KR20210155161A - Vacuum insulated pipe - Google Patents

Abstract

A vacuum insulated pipe is presented. The vacuum insulated pipe according to one embodiment comprises: an internal pipe through which a fluid flows; a vacuum insulation layer which is installed to be spaced apart from the outside of the internal pipe and surrounds the internal pipe; and a solid insulation layer which is installed on the inside and outside of the vacuum insulation layer and surrounds the vacuum insulation layer, thereby capable of solving the problems of shrinkage and expansion due to heat.

Description

VACUUM INSULATED PIPE

The following embodiments relate to a vacuum insulated pipe, and more particularly, to a vacuum insulated pipe in which the vacuum insulating layer is configured in the space between or outside of the solid heat insulating layer that insulates the inner pipe.

In general, since cryogenic liquefied gas has a low temperature and low latent heat, it can be easily vaporized by intrusion of a small amount of heat. Therefore, a vacuum insulated pipe with excellent thermal insulation performance is used to transport the cryogenic liquefied gas from the storage tank to distant equipment. Vacuum insulated piping is used for cryogenic fluids (eg, -163℃ LNG) for carriers, fuel propulsion ships, and onshore piping for supplying cryogenic fluids to these ships. BOG (Boil Off Gas) generated during transport In order to minimize the occurrence, the pipe is made of a double pipe and a vacuum layer is placed between the inner pipe and the external pipe to effectively block heat intrusion from the outside.

Vacuum insulation technology simply exhibits a thermal insulation effect that is several dozen times that of solid insulation materials such as urethane foam or styrene foam. Pipe insulation of cryogenic liquids such as liquid hydrogen or LNG is a very important process, and the temperature rise and vaporization of the liquid flowing through the distribution pipe should be blocked as much as possible. . On the other hand, vacuum insulation requires a physical device that can absorb the stress of thermal contraction and thermal expansion, and requires careful attention in piping construction and operation.

Korean Patent Registration No. 10-2050809 relates to such a vacuum insulated pipe, and while preventing the generation of dew condensation between the inner tube and the vacuum outer tube, the vacuum space formed between the inner tube and the vacuum outer tube is uniformly formed, so that the vacuum appearance is deformed according to the vacuum. Describes the technology for vacuum insulated piping to prevent

Korean Patent No. 10-2050809

The embodiments are described with respect to the vacuum insulation pipe, and more specifically, in the insulation of the pipe, by forming an independent vacuum insulation layer by separating it from the internal pipe through which an internal cryogenic or high temperature fluid flows, the problem of contraction and expansion due to heat can be solved. Provide vacuum insulated piping.

In addition, there is provided a technique capable of obtaining the maximum thermal insulation effect by constructing a vacuum insulation layer outside or in the space between the solid insulation layer that insulates the inner pipe.

A vacuum insulation pipe according to an embodiment includes: an internal pipe through which a fluid flows; a vacuum insulation layer which is installed to be spaced apart from the outside of the inner pipe and surrounds the inner pipe; and a solid heat insulating layer installed on the inside and outside of the vacuum heat insulating layer and surrounding the vacuum heat insulating layer.

The solid heat insulating layer may include: a first solid heat insulating layer installed in a space between the inner pipe and the vacuum insulating layer; and a second solid heat insulating layer installed outside the vacuum insulating layer and surrounding the vacuum insulating layer.

The solid insulating layer may be made of a solid insulating material made of at least one of glass wool, hydrophobic airgel, urethane foam, and styrene foam.

A vacuum insulation pipe according to another embodiment includes: an inner pipe through which a fluid flows therein including an elbow or straight pipe connection; a vacuum insulation layer of a prefabricated structure constructed on the outside of the inner pipe and having two separate structures surrounding the elbow or straight pipe connection part of the inner pipe; and a solid heat insulating layer erected inside and outside the vacuum heat insulating layer.

After forming a space inside the solid heat insulating layer, the vacuum insulating layer is formed in the space, and the solid heat insulating layer and the vacuum insulating layer are prefabricated with at least one or more blocks, and are coupled to the outside of the inner pipe or a plurality of By combining the block, it can be configured to surround the outside of the inner pipe.

According to embodiments, in insulating the internal pipe, a vacuum insulating layer is installed to be spaced apart from the internal fluid pipe, and a solid insulating material is installed therebetween to provide an insulating pipe capable of obtaining the maximum thermal insulation effect.

