KR20200106781A - Liquid dome and floating structure including the same - Google Patents

Abstract

The present invention relates to a liquid dome and a floating structure including the same. More specifically, according to one embodiment of the present invention, the liquid dome includes: a wall part extended between a main deck and an inner deck of the floating structure to form a path communicating with a cargo hold of the floating structure; and a cover covering the path, wherein the cover may include a cover membrane arranged at a height lower than that of the main deck. Therefore, the liquid dome can have a simplified structure compared to the prior art.

Description

Liquid dome and floating structure including the same {LIQUID DOME AND FLOATING STRUCTURE INCLUDING THE SAME}

The present invention relates to a liquid dome and a floating structure including the same.

In general, floating structures such as liquefied natural gas carriers have a cargo hold for storing liquefied natural gas, and a liquid dome is generally provided in such a cargo hold. The liquid dome provided in the cargo hold is located above the liquefied natural gas cargo hold, and serves as a passage for loading and unloading the liquefied natural gas.

However, in the conventional liquid dome, a protruding sheet was provided to support the cover, and in general, the protruding sheet has a complicated structure, so it was difficult to design and manufacture.

Embodiments of the present invention are invented to solve the above-described problems, and to provide a liquid dome capable of reducing manufacturing cost and manufacturing time, and a floating structure including the same.

In addition, it is intended to provide a liquid dome and a floating structure including the same with a simplified structure compared to the prior art.

According to an aspect of the present invention, a wall portion extending between the main deck and the inner deck of the floating structure to form a passage communicating with the cargo hold of the floating structure; And a cover covering the passage, wherein the cover includes a cover membrane disposed at a lower height than the main deck, and a liquid dome may be provided.

In addition, the cover may be provided with a liquid dome further including a plate disposed above the cover membrane.

In addition, the cover is provided under the plate, the first cover insulation disposed to be spaced apart from the wall portion; And a second cover insulating material provided between the first cover insulating material and the wall portion, wherein the second cover insulating material is configured to be installed separately from the first cover insulating material. A liquid dome may be provided.

In addition, a liquid dome may be provided in which the first cover insulating material and the second cover insulating material are disposed between the plate and the cover membrane.

Also, the main deck; A cargo hold that provides a space for storing liquefied natural gas; An inner deck spaced downward from the main deck; And a liquid dome connected to the cargo hold, wherein the liquid dome includes: a passage extending between the main deck and the inner deck so as to communicate with the cargo hold; And a cover covering the passage, wherein the cover includes a cover membrane disposed at a height lower than that of the main deck, and a floating structure may be provided.

According to an embodiment of the present invention, there is an effect that the cost and time for manufacturing a liquid dome and a floating structure including the same can be reduced.

In addition, there is an effect that the structure of the liquid dome and the floating structure including the same can be simplified compared to the prior art.

1 is a perspective view conceptually showing a liquid dome and a floating structure including the same according to an embodiment of the present invention.
2 is an exploded perspective view of the liquid dome of FIG. 1.
3 is a perspective view of the cover of the liquid dome of FIG. 2.
FIG. 4 is a side view showing the main deck around the liquid dome of the floating structure of FIG. 1.
5 is a side view of a cargo hold and a liquid dome of the floating structure of FIG. 1;
6 is a side view showing an example of the arrangement of the cover insulation of the liquid dome of FIG.
7 is an enlarged side view of A of FIG. 6.
8 is a side view showing another example of the arrangement of the cover insulation of the liquid dome of FIG. 1.
9 is a flow chart illustrating a manufacturing process of the liquid dome of FIG. 1 and a floating structure including the same.

In describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the subject matter of the present invention, a detailed description thereof will be omitted.

In addition, in the present specification, expressions such as the upper side, the lower side, and the side are described with reference to the drawings in the drawings, and it should be noted in advance that if the direction of the object is changed, it may be expressed differently. In addition, expressions such as upwards and downwards are not limited to direct upwards and downwards, and include those that are slightly inclined therefrom. For the same reason, some components in the accompanying drawings are exaggerated, omitted, or schematically illustrated, and the size of each component does not entirely reflect the actual size.

