KR20230051359A - Insulation structure for liquified gas storage tank and method for forming the insulation structure - Google Patents

Abstract

The present invention is to provide an insulation structure of a liquefied gas storage tank that can function as an auxiliary barrier when a leak of liquefied gas occurs on the outer wall of the tank, and a method of forming the insulation structure. The present invention relates to an insulation structure of a liquefied gas storage tank for insulating the liquefied gas stored inside a tank body. The insulation structure of a liquefied gas storage tank comprises: a composite layer installed to surround the tank body; an insulating part formed by being applied on the composite layer; and a fixing part for fixing the composite layer to the tank body. The composite layer is composed of a watertight or airtight metal film and a glass fiber-based reinforcement sheet laminated.

Description

The insulation structure of the liquefied gas storage tank and the method of forming the insulation structure of the liquefied gas storage tank

The present invention relates to an insulation structure of a liquefied gas storage tank for storing liquefied gas, and more particularly, in forming an insulation layer on the outer wall of the tank by a spraying method, the soundness of the insulation layer is secured to maintain the insulation performance and at the same time leak gas It relates to a thermal insulation structure of a liquefied gas storage tank that can have a broad function of a secondary barrier for effective detection and discharge of and a method of forming the thermal insulation structure of the liquefied gas storage tank.

Due to the recent strengthening of environmental pollution regulation standards for ships, interest in eco-friendly and highly efficient liquefied gas fuels such as liquefied natural gas (LNG) or liquefied petroleum gas (LPG) this is increasing

Liquefied natural gas is obtained by cooling and liquefying methane obtained by refining natural gas collected from gas fields. .

In particular, liquefied natural gas (hereinafter referred to as 'LNG') is obtained by cooling natural gas to an extremely low temperature (about -163 ° C), and its volume is reduced to about 1/600 of that of gaseous natural gas, so it is safe to use the sea. It is very suitable for transport over long distances.

Liquefied gas is transported in a gaseous state through onshore or offshore gas pipelines, or transported in a liquid state to a distant consumer while stored on a transport ship.

A liquefied gas carrier for loading and unloading liquefied gas such as LNG by sea and loading and unloading liquefied gas to a place on land, or a liquefied gas carrier carrying LNG and navigating the sea and arriving at a place on land, regasifying stored LNG and unloading it in the form of natural gas A liquefied gas storage tank (commonly referred to as a 'cargo hold') that can withstand the cryogenic temperature of LNG is provided in an LNG RV (Regasification Vessel)

In addition, LNG FPSO (Floating, Production, Storage and Offloading) used to liquefy and store produced natural gas directly at sea, and to transfer stored LNG to LNG carriers when necessary, and to store LNG unloaded from LNG carriers at sea. Liquefied gas storage tanks installed in LNG carriers or LNG RVs are also included in offshore structures such as LNG Floating Storage and Regasification Units (FSRUs) that vaporize LNG as needed and supply it to onshore consumers.

These liquefied gas storage tanks can be classified into a membrane type and an independent type depending on whether the cargo load directly acts on the insulation.

Membrane type storage tanks are divided into No 96 type and Mark III type, and independent storage tanks are divided into Type A, Type B, and Type C according to the regulations of the International Maritime Organization (IMO), among which Type B independent type Storage tanks include a spherical type MOSS tank and a prismatic type SPB tank.

The membrane type storage tank is directly connected to the hull structure and is not separated from the hull structure, and has a structure in which a primary barrier and a secondary barrier are stacked on the inner wall of the hull. As the membrane type tank is directly connected to the hull, the load of the liquefied gas stored inside is transmitted to the hull without the storage tank supporting it.

On the other hand, the independent storage tank is manufactured in a form that is separated from the structure of the hull and mounted on the hull, and has a structure in which an insulating material is surrounded by an outer wall of the storage tank. As the independent storage tank is separated from the hull and supported by a support structure provided inside the hull, the load of the liquefied gas stored therein directly acts on the storage tank.

Unlike membrane-type storage tanks, independent storage tanks do not have a complex barrier structure, and are relatively advantageous in terms of structural stability against sloshing compared to membrane-type storage tanks. It has the advantage of facilitating maintenance.

The foregoing technical configuration is a background technology for helping understanding of the present invention, and does not mean the prior art widely known in the technical field to which the present invention belongs.