Further, according to embodiments, it is possible to provide a vacuum insulating pipe capable of solving the problems of shrinkage and expansion due to heat by forming an independent vacuum insulating layer by separating it from the internal pipe through which the internal cryogenic or high temperature fluid flows.

In addition, the straight pipe connection part or the elbow connection part of the vacuum insulated pipe is manufactured in a prefabricated manner and may consist of at least two separate components for easy construction in the field. After doing this, the work of applying a vacuum is eliminated, and the workability is greatly improved.

1 is a view for explaining a side cross-section of a conventional vacuum insulated pipe.
2 is a view showing a perspective view of a vacuum insulated pipe according to an embodiment.
3 is a view showing a cross section AA′ of FIG. 2 .
4 is a view showing a perspective view of a vacuum insulated pipe according to another embodiment.
5 is a view showing a vacuum insulated pipe having a straight pipe connection structure according to another embodiment.
6 is a view for explaining the prefabricated cylindrical structure of the elbow connection portion of the vacuum insulated pipe according to another embodiment.
7 is a view for explaining the prefabricated rectangular columnar structure of the straight pipe connection part of the vacuum insulated pipe according to another embodiment.

Hereinafter, embodiments will be described with reference to the accompanying drawings. However, the described embodiments may be modified in various other forms, and the scope of the present invention is not limited by the embodiments described below. In addition, various embodiments are provided in order to more completely explain the present invention to those of ordinary skill in the art. The shapes and sizes of elements in the drawings may be exaggerated for clearer description.

1 is a view for explaining a side cross-section of a conventional vacuum insulated pipe.

Referring to FIG. 1 , a conventional vacuum insulation pipe 1 has a double pipe structure in which an external pipe 20 is installed on an internal pipe 10 through which a fluid l flows, and the internal pipe 10 and the external pipe By forming a vacuum in the space between (20), it is possible to provide a thermal insulation function. Such vacuum insulation has a large thermal barrier effect because there are no molecules such as air. Accordingly, vacuum insulated piping is used to insulate pipes through which cryogenic liquids such as liquid hydrogen (-253°C), LNG (-162°C), liquid nitrogen (-196°C), and liquid oxygen flow or high-temperature thermal fluids flow. can be applied

However, in the case of a conventional vacuum insulated pipe that insulates a cryogenic liquid or a high temperature thermal fluid, the internal pipe 10 contracts or expands due to the temperature of the internal fluid (l), which causes the external appearance of a vacuum welded to the outside. Stress acts on (20) to cause breakage and leakage.

In order to solve this problem, elastic bellows 21, etc. that absorb this stress must be installed inevitably, and heat transfer through the connection part where the inner pipe 10 and the outer pipe 20 are combined and welded. It becomes a problem.

The following embodiments are intended to solve the stress problem, and it is possible to provide a vacuum insulated pipe that can obtain an insulating effect by constructing a vacuum insulating layer outside or in the space between the solid insulating layer that insulates the internal pipe.

More specifically, in order to solve the problem of the existing vacuum insulated pipe in which damage and leakage occur due to stress acting on the vacuum pipe welded to the outside as the internal pipe is contracted or expanded by the temperature of the internal fluid, the internal cryogenic temperature Alternatively, by forming an independent vacuum insulating layer by separating from the internal pipe through which a high-temperature fluid flows, it is possible to provide a vacuum insulating pipe capable of solving the problems of shrinkage and expansion due to heat.

2 is a view showing a perspective view of a vacuum insulated pipe according to an embodiment. And FIG. 3 is a view showing a cross section AA′ of FIG. 2 .

2 and 3, when the vacuum insulating pipe 100 according to an embodiment is installed to be spaced apart from the internal pipe 110 through which the fluid (l) flows therein, the vacuum insulating layer 130 is installed, the internal pipe ( The solid heat insulating layer 120 may be erected on the outside of 110 and the vacuum insulating layer 130 may be erected on the outside thereof. In addition, the solid insulation layer 140 may be erected outside the vacuum insulation layer 130 .

Below, the vacuum insulation pipe 100 according to an embodiment will be described in more detail.

The vacuum insulation pipe 100 according to an embodiment may include an inner pipe 110 , solid heat insulation layers 120 and 140 , and a vacuum insulation layer 130 .

