the second support.

In addition, the first pipe extending from any one of the modules; A second pipe extending from the other of the modules; And connecting the first pipe and the second pipe, it can provide a floating structure further comprises a connecting member capable of stretching and bending.

In addition, connecting the modules, a portion may provide a floating structure further comprises a pipe formed to pass through the interior of the first support or the second support.

In addition, the module may include a drilling module for drilling an oil well, and the hull may provide a floating structure, characterized in that the door pool is formed at a position corresponding to the drilling module.

In addition, the upper end of the door pool may provide a floating structure, characterized in that formed to be spaced apart from the drilling module.

According to the floating structure according to the embodiment of the present invention as described above, since the semi-submersible structure is used, there is an advantage that it is possible to minimize the fluctuation caused by waves and tides.

In addition, since the drift ice can flow into the space above the submerged hull, it is easy to control the position of the floating structure, there is an effect that can be operated in the sea ice.

In addition, by mounting a drilling module with a refinery module and a storage tank of crude oil, there is an advantage that all the operations required for crude oil production can be performed only by the floating structure without any additional device.

1 is a view showing the configuration of a floating structure according to an embodiment of the present invention.
2 is a cross-sectional view taken along the line II ′ of FIG. 1.
3 is an enlarged view of a portion A in Fig.
4 is a view showing a piping structure connecting the module of FIG.

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

In the following description of the present invention, detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

1 is a view showing the configuration of a floating structure according to an embodiment of the present invention, Figure 2 is a cross-sectional view taken in line II 'of Figure 1, Figure 3 is an enlarged view of portion A of FIG.

1 to 3, the floating structure 10 according to an embodiment of the present invention is a hull 100 submerged under the sea surface, a plurality of rigs (rig, 210) provided on the upper portion of the hull 100 ), And may be installed in the rig 210 and include a plurality of modules 300 exposed on the sea level.

The floating structure 10 may be a Floating Production Storage Offloading (FPSO) capable of producing and storing crude oil or liquefied natural gas. In this embodiment, the floating structure 10 will be described as an example of a floating crude oil production storage facility.

The hull 100 is provided submersible, and may include a storage tank 110 for storing crude oil and a ballast tank 120 for controlling the fluctuation of the hull 100. Here, the storage tank 110 may be formed in a double hull structure to store the crude oil more safely.

The hull 100 is provided to be completely submerged below the sea level, it is possible to adjust the depth of the diving by adjusting the amount of water or air in the ballast tank 120.

In addition, the hull 100 may further include a door pool 130 connected to the drilling module 330 to be described later. The door pool 130 may be formed to penetrate the hull 100 in the vertical direction.

A plurality of the rig 210 is provided on the upper portion of the hull 100, may be formed in the form of a column standing in the vertical direction. The rig 210 spaces the module 300 from the hull 100 and may be formed at a predetermined height so that the module 300 is not submerged in water.

The rigs 210 may be arranged to be spaced apart at a predetermined interval in the longitudinal direction (left and right directions of FIG. 2) of the hull 100, and a pair of each other in a width direction (up and down directions of FIG. 2) of the hull 100. It may be arranged to face. In addition, the rig 210 may be provided at the side end portion in the width direction of the hull 100.

On the other hand, the rig 210 is a certain degree in the rig 210, so that the module 300 can function stably, even if the hull 100 is statically deformed by the load of crude oil, etc. Support to be movable. Detailed information related to this will be described later.

Since the hull 100 and the module 300 are spaced apart from each other by the rig 210, a portion directly colliding with the waves around the sea surface in the floating structure 10 may be limited to the rig 210. Can be. That is, the waves around the sea level passes between the hull 100 and the module 300, only a portion of the waves hit the rig 210, the rest will pass between the rig 210. Therefore, fluctuations due to the waves of the floating structure 10 can be minimized.

In addition, the lateral cross section of the rig 210 may be formed in a circular shape so that seawater flows smoothly.

