KR20200093819A - Dome barrier structure of independence type storage tank - Google Patents

Abstract

Disclosed is a dome barrier structure for an independent type storage tank, which performs insulating and sealing functions around a dome installed on an upper portion of the independent type storage tank. The dome barrier structure for an independent type storage tank includes: a side surface insulating material (44) installed around a dome body (42) extended from a tank body (22) of the independent type storage tank to the top; an upper insulating material (48) installed on an upper portion of a dome cover (46) covering an upper portion of the dome body; and a cover side surface insulating material (60) installed on a side surface of the dome cover.

Description

Dome barrier structure of a standalone storage tank {DOME BARRIER STRUCTURE OF INDEPENDENCE TYPE STORAGE TANK}

The present invention relates to a dome barrier structure of a stand-alone storage tank for storing liquefied gas such as LNG or LPG, and more specifically, around a dome installed on the top of a stand-alone storage tank to allow various pipes to pass through. It relates to a dome barrier structure that performs an insulating and sealing function.

Natural gas is transported in gaseous form through on-shore or offshore gas piping, or stored in LNG carriers in the form of liquefied liquefied natural gas (LNG) or liquefied petroleum gas (LPG) and transported to remote consumers. Liquefied natural gas is obtained by cooling natural gas to an extremely low temperature (approximately -163°C), and its volume is reduced to approximately 1/600 than that of natural gas in gas, so it is very suitable for long-distance transportation by sea.

A liquefied gas carrier for carrying liquefied gas such as LNG or LPG and operating the sea to unload the liquefied gas shipped from the production site is a storage tank (commonly referred to as a'cargo') that can withstand the cryogenic temperature of liquefied gas. Includes.

In addition to the liquefied gas carrier, the storage tank capable of receiving the liquefied gas may be installed in a floating plant such as LNG FPSO (Floating, Production, Storage and Offloading), LNG FSRU (Floating Storage and Regasification Unit).

In recent years, ships (LNG propulsion vessels) propelled by engines that use clean fuel, LNG, as fuel to suppress environmental pollution are increasing, and in the case of such LNG propulsion vessels, liquefied gas storage tanks capable of storing LNG as fuel It is mounted. In addition, as the number of LNG propulsion vessels increased, a fuel bunkering ship (LNG bunkering ship) was developed to supply fuel to the LNG propulsion vessel for refueling, and the liquefied gas storage tank is also installed inside the hull.

As such, LNG carriers, LNG RVs, LNG propulsion vessels, and fuel supply ships that transport or store liquefied gases such as LNG as cargo or store them as fuel, or LNG in floating plants such as LNG FPSO, LNG FSRU, etc. A liquefied gas storage tank for storing liquefied gas in a cryogenic state is installed.

Liquefied gas storage tanks can be classified into an independent type and a membrane type according to whether a load of a cargo directly acts on an insulating material. Usually, the membrane storage tank is divided into GT NO 96 type and TGZ Mark III type, and the independent storage tank can be divided into MOSS type and SPB type.

Stand-alone storage tanks can be classified as type A, type B, type C, etc. according to the classification criteria in the IMO IGC code. Among them, in general, in the case of an IMO type A tank, there is a problem in that it is impossible to implement a secondary barrier for cryogenic cargo such as LNG with steel used for the hull. In addition, in the case of an IMO type C tank, there is a problem that it is difficult to manufacture a large-capacity tank as a pressure vessel type tank.

In view of this, IMO type B tanks are in the spotlight as standalone storage tanks used to transport or store cryogenic liquefied gases such as LNG. In general, the IMO type B tank among stand-alone storage tanks is made by attaching a relatively hard insulation panel such as polyurethane to the outside of the tank body made of metal having good properties at cryogenic temperatures, such as stainless steel and aluminum alloy, and the inner bottom of the hull. It is placed on a plurality of tank supports arranged in. The structure of the tank support for supporting the independent storage tank is described in Japanese Patent Laid-Open No. 60-26900, Japanese Patent Laid-Open No. Hei 7-52870, and Korean Patent No. 10-189306.

1 shows an example of a standalone storage tank.

As illustrated in FIG. 1, the independent storage tank 20 may be installed in a space formed inside the hull 10. The independent storage tank 20 is made of a metal material that can withstand cryogenic temperatures, and the tank body 22 that functions as a primary sealing wall and an insulating layer 24 that is installed to surround the outside of the tank body 22 ) And a drip tray which is installed outside of the heat insulating layer 24 to perform the function of the secondary sealing wall by collecting and temporarily storing the leaked liquid in the event of liquefied gas leakage from the tank body 22.

The drip tray is usually disposed between the stand-alone storage tank 20 and the bottom of the interior space of the hull 10, and in particular, is disposed at a location where the leaked liquid from the tank body 22 flows down and can be collected.

