KR20190033827A - Insulation structure and insulation method of storage tank for cryogenic gas - Google Patents

Abstract

The present invention relates to an insulation structure and an insulation method of a storage tank for cryogenic gas which can reduce heat loss of a storage tank in which cryogenic gas is stored. The insulation structure of a storage tank for cryogenic gas comprises a storage tank, a saddle, an insulation block, a foaming member, and a heat blocking member. The storage tank has a space formed therein, in which cryogenic gas can be stored. The saddle is fixed on the bottom of a hull to support the storage tank. The insulation block is arranged between the storage tank and the saddle to insulate the gap between the storage tank and the saddle. The foaming member is formed to enclose a portion of the insulation block and the storage tank. A portion of the heat blocking member is inserted and fixed on both sides of the insulation block, and the remaining portion is arranged in the foaming member. The insulation method of a storage tank for cryogenic gas comprises: a step of preparing a storage tank having a space formed therein, in which cryogenic gas can be stored; a step of installing an insulation block on a lower portion of the storage tank; a step of placing the storage tank on a saddle fixed on the bottom of a hull to allow the saddle and the insulation block to come in contact; a step of inserting and fixing a portion of a heat blocking member on both sides of the insulation block; and a step of forming insulation foam on an outer surface of the storage tank to form a foaming member enclosing a portion of the insulation block, the heat blocking member exposed to the outside of the insulation block, and the storage tank.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cryogenic gas storage tank,

The present invention provides a heat insulating structure for preventing cold air from flowing out from a storage tank in which cryogenic gas is stored or preventing external heat from flowing into the storage tank, Structure and a method of insulation.

In general, natural gas is transported in a gaseous state via land or sea gas pipelines, or transported to a remote location where it is stored in an LNG carrier in the form of liquefied natural gas (LNG). Liquefied natural gas is obtained by cooling natural gas to a cryogenic temperature (approximately -163), which is very suitable for long distance transport through the sea because its volume is reduced to approximately 1/600 of that of natural gas.

As such natural gas can only be liquefied at very low temperatures of about -163 ° C at atmospheric pressure, it must be stored and transported at this temperature. Therefore, it is necessary to insulate the storage tank to lower the loss of liquefied gas by evaporation.

If insulation of the storage tank is not sufficiently carried out during transportation, the pressure inside the storage tank is increased, which causes the safety of the ship to be threatened. In addition, if the storage tank is insufficiently insulated, the liquefied gas stored in the storage tank is evaporated, and even the property of the liquefied gas is changed to lower the value of the product.

The object of the present invention is to prevent the cool air from flowing out of the storage tank or the external heat from flowing into the storage tank by changing the structure so that the insulation tank of the storage tank storing the cryogenic gas is sufficiently provided, And a method for inspecting a cryogenic gas storage tank capable of maintaining a constant temperature.

According to an aspect of the present invention, there is provided a heat insulating structure for a cryogenic gas storage tank, including a storage tank, a saddle, a heat insulating block, a foam member, and a heat shield member. The storage tank has a space in which the cryogenic gas can be stored. The birds are secured to the bottom of the hull to support the storage tank. An insulating block is disposed between the storage tank and the saddle to insulate between the storage tank and the saddle. The foam member is formed to enclose a part of the storage tank and the heat insulating block. A part of the heat shielding member is inserted and fixed on both side surfaces of the heat insulating block, and the remaining part is disposed in the foaming member.

According to the present invention, there is provided a method for inspecting a cryogenic gas storage tank, comprising the steps of: providing a storage tank in which a space capable of storing cryogenic gas is formed; installing a heat insulating block in a lower portion of the storage tank; Placing the storage tank on the saddle so that the fixed saddle and the heat insulating block are in contact with each other; inserting and fixing a part of the heat shielding member on both sides of the heat insulating block, respectively; and foaming and storing the heat insulating foam on the outer surface of the storage tank Forming a tank, a heat shielding member exposed outside the heat insulating block, and a foaming member surrounding a part of the heat insulating block.

