KR102499089B1 - Insulation structure of flange joint for cryogenic gas - Google Patents

Abstract

It relates to a heat insulation structure of a flange joint for cryogenic gas that facilitates maintenance. The insulation structure of the flange joint for cryogenic gas includes a storage container in which cryogenic gas is stored; Flange coupled to the joint of the storage container; A first heat insulation assembly for covering and insulating the outside of the storage container except for a portion where the flange is disposed; and a second heat insulation assembly that covers and insulates the outside of the flange.

Description

Insulation structure of flange joint for cryogenic gas}

The present invention relates to an insulation structure of a flange joint for cryogenic gas that is easy to maintain, and more particularly, covers and insulates a flange coupled to a container or pipe for cryogenic gas, so that when gas leaks to the outside of the flange, other It relates to an insulation structure of a flange joint for cryogenic gas that can detect and repair leaks by separating only the insulation assembly without dismantling the structure.

In general, natural gas is transported in a gaseous state through onshore or offshore gas pipelines, or transported to a remote consumer while being stored in an LNG carrier in a liquefied liquefied natural gas (LNG) state. Liquefied natural gas is obtained by cooling natural gas to a cryogenic temperature (approximately -163 ° C), and since its volume is reduced to approximately 1/600 of that of gaseous natural gas, it is very suitable for long-distance transportation through sea.

As such, since natural gas can only be liquefied at a very low temperature of about -163°C at atmospheric pressure, it must be stored and transported at this temperature. Therefore, it is necessary to insulate the storage vessel in order to reduce the loss of liquefied gas due to evaporation.

On the other hand, Figure 1 is a view showing the thermal insulation structure of the flange joint for cryogenic gas according to the prior art.

As shown in FIG. 1, the insulation structure 1 of the flange joint for cryogenic gas includes a storage container 10 in which cryogenic gas is stored, a pipe 20 connected to the storage container 10 and communicatively, Flange 30 connecting the joint of the storage container 10 or the joint of the storage container 10 and the pipe 20, and insulation covering the storage container 10, the pipe 20 and the flange 30 The member 40 and the cover portion 50 covering the heat insulating member 40 may be included.

With this structure, even if leakage occurs at the joint of the storage container 10 or the joint of the pipe 20, it is possible to form a neat appearance without affecting the external structure. However, since the cover part 50 covers all of the storage container 10, the pipe 20, and the flange 30, it is difficult to detect and repair leaks in this structure.

That is, when a leak occurs at the joint of the storage container 10 or the joint of the pipe 20, it is necessary to cut a portion of the insulation member 40 and the cover 50, which are presumed to be the leaked portion, through a cutting machine. However, since the joint of the storage container 10 and the pipe 20 is not visible from the outside, it often occurs that the cut portion is incorrectly set. Accordingly, since the cutting operation must be performed several times, there is a problem in that the number of man-hours increases.

In addition, after the repair is completed, there is a problem in that maintenance costs increase because the new insulation member 40 and the cover unit 50 must be prepared and installed again.

Patent Publication No. 10-2019-0033827 (published on April 1, 2019)

An object of the present invention is to provide a heat insulation assembly for covering and insulating the outside of the flange, so that when gas or fluid leaks around the flange, it is easy to perform maintenance by separating only the heat insulation assembly without dismantling other structures. It is to provide a heat insulation structure for a flange joint for a cryogenic gas.

Insulation structure of the cryogenic gas flange joint according to the present invention for achieving the above object is a storage container in which the cryogenic gas is stored; Flange coupled to the joint of the storage container; A first heat insulation assembly for covering and insulating the outside of the storage container except for a portion where the flange is disposed; and a second heat insulation assembly that covers and insulates the outside of the flange.

The first heat insulating assembly may include a first heat insulating member covering the outside of the storage container except for a portion where the flange is disposed, and a first cover part covering the outside of the first heat insulating member.

In addition, the second heat insulation assembly may be detachably coupled to the flange.

In addition, the second heat insulation assembly may include a second heat insulation member formed to surround the outside of the flange, and a second cover portion formed with an accommodation space in which the second heat insulation member can be accommodated.

In addition, the second cover part is formed in an arc shape and is in close contact with the storage container or the flange, and a first body part having a part of the inner circumference formed in a depression to form the accommodation space therein, and the first body part It is formed in a shape corresponding to and may include a second body portion formed in a ring shape with a through hole formed therein when combined with the first body portion.