The independent storage tank 20 is seated and supported on a plurality of tank supports 30 arranged at the bottom of the interior space of the hull 10. Each tank support 30 is in contact with the tank body 22 to support the tank body 22, the insulating layer 24 is not formed in a position where the tank support 30 is disposed, shown in Figure 1 Tank support 30 is made of a form that penetrates the heat insulating layer 24 as shown.

In addition, a pipe for loading and unloading liquefied gas or a pipe for discharging boil-off gas generated from the liquefied gas is installed in the independent storage tank 20 in the upper part of the independent storage tank 20, the insulating layer 24 ), a dome 40 (eg, gas dome or liquid dome) extending from the tank body 22 must be formed. The dome 40 formed on the stand-alone storage tank passes through the upper wall 10a of the hull 10 and protrudes from inside the hull to outside the hull.

As described above, the independent storage tank 20 is installed inside the hull by being supported by a plurality of tank supports 30, the tank support 30 is made of wood, including a Wooden Block (32) Can.

When the liquefied gas (LNG, etc.), which is a cryogenic cargo, is loaded into the independent storage tank 20, thermal contraction occurs and thermal expansion occurs when the liquefied gas is unloaded, so that the independent storage tank 20 has a tank body 22, the tank support 30 ). When such thermal deformation occurs, relative behavior may occur between the independent storage tank and the hull. In particular, the upper wall 10a of the hull and the dome 40 of the independent storage tank may be sealed and insulated while allowing such relative behavior. Should be connected.

Figure 2 is a partial cross-sectional view showing an enlarged view around the dome 40 of the stand-alone storage tank, forming the heat insulating layer 24 on the outside of the tank body 22, and attaching the heat insulating material 44 around the dome 40 as well. By doing so, it shows the dome barrier structure of the independent storage tank forming the heat insulating layer.

Referring to FIG. 2, a side heat insulating material 44 is attached around the dome body 42 extending upwardly from the tank body 22, and an upper heat insulating material is applied to the top of the dome cover 46 covering the dome body 42. By attaching (48), a dome barrier structure of a stand-alone storage tank is formed. In addition, a flexible sealing member 50 is installed between the upper wall 10a of the hull and the dome cover 46 to prevent intrusion of outside air.

However, when the dome barrier structure is configured as shown in FIG. 2, thermal insulation is not installed on the side surface of the dome cover 46, and heat is introduced through the side surface of the dome cover 46, and the storage tank There is a concern that the vaporization rate of the liquefied gas contained in the gas may increase.

In addition, the structure of the dome barrier of the stand-alone storage tank, the sealing and insulating barrier between the hull and the dome is broken when heat deformation occurs while the loading and unloading of liquefied gas is repeated or shaking occurs in the storage tank when sailing. There is a possibility that outside air flows in or the insulation performance deteriorates.

The present invention is to solve the above problems, and to provide a dome barrier structure of a stand-alone storage tank capable of stably performing an insulating and sealing function around a dome installed on the stand-alone storage tank.

According to an aspect of the present invention for achieving the above object, as a dome barrier structure of a stand-alone storage tank that performs insulation and sealing functions around the dome installed on the top of the stand-alone storage tank, from the tank body of the stand-alone storage tank A side heat insulating material installed around the dome body extending upward; An upper insulating material installed on an upper portion of the dome cover covering the upper portion of the dome body; A cover side heat insulating material installed on the side of the dome cover; Dome barrier structure of a stand-alone storage tank, characterized in that it can be provided.

The dome barrier structure of the stand-alone storage tank may further include a sealing member installed between the upper wall of the hull and the dome cover to prevent outside air from entering the interior space of the hull.

The cover side heat insulating material may be installed to surround the sealing member.

The cover side heat insulating material may form a continuous heat insulating layer from the top heat insulating material, and the cover side heat insulating material may be installed to extend downward from the top heat insulating material to pass through the dome cover and contact the upper wall of the hull.

The cover side heat insulating material may include a portion having flexibility or elasticity to allow relative behavior between the dome cover and the hull.

The cover side heat insulating material may include a first part attached to the upper heat insulating material to be able to behave together with the dome cover, and a second part attached to the upper wall of the hull so as to be able to behave together with the hull.

The first portion and the second portion may be installed to enable relative movement between each other.

The cover side insulation may be slidably installed on the upper wall of the hull.

According to another aspect of the present invention, an independent storage tank capable of storing liquefied gas, comprising: a tank body made of a metal material capable of withstanding cryogenic temperatures; An insulating layer installed to surround the outside of the tank body; A dome installed on an upper portion of the tank body to provide a passage for the pipe; A dome barrier structure for performing insulation and sealing functions around the dome; Including, the dome barrier structure, the side insulation is installed around the dome body extending upward from the tank body, the upper insulation is installed on top of the dome cover covering the top of the dome body, the dome cover Stand-alone storage tank, characterized in that it comprises a cover side insulation installed on the side of the can be provided.