According to the present invention, since the outer peripheral surface of the storage tank in which the cryogenic gas is stored is formed so as to enclose the foam member, it is possible to prevent the cool air in the storage tank from flowing out or flowing outside.

In addition, since both ends of the heat shielding member formed of the triplex material are inserted and fixed to the heat insulating block and the foam member, respectively, the gaps between the heat insulating block and the foam member can be filled, .

Also, by sealing the gap between the heat insulating block and the foam member through the coating part formed of the polymer material, the flow of cool air flowing out from the storage tank can be more effectively blocked, thereby reducing the heat loss of the storage tank in which the cryogenic gas is stored .

In addition, since the storage tank is adequately insulated through the foam member, the heat shielding member, and the coating unit, the pressure inside the storage tank can be kept constant and the cryogenic gas stored in the storage tank can be prevented from being evaporated do.

1 is a side view showing a heat insulating structure of a storage tank for a cryogenic gas according to an embodiment of the present invention;
2 is a sectional view of the AA 'portion shown in FIG. 1;
FIG. 3 is a side view showing the heat blocking member shown in FIG. 1; FIG.
4 is a block diagram of a method for inspecting a storage tank for cryogenic gas according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings. Here, the same reference numerals are used for the same components, and repeated descriptions and known functions and configurations that may obscure the gist of the present invention will not be described in detail. Embodiments of the invention are provided to more fully describe the present invention to those skilled in the art. Accordingly, the shapes and sizes of the elements in the drawings and the like can be exaggerated for clarity.

FIG. 1 is a side view showing a heat insulating structure of a cryogenic gas storage tank according to an embodiment of the present invention, and FIG. 2 is a sectional view taken along the line A-A 'shown in FIG. 3 is a side view illustrating the heat blocking member shown in FIG. 1. FIG.

1 to 3, a heat insulating structure 100 of a storage tank for a cryogenic gas includes a storage tank 110, saddles 120, a heat insulating block 130, a foam member 140, And a heat blocking member 150.

The storage tank 110 has a space in which the cryogenic gas can be stored. For example, in the storage tank 110, a cryogenic gas such as liquefied natural gas (LNG) liquefied at a cryogenic temperature of -163 DEG C, liquefied nitrogen gas (LN2) liquefied at a cryogenic temperature of -196 DEG C and compressed natural gas Can be stored. The storage tank 110 may be formed of a stainless steel material to withstand the internal pressure.

The storage tank 110 may have a bi-lobe shape in which a pair of cylinders are coupled as shown in FIG. When the storage tank 110 is formed in the form of a vibro, there is an advantage that the space can be utilized more efficiently than the storage tank having the cylindrical storage tank 110 and the mechanical stability can be maintained. However, the shape of the storage tank 110 is not limited thereto, and can be implemented in various forms.

The saddle 120 is secured to the bottom of the hull to support a lower portion of the storage tank 110.

The saddle 120 may be formed of stainless steel and welded to the bottom of the hull. The saddles 120 may be disposed on both sides in the longitudinal direction of the storage tank 110, respectively. The number and the size of the saddles 120 are not limited and can be variously modified according to the size of the storage tank 110.

The heat insulating block 130 is disposed between the storage tank 110 and the saddle 120 to insulate the storage tank 110 and the saddle 120. That is, the heat insulating block 130 is made of a material having a low thermal conductivity and serves to prevent the temperature of the storage tank 110 from being transferred to the saddle 120.

The heat insulating block 130 may be formed of FRP (Fiber Reinforced Plastics) or a wood material. FRP is a plastic composite material reinforced with glass and carbon fiber. Since it is light, it has little influence on load increase of saddle 120 and has excellent heat insulation and warming property. Therefore, it is used as insulation material in cryogenic space filled with liquefied natural gas It is advantageous.

Since the wood is light, it has little adverse effect on the load increase of the saddle 120, and is excellent in heat insulation and warmth. Also, since the dimension and strength are stable even in a sudden temperature change, the glass used as a heat insulating material in a cryogenic space filled with liquefied natural gas Do.