Particularly, in the case of the ice-floating area in which ice cubes float, the drift ice having a predetermined size or less may pass through the rig 210 as it is, and thus the risk of the floating structure 10 hitting the drift ice may be reduced. . Thus, the floating structure 10 can also be used in the sea ice.

The module 300 may be configured in a form in which devices for performing various functions are installed on the support plate 390 seated and fixed to the rig 210. In detail, the support plate 390 may be formed in a rectangular shape, and each vertex may be supported by the rig 210. Of course, the support plate 390 may be further supported by the rig 210 in addition to the four vertices.

The module 300 is a housing module 310 that provides a living space of the crew, a mechanical module 320, a drilling derrick 331 is installed is installed a variety of mechanical devices required for the operation of the floating structure (10). Drilling module 330, a lifting module 340 for extracting crude oil from an oil well, a refinery module 350 for refining crude oil, and the amount of fluid stored in the storage tank 110 and the ballast tank 120 It may include a pumping module 360 to adjust. In addition, it may further include a flare tower 370, which is a safety facility for discharging and incineration of crude oil and gas being stored at once.

In the drilling module 330, the oil well is drilled through the door pool 130 using the derrick 331. The door pool 130 may extend upward from the hull 100 in order to prevent the drilling pipe (not shown) from being out of place or damaged by waves or drift ice.

In this case, since the support plate 390 is provided to be movable within a predetermined range, the door pool 130 and the support plate 390 may be spaced apart from each other by a predetermined distance to prevent damage of the door pool 130. The separation distance between the door pool 130 and the support plate 390 may be set within a few meters to protect the drilling pipe.

In addition, the upper end of the door pool 130 and the support plate 390 may be connected to each other by a joint member formed of a soft material.

As such, since one floating structure is provided with a drilling function and a crude oil production function, the floating structure 10 may repeatedly produce oil while moving an oil well even if no separate equipment is used.

On the other hand, the hull 100 may be statically deformed into a '∧' or '자' shape according to the loading amount of crude oil. Even if the hull 100 is deformed, the module 300 should be able to maintain its function stably.

To this end, the support plate 390 is installed to be movable in the rig 210. For example, when the support plate 390 is formed in a rectangular shape and four vertices are respectively supported by the rig 210, the support plate 390 is rotatably fixed to two of the four rigs 210. And the other two are slidably seated. That is, the support plate 390 is rotated about one side, the other side can be moved slide to correspond to the rotation.

In this embodiment, the support plate 390 will be described to be installed to be slidable in the front and rear direction of the hull 100 as an example.

In detail, two vertex portions of the rear end of the support plate 390 may be rotatably fixed to the rig 210, respectively. Here, the rig to which the support plate 390 is rotatably fixed will be referred to as a fixed side support or first support 220. That is, the first support 220 includes at least one rig.

A fixing unit 230 is formed at an upper end of the first support part 220 to rotatably fix the support plate 390 in the vertical direction. The base (232), the base 232 formed on the upper end of the first support portion 220, the rotation shaft 231 is fitted to the fixing unit 230 is coupled to the support plate 390 ( The connection part 233 fixed on the 232 may be included. Therefore, the rear end of the support plate 390 may be rotated in the vertical direction about the rotation shaft 231.

In addition, two vertex portions of the front end portion of the support plate 390 may be slidably seated in a rig 210 different from the rig that forms the first support portion 220, respectively. Here, the rig to which the support plate 390 is rotatably fixed will be referred to as a sliding side support part or a second support part 240. That is, the second support 240 also includes at least one rig.

A sliding unit 250 for sliding the support plate 390 in the front-rear direction of the hull 100 is formed at an upper end of the second support part 240. The sliding unit 250 includes a rotation shaft 251 coupled to the support plate 390, a base 252 formed at an upper end of the second support portion 240, a roller 253 fitted to the rotation shaft 251, and And a slide groove 254 formed in the base 252 so that the roller 253 is inserted and rolled in the front-rear direction. That is, the front end portion of the support plate 390 may be slidably moved along the slide groove 254 in the front-rear direction by the roller 253 rotated about the rotation shaft 251.

By the above structure, the module 300 can be driven stably even if the hull 100 is deformed.