In addition, coupling parts may be formed protruding outward from both ends of the first body and both ends of the second body.

In addition, the second heat insulating member protrudes more toward the flange than the second cover part, and is compressed when the second cover part is coupled to the flange and may be in close contact with the flange.

In addition, the second heat insulating member may be formed of an elastic material.

In addition, the second heat insulating member may be formed of a glass wool material.

In addition, a pipe connected to the storage container and communicatively may be further included, and the flange may be further installed at a joint between the storage container and the pipe.

In addition, a plurality of the pipes may be coupled to each other to form a pipe through which the cryogenic gas may flow, and the flange may be further installed at a joint of the pipe.

The insulation structure of the flange joint for cryogenic gas according to the present invention includes a storage container in which cryogenic gas is stored; a pipe that is communicatively connected to the storage vessel and has a plurality of pipes coupled to each other to form a conduit through which the cryogenic gas can flow; A flange for closely connecting the joint of the storage vessel and the pipe, and the joint of the pipes forming the pipe; a first heat insulation assembly covering and insulating the outside of the storage container and the pipe except for a portion where the flange is disposed; and a second heat insulation assembly that covers and insulates the outside of the flange.

In addition, the first heat insulating assembly may include a first heat insulating member covering the outside of the storage container and the pipe except for a portion where the flange is disposed, and a first cover portion covering the outside of the first heat insulating member. there is.

In addition, the second heat insulation assembly may include a second heat insulation member formed to surround the outside of the flange, and a second cover portion formed with an accommodation space in which the second heat insulation member can be accommodated.

According to the present invention, when leakage of cryogenic gas occurs due to a defect in the flange, only the second heat insulation assembly covering the flange needs to be separated and repaired, thereby facilitating maintenance.

In addition, in the prior art, since the insulation member and the cover portion surrounding the flange were cut and separated, repairs were performed so that the cut members could not be reused, but in the present invention, the second insulation assembly surrounding the flange is detachably formed. It can be reused, reducing maintenance costs.

In addition, since the exterior of the flange can be insulated using the second insulation assembly surrounding the flange, safety can be ensured by preventing frost around the flange or change in density of cryogenic gas due to heat loss. .

1 is a view showing a thermal insulation structure of a flange joint for cryogenic gas according to the prior art.
Figure 2 is a view showing the thermal insulation structure of the flange joint for cryogenic gas according to an embodiment of the present invention.
Figure 3 is a view showing the appearance of the cryogenic gas storage container shown in Figure 2;
4 is a longitudinal cross-sectional view of the cryogenic gas storage container shown in FIG. 2;
5 is a perspective view of the second cover part shown in FIG. 2;
Figure 6 is a cross-sectional view showing a state in which the flange shown in Figure 2 is coupled to a joint of a pair of pipes forming a pipeline.

Hereinafter, with reference to the accompanying drawings, a detailed description of the thermal insulation structure of the flange joint for cryogenic gas according to a preferred embodiment is as follows. Here, the same reference numerals are used for the same components, and repeated descriptions and detailed descriptions of known functions and configurations that may unnecessarily obscure the subject matter of the invention are omitted. Embodiments of the invention are provided to more completely explain the present invention to those skilled in the art. Accordingly, the shapes and sizes of elements in the drawings may be exaggerated for clarity.

Figure 2 is a view showing the insulation structure of the flange joint for cryogenic gas according to an embodiment of the present invention, Figure 3 is a view showing the appearance of the storage container for cryogenic gas shown in Figure 2, Figure 4 is 2 is a longitudinal cross-sectional view of the cryogenic gas storage container, and FIG. 5 is a perspective view of the second cover portion shown in FIG. 2 .

2 to 5, the insulation structure 100 of the flange joint for cryogenic gas includes a storage container 110, a flange 120, a first insulation assembly 130, and a second insulation assembly 140 can include

The storage container 110 may have a storage space 110a in which cryogenic gas may be stored. For example, in the storage space 110a, cryogenic gases such as liquefied natural gas (LNG) liquefied at a cryogenic temperature of -163 ° C, liquefied nitrogen gas (LN2) and compressed natural gas (CNG) liquefied at a cryogenic temperature of -196 ° C can be stored.