In addition, terms including ordinal numbers such as first and second may be used to describe various elements, but the corresponding elements are not limited by these terms. These terms are only used for the purpose of distinguishing one component from another.

The meaning of “comprising” as used in the specification specifies a specific characteristic, region, integer, step, action, element and/or component, and other specific characteristic, region, integer, step, action, element, component and/or group It does not exclude the existence or addition of

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

First, referring to Figures 1 to 3, the floating structure (1) may be a ship for storing and transporting liquefied natural gas, a floating body on the sea that does not have self-portability, for example, a liquefied natural gas carrier, a liquefied natural gas It may be FPSO, liquefied natural gas RV, FLNG, and the like. The floating structure 1 may include a main deck 10, an inner deck 20, a cargo hold 30, a pump tower 40, and a liquid dome 70.

Referring further to FIG. 4, the main deck 10 may form the outer shape of the floating structure 1 and may have a plate shape. The main deck 10 may include a trunk deck and an upper deck. The main deck 10 may be a deck positioned on the uppermost side of the floating structure 1. The main deck 10 may include a passage deck portion 11, a peripheral deck portion 12 surrounding the passage deck portion 11, and a general deck portion 13 surrounding the peripheral deck portion 12. . The main deck 10 may extend so as to incline upward at an angle θ of 1.5° or more and 2.0° or less with respect to the horizontal direction while extending from the outside toward the passage P. For example, the main deck 10 may be inclined upward at an angle θ of approximately 1.75° with respect to the horizontal direction. In addition, such an inclination may be formed in the peripheral deck portion 12 of the main deck 10, and the passage deck portion 11 may extend parallel to the horizontal direction so as to be flat.

The passage deck 11 may be a portion of the main deck 10 surrounding the passage P, and at least a portion of the passage deck 11 may constitute the wall portion 100 forming the passage P. Here, the passage P is a space formed by the liquid dome 70, communicates with the inner space of the cargo hold 30 and may penetrate the inner deck 20. The passage deck 11 may protrude further toward the center of the passage P than the dome membrane 122. In addition, the passage deck 11 may protrude further toward the center of the passage P than the outer circumferential surface of the second cover insulating material 240 to be described later.

The passage deck portion 11 may have a thickness as thin as that of the general deck portion 13. For example, when the average thickness of the general deck portion 13 is tmm, the passage deck portion 11 may have a thickness of tmm or more and t+5 mm or less. For example, the passage deck portion 11 may have a thickness of approximately 15 mm. The passage deck portion 11 may be formed of a material having a higher yield stress than the peripheral deck portion 12 and the general deck portion 13. In addition, the passage deck portion 11 may have a yield stress of 220 MPa or more and 500 MPa or less. For example, the passage deck portion 11 may be formed of SUS and may have a yield stress of approximately 235 MPa.

The peripheral deck portion 12 may have a thickness equal to or greater than that of the general deck portion 13, and may have a thickness smaller than that of the passage deck portion 11. Further, the peripheral deck portion 12 may be formed of the same material as the general deck portion 13.

The general deck portion 13 may form the remaining decks other than the passage deck portion 11 and the peripheral deck portion 12. The general deck part 13 may include a plate having a thickness of 10 mm or more and 15 mm or less. For example, the general deck portion 13 may have a thickness of approximately 12 mm.

The inner deck 20 may fix the upper portion of the cargo hold 30 and may have a plate shape. This inner deck 20 may be disposed approximately parallel to the main deck 10. The inner deck 20 may be a deck auxiliaryly formed in addition to the main deck 10.

The cargo hold 30 provides a space in which liquefied natural gas can be stored. The cargo hold 30 may be configured integrally with the floating structure 1 or may be configured as a separate body inside the floating structure 1. The cargo hold 30 may include at least one cargo hold insulation panel 31 and a cargo hold membrane 32, and the cargo hold insulation panel 31 and the cargo hold membrane 32 may be formed of a plurality of layers.