In detail, when the hull 100 is statically deformed, the distance between the first support 220 and the second support 240 is closer or farther away. In this case, if the support plate 390 is fixed to the first support part 220 and the second support part 240 without any degree of freedom in one direction, the support plate 390 is also deformed by the deformation of the hull 100. Since it is deformed, it may pose a serious danger to the operation of the device installed on the support plate 390.

However, when the support plate 390 is slidably installed in one direction as in the embodiment of the present invention, even if the hull 100 is deformed, the distance between the support plates 220 and 250 may vary. Since the support plate 390 can slide, the devices installed on the support plate 390 can be stably operated.

For example, when the hull 100 is deformed in a '∧' shape, the first support portion 220 and the second support portion 240 are open, but the front end of the support plate 390 is the roller ( 253 is moved backwards, and the rear end of the support plate 390 is rotated to maintain the roller 253 in close contact with the base 252, the support plate 390 is not deformed Will not. When the hull 100 is deformed in the '∨' shape, the support plate 390 is moved forward to prevent deformation.

Meanwhile, the first support unit 220 may be provided with a sliding unit adjacent to the fixed unit 230. In this case, the sliding unit provided to the first support unit 220 may be connected to a support plate adjacent to the support plate connected to the fixed unit 230 of the first support unit 220. Similarly, the second support part 240 may further be provided with a fixing unit to which adjacent support plates are connected.

In the present embodiment, the support plate 390 is provided to be movable in the front and rear direction of the hull 100 as an example, but this is only one example, according to the arrangement of the storage tank 110, the hull It may be provided to be movable in the left and right directions of the (100). In this case, the first support unit 220 may be two rigs supporting either one of the left side and the right side of the hull 100, and the second support unit 240 may support the two rigs supporting the other side. Can be.

In addition, in the present embodiment, the floating structure 10 has been described as an example including a module for drilling, producing, and storing crude oil, but is not limited thereto, and includes a module for drilling, producing, and storing liquefied natural gas. You may.

On the other hand, the upper side of the hull 100 may be provided with a thruster (140) for controlling the position of the floating structure (10). The thruster 140 may be disposed between the rigs 210 and is provided to be submerged below the sea level. In this embodiment, the thruster 140 will be described as an example formed in the stern portion of the hull 100.

By providing the thruster 140 to the upper side of the hull 100, the action point of the thrust generated by the thruster 140 can be a position close to the center of mass of the hull 100. Therefore, rolling of the hull 100 due to the operation of the thruster 140 can be minimized.

In addition, the thruster 140 may be disposed near the surface of the water to further facilitate maintenance.

Hereinafter, a pipe structure connecting the module 300 will be described with reference to the drawings.

4 is a view showing a pipe structure connecting the module of FIG.

Referring to FIG. 4, the modules 300 installed on the support plate 390 may be connected to each other by a pipe 410. In the present embodiment, the piping connecting the lifting module 340 and the purification module 350 will be described as an example, but the spirit of the present invention is not limited thereto, and the piping connecting the modules having various functions installed to be spaced apart from each other. Can be applied.

As described above, since the sliding unit 250 and the fixing unit 230 are installed in the rig 210, the support plate 390 is movable. Therefore, the distance and relative position between the lift module 340 and the purification module 350 installed on two adjacent support plates 391 and 392 may be varied.

In this case, the pipe 410 connecting the lift module 340 and the purification module 350 has a high risk of being damaged due to the structural load according to the position of the lift module 340 and the purification module 350. .

To prevent this, the pipe 410 may include a first pipe 411 extending from the lifting module 340, a second pipe 412 extending from the purification module 350, and the first pipe ( 411 and the second pipe 412 may be composed of a connecting member 413. Here, the first pipe 411 or the second pipe 412 may extend to the upper space of the support plate (391, 392).

The connection member 413 is a tube having a characteristic of being stretched or bent in accordance with the direction of the force applied to both ends, and a crimped hose, bellows, or the like may be used. In addition, the connection member 413 may be located at a corresponding point between two adjacent support plates 391 and 392.