Republic of Korea Patent Registration No. 10-1034472 "Insulation structure of independent liquefied gas tank and method of forming the same"

Independent storage tanks according to the prior art, polyurethane foam (PUF) on the outer wall of the tank made of an alloy resistant to low temperatures such as aluminum alloy, SUS (Steel Use Stainless), or 9% nickel alloy (9% Nickel steel) Polymeric foam such as Polyurethane Foam is used to form an insulation layer, and it is placed on a separate support structure provided at the bottom of the hull.

In the prior art, the heat insulating layer may be applied by spraying and stacking a spray foam type heat insulating material on the outer wall of the tank for a certain period of time using a device such as a spray gun, and the type of heat insulating material or The thickness is determined according to the thermal insulation performance of the insulator.

The spray type independent liquefied gas storage tank has advantages in terms of insulation performance and production cost because it is easy to work because it is possible to continuously construct an insulation layer on the outer wall of the tank and there is little thermal bridge, but the liquefaction point of liquefied gas is very high. In the case of cryogenic fluids such as low LNG or liquid hydrogen (LH2), there is a possibility of interface damage between the tank outer wall and the insulation layer or separation of the insulation layer from the tank outer wall without enduring the thermal stress due to the extreme temperature difference.

On the other hand, such an independent storage tank can cause fatal damage to the hull, which is vulnerable to cryogenic temperatures, if leaks of liquefied gas occur on the outer wall of the tank. , may have a partial secondary barrier structure for recovery.

That is, a drip tray is installed at the bottom of the storage tank to minimize the direct impact on the hull in the event of a leak of liquefied gas, and the ship construction standard (IGC code; International code for the construction and equipment of ships carrying Design the size of the drip tray by estimating the amount of leakage for 15 days according to liquefied gases in bulk.

Here, a leak path through which the leaked liquefied gas can flow to the drip tray by gravity should be provided between the outer wall of the tank and the insulation layer. In the case of forming the insulation layer by applying a spray foam insulation to the outer wall of the tank, Since the outer wall of the tank and the insulation layer are completely bonded, it is difficult to form a leakage movement path in case of leakage of liquefied gas.

The present invention secures the soundness of the insulation structure by providing a non-bonding type insulation layer and providing a separate insulation layer fixing device, which is not a type in which the insulation layer is directly adhered to the outer wall of the tank, and at the same time, between the outer wall of the tank and the insulation layer It is an object of the present invention to provide a heat insulation structure of a liquefied gas storage tank and a method of forming the heat insulation structure that can perform the function of an auxiliary barrier when a leak of liquefied gas occurs on the outer wall of the tank by forming a leakage movement path.

According to one aspect of the present invention, a heat insulating structure of a liquefied gas storage tank for insulating liquefied gas stored inside the tank body, comprising: a composite layer installed to surround and surround the tank body; a heat insulating part formed by being coated on the composite layer; And a heat insulating structure of a liquefied gas storage tank including a fixing part for fixing the composite layer to the tank body may be provided.

The composite layer may be formed by laminating a watertight or airtight metal film and a glass fiber-based reinforcing sheet.

In addition, a flow passage forming part installed between the tank body and the composite layer to form a water leakage movement path may be further included.

In addition, the flow path forming part is formed on the lower surface of the composite layer to support the composite layer; and a support pad spaced apart from the outer surface of the tank body to support the support plate.

Also, studs formed on an outer surface of the tank body may sequentially pass through the support pad, the support plate, and the composite layer.

In addition, the support plate and the support pad may be made of an engineering plastic material.

In addition, the support pad may form an empty space between the tank body and the support plate, and one or more grooves may be formed on a lower surface of the support pad that comes into contact with the tank body.

In addition, two or more grooves may be formed in different directions on the lower surface of the support pad.

In addition, the fixing part, an extension member having one end coupled to the stud; a nut member coupled to the other end of the extension member; and washers respectively installed between the stud and one end of the extension member and between the other end of the extension member and the nut member.

In addition, a fixing block installed on the composite layer before forming the heat insulating part may be further included.

In addition, the fixing block may be installed such that a through hole corresponding to a diameter of the extension member is formed to surround the circumference of the extension member.

In addition, concave grooves may be formed at upper and lower portions of the fixing block to provide a space in which the washer member or the washer member and the nut member are accommodated.

In addition, the extension member, the washer member, and the nut member may be made of an engineering plastic material.

In addition, a reinforcing part installed in the heat insulating part may be further included to prevent propagation of cracks in the thickness direction of the heat insulating part.

In addition, the reinforcing part may include a first anti-crack layer installed on an upper surface of the fixing block.

In addition, the heat insulating part may include a first heat insulating layer, a second heat insulating layer, and a third heat insulating layer sequentially formed in a direction away from the outer surface of the tank body.