The pump tower 40 may discharge liquefied natural gas stored in the cargo hold 30 to the outside of the cargo hold 30 or may supply liquefied natural gas into the cargo hold 30. The pump tower 40 may include a pump that provides power for transporting liquefied natural gas, and one or more pipes connected to the pump and passing through the liquid dome 70. In addition, the pump tower 40 may be supported by a pump tower support 41 provided at the bottom of the cargo hold 30.

5 to 9, the liquid dome 70 may provide a passage P through which the inside of the cargo hold 30 and the outside of the hold 30 can communicate with each other. The passage P may have an opening on the main deck 10 side and an opening on the inner deck 20 side, and the opening on the main deck 10 side may be smaller than the opening on the inner deck 20 side. The liquid dome 70 may be provided on the cargo hold 30. The liquid dome 70 includes a wall portion 100 forming a passage P communicating with the cargo hold 30, a cover 200 covering the passage P, a stiffener 300 fixing the cover 200, And the pipe of the pump tower 40 may include a pipe support 400.

The wall portion 100 may include a wall frame 110, a barrier portion 120 forming the passage P, and a support portion 134.

The wall frame 110 may connect the main deck 10 and the inner deck 20 between the main deck 10 and the inner deck 20. The wall frame 110 may extend in a direction that deviates from the direction in which the main deck 10 and the inner deck 20 extend. For example, the wall frame 110 may be formed in parallel with the passage, and may extend perpendicular to the main deck 10. The wall frame 110 may be formed of a material having a higher yield stress than the peripheral deck portion 12 and the general deck portion 13. Such, the wall frame 110 may have a yield stress (yield stress) of 220 MPa or more and 500 MPa or less. For example, the wall frame 110 may be formed of SUS, and may have a yield stress of approximately 235 MPa.

The barrier portion 120 may be configured to surround the passage P, and may extend in the same direction as the direction in which the passage P extends. The barrier part 120 may include a dome insulation panel connected to the cargo hold insulation panel 31, and a support for covering the dome insulation member and supporting the dome membrane 122 connected to the cargo hold membrane 32. The dome insulation member 121 and the dome membrane 122 may extend in the vertical direction. The dome membrane 122 may be formed with a convex embossed portion, and this embossed portion may be formed in a lattice structure.

The dome insulating member 121 may include a first dome insulating member 121a and a second dome insulating member 121b to form a plurality of layers. The first dome insulating member 121a may be disposed closer to the passage P than the second dome insulating member 121b, and the second dome insulating member 121b is a wall frame than the first dome insulating member 121a. It may be disposed adjacent to 110.

The dome membrane 122 may also include a first dome membrane 122a and a second dome membrane 122b to form a plurality of layers. The first dome membrane 122a may be disposed closer to the passage P than the second dome membrane 122b, and the dome insulating member 121 is provided so that the dome insulating member 121 is not exposed to the passage P. I can cover it. The edge of the first dome membrane 122a may be connected to the edge of the cover membrane 250. The second dome membrane 122b may be disposed adjacent to the wall frame 110 than the first dome membrane 122a. The second dome membrane 122b may be disposed between the first dome insulating member 121a and the second dome insulating member 121b, and may extend upward to the support 134 or the main deck 10. .

The support part 134 may support the upper end of the barrier part 120. This support 134 may be disposed between the barrier unit 120 and the main deck 10. In addition, the support part 134 may be integrally formed with the main deck 10. On the other hand, as a modified example of the present invention, the support 134 may be formed of an insulating material, and may be omitted in some cases.

The cover 200 covers the passage P. The cover 200 may include a plate 210, a reinforcing part 220, a first cover insulation 230, a second cover insulation 240, and a cover membrane 250.