By the above structure, even if the distance and the relative position between the lift module 340 and the purification module 350 is changed, the connection member 413 is deformed so that the first pipe 411 and the second The force is applied to the pipe 412 to a minimum, it can eliminate the risk of damage to the pipe 410.

On the other hand, if there is an obstacle in the upper space of the support plate 390 and the pipe is difficult to install, the pipe 430 connecting the lifting module 340 and the purification module 350 to the lower side of the support plate 390 It may extend across the rig 210.

In detail, the pipe 430 extends from the lifting module 340 to the lower side of the support plate 391 and extends from the purification module 350 to the lower side of the support plate 392. A second pipe 432, a connection pipe 433 extending across the rig 210, and both ends of the connection pipe 433 to be provided at the first pipe 431 and the second pipe. It may include a connection member 434 connecting the (432). Here, the connection member 434 may be a tube having a characteristic of being stretched or bent in the same direction as the force applied to both ends of the connection member 413.

Each of the first pipe 431 and the second pipe 432 may be formed of a plurality of pipes, and the connection member 434 may be provided at a portion to which each pipe is connected. For example, the first pipe 431 extends downwardly through the pipe 431a extending from the lifting module 340 in the direction of the purification module 350 and the support plate 391. The connection member 434 may be provided between the pipes 431a and 431b.

In this case, the first pipe 431 and the second pipe 432 may pass through the support plates 391 and 392, respectively, and extend below the support plates 391 and 392.

On the other hand, the connection pipe 433 may be formed to penetrate the rig 210 or bypass the periphery of the rig 210, the rig 210 is connected to the connection pipe 433 through the connection pipe. The through hole 211 may be formed.

In summary, the pipes 410 and 430 connecting the modules 300 may be configured to be partially stretched or bent.

As described above, by configuring the pipes 410 and 430 connecting the modules 300 to be stretched or bent, the pipes 410 and 430 may be changed even if the distance and relative position between the respective modules 300 are changed. The risk of breakage can be eliminated.

In particular, by extending the pipe below the support plate 390, the upper space of the support plate 390 can be fully utilized.

In addition, by forming a portion of the pipe 430 to penetrate the inside of the rig 210, it is possible to eliminate the risk of damage to the pipe due to waves and the like.

As described above as a specific embodiment of the floating structure according to the embodiment of the present invention, but this is only an example, the present invention is not limited to this, should be construed as having the broadest range in accordance with the basic idea disclosed herein. do. Those skilled in the art can easily change the material, size, etc. of each component according to the application field, and can be combined / substituted the disclosed embodiments to implement a pattern of a timeless shape, but this also does not depart from the scope of the present invention will be. It will be apparent to those skilled in the art that various changes and modifications may be readily made without departing from the spirit and scope of the invention as defined by the appended claims.

100: hull 110: storage tank
120: ballast tank 130: moon pool
210: league 220: first support
230: fixed unit 240: second support part
250: sliding unit 330: drilling module
331: drilling derrick 340: lifting module
350: purification module 410, 430: piping
413, 434: connecting member

Claims (8)

Submerged hulls below sea level;
A plurality of modules provided on an upper portion of the hull;
A first support part on which one side of the module is rotatably fixed;
A second support part on which the other side of the module is slidably seated; And
A thruster provided between the hull and the module and generating a thrust for position control of the hull;
A first tubing extending from any of the modules;
A second pipe extending from the other of the modules; And
A connecting member connecting the first pipe and the second pipe and capable of stretching and bending;
And said first support and said second support are spaced apart from said hull and said module such that said module is located above sea level. The method of claim 1,
And the first support and the second support have a circular cross section. delete delete delete The method of claim 1,
Floating structure further comprising a pipe connecting the modules, a part of which is formed to pass through the inside of the first support or the second support. The method of claim 1,
The module includes a drilling module for drilling an oil well,
Floating structure, characterized in that the hull is formed in the hull corresponding to the drilling module. The method of claim 7, wherein
The upper portion of the door pool floating structure, characterized in that formed to be spaced apart from the drilling module.

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