The foam member 140 may be formed to enclose the storage tank 110 and a part of the heat insulating block 130. Specifically, the foam member 140 may be formed of polyurethane foam, and the thickness of the foam member 140 may be greater than a distance between the storage tank 110 and the heat shield member 150 .

Since the foaming member 140 made of a polyurethane foam material having a good thermal insulation is formed to enclose a part of the storage tank 110 and the heat insulating block 130, the cool air in the storage tank 110 flows out, It is possible to prevent the heat outside the heat exchanger 110 from flowing into the inside.

A part of the heat shielding member 150 may be inserted and fixed to both sides of the heat insulating block 130 respectively and the remaining part may be disposed in the foam member 140. [ That is, one side of the heat blocking member 150 is inserted and fixed in the heat insulating block 130, and the other side is inserted and fixed in the foam member 140.

In order to insert the heat shielding member 150 into the heat insulating block 130, insertion grooves for inserting the heat shielding member 150 may be formed on both sides of the heat insulating block 130. The heat blocking member 150 may be fixed to the heat insulating block 130 through an interference fit method, but may be fixed to the heat insulating block 130 through an adhesive to improve the fixing force.

Since the heat blocking member 150 is installed on both sides of the heat insulating block 130, it is possible to block the flow of the cold air flowing into the gap between the heat insulating block 130 and the foam member 140. That is, the foam member 140 for inserting the storage tank 110 is inevitably opened at a lower part due to the heat insulating block 130 disposed at the lower portion of the storage tank 110.

As a result, a minute gap is formed between the foam member 140 and the heat insulating block 130 and the cool air of the storage tank 110 can be discharged to the outside through the gap. Therefore, the heat insulating block 130 and the foam member 140 And the heat shielding member 150 is disposed between the heat shield member 150 and the heat shield member 150. Since the gap between the heat insulating block 130 and the foam member 140 is filled with the heat blocking member 150, the flow of cool air flowing out of the storage tank 110 can be blocked.

The heat shielding member 150 may be formed of a flexible material to improve durability. Specifically, the heat shielding member 150 includes a lower glass fiber layer 151, an aluminum foil layer 152 stacked on the lower glass fiber layer, And may be formed of a triplex including an upper glass fiber layer 153. Here, the aluminum foil has a characteristic of being resistant to cold weather because it has high corrosion resistance and moisture resistance, and the glass fiber is excellent in heat resistance, chemical resistance, and heat insulation, and has an advantage of protecting the aluminum foil and improving the heat insulation property.

The heat insulating structure 100 of the cryogenic gas storage tank may further include a coating portion 160 applied to a contact portion between the heat insulating block 130 and the foam member 140. Here, the coating unit 160 may be formed of a polymer material, which is a polymer compound.

Polymers have a low thermal conductivity coefficient compared to metals and have a high insulation effect. Therefore, once the gap between the heat insulating block 130 and the foam member 140 is sealed through the coating portion 160 formed of the polymer material, the flow of the cool air flowing out from the storage tank 110 is more effectively blocked The heat loss of the storage tank 110 in which the cryogenic gas is stored can be reduced.

4 is a block diagram of a method for inspecting a cryogenic gas storage tank according to an embodiment of the present invention. 1 to 4, a description will be made of a method of insulating a cryogenic gas storage tank (S100) as follows.

A method for inspecting a cryogenic gas storage tank (S100) includes a step S110 of providing a storage tank, a step S120 of installing a heat insulating block in a lower part of the storage tank, a step S130 of placing a storage tank on the saddle (S140) of inserting and fixing a part of the heat shielding member on both sides of the heat insulating block, and forming a foam member by foaming the heat insulating foam on the outer circumferential surface of the storage tank (S150).

In the step S110 of providing the storage tank, a storage tank 110 in which a space capable of storing cryogenic gas is formed is provided. Here, in the interior of the storage tank 110, a cryogenic gas such as liquefied natural gas (LNG) liquefied at a cryogenic temperature of -163 DEG C, liquefied nitrogen gas (LN2) liquefied at a cryogenic temperature of -196 DEG C and compressed natural gas May be stored and may be formed of a stainless steel material to withstand the internal pressure.