This cover 200 is configured to withstand the stress applied to the floating structure (1). In addition, the cover 200 may have a yield stress of 220 MPa or more and 500 MPa or less. For example, at least a portion of the cover 200 may be formed of SUS, and may have a yield stress of approximately 235 MPa. Meanwhile. The liquefied natural gas vaporized due to the cover membrane 250 may be prevented from penetrating into the cover insulators 230 and 240, and thus the thermal insulation performance of the cover insulators 230 and 240 may be improved. Since the need for strong cryogenic brittleness for the plate 210 is reduced due to the improvement in insulation performance, the plate 210 may be formed of steel.

The plate 210 may be a member having a size capable of covering the passage P and extending in the transverse direction. The direction in which the plate 210 extends may be different from the direction in which the main deck 10 extends. For example, the plate 210 may extend flat in a horizontal direction. The plate 210 may be disposed at the same or lower position than the main deck 10. That the plate 210 of the cover 200 is disposed at the same height as the main deck 10 is not limited to being disposed at the same level as the plate 210 and the main deck 10, and the plate 210 The upper surface of the main deck 10 is slightly more protruding, but the lower surface of the plate 210 may include a range that does not cover the upper surface of the main deck (10).

The edge of the plate 210 may be connected to one or more of the main deck 10, the wall part 100, and the stiffener 300. The plate 210 may be disposed at the same or lower position than the main deck 10. Accordingly, the side surface of the plate 210 may be disposed to face the side surface of the main deck 10. In other words, the side surface of the plate 210 may be substantially parallel to the side surface of the main deck 10. The plate 210 may be supported by welding its edge to the main deck 10. In the present specification, that two or more members are connected by welding to each other may mean the same as that a welding part is provided on two or more members.

In addition, the plate 210 may have a size covering the passage P formed in the main deck 10. The width of the passage P on the side of the main deck 10 may be smaller than the width of the passage P on the side of the wall portion 100. In this case, the size of the plate 210 may be smaller than the width of the passage P on the side of the wall portion 100. Meanwhile, the width of the passage P on the side of the main deck 10 may be the same as the width of the passage P on the side of the wall portion 100. In this case, the size of the plate 210 may be the same as the width of the passage P on the side of the wall portion 100. In addition, in this case, the second cover insulation 240 is an inner portion having the same thickness as the first cover insulation 230, and between the plate 210 and the support 134 or between the main deck 10 and the support 134. It may include an outer portion extending transversely from the inner portion to the outside so as to be interposed therebetween.

In this way, when the second cover insulation 240 extends into the space between the support part 134 and the main deck 10, for example, the support part 134 is disposed to be adjacent to or in contact with the second cover insulation 240, The outer portion of the second cover insulating material 240 may have a thinner thickness in the vertical direction (orthogonal to the main deck) than the inner portion [Fig. 8].

A hole 211 for a pump tower may be formed in the plate 210 to allow the pump tower 40 to pass therethrough. The pump tower hole 211 may have the same size as the pump tower 40 or slightly larger than the pump tower 40 so that the pump tower 40 can be inserted therethrough. The pump tower 40 is inserted through the hole 211 for the pump tower, and the pump tower 40 is coupled to the plate 210 by welding with the hole 211 for the pump tower.

The reinforcing part 220 may be disposed on the plate 210 and extend in the transverse direction. The reinforcing part 220 may include a first reinforcing part 220a extending in a first direction, and a second reinforcing part 220b extending in a second direction that is a direction deviating from the first direction. In addition, the first reinforcement portion 220a and the second reinforcement portion 220b may be disposed to cross each other. At least one of the first and second reinforcement parts 220a and 220b may extend in the same direction as the direction in which the plate 210 extends. For example, at least one of the first reinforcement part 220a and the second reinforcement part 220b may extend flat in the horizontal direction.

The first and second reinforcing parts 220 may include a reinforcing body 221 and a reinforcing head 222. The reinforcing body 221 may have a shape protruding from the plate 210. For example, the reinforcing body 221 may be a protruding rib. The reinforcing head 222 may be connected to the upper end of the reinforcing body 221 and may extend from the reinforcing body 221 in a direction different from the direction in which the reinforcing body 221 protrudes. This reinforcing body 221 may have a shape of a flange extending in the transverse direction. The reinforcing part 220 may be welded to the stiffener 300. The reinforcing portion 220 positioned at the edge of the plate 210 may form an inclined surface 300a such that an upper portion of the reinforcing portion 220 is positioned outside the edge of the plate 210.