In addition, the first heat insulating layer may be formed to have the same thickness as the fixing block, and the first crack prevention layer may be installed between the first heat insulating layer and the second heat insulating layer.

According to another aspect of the present invention, a method of forming a thermal insulation structure of a liquefied gas storage tank for insulating liquefied gas stored inside the tank body, comprising: installing a composite layer on an outer surface of the tank body to surround the tank body; and forming a thermal insulation unit by applying a spray foam thermal insulation material on the composite layer.

The composite layer may be formed by laminating a watertight or airtight metal film and a glass fiber-based reinforcing sheet.

In addition, before the step of installing the composite layer, a step of installing a flow path forming part for forming a leak movement path of the liquefied gas leaked to the outer surface of the tank body between the tank body and the composite layer may be further included. .

In addition, the flow path forming part may be fixed to the tank body through a fixing part coupled to a stud formed on an outer surface of the tank body.

In addition, the passage forming part and the fixing part may be made of an engineering plastic material.

According to the present invention, by installing a liquid-tight or water-tight composite layer between the tank body and the heat insulation unit, it is possible to minimize penetration of liquefied gas leaking from the tank body into the insulation unit.

In addition, it is possible to secure a leak movement path for movement of leaked liquefied gas through an empty space between the tank body and the support plate and a groove formed on the lower surface of the support pad.

In addition, since the support plate and support pad constituting the flow path forming part are made of engineering plastic material, it is possible to avoid the risk of damage due to the difference in heat shrinkage between the interface of the tank body and the insulation part, and it is effective in promptly detecting and discharging leaked liquefied gas. can

In addition, by installing a fixing block on the composite layer, the spray foam insulator is adhered to the outer surface of the fixing block in the process of forming the insulator, thereby improving the fixing force of the insulator.

In addition, a fixing block is installed on the composite layer before forming the insulator to improve the fixing power of the insulator, but through an extension member coupled to the stud and a washer member and a nut member coupled to the extension member, the composite layer and the fixing block By tightly fixing to the tank body, it is possible to secure the soundness of the insulation structure.

In addition, the extension member, washer member, and nut member constituting the fixing part are made of engineering plastic material, so they can have a relatively low thermal conductivity compared to SUS, and minimize heat loss. Advantageous effect of securing stable fixing force can have

In addition, direct contact between the heat insulating part and the fixing part can be blocked through the recess structure formed on the upper and lower parts of the fixed block and the reinforcing part disposed on the upper surface of the fixed block, and the risk of breakage of the insulating material due to the fixing part can be avoided.

1 is a view schematically showing a portion of a cross section of a thermal insulation structure of a liquefied gas storage tank according to an embodiment of the present invention.
FIG. 2 is a view separately showing the configuration of the passage forming part shown in FIG. 1 .
Figure 3 is a view showing the configuration of the fixing portion shown in Figure 1, respectively.
Figure 4 is a perspective view showing the fixed block shown in Figure 1;

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

First, in adding reference numerals to components of each drawing, it should be noted that the same components have the same numerals as much as possible even if they are displayed on different drawings.

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

Preferred embodiments of the present invention will be described below, but the technical spirit of the present invention is not limited or limited thereto and can be modified and implemented in various ways by those skilled in the art, of course.

In the description of the present invention, liquefied gas is generally liquefied, such as cryogenic (approximately -163 ° C) LNG (Liquified Natural Gas), LPG (Liquefied Petroleum Gas) or liquefied ethylene gas (Liquefied Ethylene Gas). It may include all gaseous fuels stored as , and liquefied gas may mean liquefied gas as well as liquefied gas in a liquid state.

1 is a view schematically showing a part of the cross section of a heat insulation structure of a liquefied gas storage tank according to an embodiment of the present invention, and FIGS. 2 and 3 separate the configuration of the flow path forming part and the fixing part shown in FIG. 1 4 is a perspective view of the fixed block shown in FIG. 1 .

The present invention relates to an insulation structure (100) of a liquefied gas storage tank for insulating liquefied gas stored inside a tank body (10), and is provided separately from the structure of a hull and is manufactured in a form mounted on the hull. It can be applied to the tank, preferably a heat insulating layer installed to surround the outside of the tank body 10 that serves as a primary barrier and a drip tray that temporarily stores liquefied gas leaked from the lower portion of the tank body 10 It can be applied to Type B independent liquefied gas storage tanks including

Here, the tank body 10 may be made of an alloy that is resistant to low temperatures, such as aluminum alloy, SUS (Steel Use Stainless), or 9% nickel alloy, and is preferably inexpensive. It can be made of a high-Mn steel material that is inexpensive and has excellent resistance to brittleness at low temperatures and can withstand extremely low temperatures.