The storage vessel 110 may be formed in a long cylindrical shape in the longitudinal direction on the drawing, and may be formed of a stainless steel material to withstand internal pressure. In addition, both ends of the storage container 110 may be formed in a dome shape convex outward, and the cryogenic gas is supplied to the inside of the storage container 110 or the cryogenic gas stored in the storage container 110 is supplied to the side. A communication hole 110b for discharging to the outside may be formed.

The storage container 110 may be formed in a structure in which a plurality of bodies are coupled. For example, the storage container 110 may include a cylindrical first body 111 and a second body 112 and a third body 113 coupled to both ends of the first body 111, respectively. there is. In this way, as the storage container 110 is provided with a plurality of bodies, processing becomes easy, it can always be disassembled when internal maintenance is required, and the pressure is concentrated on the second body 112 and the third body 113. It is replaceable and has the advantage of reducing maintenance costs.

Flange 120 may be coupled to the joint of the storage container (110). For example, the flange 120 is formed to surround the joints of the first body 111 and the second body 112 and the first body 111 and the third body 113 to closely connect them. At this time, the flanges 120 may be formed in a pair and closely connect the first body 111 and the second body 112 or the first body 111 and the third body 113 in a mutually coupled manner.

The first heat insulation assembly 130 covers and insulates the outside of the storage container 110 except for the portion where the flange 120 is disposed, and includes a first heat insulation member 131 and a first cover part 132. can do.

The first heat insulating member 131 is to prevent the cold air of the cryogenic gas flowing into the storage vessel 110 and the pipe 150 from flowing out to the outside or external heat from flowing into the cryogenic gas, and the flange 120 ) may cover the outside of the storage container 110 except for the portion where it is disposed.

For example, the first heat insulating member 131 may be formed of a glass wool material having elasticity, and is manufactured to have a predetermined thickness, so that the storage container 110 and It may be formed to surround the outside of the pipe 150. In this embodiment, the first heat insulating member 131 has been described as glass fiber, but any material having excellent heat insulation performance and elasticity, such as polyurethane foam, can be applied.

In this way, as the first heat insulating member 131 is formed to cover the outside of the storage container 110 and the pipe 150 except for the portion where the flange 120 is disposed, the flange 120 may be exposed to the outside. there is. Therefore, when a leak is suspected at the joint between the storage container 110 and the pipe 150, the gas detector is used to determine whether the cryogenic gas is leaking, and to replace the flange 120 installed at the leaking portion of the cryogenic gas. Repairs can be completed in a number of ways. Due to this feature, it is possible to omit the operation of cutting the heat insulating member 40 and the cover part 50 shown in FIG. 1 using a cutting key in order to repair the leaking part as in the prior art, thereby facilitating maintenance. There are advantages.

The first cover part 132 may cover the outside of the first heat insulating member 131 . For example, the first cover portion 132 may be formed of an aluminum material having good corrosion resistance and moisture resistance, and may be formed to surround the outside of the first heat insulating member 131 to form a clean appearance.

On the other hand, if the area where the flange 120 is installed is not insulated, frost may occur in the area due to a temperature difference or density of cryogenic gas may change due to heat loss, which may affect safety. Therefore, the flange 120 may be thermally insulated by further including a second heat insulation assembly 140 for covering and insulating the outside of the flange 120 .

Specifically, the second heat insulation assembly 140 may be detachably coupled to the outside of the flange 120 and may include a second heat insulation member 141 and a second cover portion 142 .

The second heat insulating member 141 may be formed to surround the outside of the flange 120 . Like the first heat insulating member 131, the second heat insulating member 141 may be formed of an elastic material. For example, the second heat insulating member 141 may be made of a glass wool material to have a predetermined thickness, and may be formed to surround the outer circumference of the flange 120 .

In this way, as the second heat insulating member 141 is formed to cover the outside of the flange 120, it prevents frost from occurring around the flange 120 and also prevents external heat from flowing into the flange 120. can be prevented from changing the density of cryogenic gas.

An accommodation space 140a in which the second heat insulating member 141 can be accommodated may be formed in the second cover part 142 . Therefore, the second heat insulating member 141 made of an elastic material can be coupled to the second cover part 142 by compressing the second heat insulating member 141 made of elastic material and then inserting it into the receiving space 140a without a separate adhesive. there is. In this way, as the second heat insulating member 141 is coupled to the second cover part 142 without a separate adhesive, it is possible to easily replace the second heat insulating member 141 when it is damaged or contaminated. At this time, the second heat insulating member 141 may protrude further toward the flange 120 than the second cover portion 142, which is compressed when the second cover portion 142 is coupled to the flange 120, and the flange ( 120) to be in close contact.