The first cover insulation 230 may be installed under the plate 210. The first cover insulation 230 may be installed such that its edge is spaced apart from the lower end of the wall portion 100 or the stiffener 300 by a distance of about 20 cm or more and 80 cm or less in the horizontal direction, and the lower surface of the plate 210 Can cover some. For example, this separation distance may be approximately 30 cm. In addition, the first cover insulation 230 may be fixed to the plate 210 alone without the second cover insulation 240.

The second cover insulation 240 may be installed in a space between the first cover insulation 230 and the wall portion 100. The second cover insulation 240 may surround the first cover insulation 230 while covering an edge of the lower side of the plate 210. In addition, the second cover insulation 240 may extend laterally than the edge of the plate 210. The second cover insulation 240 may be made of substantially the same material as the first cover insulation 230. The second cover insulation 240 may be configured to be installed separately from the first cover insulation 230. For example, the second cover insulation 240 may be separated from the first cover insulation 230 and may be installed after the first cover insulation 230 is installed.

The lower edge of the plate 210 may be covered by the second cover insulating material 240, and the remaining portion including the lower center of the plate 210 may be covered by the first cover insulating material 230. Here, each of the first cover insulating material 230 and the second cover insulating material 240 does not necessarily mean a single panel, and may be a combination of a plurality of panels.

The cover membrane 250 may cover the cover insulation 230 and 240. In addition, the cover membrane 250 may be formed with a convex embossed portion, such embossed portion may be formed in a lattice structure. The lattice spacing of the embossing of the cover membrane 250 may be the same as the lattice spacing of the embossing of the dome membrane 122. In addition, the upper surface of the cover membrane 250 may face the lower surfaces of the cover insulating materials 230 and 240. In addition, the edge of the cover membrane 250 may be connected to the first dome membrane 122a. The cover membrane 250 may be disposed under the cover insulation 230 and 240. Accordingly, the cover insulation 230 and 240 may be disposed between the plate 210 and the cover membrane 250, and may be disposed at a lower position than the main deck 10.

The cover membrane 250 may extend in a horizontal direction parallel to the plate 210. The cover membrane 250 and the dome membrane 122 may be connected to each other without a gap so that the liquefied natural gas does not leak. For example, the cover membrane 250 and the dome membrane 122 may be welded to each other.

The stiffener 300 may be connected to the cover 200 to support the cover 200. The stiffener 300 may be fixedly installed on the upper side of the main deck 10 and may be connected to the reinforcing part 220 of the cover 200 by welding. The stiffener 300 may include a stiffener body 310, a stiffener head 320, and a bracket part 330.

The stiffener body 310 may have a shape protruding from the main deck 10. For example, the stiffener body 310 may be a protruding rib. The stiffener head 320 may be connected to the upper end of the stiffener body 310, and may extend from the stiffener body 310 in a direction different from the direction in which the stiffener body 310 protrudes. This stiffener body 310 may have a shape of a flange extending in the transverse direction. The stiffener 300 may have a shape corresponding to the reinforcing part 220 to be welded to the reinforcing part 220. For example, the stiffener 300 at a portion adjacent to the edge of the cover 200 may form an inclined surface 300a such that the upper portion of the stiffener 300 is positioned outside the edge of the plate 210. .

The bracket portion 330 may be disposed on the opposite side of the inclined surface 300a of the stiffener 300. The bracket portion 330 may have a tapered shape extending from the upper surface of the stiffener body 310 or the stiffener head 320 toward the upper surface of the main deck 10. The bracket part 330 may be fixedly installed on the upper surface of the main deck 10.