Referring to FIG. 1, the insulation structure 100 of the liquefied gas storage tank according to an embodiment of the present invention is to insulate the liquefied gas stored inside the tank body 1, and surrounds the tank body 10. A composite layer 110 installed so as to be installed, an insulation part 130 formed by being applied on the composite layer 110, and a fixing part 150 for fixing the composite layer 110 to the outer surface of the tank body 10 can include

The composite layer 110 is installed to surround the tank body 10, and studs 11 formed on the outer surface of the tank body 10 are inserted through the tank through a fixing part 150 to be described later. It may be fixed to the outside of the body 10.

In this embodiment, the stud 11 is installed vertically on the outer surface of the tank body 10 through a welding method or the like before installing the composite layer 110, and may be made of the same material as the tank body 10. there is.

On the composite layer 110 of this embodiment, a through hole (not marked) having the same or similar size as the diameter of the stud 11 may be formed in advance, and the stud 11 protrudes through the composite layer 110. can be formed to

In addition, although not shown in detail in the drawings, the composite layer 110 of this embodiment is a metal film capable of being liquid tight or air tight, such as an aluminum film, from the outside of the tank body 10. And a glass fiber-based reinforcing sheet may be laminated.

In this embodiment, the metal film may be made of a metal material that is resistant to low-temperature brittleness, such as aluminum, and has watertight or airtight characteristics in an area except for a portion where the stud 11 is inserted through, so that the leaked liquefied gas escapes from the heat insulating portion. (130) can be minimized.

The composite layer 110 is a spray foam insulator forming the insulator 130 by disposing (or stacking) a glass fiber-based reinforcing sheet on the upper surface of the metal film, more specifically, on the surface facing the insulator 130. It is possible to improve adhesion with and reduce the possibility of cracks occurring in the heat insulating part 130 in a cryogenic environment.

The composite layer 110 of this embodiment may be provided in the form of a single large sheet to cover the entire outer surface of the tank body 10, but is divided into a plurality of unit sheets to improve installation convenience. ) may be installed in close contact with each other on the outer surface of the

In the heat insulation structure 100 of the liquefied gas storage tank according to an embodiment of the present invention, a liquid-tight or water-tight composite layer 110 is installed between the tank body 10 and the heat insulation unit 130, so that the tank body ( It is possible to minimize the penetration of liquefied gas leaking from 10) into the heat insulating unit 130.

In this embodiment, it can be taken for granted that the composite layer 110 may be formed by laminating the metal film and the reinforcing sheet in three stages, four stages, or more, if necessary.

As shown in FIG. 1, the heat insulation structure 100 of the liquefied gas storage tank according to an embodiment of the present invention is installed between the tank body 10 and the composite layer 110 to form a water leak movement path. A forming unit 120 may be further included.

The insulation structure 100 of the liquefied gas storage tank according to an embodiment of the present invention leaks from the tank body 10 through the composite layer 110 installed between the tank body 10 and the insulation unit 130. In addition to minimizing the penetration of the liquefied gas into the thermal insulation unit 130, it is intended to provide a movement path for the leaked liquefied gas.

The flow path forming part 120 includes a support plate 121 formed on the bottom surface of the composite layer 110 to support the composite layer 110 and a support plate 121 spaced apart from the outer surface of the tank body 10. A pad 123 may be included.

The support plate 121 is installed to surround the tank body 10 between the tank body 10 and the composite layer 110, and supports the tank body 10 on the support pad 123 having a predetermined size. It can be separated from the exterior.

Similar to the composite layer 110, the support plate 121 of this embodiment may be provided in the form of one large sheet to cover the entire outer surface of the tank body 10, but as shown in FIG. Likewise, it may be divided into a plurality of unit sheets and installed in close contact with each other on the outer surface of the tank body 10.

The support pad 123 is for maintaining a constant distance between the tank body 10 and the support plate 121, and between the tank body 10 and the support plate 121 Void space (unsigned) can form

The support pad 123 of this embodiment may have a through hole 123a through which the stud 11 formed on the outer surface of the tank body 10 passes through in the center, and on the lower surface in contact with the tank body 10 One or more grooves 123b may be formed.

Referring to (b) of FIG. 2, the support pad 123 of this embodiment has a rectangular planar shape, and two grooves 123b are formed long in directions orthogonal to each other on the lower surface of the support pad 123 Although it is shown that it is, the present invention is not limited thereto, and the support pad 123 of this embodiment may have various shapes such as circular or polygonal.