Like the first cover part 132, the second cover part 142 may be formed of an aluminum material, and includes a first body part 41, a second body part 42, and a coupling part 43. can do.

The first body portion 41 is formed in an arc shape to be in close contact with the storage container 110 or the flange 120, and a portion of the inner circumferential surface is recessed to form an accommodation space 140a therein. For example, the accommodating space 140a formed in the first body portion 41 may also be formed in an arc shape, and the second insulating member 141 is inserted into the accommodating space 140a to form a second insulation assembly 140. may form part of

The second body portion 42 may be formed in a shape corresponding to the first body portion 41 and may be formed in a ring shape having a through hole therein when coupled to the first body portion 41 . In this way, as the second body portion 42 is formed in a structure in which the first body portion 42 is separated from and combined with the first body portion 41, when the cryogenic gas leaks, the first body portion 41 and the second body portion 42 Since the repair can be performed by separating the , the work becomes easier.

The coupling portion 43 is a portion for mutually coupling the first body portion 41 and the second body portion 42, both ends of both ends of the first body portion 41 and both ends of the second body portion 42. It may protrude outward from. In addition, at least one coupling hole 43a is formed in the coupling portion 43 so that they can be coupled to each other by a fastening means made of bolts and nuts. In this way, when the first body portion 41 and the second body portion 42 are coupled by the coupling portion 43, the flange 120 is positioned in the through hole, so that the second insulation assembly 140 and the flange ( 120) may be in close contact with each other.

6 is a cross-sectional view showing a state in which the flange shown in FIG. 2 is coupled to a joint of a pair of pipes forming a pipe.

2 to 6, the insulation structure 100 of the flange joint for cryogenic gas may further include a pipe 150 coupled to communicate with the storage container 110.

The pipe 150 forms a flow path for the cryogenic gas when supplying the cryogenic gas to the storage container 110 or discharging the cryogenic gas stored in the storage container 110, and is communicatively connected to the storage container 110. For example, the pipe 150 is formed in a cylindrical shape with a hollow inside, and one side may be coupled to the communication hole 110b of the storage container 110.

A plurality of pipes 150 may be coupled to each other to form a conduit through which cryogenic gas may flow. That is, if the conduit is composed of one pipe 150, it is preferable because problems such as gas leakage do not occur, but due to space limitations and production limitations, a plurality of pipes 150 are connected to create and use the conduit .

According to the present invention, a flange 120 may be installed at a joint between the storage container 110 and the pipe 150 and at a joint between the pipes 150 forming the pipe to closely connect them. For example, after interposing a gasket between the storage vessel 110 and the pipe 150 or the pipes 150, and then coupling them to each other using a pair of flanges 120 so that the cryogenic gas does not leak to the outside. can form

The flange 120 may be covered and insulated through the second heat insulation assembly 140, and the outside of the storage container 110 and the pipe 150 excluding the portion where the flange 120 is disposed is the first heat insulation assembly ( 130) can be covered and insulated. Here, since the configurations of the first insulation assembly 130 and the second insulation assembly 140 are the same as those described above, detailed descriptions thereof will be omitted.

In this way, as the flange 120 installed at the connection portion of the pipe 150 is also covered by the second heat insulation assembly 140, when cryogenic gas leaks from the joint portion of the pipe 150, the first heat insulation assembly 130 ) Since only the second heat insulation assembly 140 needs to be separated and repaired without disassembly, there is an effect of facilitating work.

Referring to FIGS. 2 to 6 , a repair process in case of leakage of cryogenic gas is described below.

A gap is formed between the pair of flanges 120 because the fastening force of the flange 120 is weakened, or the gasket interposed between the flange 120 and the storage container 110 or the flange 120 and the pipe 150 is old. When leakage of cryogenic gas occurs to the outside of the flange 120, it is determined whether or not the suspected part leaks using a gas detector.