The inner pipe 110 is a pipe through which a fluid l flows therein, and a cryogenic liquid or a high temperature thermal fluid l may flow therein. For example, the fluid l flowing in the inner pipe 110 is a cryogenic liquid of at least one of liquid hydrogen (-253°C), LNG (-162°C), liquid nitrogen (-196°C), and liquid oxygen. Or, it may be a high-temperature thermal fluid (l).

The solid heat insulating layers 120 and 140 may be installed inside and outside the vacuum insulating layer 130 and may be configured to surround the vacuum insulating layer 130 . These solid heat insulating layers 120 and 140 are installed on the outside of the first solid heat insulating layer 120 and the vacuum insulating layer 130 installed in the space between the inner pipe 110 and the vacuum insulating layer 130 and surround the vacuum insulating layer 130 . may include the second solid heat insulating layer 140 . That is, the first solid heat insulating layer 120 is erected to fill a predetermined thickness between the vacuum insulating layer 130 on the outside of the inner pipe 110 and may be configured to surround the inner pipe 110 , and the second The solid insulation layer 140 may be configured to surround the vacuum insulation layer 130 from the outside of the vacuum insulation layer 130 .

For example, the solid heat insulating layers 120 and 140 may be configured in a cylindrical shape to accommodate the cylindrical inner pipe 110 or the vacuum heat insulating layer 130 . Meanwhile, the solid heat insulating layers 120 and 140 may be formed in various shapes such as a polygonal pole shape including a rectangular pole shape as well as a cylindrical shape.

Here, the solid insulating layers 120 and 140 are made of a solid insulating material, and may be made of a solid insulating material made of at least one of glass wool, hydrophobic airgel, urethane foam, and styrene foam. For example, the solid insulators 120 and 140 may be urethane foam or styrene foam. Styrene foam may include polystyrene.

The vacuum insulation layer 130 is installed to be spaced apart from the outside of the inner pipe 11 and may be configured to surround the inner pipe 110 . That is, the vacuum insulating layer 130 may be constructed outside the first solid insulating layer 120 to surround the first solid insulating layer 120 .

For example, the vacuum insulation layer 130 may be configured in a cylindrical shape to accommodate the cylindrical inner pipe 110 and the first solid heat insulation layer 120 . Meanwhile, the vacuum insulation layer 130 may be formed in various shapes such as a polygonal pole shape including a rectangular pole shape as well as a cylindrical shape. In addition, when the vacuum insulation layer 130 is spaced apart from 1/3 to 1/2 of the total insulation thickness in the inner pipe 110 , an optimal insulation effect can be obtained.

In this way, the vacuum insulation pipe 100 is the inner pipe 110 through which the fluid (l) flows, the first solid heat insulating layer 120 configured on the outside of the inner pipe 110, and the first solid heat insulating layer 120 to the outside. The vacuum insulation layer 130 is configured, and the second solid insulation layer 140 configured outside the vacuum insulation layer 130 may be included. In this case, the first solid heat insulating layer 120 and the second solid heat insulating layer 140 may be made of a solid heat insulating material of the same material. In addition, the first solid heat insulating layer 120 and the second solid heat insulating layer 140 may be made of solid heat insulating materials of different materials.

4 is a view showing a perspective view of a vacuum insulated pipe according to another embodiment. And FIG. 5 is a view showing a vacuum insulated pipe having a straight pipe connection structure according to another embodiment.

4 and 5, in the vacuum insulation pipe 200 according to another embodiment, the solid insulation layers 220 and 240 are erected on the outside of the inner pipe 210 through which the fluid l flows therein, and the solid The vacuum insulation layer 230 may be erected in the middle of the heat insulation layers 220 and 240 , that is, inside the solid heat insulation layers 220 and 240 . In other words, the vacuum insulation layer 230 is separated from the internal pipe 210 and erected while being placed in the middle of a solid insulation material such as glass wool, hydrophobic airgel, urethane foam or styrene foam.

Below, the vacuum insulation pipe 200 according to another embodiment will be described in more detail. The vacuum insulation pipe 200 according to another embodiment will be briefly described because some descriptions overlap with the vacuum insulation pipe 100 according to the embodiment described above.

The vacuum insulating pipe 200 according to another embodiment may include an inner pipe 210 , solid insulating layers 220 and 240 , and a vacuum insulating layer 230 .