In addition, the number of grooves 123b formed on the lower surface of the support pad 123 may be variously applied in consideration of the shape (or size) of the support pad 123 and the amount of leaking liquefied gas. It may be preferable to form two or more in different directions on the lower surface of (123).

In this embodiment, the shape of the groove 123b of the support pad 123 is not particularly limited as long as the leaked liquefied gas can flow smoothly, but may preferably have a semicircular or elliptical cross-sectional shape.

In the flow path forming part 120 of this embodiment, the support pad 123, the support plate 121, and the stud 11 sequentially penetrating the composite layer 110 may be combined with a fixing part 150 to be described later and fixed. there is.

The insulation structure 100 of the liquefied gas storage tank according to an embodiment of the present invention includes an empty space between the tank body 10 and the support plate 121 and a groove 123b formed on the lower surface of the support pad 123 Through this, it is possible to secure a leak path for the movement of leaked liquefied gas.

In this embodiment, the support plate 121 and the support pad 123 constituting the passage forming part 120 may be made of an engineering plastic (EP) material.

In other words, engineering plastic (EP) is different from general plastics such as polyethylene and polypropylene, and has excellent strength and elasticity, so it cannot be easily deformed or damaged under extreme temperature conditions. .

In this embodiment, the use temperature of the engineering plastic (EP) is from room temperature to a cryogenic temperature of -163 ° C or less.

In the flow path forming part 120 of this embodiment, the polarity of engineering plastic (EP) may not be considered, and a material without additional reinforcement such as glass fiber or carbon, such as non-polar PTFE (Polytetra fluoroethylene) can be made with

In the heat insulation structure 100 of the liquefied gas storage tank according to an embodiment of the present invention, the flow path forming part 120 for the movement of the liquefied gas leaked between the outer surface of the tank body 10 and the composite layer 110 is provided. However, since the support plate 121 and the support pad 123 constituting the flow path forming part 120 are made of engineering plastic (EP) material, the heat shrinkage difference between the interface between the tank body 10 and the heat insulating part 130 It is possible to avoid the risk of damage due to this, and it can be effective in promptly detecting and discharging leaked liquefied gas.

The heat insulating unit 130 may be formed by applying a spray foam heat insulating material on the composite layer 110, considering the size of the tank body 10 or the type or density of the heat insulating material applied on the composite layer 110. It may have a thickness capable of ensuring sufficient thermal insulation performance.

The heat insulation unit 130 of this embodiment may form one or more layers in order to store the liquefied gas stored inside the tank body 10 .

Hereinafter, for convenience of description, the heat insulating unit 130 of this embodiment will be described as an example in which three layers are formed by spraying and stacking a heat insulating material on the composite layer 110 a plurality of times, and the outer surface of the tank body 10 It is divided into a first heat insulating layer 131, a second heat insulating layer 133, and a third heat insulating layer 135 in a direction away from .

In other words, the heat insulating unit 130 of this embodiment is formed of three layers by sequentially installing the first heat insulating layer 131, the second heat insulating layer 133, and the third heat insulating layer 133 on the composite layer 110. can

In this embodiment, the first to third heat insulating layers 131, 133, and 135 may be formed by spraying and stacking a heat insulating material having the same material and density a plurality of times, and the first to third heat insulating layers ( At least one of 131, 133, and 135) may be formed with a density different from the rest.

In addition, when the first to third heat insulating layers 131, 133, and 135 are applied with different densities, it may be preferable to form a higher density as they are relatively closer to the tank body 10, and the higher the density, the higher the density. It may be desirable to form a thin thickness.

On the other hand, by installing the composite layer 110 and the flow path forming part 120 between the tank body 10 and the heat insulating part 130, the difference in thermal expansion coefficient between the tank body 10 and the heat insulating part 130 causes Although stress can be relieved, since the insulator 130 can be separated from the composite layer 110 in a cryogenic environment, it is necessary to fix the insulator 130 to the tank body 10.

The heat insulating structure 100 of the liquefied gas storage tank according to an embodiment of the present invention may further include a fixing block 140 installed on the composite layer 110 before forming the heat insulating part 130 .

The fixing block 140 serves to improve the fixing power of the insulator 130 by attaching the spray foam insulation to the outer surface of the fixing block 140 in the process of forming the insulator 130, and is made of polyurethane foam. It may be fixedly installed on the composite layer 110 by the fixing part 150 before forming the heat insulating part 130 .

