KR101794359B1 - A tank inner wall structure for LNG carrier - Google Patents

Abstract

The present invention relates to a tank inner wall structure of a liquefied natural gas carrier, which comprises a lower insulating panel continuously disposed on an inner wall of a tank; An upper heat insulating panel installed above the lower heat insulating panel; A top bridge panel attached on the lower insulating panel between the upper insulating panels; And a corrugation membrane sheet installed on the upper side of the upper insulating panel, wherein the upper side insulating panel is formed at regular intervals and includes a sawing line for preventing damage due to deformation of the hull and thermal deformation of the membrane sheet, ; A metal insert formed at a position spaced apart from the end of the upper insulating panel by a predetermined distance to provide a rail of the automatic bonding device; An anchor strip which is grooved on the upper heat insulating panel; And a heat shield plate formed on at least one end of the anchor strip.
The inner wall structure of the tank of the liquefied natural gas carrier according to the present invention is characterized in that the function of the sawing line is compensated by the gap formed between the upper shield panel and / or the upper shield panel provided at least one end of the anchor strip and / It is possible to form a metal insert on the portion without forming a sawing line overlapping with the rail mounting metal insert of the bonding apparatus, so that the automatic bonding apparatus can be used in all the regions of the tank inner wall.

Description

[0001] The present invention relates to a tank inner wall structure for LNG carrier,

The present invention relates to a tank inner wall structure of a liquefied natural gas carrier.

Generally, a liquefied natural gas carrier is equipped with a tank for storing and transporting liquefied natural gas, which is a cryogenic liquid having a boiling point of minus 162 ° C under atmospheric pressure, at a temperature of minus 162 ° C. In order to store such liquefied natural gas, a material such as an aluminum alloy, stainless steel, nickel steel, Invar and the like which can withstand extremely low temperature and an insulating material A plurality of unit thermal insulation systems manufactured by using a material such as polyurethane foam or the like are continuously arranged.

The unitary insulation system includes a lower insulation panel, an upper insulation panel, a flat joint, a top bridge panel, and a corrugation membrane sheet, and has a standardized predetermined area. The lower insulation panel is fixed to the inner wall of the tank, the upper insulation panel is attached to the upper part of the lower insulation panel, the flat joint is filled in the space between the lower insulation panels when the unit insulation system is arranged, On the panel, an upper insulating panel is attached on the unattached upper surface, and the corrugation membrane sheet is fixed to the upper part of the upper insulating panel and the top bridge panel.

A sawing line is formed in the horizontal and vertical directions at predetermined intervals in order to prevent the hull from being deformed due to expansion and contraction due to cryogenic temperatures. A plurality of metallic inserts are formed at a position spaced apart from the end of the upper insulating panel for use in rail mounting of an Auto Bonding Machine (ABM).

However, in the case where a sawing line disposed on both sides in the longitudinal direction of the upper insulating panel overlaps with the metal insert, it is necessary to mount a metal insert to the automatic bonding device It is inevitable to form it at a position different from the position suitable for rail installation of the rail. Therefore, although the unitary insulation system can be transferred to the manipulator using the metal insert, there arises a problem that the rail interval is different and the automatic bonding apparatus can not be used.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the problems of the prior art as described above, and it is an object of the present invention to provide a heat shielding plate provided at least at one end of an anchor strip and / By compensating for the function of the line, it is possible to form a metal insert on the part without forming a sawing line which overlaps with the metal insert for rail mounting of the automatic bonding apparatus, so that a liquefied natural To provide a tank inner wall structure of a gas carrier.

A tank inner wall structure of a liquefied natural gas carrier according to an embodiment of the present invention includes: a lower heat insulating panel continuously disposed on an inner wall of a tank; An upper heat insulating panel installed above the lower heat insulating panel; A top bridge panel attached on the lower insulating panel between the upper insulating panels; And a membrane sheet disposed above the upper insulating panel, wherein the upper insulating panel is formed at a predetermined interval and includes a sawing line for preventing damage due to deformation of the hull and thermal deformation of the membrane sheet; A metal insert formed at a position spaced apart from the end of the upper insulating panel by a predetermined distance to provide a rail of the automatic bonding device; An anchor strip seated in a groove formed in the upper heat insulating panel; And a heat shield plate formed on at least one end of the anchor strip.

The inner wall structure of the tank of the liquefied natural gas carrier according to the present invention is characterized in that the function of the sawing line is compensated by the gap formed between the upper shield panel and / or the upper shield panel provided at least one end of the anchor strip and / It is possible to form a metal insert on the portion without forming a sawing line overlapping with the rail mounting metal insert of the bonding apparatus, so that the automatic bonding apparatus can be used in all the regions of the tank inner wall.