The inner pipe 210 is a pipe through which a fluid l flows therein, and a cryogenic liquid or a high temperature thermal fluid l may flow therein. Here, the inner pipe 210 may include an elbow connection part or a straight pipe connection part. As shown in FIG. 5 , the straight pipe connection part may be configured as a straight internal pipe 210 , and a plurality of internal pipes 210 may be connected to each other through the welding part 250 .

6 is a view for explaining the prefabricated cylindrical structure of the elbow connection portion of the vacuum insulated pipe according to another embodiment.

As shown in FIG. 6 , the elbow connection part may be composed of an internal pipe 210 in a bent form, and in this case, solid heat insulating layers 220 and 240 configured on the outside of the internal pipe 210 including the elbow connection part; and The vacuum insulation layer 230 may be configured in a bent shape. At this time, at least one of the solid heat insulating layers 220 and 240 and the vacuum insulating layer 230 may be formed of a prefabricated structure having two separate structures. For example, the vacuum insulation layer 230 may be installed on the outside of the inner pipe 210 and may have a prefabricated structure having two separate structures surrounding the elbow or straight pipe connection portion of the inner pipe 210 .

The solid heat insulating layers 220 and 240 may be installed on the outside of the inner pipe 210 and may be configured to surround the inner pipe 210 . Here, the solid insulating layers 220 and 240 are made of a solid insulating material, for example, glass wool, hydrophobic airgel, urethane foam or styrene foam may be used as the solid insulating material.

The vacuum insulation layer 230 may be installed inside the solid insulation layers 220 and 240 . For example, the cylindrical solid heat insulating layers 220 and 240 are formed to a predetermined thickness on the outside of the cylindrical inner pipe 210, and the cylindrical vacuum insulating layer 230 is formed in the middle of the solid heat insulating layers 220 and 240. can be formed. As another example, the cylindrical solid heat insulating layers 220 and 240 are formed with a predetermined thickness on the outside of the cylindrical inner pipe 210, and at least a predetermined space is formed in the middle of the solid heat insulating layers 220 and 240, so that the A vacuum insulation layer 230 may be formed in the space. Here, the inner pipe 210 and the solid heat insulating layers 220 and 240 are described as an example in a cylindrical shape, but may be formed in various shapes as needed, such as a rectangular column shape.

In particular, after forming a space in the solid heat insulating layers 220 and 240 , the vacuum insulating layer 230 may be formed in the space. The solid heat insulating layers 220 and 240 and the vacuum insulating layer 230 may be prefabricated with at least one block. Accordingly, by coupling at least one or more blocks to the outside of the inner pipe 210 or by combining a plurality of blocks to surround the outside of the inner pipe 210, assembling in the straight pipe connection part or the elbow connection part can be improved. have.

7 is a view for explaining the prefabricated rectangular columnar structure of the straight pipe connection part of the vacuum insulated pipe according to another embodiment. 7 is a description for a case in which the vacuum insulation pipe 200 described with reference to FIGS. 4 to 6 is formed in a rectangular column shape.

Referring to FIG. 7 , the vacuum insulation layer 230 may be installed inside the solid insulation layers 220 and 240 . At this time, the vacuum insulation layer 230 may be configured as one of a hollow cylindrical shape or a rectangular pillar shape, or may be formed of at least two or more separate components to be configured in such a cylindrical shape or a rectangular pillar shape.

In this way, the straight pipe connection part of the vacuum insulation pipe or the connection part of the elbow may be manufactured in a prefabricated manner, and thus may consist of at least two or more separate components for easy construction in the field. According to the embodiments, after welding the connection of the straight pipe part or the elbow part of the conventional vacuum insulation pipe in the field, the operation of applying a vacuum is eliminated, thereby greatly improving the workability.

The straight pipe connection part of the vacuum insulation layer 230 or the elbow connection part may be assembled on-site by making up at least two or more separate components. A solid heat insulating layer may be installed in the space between the inner pipe of the elbow or straight pipe connection part and the vacuum insulating part.

For example, after forming a cylindrical or square columnar space inside the solid heat insulating layers 220 and 240 , the vacuum heat insulating layer 230 having one configuration of a cylindrical or square columnar shape is formed with the solid heat insulating layers 220 and 240 . ) can be assembled in the space between As another example, after forming a cylindrical or square columnar space inside the solid heat insulation layers 220 and 240, the vacuum insulation layer 230 consisting of at least two separate components to be configured in a cylindrical or square columnar shape is It may be assembled in the space between the solid heat insulating layers 220 and 240 .