Hereinafter, in describing the insulation structure 100 of this embodiment, the configuration of the fixing part 150 will be described first, and the fixing block 140 will be described later.

The fixing part 150 includes an extension member 151 having one end coupled to the stud 11 to fix the composite layer 110 and the other end extending in an outward direction of the tank body 10, and the stud 11 Alternatively, a washer member 153 fitted to the outer circumferential surface of the distal end of the extension member 151 may be included.

The extension member 151 may have a larger diameter than the stud 11 in order to accommodate the end of the stud 11 protruding on the composite layer 110, and a thread formed on the outer circumferential surface of the stud 11 (not shown). ) Correspondingly, a screw groove 151a (see FIG. 3 (a)) may be formed on the inner circumferential surface of one end.

The washer member 153 may be fitted to the stud 11 to be positioned on the composite layer 110 before the extension member 151 is coupled to the outer circumferential surface of the stud 11, and the stud 11 and the extension member ( 151) can be located between.

In this embodiment, an insertion hole 153a corresponding to the diameter of the end of the stud 11 (see (b) of FIG. 3) may be formed at the center of the washer member 153.

The washer member 153 of this embodiment may be formed to have an inner diameter equal to or greater than the outer diameter of the stud 11, but smaller in inner diameter than the diameter of one end of the extension member 151.

That is, in the fixing part 150 of this embodiment, one end of the extension member 151 screwed to the outer circumferential surface of the stud 11 at the top of the washer member 153 located on the composite layer 110 is a washer member ( 153), and the position of the composite layer 110 may be fixed through a simple screwing method.

On the other hand, the fixing part 150 of this embodiment may further include a nut member 155 coupled to a screw thread 151b (see FIG. 3(a)) formed on the outer circumferential surface of the other end of the extension member 151. .

In this embodiment, the other end of the extension member 151 may have the same or similar diameter as the end of the stud 11, and the nut member 155 is coupled to the outer circumferential surface of the other end of the extension member 151. A previous washer member 153 may be inserted.

As shown in FIG. 4, the fixing block 140 of this embodiment may have a through hole 140a (see FIG. 4) formed in the center thereof, and an extension member screwed to the outer circumferential surface of the stud 11 through this. It can be installed to surround the periphery of (151).

In addition, the fixing block 140 of this embodiment is installed to surround the periphery of the extension member 151, the composite layer 110 by the nut member 155 fastened to the outer circumferential surface of the other end of the extension member 151 It can be tightly fixed on top.

In this embodiment, a fastening hole 155a corresponding to the screw thread 151b formed on the outer circumferential surface of the other end of the extension member 151 (see FIG. 3(c)) may be formed on the inner circumferential surface of the nut member 155. It may be natural for the washer member 153 to be inserted into the outer circumferential surface of the other end of the extension member 151 before the nut member 155 is coupled.

That is, in the fixing part 150 of this embodiment, the composite layer 110 and the flow path forming part 120 are connected to the tank body 10 through the extension member 151 and the washer member 153 fastened to the stud 11. Anchor ( can serve as an anchor.

In this embodiment, concave grooves (see reference numeral '141' in FIG. 4) are formed in the upper and lower portions of the fixing block 140 to provide a space in which the washer member 153 and the nut member 155 are fastened. can

In the heat insulating structure 100 of a liquefied gas storage tank according to an embodiment of the present invention, a fixing block for improving the fixing power of the heat insulating part 130 on the composite layer 110 before forming the heat insulating part 130 140 is installed, but through the extension member 151 coupled to the stud 11 and the washer member 153 and nut member 155 coupled to the extension member 151, the composite layer 110 and the fixed block By tightly fixing the 140 to the tank body 10, it is possible to have an effect of securing the soundness of the insulation structure.

In this embodiment, the extension member 151 constituting the fixing part 150, the washer member 153, and the nut member 155 are, like the flow path forming part 120, made of engineering plastic (EP) material. It may be desirable to make

The fixing part 150 made of this material may have a relatively low thermal conductivity compared to SUS, and may have an advantageous effect of securing a stable fixing force while minimizing heat loss.

On the other hand, when liquefied gas leaks on the outer surface of the tank body 10, even if a leak movement path is formed between the tank body 10 and the heat insulation portion 130, the gap between the tank body 10 and the heat insulation portion 130 Due to the increase in pressure, the heat insulating material constituting the heat insulating part 130 contracts or relaxes, and cracks may occur or propagate.

The insulation structure 100 of the liquefied gas storage tank according to an embodiment of the present invention may further include a reinforcement part 170 installed in the insulation part 130.