1 is a plan view of a unit insulation system for explaining a tank inner wall structure of a liquefied natural gas carrier according to an embodiment of the present invention.
2 is a partial cross-sectional view illustrating an arrangement of a unit insulation system for explaining a tank inner wall structure of a liquefied natural gas carrier according to an embodiment of the present invention.
3 is a partially enlarged view of 'A' in FIG.

BRIEF DESCRIPTION OF THE DRAWINGS The objects, particular advantages and novel features of the present invention will become more apparent from the following detailed description taken in conjunction with the accompanying drawings, in which: FIG. It should be noted that, in the present specification, the reference numerals are added to the constituent elements of the drawings, and the same constituent elements are assigned the same number as much as possible even if they are displayed on different drawings. In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail.

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

FIG. 1 is a plan view of a unit insulation system for explaining a tank inner wall structure of a liquefied natural gas carrier according to an embodiment of the present invention, and FIG. 2 is a plan view of a tank inner wall structure of a liquefied natural gas carrier according to an embodiment of the present invention. FIG. 3 is a partial enlarged view of 'A' in FIG. 2. FIG.

1 to 3, a tank inner wall structure of a liquefied natural gas carrier according to an embodiment of the present invention includes a lower insulation panel 10, an upper insulation panel 20, A plurality of unit insulation systems 1 including a flat joint 30, a top bridge panel 40 and a membrane sheet 50 are continuously arranged .

The lower insulating panel 10 is installed on the tank inner wall 2 by a fixing portion 11 such as a stud bolt. When the unit thermal insulation systems 1 are continuously arranged, a flat joint 30 to be described later is installed in a space between facing lower thermal insulation panels 10 to seal the space, and a secondary insulation function do.

The lower insulating panel 10 may be formed of a reinforced polyurethane foam and a rigid triplex (RSB) 12 is installed on the upper surface thereof. A plywood may be provided between the inner wall 2 and the upper surface which is the opposite surface, and a rigid triplex 12 may be provided as mentioned above.

The upper insulating panel 20 may be comprised of a sawing line 21, a metallic insert 22, an anchor strip 23 and a thermal protection 24 , And is attached to the upper part of the lower heat insulating panel (10). When the unit thermal insulation systems 1 are continuously arranged, a top bridge panel 40, which will be described later, is installed in the space between the facing upper insulation panels 20 to seal the space, .

The upper insulating panel 20 can be formed of a reinforced-polyurethane foam and a plywood on the upper surface.

A plurality of sawing lines 21 are formed in the upper insulating panel 20 in a grid shape orthogonal to the longitudinal and transverse directions in order to prevent deformation of the hull due to contraction expansion due to cryogenic temperatures. The spacing between the sawing lines 21 in the longitudinal direction is kept constant as prescribed, but shorter than the distance from the sawing line 21 disposed on both sides in the longitudinal direction to the end of the upper insulating panel 20. It is possible to prevent the deformation of the hull and the deformation of the hull of the membrane sheet 50 due to the wide spacing from the sawing line 21 disposed on both sides in the longitudinal direction to the end of the upper insulating panel 20, It is possible to provide a heat shielding plate 24 to be described later on at least one end of an anchor strip 23 to be described later in order to compensate for the weakening of the function of preventing the heat insulating panels 10 and 20 from being damaged due to thermal deformation, A gap 41 may be formed between the upper insulating panel 20 and a top bridge panel 40 to be described later.

A plurality of metal inserts 22 are formed on the upper insulating panel 20 for transferring the unitary thermal insulating system 1 to a manipulator. The metal insert 22 is also used for rail mounting of an automatic bonding machine (ABM).

The metal insert 22 is formed at a position spaced apart from the end of the upper insulating panel 20 for use in rail mounting of the automatic bonding machine. That is to say that the distance between the metal insert 22 and the end of the upper insulation panel 20 is such that even if a particular unitary insulation system 1 of different sizes is manufactured according to a particular area of the inner wall 2 of the tank, It is constant so that automatic bonding equipment can be used in the area.

The anchor strip 23 is formed with grooves (not designated by reference numerals) on the upper heat insulating panel 20 for fitting and securing the membrane sheet 50 to be described later, and is seated in the grooves. At least one end of the anchor strip 23 or both ends of the horizontal line may be provided with a thermal protection plate 24 to be described later. The anchor strip 23 can be formed using stainless steel material.