In the step S120 of installing the heat insulating block in the lower part of the storage tank, the heat insulating block 130 is installed in the lower part of the storage tank 110 prepared in the step S110 of preparing the storage tank. Here, the heat insulating block 130 may be formed of FRP or a wood material, and may be fixed to the lower portion of the storage tank 110 through an adhesive.

The step of placing the storage tank on the saddle S130 includes placing the saddle 120 fixed on the bottom of the hull and the storage tank 130 on the saddle 120 in contact with the heat- 110). At this time, the heat insulating blocks 130 may be disposed on both sides of the storage tanks 110, respectively, so as to be in contact with the upper surface of the saddle 120. This prevents the storage tanks 110 from being separated from the saddle 120 The heat insulating block 130 and the saddle 120 disposed on one side of the storage tank 110 may be fixed to each other.

The heat insulating block 130 disposed on the other side may also be fixed to the saddle 120, but is preferably formed to relatively move on the saddle 120. That is, when the storage tank 110 is thermally shrunk or thermally expanded according to a change in the temperature of the cryogenic gas, the heat block 130 is formed to be slidable on the upper portion of the saddle 120. Thus, the fatigue applied to the contact portion between the heat insulating block 130 and the saddle 120 can be reduced, thereby preventing the saddle 120 from being damaged.

In step S140 of inserting and fixing a part of the heat shielding member on both sides of the heat insulating block, a part of the heat shielding member 150 is inserted and fixed to both sides of the heat insulating block 130 made of FRP or wood. In order to insert and fix the heat shielding member 150 in the heat insulating block 130, a process of forming a fixing groove on both sides of the heat insulating block 130 and a process of attaching the adhesive to the fixing groove or the heat shielding member 150 And inserting the heat blocking member 150 into the fixing groove. The heat blocking member 150 inserted and fixed to both sides of the heat insulating block 130 may be partially exposed to the outside of the heat insulating block 130.

The step S150 of foaming the heat insulating foam on the outer circumferential surface of the storage tank S150 may include foaming the heat insulating foam on the outer surface of the storage tank 110 and heating the storage tank 110 and the heat exposed outside the heat insulating block 130 A foaming member 140 is formed to enclose the blocking member 150 and a part of the heat insulating block 130.

That is, the foam member 140 is not formed in advance, but is formed by foaming the heat insulating foam on the outer circumferential surface of the storage tank 110 after seating the storage tank 110 on the saddle 120. Accordingly, a part of the heat shielding member 150 exposed to the outside of the heat insulating block 130 can be disposed in the foam member 140. For this, the thickness of the foam member 140 is preferably formed to be larger than the distance between the storage tank 110 and the heat shield member 150. Further, the heat insulating foam may be formed of polyurethane foam material having good heat insulation property.

 Since the heat shielding members 150 are installed on both sides of the heat insulating block, the flow of cool air flowing through the gap between the heat insulating block 130 and the foam member 140 can be blocked through the heat shielding member 150 do.

The heat shielding member 150 may be formed of a triplex having good durability and heat insulation. Specifically, the triplex may include a lower glass fiber layer 151, an aluminum foil layer 152 stacked on the lower glass fiber layer, and an upper glass fiber layer 153 stacked on the aluminum foil layer.

Meanwhile, the insulation method (S100) of the storage tank for cryogenic gas may further include a step (S160) of applying a coating material to a contact portion between the heat insulating block and the foam member. The coating portion 160 may be formed at the contact portion between the heat insulating block 130 and the foam member 140 by this step. Here, the coating material may be formed of a polymer material.

Since the coating part 160 made of a polymer material having a low thermal conductivity is formed at the contact area between the heat insulating block 130 and the foamed part, the flow of cool air flowing out from the storage tank 110 can be more effectively blocked.

As described above, since the foam member 140 is formed so as to surround the outer circumferential surface of the storage tank 110 in which the cryogenic gas is stored, the cool air in the storage tank 110 flows out to the outside, .