The pipe support 400 may support a pipe. The pipe supported by the pipe support 400 may be a pipe included in or extending from the pump tower 40. The pipe support 400 may be disposed above the cover 200. The pipe support 400 may include a support plate 410, an auxiliary fixing member 420, and a support leg 430.

The support plate 410 may support the pipe from the lower side. The support plate 410 may be supported at a height of about 0.5m or more and 1.5m or less from the main deck 10. In other words, the pipe may be supported by the pipe support 400 at a height of approximately 0.5m or more and 1.5m or less. For example, the support plate 410 may be supported at a height of approximately 1.0 m from the main deck 10. Therefore, the operator can easily perform the work on the pipe without a separate support.

The auxiliary fixing member 420 may be disposed above the support plate 410, and the pipe may be stably fixed to the support plate 410. The auxiliary fixing member 420 may be configured to surround the upper side, left and right sides of the pipe.

The support leg 430 may support the support plate 410 with respect to the main deck 10. The support leg 430 may extend downward from the support plate 410. In the drawings according to the present embodiment, the support leg 430 is shown to have a bar shape, but the spirit of the present invention is not necessarily limited thereto. The support leg 430 may not be inclined and may extend in a direction substantially perpendicular to the main deck 10.

Hereinafter, a process of installing the liquid dome 70 having the above configuration on the floating structure 1 will be described with reference to FIG. 9.

First, a frame of the main deck 10, the inner deck 20, and the cargo hold 30 of the floating structure 1 is provided (main deck, inner deck and cargo hold preparation step (S10)). The order and process of manufacturing the main deck 10 and the inner deck 20 may be changed and applied according to circumstances.

In addition, one or more of the wall frame 110 and the barrier 120 of the wall portion 100 may be installed to form a passage extending between the main deck 10 and the inner deck 20 (wall installation step (S20)). In this wall installation step (S20), the upper end of the wall portion 100 is not constructed in order to prevent the welding in the cover fixing step (S70) to be described later from damaging the heat insulating material.

On the other hand, after manufacturing the frame of the cargo hold 30, before installing the cargo hold insulation panel 31 on the frame, the pump tower support part 41 in the cargo hold 30 is connected to the bottom of the frame of the cargo hold 30 (Pump tower support installation step (S30)).

When the pump tower support part 41 is fixed to the bottom of the frame of the cargo hold 30, the cargo hold insulation panel 31 is installed inside the cargo hold 30 including the vicinity of the pump tower 40 (installation of insulation panels Step (S40)). Insulation panel installation step (S40) may include installing the cargo hold membrane 32 after the cargo hold insulation panel 31 is installed. The cargo hold membrane 32 may cover the cargo hold insulation panel 31 so that the cargo hold insulation panel 31 is not exposed to liquefied natural gas stored in the cargo hold. In addition, in the insulating panel installation step (S40), the barrier unit 120 is installed, so that the thermal insulation work of the lower portion of the wall unit 100 may be performed. In other words, when the cargo hold insulation panel 31 inside the cargo hold 30 is installed, the barrier unit 120 may also be installed.

When the installation of the cargo hold insulation panel 31 in the cargo hold 30 is completed, the pump tower 40 is mounted and installed on the pump tower support 41 (pump tower mounting step S50). Meanwhile, in the present embodiment, it has been described that the installation of the pump tower 40 is performed after the installation of the cargo hold insulation panel 31 is completed, but the spirit of the present invention is not necessarily limited thereto, and the pump tower support part 41 and After the cargo hold 30 frames are connected to each other, the pump tower 40 may be mounted on the pump tower support part 41 before installation of the cargo hold insulation panel 31.

In addition, the barrier portion 120 of the wall portion 100 of the liquid dome 70 may be installed, and the stiffener 300 may be fixedly installed on the main deck 10.

Meanwhile, a cover 200 to which the first cover insulation 230 is attached without the second cover insulation 240 is provided under the plate 210 (cover preparation step S60). The cover 200 to which the first cover insulation 230 is attached covers the passage P formed in the liquid dome 70. The pump tower 40 is inserted into the hole 211 for the pump tower of the cover 200, and the main deck 10 is disposed adjacent to the plate 210, and the reinforcing part 220 includes the stiffener 300 and Are placed adjacent to each other.