The thermal protection plate 24 is provided on at least one end of the anchor strip 23 or at both ends of the horizontal line in the upper insulation panel 20 and the membrane sheet 50 is welded to the upper insulation panel 20 And also has a function of protecting the upper insulating panel 20 from breakage due to the fire when the membrane sheet 50 is welded. The thermal protection plate 24 can be formed using a material that is covered with a glass cross on an aluminum foil.

The flat joints 30 are installed in the space between the lower insulating panels 10 facing each other when the unit thermal insulating systems 1 are arranged so as to perform the secondary thermal insulating function. The flat joint 30 can be formed using a glass wool material.

The top bridge panel 40 is attached to the upper portion of the lower heat insulating panel 10 to which the upper heat insulating panel 20 is not attached and the upper portion of the flat joint 30, The space between the panels 20 is sealed, and the primary insulation function can be performed. The top bridge panel 40 may be formed of a reinforced-polyurethane foam and may be attached to the upper portion of the lower heat insulating panel 10 and the upper portion of the flexible triplex 13 provided on the upper portion of the flat joint 30. [ can do.

The top bridge panel 40 allows the gaps 41 to be formed between the upper insulating panels 20 facing each other when the unit thermal insulating systems 1 are arranged so that the deformation of the hull as a function of the sawing line 21, It is possible to perform the function of preventing the heat insulating panels 10 and 20 from being broken due to thermal deformation of the heat insulating member 50.

The membrane sheet 50 is fixedly connected to the top of the top insulation panel 20 and top bridge panel 40 by anchor strips 23. The membrane sheet 50 may be a corrugation membrane sheet, and may have an embossed shape having top and bottom concavities and convexities.

As described above, the present embodiment is characterized in that the heat shielding plate 24 provided at at least one end of the anchor strip 23 or / and the gap 41 formed between the upper heat insulating panel 20 and the top bridge panel 40 The metal insert 22 can be formed on the portion without forming the sawing line 21 overlapping with the rail mounting metal insert 22 of the automatic bonding apparatus, 2) can use automatic bonding equipment in all areas.

Thus, in the present embodiment, when a specific insulating system of different sizes is manufactured in a specific area of the inner wall of the tank, when the sawing line arranged on both sides in the longitudinal direction in the upper insulating panel overlaps the metal insert, The unitary insulation system can be transferred to the manipulator by using the metal insert. However, since the rail spacing is different and the automatic bonding apparatus can not be used, Can be solved.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the same is by way of illustration and example only and is not to be construed as limiting the present invention. It is obvious that the modification and the modification are possible.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

1: unit insulation system 2: tank inner wall
10: lower insulation panel 11: fixing section
12: Rigid triplex 13: Flexible triplex
20: upper insulation panel 21: sawing line
22: metal insert 23: anchor strip
24: heat shield plate 30: flat joint
40: Top bridge panel 41: Gap
50; Membrane Sheet

Claims (7)

A bottom insulating panel continuously disposed on the inner wall of the tank;
An upper heat insulating panel installed above the lower heat insulating panel;
A top bridge panel attached on the lower insulating panel between the upper insulating panels; And
And a membrane sheet disposed above the upper heat insulating panel,
Wherein the upper insulating panel comprises:
Polyurethane foam;
A plywood provided on the upper surface of the polyurethane foam;
A sawing line formed at regular intervals, for preventing deformation of the hull and damage due to thermal deformation of the membrane sheet;
A metal insert formed at a position spaced apart from the end of the upper insulating panel by a predetermined distance to provide a rail of the automatic bonding device;
An anchor strip seated in a groove formed in the upper heat insulating panel; And
And a heat shield plate formed on at least one end of the anchor strip,
The heat-
And is disposed in parallel with the anchor strip to prevent the membrane sheet from being welded to the upper heat insulating panel. The heat exchanger according to claim 1,
Wherein a flat joint is provided in a space between facing lower heat insulating panels and a flexible triplex is provided on an upper portion of the flat joint to seal the space. The method according to claim 1,
Wherein the spacing from the sawing line disposed on both sides in the longitudinal direction to the end of the upper insulating panel is larger than a distance between the sawing lines in the longitudinal direction in a lattice form in the transverse and longitudinal directions, Structure of tank inner wall of carrier. The method according to claim 1,
Wherein the distance between the metal insert and the end of the upper insulating panel is constant. The heat exchanger according to claim 1,
Wherein the liner is formed at both ends of a horizontal line of the anchor strip to prevent deformation of the hull. The heat exchanger according to claim 1,
Characterized in that the inner wall structure of the tank of the liquefied natural gas carrier is formed by using a material that covers the glass cloth on the aluminum foil. The apparatus of claim 1, wherein the top bridge panel comprises:
And a gap is formed between the upper insulating panel and the upper insulating panel so as to prevent deformation of the hull.

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