The reinforcing part 170 may be provided in the form of a mesh made of glass fiber or SUS material, and may serve as a crack arrester for preventing the propagation of cracks in the thickness direction of the heat insulating part 130 .

The reinforcing part 170 of this embodiment may serve to prevent separation of the heat insulating part 130 due to a pressure rise due to leakage of liquefied gas or an external shock in a cryogenic environment.

In this embodiment, the reinforcement part 170 may be necessarily disposed on the upper surface of the fixing block 140, and one or more may be preferably disposed according to the thickness of the heat insulating part 130.

The insulation structure 100 of the liquefied gas storage tank according to an embodiment of the present invention includes a recess structure formed on the upper and lower portions of the fixing block 140 and a reinforcement part 170 disposed on the upper surface of the fixing block 140. Through this, direct contact between the heat insulating part 130 and the fixing part 150 can be blocked, and the risk of damage to the spray foam heat insulating material caused by the fixing part 150 can be avoided.

In this embodiment, it may be preferable that the first heat insulation layer 131 formed by initially applying on the composite layer 110 has the same thickness as or similar to that of the fixing block 140 .

1, in the reinforcement part 170 of this embodiment, the first crack prevention layer 171 is installed between the upper surface of the fixing block 140 and the first heat insulating layer 131 and the second heat insulating layer 133, It is shown that the second crack prevention layer 173 is installed between the second heat insulating layer 133 and the third heat insulating layer 135 .

On the other hand, the heat insulation structure 100 of the liquefied gas storage tank according to an embodiment of the present invention is on the heat insulation portion 130 to prevent damage to the insulation portion 130 due to moisture, contamination, or impact from the outside. A formed external coating layer 190 may be further included.

The outer coating layer 190 may be formed on the outer surface of the heat insulator 130 through any one of poly urea coating, metal cladding, and fiber reinforced plastic coating. In addition, various methods may be applied as long as it is configured to block moisture from entering from the outside and prevent damage due to external force.

In the heat insulation structure 100 of the liquefied gas storage tank according to an embodiment of the present invention, a liquid-tight or water-tight composite layer 110 is installed between the tank body 10 and the heat insulation unit 130, so that the tank body ( It is possible to minimize the penetration of liquefied gas leaking from 10) into the heat insulating unit 130.

In addition, through the empty space between the tank body 10 and the support plate 121 and the groove 123b formed on the lower surface of the support pad 123, a leak movement path for the movement of leaked liquefied gas can be secured. .

In addition, since the support plate 121 and the support pad 123 constituting the flow path forming part 120 are made of engineering plastic (EP) material, due to the difference in heat shrinkage between the interface between the tank body 10 and the heat insulating part 130 The risk of damage can be avoided, and it can be effective in promptly detecting and discharging leaked liquefied gas.

In addition, by installing the fixing block 140 on the composite layer 110, the spray foam insulation is adhered to the outer surface of the fixing block 140 in the process of forming the heat insulating portion 130 to improve the fixing power of the heat insulating portion 130. can

In addition, a fixing block 140 is installed on the composite layer 110 before forming the heat insulating part 130 to improve the fixing power of the heat insulating part 130, but the extension member 151 coupled to the stud 11 ) and by closely fixing the composite layer 110 and the fixing block 140 to the tank body 10 through the washer member 153 and the nut member 155 fastened to the extension member 151, the soundness of the insulation structure can be obtained.

In addition, the extension member 151, the washer member 153, and the nut member 155 constituting the fixing part 150 are made of engineering plastic (EP) material, so they can have a relatively low thermal conductivity compared to SUS, It may have an advantageous effect of securing a stable fixing force while minimizing heat loss.

In addition, direct contact between the heat insulating part 130 and the fixing part 150 can be blocked through the recess structure formed on the upper and lower parts of the fixing block 140 and the reinforcing part 170 disposed on the upper surface of the fixing block 140. And, it is possible to avoid the risk of breakage of the heat insulating material due to the fixing part 150.

The insulation structure 100 of the liquefied gas storage tank according to the present invention can be applied to any of the offshore structures used while floating in the sea where flow occurs, and can be applied to liquefied gas carriers or LNG RVs that transport LNG or LPG. It can be applied to ships such as LNG Regasification Vessel, as well as offshore plants such as LNG Floating, Production, Storage and Offloading (FPSO) or LNG Floating Storage and Regasification Unit (FSRU).

The above description is merely an example of the technical idea of the present invention, and those skilled in the art can make various modifications, changes, and substitutions without departing from the essential characteristics of the present invention. will be.