According to the present invention, a dome barrier structure of a stand-alone storage tank capable of stably performing an insulating and sealing function around a dome installed on the stand-alone storage tank may be provided.

According to the dome barrier structure of the stand-alone storage tank according to the present invention, it is possible to prevent the inflow of heat through the side surface of the dome cover by installing an insulating material on the side surface of the dome cover.

In addition, according to the dome barrier structure of the stand-alone storage tank according to the present invention, even when heat deformation occurs while shipping and unloading of liquefied gas or shaking occurs in the storage tank when sailing, the sealing between the hull and the dome and It is possible to perform a stable insulation and sealing function without breaking the insulation barrier.

1 is a schematic cross-sectional view of a ship equipped with a stand-alone storage tank.
Figure 2 is a partial cross-sectional view showing an enlarged vicinity of the dome of the independent storage tank.
3 is a partial cross-sectional view showing a dome barrier structure of a stand-alone storage tank around a dome according to an embodiment of the present invention.

Hereinafter, a dome barrier structure of a stand-alone storage tank according to a preferred embodiment of the present invention will be described in detail with reference to the drawings.

3 is a partial cross-sectional view showing a dome barrier structure of a stand-alone storage tank around a dome according to an embodiment of the present invention.

As shown in Figure 3, the dome barrier structure of the independent storage tank according to an embodiment of the present invention, the side insulation is installed around the dome body 42 extending upward from the tank body 22 of the independent storage tank (44), the upper heat insulating material (48) installed on top of the dome cover (46) covering the top of the dome body (42), and is installed between the top wall (10a) and the dome cover (46) of the hull of the hull It includes a sealing member 50 to prevent outside air from entering the interior space.

The dome barrier structure of the stand-alone storage tank according to an embodiment of the present invention may further include a cover side heat insulating material 60 installed on the side of the dome cover 46.

The cover side heat insulating material 60 forms a continuous heat insulating layer from the top heat insulating material 48, extends downward from the top heat insulating material 48, passes through the dome cover 46, and is installed to contact the top wall 10a of the hull. do. Accordingly, the sealing member 50 may be wrapped by a cover side heat insulating material 60.

The sealing member 50 seals between the lower surface of the dome cover 46 and the upper surface of the upper wall 10a of the hull, to allow relative behavior between the dome cover 46 and the hull 10 Includes flexible parts.

In addition, the cover side insulation 60 may include portions that are flexible or stretchable to allow relative behavior between the dome cover 46 and the hull 10, similar to the sealing member 50.

The cover side thermal insulator 60 includes a first portion 62 attached to the upper thermal insulator 48 so as to be able to act together with the dome cover 46, and an upper wall of the hull to be able to act together with the hull 10 ( It may include a second portion 64 attached to 10a). At least one of the first portion 62 and the second portion 64 may be made of a material having flexibility or elasticity.

According to one embodiment, the first portion 62 and the second portion 64 may be installed to enable relative movement between each other. For example, the first portion 62 and the second portion 64 may be configured to slidably contact each other.

According to one embodiment, the cover side insulation 60 (eg, the second portion 64) can be slidably installed on the upper wall 10a of the hull.

As described above with reference to FIG. 1, a standalone storage tank having a dome barrier structure according to an embodiment of the present invention may be installed in a space formed inside the hull. Similar to the stand-alone storage tank shown in FIG. 1, the stand-alone storage tank having a dome barrier structure according to an embodiment of the present invention is made of a metal material that can withstand cryogenic temperatures and performs a function of a primary sealing wall. The body 22, the heat insulating layer 24 installed to surround the outside of the tank body 22, and the leakage liquid when the liquefied gas leaks from the tank body 22 is installed outside the heat insulating layer 24 It includes a drip tray (not shown) that performs the function of the secondary sealing wall by collecting and temporarily storing.

The drip tray may be appropriately disposed at a position where multiple pieces are required. The drip tray is disposed, for example, between the tank body of the stand-alone storage tank and the bottom of the interior space of the hull, and in particular, is disposed at a position where the leaked liquid from the tank body can flow and collect.

In the upper portion of the independent storage tank 20, a pipe for loading and unloading liquefied gas to the independent storage tank 20, a pipe for discharging evaporated gas generated from liquefied gas, and the like, are provided with an insulating layer 24. A dome 40 (eg, gas dome or liquid dome) extending from the tank body 22 to penetrate must be formed. The dome 40 formed on the stand-alone storage tank passes through the upper wall 10a of the hull 10 and protrudes from inside the hull to outside the hull. In FIG. 3, various pipes installed to pass through the dome 40 are not shown for convenience.