At this time, at least two or more separated components to be configured in a cylindrical shape may be formed in a semicircular shape. In addition, at least two or more separate components to be configured in the shape of a square pillar may be formed in a 'C' shape.

As such, the vacuum insulation layer 230 of the elbow or straight pipe connection may be of one configuration, such as a cylindrical or square column shape, or a separate configuration, and at least one or more sets in advance with the solid heat insulation layers 220 and 240. It can be configured to improve assembly and construction workability.

In addition, the vacuum insulation layer 230 may insert a honeycomb or net-shaped steel plate or a plastic support structure for support. And a polyethylene terephthalate sheet (Sheet) can be hypothesized for the enhancement of the radiant heat shielding effect.

The vacuum insulation piping 200 is constructed by inserting or combining the solid insulation layers 220 and 240 and the vacuum insulation layer 230 block composed of at least one or more sets to the outside of the internal piping 210 through which the fluid (l) flows. can do. For example, the solid heat insulating layers 220 and 240 and the vacuum insulating layer 230 block may be inserted into one block having a cylindrical shape or a rectangular column shape and inserted outside the inner pipe 210 through which the fluid l flows. As another example, the straight pipe connection part or the elbow connection part consists of two blocks of the solid heat insulating layer 220 and 240 and the vacuum insulating layer 230 block having a semicircle or 'C' shape, so that the fluid l flows through the inner pipe 210 of the It may be coupled and fixed to the outside. At this time, the solid heat insulating layers 220 and 240 and the vacuum insulating layer 230 block composed of two blocks of a semicircle or 'C' shape may be combined to form a single cylindrical shape or a quadrangular prism shape. The spaced space or the interspace generated during assembly may be filled and sealed by spraying a solid insulating material such as urethane foam.

Like the vacuum insulation pipe of FIGS. 2 to 7 described above, in the case of the vacuum insulation pipe in which the vacuum insulation layer is spaced apart from the inner pipe, the insulation effect is excellent. The insulation effect of the vacuum insulation pipe in which the solid insulation layer is formed inside and outside the vacuum insulation layer according to the present embodiments is superior to that of the vacuum insulation pipe in which the solid insulation layer is formed between the inner tube and the vacuum insulation layer by 10% or more.

According to embodiments, the maximum thermal barrier effect may be obtained by installing a vacuum insulation layer inside the solid insulation layer that insulates the inner pipe. In particular, the insulation effect becomes the optimal position when the vacuum insulation layer is located at 1/3 to 1/2 of the total insulation thickness, and at this time, the insulation effect increases by 10% or more.

In addition, according to embodiments, it is possible to solve the problem of shrinkage and expansion due to heat by forming an independent vacuum insulation layer by separating it from the internal pipe through which the internal cryogenic or high temperature fluid flows.

The operation of the present embodiment configured in this way will be described as follows. Hereinafter, a vacuum insulation pipe will be described as an example with reference to FIGS. 4 to 7 .

The vacuum insulation pipe may be spaced apart from the outside of the inner pipe through which the fluid flows to form a vacuum insulation layer separated therebetween, and a solid insulation layer may be formed therebetween, and a solid insulation layer may be formed again on the outside of the vacuum insulation layer. That is, the vacuum insulating pipe may be composed of an inner pipe + a solid insulating layer (urethane foam) + a vacuum insulating layer (double pipe type) + a solid insulating layer (urethane foam).

Here, the vacuum insulation layer is a double pipe type, and if the thickness is thick, a thin pipe is applied because it costs a lot and there is a load problem. If the pipe thickness is very thin and there is concern about damage due to shrinkage when high vacuum is applied, it can be prevented by inserting a honeycomb or net-shaped thin steel or plastic plate to prevent breakage.

Here, by forming a solid heat insulating layer in the space inside and outside the vacuum heat insulating layer, it is possible to form a solid heat insulating layer (urethane foam) + vacuum insulating layer (double pipe type) + solid heat insulating layer (urethane foam) structure. To this end, a vacuum insulation layer having a hollow cylindrical shape or a polygonal columnar shape may be inserted into the space between the solid heat insulation layers and assembled.