The embodiments disclosed in the present invention and the accompanying drawings are not intended to limit the technical idea of the present invention, but to explain, and the scope of the technical idea of the present invention is not limited by these embodiments and the accompanying drawings.

In addition, the protection scope of the present invention should be construed according to the claims below, and all technical ideas within the equivalent range should be construed as being included in the scope of the present invention.

10: tank body
11: Stud
100: insulation structure
110: Composite layer
120: flow path forming unit
121: Supporting plate
123: Supporting pad
130: heat insulation
131: first insulating layer
133: second heat insulating layer
135: third insulating layer
140: fixed block
150: fixing part
151: Extender
153: washer member
155: nut member
170: crack arrester
171: first anti-crack layer
173: second anti-crack layer
190: External coating layer

Claims (16)

As an insulation structure of a liquefied gas storage tank for insulating the liquefied gas stored inside the tank body,
a composite layer installed to surround and surround the tank body;
a heat insulating part formed by being coated on the composite layer; and
A fixing part for fixing the composite layer to the tank body,
The composite layer,
Insulation structure of a liquefied gas storage tank composed of a metal film that can be watertight or airtight and a glass fiber-based reinforcing sheet laminated. According to claim 1,
The insulation structure of the liquefied gas storage tank further comprising a flow path forming part installed between the tank body and the composite layer to form a leak movement path. According to claim 2,
The flow path forming part,
a support plate formed on a lower surface of the composite layer to support the composite layer; and
A thermal insulation structure of a liquefied gas storage tank including a support pad that supports the support plate spaced apart from the outer surface of the tank body. According to claim 3,
The stud formed on the outer surface of the tank body sequentially penetrates the support pad, the support plate, and the composite layer. According to claim 3,
The support plate and the support pad are a thermal insulation structure of a liquefied gas storage tank made of an engineering plastic material. According to claim 3,
The support pad,
An empty space is formed between the tank body and the support plate,
Insulation structure of a liquefied gas storage tank in which one or more grooves are formed on the lower surface in contact with the tank body. According to claim 6,
The groove,
Insulation structure of a liquefied gas storage tank formed at least two in different directions on the lower surface of the supporting pad. According to claim 4,
The fixing part,
an extension member having one end coupled to the stud;
a nut member coupled to the other end of the extension member; and
The insulating structure of the liquefied gas storage tank comprising a washer member installed between the stud and one end of the extension member and between the other end of the extension member and the nut member, respectively. According to claim 8,
Further comprising a fixing block installed on the composite layer before forming the heat insulating part,
The fixed block,
A heat insulation structure of a liquefied gas storage tank in which a through hole corresponding to a diameter of the extension member is formed and installed to surround the circumference of the extension member. According to claim 9,
A heat insulation structure of a liquefied gas storage tank in which a concave groove is formed on the upper and lower portions of the fixing block to provide a space in which the washer member or the washer member and the nut member are accommodated. According to claim 8,
The extension member, the washer member and the nut member are a thermal insulation structure of a liquefied gas storage tank made of an engineering plastic material. According to claim 10,
Further comprising a reinforcement part installed in the heat insulating part to prevent the propagation of cracks in the thickness direction of the heat insulating part,
The insulation structure of the liquefied gas storage tank comprising a first anti-crack layer installed on the upper surface of the reinforcing unit. According to claim 12,
the insulator,
A first heat insulating layer, a second heat insulating layer, and a third heat insulating layer sequentially formed in a direction away from the outer surface of the tank body,
The first heat insulating layer is formed to have the same thickness as the fixing block, and the first heat insulating layer is installed between the first heat insulating layer and the second heat insulating layer. A method of forming a heat insulation structure of a liquefied gas storage tank for insulating liquefied gas stored inside the tank body,
installing a composite layer on an outer surface of the tank body to surround the tank body; and
Forming a heat insulating part by applying a spray foam heat insulating material on the composite layer,
The method of forming a heat insulation structure of a liquefied gas storage tank in which the composite layer is formed by laminating a watertight or airtight metal film and a glass fiber-based reinforcing sheet. According to claim 14,
The liquefied gas storage tank further comprising installing a flow path forming part for forming a leak movement path of the liquefied gas leaked to the outer surface of the tank body between the tank body and the composite layer before the step of installing the composite layer. A method of forming an adiabatic structure. According to claim 15,
The flow path forming part is fixed to the tank body through a fixing part coupled to a stud formed on an outer surface of the tank body,
The flow path forming part and the fixing part are made of engineering plastic material.

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