The independent storage tank is seated and supported on a plurality of tank supports 30 arranged at the bottom of the hull interior space. Each tank support 30 is in contact with the tank body 22 to support the tank body 22, and the insulating layer 24 is not installed at a position where the tank support 30 is disposed.

The heat insulating layer 24 disposed on the outside of the tank body 22 is foamed by spraying or spraying polyurethane on the outer surface of the tank body 22 directly at the manufacturing site of the storage tank. Can be formed by.

Alternatively, the heat insulating layer 24 disposed outside the tank body 22 may be formed by, for example, a plurality of heat insulating panels arranged outside the tank body 22. The insulation panel may be manufactured in a separate place to have a predetermined size and thickness in advance, and then transported to the construction site of the storage tank and attached to the tank body 22. The insulating panel may be made of an insulating material such as, for example, polyurethane (or reinforced polyurethane), and at least one surface (eg, insulating) of the insulating material to prevent damage to the insulating material and facilitate manufacturing and handling. Materials with higher strength than the insulating material may be integrally attached to the upper and lower surfaces of the material.

As described above, according to the dome barrier structure according to an embodiment of the present invention, heat is introduced through the side surface of the dome cover 46 as the cover side insulation 60 is installed on the side surface of the dome cover 46. Can be blocked. Therefore, it is possible to suppress an increase in the vaporization rate of the liquefied gas contained in the storage tank.

In addition, due to the nature of the independent storage tank installed on the tank support in the interior space of the hull, even when thermal deformation occurs in the tank body or shaking or warping occurs during operation, the dome barrier structure according to one embodiment of the present invention According to, the sealing member 50 for sealing between the lower surface of the dome cover 46 and the upper surface of the upper wall 10a of the hull is formed by the cover side heat insulating material 60 to form a structure to be wrapped from the outside. It is possible to secure a more stable sealing and insulation performance.

As described above, although specific embodiments have been described in the detailed description of the present invention, various modifications are possible without departing from the scope of the technical spirit of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined not only by the claims described below but also by the claims and equivalents.

22: tank body (of independent storage tank), 24: thermal insulation layer (of independent storage tank), 30: tank support, 32: wooden block (of tank support), 40: dome, 42: dome body, 44: side insulation, 46: dome cover, 48: top insulation, 50: sealing member, 60: cover side insulation, 62: first part, 64: second part.

Claims (9)

As a dome barrier structure of a stand-alone storage tank that performs insulation and sealing functions around the dome installed on the top of the stand-alone storage tank,
A side heat insulating material installed around the dome body extending upwardly from the tank body of the independent storage tank;
An upper insulating material installed on an upper portion of the dome cover covering the upper portion of the dome body;
A cover side heat insulating material installed on the side of the dome cover;
Dome barrier structure of a stand-alone storage tank comprising a. The method according to claim 1,
A dome barrier structure of a stand-alone storage tank, further comprising a sealing member installed between the upper wall of the hull and the dome cover to prevent outside air from entering the interior space of the hull. The method according to claim 2,
The cover side heat insulating material is installed to surround the sealing member, the dome barrier structure of the independent storage tank. The method according to claim 1,
The cover side heat insulating material forms a continuous heat insulating layer from the top heat insulating material, and the cover side heat insulating material extends downward from the top heat insulating material and is installed to contact the upper wall of the hull through the dome cover. Dome barrier structure. The method according to claim 4,
The cover side insulation material comprises a flexible or stretchable portion to allow relative behavior between the dome cover and the hull, the dome barrier structure of a standalone storage tank. The method according to claim 4,
The cover side heat insulating material includes a first part attached to the upper heat insulating material to be able to behave together with the dome cover, and a second part attached to the upper wall of the hull to be able to behave together with the hull, independent storage. Tank dome barrier structure. The method according to claim 6,
The first portion and the second portion are installed to enable relative movement between each other, the dome barrier structure of the independent storage tank. The method according to claim 4,
The cover side insulation is slidably installed on the upper wall of the hull, the dome barrier structure of the independent storage tank. As a stand-alone storage tank that can store liquefied gas,
A tank body made of a metal material that can withstand cryogenic temperatures;
An insulating layer installed to surround the outside of the tank body;
A dome installed on an upper portion of the tank body to provide a passage for the pipe;
A dome barrier structure for performing insulation and sealing functions around the dome;
It includes,
The dome barrier structure,
It includes a side heat insulating material installed around the dome body extending upward from the tank body, an upper heat insulating material installed on the top of the dome cover covering the top of the dome body, and a cover side heat insulating material installed on the side of the dome cover. Stand-alone storage tank, characterized in that.

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