When the leakage of the cryogenic gas is confirmed, the operator removes the second insulation assembly 140 installed in the suspected leak area, and then performs repairs such as replacing a gasket or tightening the flange 120 . After the repair is completed, the separated second insulation assembly 140 is assembled back to its original position. At this time, when the second heat insulating member 141 provided in the second heat insulating assembly 140 is contaminated by the leaked cryogenic gas, the second heat insulating member 141 from the receiving space 140a of the second heat insulating assembly 140 ) After separating and replacing the second heat insulation assembly 140 can be assembled to the exterior of the flange 120.

As described above, when the cryogenic gas leak occurs due to a defect in the flange 120, the insulation structure 100 of the cryogenic gas storage container 110 covers the flange 120, the second insulation assembly 140 ), it is necessary to separate and carry out repairs, so it is effective in facilitating maintenance.

In addition, conventionally, since the insulation member and the cover portion surrounding the flange 120 are cut and separated, the repair is performed, so the cut members cannot be reused. Since the assembly 140 is detachably formed and can be reused, maintenance costs can be reduced.

In addition, since the exterior of the flange 120 can be insulated using the second insulation assembly 140 surrounding the flange 120, frost is generated around the flange 120 or the density of cryogenic gas due to heat loss. Safety can be ensured by preventing changes from occurring.

The present invention has been described with reference to an embodiment shown in the accompanying drawings, but this is only exemplary, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. You will be able to. Therefore, the true protection scope of the present invention should be defined only by the appended claims.

110: storage container
120: flange
130: first heat insulation assembly
131: first heat insulating member
132: first cover part
140: second heat insulation assembly
141: second heat insulating member
142: second cover part
150: piping

Claims (14)

A storage container composed of a plurality of bodies including a cylindrical first body, a second body and a third body coupled to both ends of the first body, respectively, and storing cryogenic gas therein; Flange coupled to the joint of the storage container; A first heat insulation assembly for covering and insulating the outside of the storage container except for a portion where the flange is disposed; And a second heat insulation assembly for covering and insulating the outside of the flange; includes,
The first heat insulating assembly includes a first heat insulating member covering the outside of the storage except for a portion where the flange is disposed, and a first cover portion covering the outside of the first heat insulating member,
The second heat insulation assembly is detachably coupled to the flange,
The second heat insulation assembly includes a second heat insulation member formed to surround the outside of the flange, and a second cover portion formed with an accommodation space in which the second heat insulation member can be accommodated,
The second cover part is formed in an arc shape and is in close contact with the storage container or the flange, and a part of the inner circumferential surface is recessed to form the accommodation space therein, and the first body part corresponds to the first body part. It is formed in a shape that is, and includes a second body portion formed in a ring shape with a through hole formed therein when combined with the first body portion,
Both ends of the first body part and both ends of the second body part have coupling parts protruding outwardly,
The second heat insulating member protrudes further toward the flange than the second cover part, and is compressed when the second cover part is coupled to the flange, and is formed of an elastic material to be in close contact with the flange for insulating the flange coupling part for cryogenic gas. structure.
delete delete delete delete delete delete delete According to claim 1,
The second heat insulating member is a heat insulating structure of the flange joint for cryogenic gas formed of a glass wool material.
According to claim 1,
Further comprising a pipe that is communicatively coupled to the storage container,
The insulation structure of the flange joint for cryogenic gas in which the flange is further installed at the joint of the storage container and the pipe.
According to claim 10,
A plurality of the pipes are coupled to each other to form a conduit through which the cryogenic gas can flow therein, and the flange is further installed at the joint of the pipe.
A storage container composed of a plurality of bodies including a cylindrical first body, a second body and a third body coupled to both ends of the first body, respectively, and storing cryogenic gas therein; a pipe that is communicatively connected to the storage vessel and has a plurality of pipes coupled to each other to form a conduit through which the cryogenic gas can flow; A flange for closely connecting the joint of the storage vessel and the pipe, and the joint of the pipes forming the pipe; a first heat insulation assembly covering and insulating the outside of the storage container and the pipe except for a portion where the flange is disposed; And a second heat insulation assembly for covering and insulating the outside of the flange; includes,
The first heat insulating assembly includes a first heat insulating member covering the outside of the storage container and the pipe except for a portion where the flange is disposed, and a first cover portion covering the outside of the first heat insulating member,
The second heat insulation assembly includes a second heat insulation member formed to surround the outside of the flange, and a second cover portion formed with a receiving space in which the second heat insulation member can be accommodated. structure. delete delete

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