At this time, by forming a solid insulation layer inside and outside the vacuum insulation layer in advance in the form of at least one or more blocks, construction convenience and efficiency can be improved. In particular, the straight pipe connection part of the vacuum insulated pipe or the elbow connection part is a very effective technique that does not require welding and vacuum work in the conventional field. In other words, the vacuum insulating pipe may be configured by inserting or combining the vacuum insulating layer and the solid insulating layer configured in the form of at least one or more blocks to the outside of the internal pipe through which the fluid flows.

In applying vacuum insulation to the insulation of cryogenic or thermal fluid piping, it is possible to obtain the maximum thermal insulation effect by installing a solid insulation layer outside or in the space between the separated vacuum insulation piping. Accordingly, since the vacuum insulation layer is installed to be spaced apart from the inner pipe, problems such as stress damage due to the current temperature difference or the installation of a bellows for stress absorption can be solved.

In particular, when the vacuum insulation layer is installed at 1/3 to 1/2 point in the thickness direction in the vacuum insulation pipe, the insulation effect can be improved by 10% or more.

When it is mentioned that a component is "connected" or "connected" to another component in the above, it may be directly connected or connected to the other component, but other components may exist in the middle. It should be understood that there is On the other hand, when it is said that a certain element is "directly connected" or "directly connected" to another element, it should be understood that the other element does not exist in the middle.

The terminology used herein is used only to describe specific embodiments, and is not intended to limit the present invention. The singular expression includes the plural expression unless the context clearly dictates otherwise. In the present specification, terms such as “comprise” or “have” are intended to designate that a feature, number, step, operation, component, part, or combination thereof described in the specification exists, but one or more other features It should be understood that this does not preclude the existence or addition of numbers, steps, operations, components, parts, or combinations thereof.

Terms such as first, second, etc. may be used to describe various elements, but the elements should not be limited by the terms. The above terms are used only for the purpose of distinguishing one component from another.

In addition, terms such as “…unit”, “…module”, etc. described in the specification mean a unit that processes at least one function or operation, which may be implemented as hardware or software or a combination of hardware and software.

In addition, the components of the embodiment described with reference to each drawing are not limitedly applied only to the embodiment, and may be implemented to be included in other embodiments within the scope of maintaining the technical spirit of the present invention, and also Even if the description is omitted, it is natural that a plurality of embodiments may be re-implemented as one integrated embodiment.

In addition, in the description with reference to the accompanying drawings, the same components regardless of the reference numerals are given the same or related reference numerals, and the overlapping description thereof will be omitted. In describing the present invention, if it is determined that a detailed description of a related known technology may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted.

As described above, although the embodiments have been described with reference to the limited embodiments and drawings, various modifications and variations are possible from the above description by those skilled in the art. For example, the described techniques are performed in an order different from the described method, and/or the described components of the system, structure, apparatus, circuit, etc. are combined or combined in a different form than the described method, or other components Or substituted or substituted by equivalents may achieve an appropriate result.

Therefore, other implementations, other embodiments, and equivalents to the claims are also within the scope of the following claims.

Claims (5)

an internal pipe through which a fluid flows;
a vacuum insulation layer which is installed to be spaced apart from the outside of the inner pipe and surrounds the inner pipe; and
A solid heat insulating layer installed on the inside and outside of the vacuum insulating layer and surrounding the vacuum insulating layer
Including, vacuum insulated piping. According to claim 1,
The solid heat insulating layer,
a first solid heat insulating layer installed in a space between the inner pipe and the vacuum insulating layer; and
A second solid heat insulating layer installed outside the vacuum insulating layer and surrounding the vacuum insulating layer
Including, vacuum insulated piping. According to claim 1,
The solid heat insulating layer,
What consists of a solid insulation material consisting of at least one of glass wool, hydrophobic airgel, urethane foam, and styrene foam
characterized in that, vacuum insulated piping. an inner pipe through which a fluid flows therein including an elbow or straight pipe connection;
a vacuum insulation layer of a prefabricated structure constructed on the outside of the inner pipe and having two separate structures surrounding the elbow or straight pipe connection part of the inner pipe; and
A solid heat insulating layer installed on the inside and outside of the vacuum heat insulating layer
Including, vacuum insulated piping. 5. The method of claim 4,
After forming a space inside the solid heat insulating layer, the vacuum insulating layer is formed in the space, and the solid heat insulating layer and the vacuum insulating layer are prefabricated with at least one or more blocks, and are coupled to the outside of the inner pipe or a plurality of By combining the blocks to configure to wrap the outside of the inner pipe
Including, vacuum insulated piping.

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