The cover 200 may be fixed to the main deck 10 (cover fixing step (S70)). In the cover fixing step (S70), the plate 210 may be fixed to the main deck 10 while the first cover insulation 230 is spaced apart from the wall part 100. The cover fixing step (S70) may include a plate fixing step (S710), a reinforcing part fixing step (S720), and a pump tower fixing step (S730). In other words, the edge of the plate 210 is welded to each other with the main deck 10 along its circumferential surface (plate fixing step (S710)), and then the reinforcing part 220 is welded to each other with the stiffener 300 It can be (reinforcement part fixing step (S720)). In addition, the pump tower 40 may be welded to each other with the pump tower hole 211 (pump tower fixing step (S730)). The pump tower fixing step (S730) may be performed after the plate fixing step (S710).

After the welding for fixing the cover 200 to the main deck 10 is completed, the second cover insulation 240 may be fixedly installed in the space between the first cover insulation 230 and the wall part 100 (welding part The cover insulation installation step (S80)). After the second cover heat insulating material 240 and the upper end of the barrier unit 120 disposed near the connection portion between the cover 200 and the main deck 10 are fixed by welding between the cover 200 and the main deck 10 Since it is installed in, the second cover insulation 240 can be prevented from being damaged due to the heat of welding.

When the cover insulation 230 and 240 are installed, the cover membrane 250 is installed. (Cover Membrane Installation Step (S100)) The edge of the cover membrane 250 may be connected to the dome membrane 122.

On the other hand, although the embodiments of the present invention have been described as specific embodiments, this is only an example, and the present invention is not limited thereto, and should be construed as having the widest scope in accordance with the basic idea disclosed herein. A person skilled in the art may combine/substitute the disclosed embodiments to implement a pattern of a shape not indicated, but this also does not depart from the scope of the present invention. In addition, those skilled in the art can easily change or modify the disclosed embodiments based on the present specification, and it is clear that such changes or modifications also belong to the scope of the present invention.

1: floating structure
10: main deck 11: aisle deck portion
12: peripheral deck section 13: general deck section
20: inner deck 30: cargo hold
31: insulation panel 40: pump tower
41: pump tower support 70: liquid dome
100: wall part 110: wall frame
121: dome insulation member 122: dome membrane
120: barrier portion
200: cover 210: plate
211: pump tower hole 220: reinforcement
220a: first reinforcement part 220b: second reinforcement part
221: reinforcing body 222: reinforcing head
230: first cover insulation 240: second cover insulation
250: cover membrane
300: stiffener 310: stiffener body
320: stiffener head 300a: inclined surface
400: pipe support 410: support plate
430: support leg

Claims (5)

A wall portion extending between the main deck and the inner deck of the floating structure to form a passage communicating with the cargo hold of the floating structure; And
And a cover covering the passage,
The cover,
Comprising a cover membrane disposed at a height lower than the main deck,
Liquid Dome. The method of claim 1,
The cover further comprises a plate disposed above the cover membrane,
Liquid Dome. The method of claim 2,
The cover is
A first cover insulating material provided under the plate and spaced apart from the wall portion; And
Further comprising a second cover insulation provided between the first cover insulation and the wall portion,
The second cover insulation is configured to be installed separately from the first cover insulation,
Liquid Dome. The method of claim 3,
The first cover insulation and the second cover insulation are disposed between the plate and the cover membrane,
Liquid Dome. Main deck;
A cargo hold that provides a space for storing liquefied natural gas;
An inner deck spaced downward from the main deck; And
Including a liquid dome connected to the cargo hold,
The liquid dome,
A passage extending between the main deck and the inner deck to communicate with the cargo hold; And
And a cover covering the passage,
The cover,
Comprising a cover membrane disposed at a height lower than the main deck,
Floating structures.

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