Both ends of the heat shielding member 150 formed of the triplex material may be inserted and fixed in the heat insulating block 130 and the foam member 140 to fill the gap between the heat insulating block 130 and the foam member 140 Therefore, it is possible to prevent the cool air from the storage tank 110 from flowing out through the gap.

When the gap between the heat insulating block 130 and the foam member 140 is sealed through the coating part 160 formed of a polymer material, the flow of cool air flowing out from the storage tank 110 is blocked more effectively, The heat loss of the storage tank 110 stored therein can be reduced.

In addition, since the insulation of the storage tank 110 is sufficiently performed through the foam member 140, the heat shielding member 150, and the coating unit 160, the pressure inside the storage tank 110 can be kept constant , It is possible to prevent the cryogenic gas stored in the storage tank 110 from being evaporated.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation and that those skilled in the art will recognize that various modifications and equivalent arrangements may be made therein. It will be possible. Accordingly, the true scope of protection of the present invention should be determined only by the appended claims.

110 .. Storage tank
120 .. Birds
130 .. Insulation block
140 .. foam member
150.
151. Lower glass fiber layer
152 .. Aluminum foil layer
153. Upper glass fiber layer
160 .. Coating portion

Claims (15)

A storage tank in which a space capable of storing cryogenic gas is formed;
A saddle fixed to the bottom of the hull to support the storage tank;
A heat insulating block disposed between the storage tank and the saddle to insulate the storage tank from the saddle;
A foam member configured to surround the storage tank and a part of the heat insulating block; And
A heat blocking member partially inserted and fixed on both side surfaces of the heat insulating block, and the remaining part being disposed in the foam member;
Wherein the cryogenic gas storage tank has an insulating structure.
The method according to claim 1,
Further comprising a coating portion applied to a contact portion between the heat insulating block and the foam member.
3. The method of claim 2,
Wherein the coating portion is formed of a polymer material.
The method according to claim 1,
The heat-
A triplex structure including a lower glass fiber layer, an aluminum foil layer stacked on the lower glass fiber layer, and an upper glass fiber layer stacked on the aluminum foil layer, Of the storage tank for cryogenic gas.
The method according to claim 1,
Wherein the heat shielding member is formed of a flexible material.
The method according to claim 1,
Wherein the foam member is made of a polyurethane foam material and has a thermal storage structure for a cryogenic gas storage tank.
The method according to claim 1,
Wherein a thickness of the foam member is larger than a distance between the storage tank and the heat shield member.
The method according to claim 1,
Wherein the heat insulating block is made of FRP (Fiber Reinforced Plastics) or a wood material and has a thermal storage structure for a cryogenic gas storage tank.
Providing a storage tank in which a space capable of storing cryogenic gas is formed;
Installing a heat insulating block in a lower portion of the storage tank;
Placing the storage tank on the saddle such that the saddle secured to the bottom of the hull is in contact with the insulating block;
Inserting and fixing portions of the heat shielding member on both sides of the heat insulating block, respectively; And
Forming a storage tank, a heat shielding member exposed to the outside of the heat insulating block, and a foaming member surrounding a part of the heat insulating block by foaming the heat insulating foam on the outer surface of the storage tank;
Gt; cryogenic gas. ≪ / RTI >
10. The method of claim 9,
Further comprising the step of applying a coating material to a contact portion between the heat insulating block and the foam member to form a coating portion.
11. The method of claim 10,
Wherein the coating material is formed of a polymeric material.
10. The method of claim 9,
The heat-
A method of adhering a storage tank for cryogenic gas formed by a triplex comprising a lower glass fiber layer, an aluminum foil layer laminated on the lower glass fiber layer, and an upper glass fiber layer laminated on the aluminum foil layer.
10. The method of claim 9,
Wherein the heat insulating foam is formed of a polyurethane foam material.
10. The method of claim 9,
Wherein the thickness of the foam member is larger than the distance between the storage tank and the heat shield member.
10. The method of claim 9,
Wherein the heat insulating block is made of FRP or a wood material.

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