KR102066576B1 - Flange sturucture and vacuum-insulated pipe includimg same - Google Patents

Abstract

An embodiment of the present invention is a flange structure positioned between an inner tube and a double tube consisting of an outer pipe, comprising: a female flange and a male flange that can be mutually fastened; A female bayonet connected to the female flange and formed along a longitudinal direction of the inner tube and connected to the inner tube at one end thereof; A male bayonet positioned adjacent to the female bayonet along a longitudinal direction of the inner tube and connected to the inner tube at one end thereof; The arm flange includes at least a portion of the inner tube side of the arm flange extending along the longitudinal direction of the inner tube and including a flange extension connected to the other end of the arm bayonet, wherein the flange extension includes the arm bayonet; An indentation portion which is a space formed by indenting one end surface of the flange extension portion from one end of the connection portion side to the other side; And a first path extension positioned to enclose the indentation, the first path extension forming at least a portion of a bypass portion bypassing a heat transfer path between the arm flange and the arm bayonet.

Description

FLANGE STURUCTURE AND VACUUM-INSULATED PIPE INCLUDIMG SAME

Embodiments of the present invention relate to a flange structure and a vacuum insulated pipe comprising the same.

Cryogenic liquefied gas can be easily vaporized by a small amount of heat intrusion because of the low temperature and low latent heat, and in order to transfer the cryogenic liquefied gas from the storage tank to the equipment far from the storage tank, a vacuum insulated pipe having excellent thermal insulation performance is used.

The conventional bayonet type vacuum insulated pipe blocks heat intrusion from the outside so that the liquefied gas in the cryogenic state can be smoothly transferred to the liquid state without vaporization. Since the bayonet type vacuum insulated pipe cannot be operated in the same length as the general pipe, it is possible to weld several pipes in the field after making several unit pipes according to the pipe diagram of the site in the facility equipped facility. do. In general, the bayonet-type vacuum insulated pipe needs a connection device for transferring cryogenic liquefied gas to another device, and the connection structure on both sides should have a certain length to prevent heat loss of the liquid gas. For example, liquid nitrogen should have a length of 600 mm or more and liquid helium of 800 mm or more to prevent heat loss. Therefore, conventionally, the bayonet type vacuum insulated pipe which has the length which can prevent the heat loss of cryogenic liquefied gas is manufactured.

Conventionally, a bayonet type vacuum insulated pipe for transferring cryogenic liquefied gas is as shown in FIG. 1. A male bayonet 5 connected to the male flange 3 between the inner tube 1 through which the liquefied gas flows and an outer side 2 for preventing heat ingress from the outside, and which is connected to the male flange 3. And an arm bayonet 6 which is connected to the arm flange 4 is disposed. The female and male bayonets 5 and 6 form a vacuum insulated space for blocking heat intrusion into the inner tube 1. In order to prevent heat loss of the cryogenic liquefied gas, the female and male bayonets 5 and 6 have a predetermined length L. That is, since the conventional female and male bayonets 5 and 6 are manufactured to the length which can prevent the heat loss of the cryogenic liquefied gas, the length of the bayonet is difficult to change and it is necessary to manufacture by accurate measurement. In addition, the length of the bayonet is subject to a lot of maintenance and space constraints.

Korean Registered Patent Publication No. 20-0203444 (2000.09.06)

Embodiments of the present invention, to reduce the length of the female bayonet and male bayonet, to provide a flange structure free of space constraints and vacuum insulated piping including the same.

In addition, it is to provide a flange structure and a vacuum insulated pipe including the same that can be adjusted in length according to the working environment.

In addition, as the length of the female bayonet and male bayonet is reduced, the length of the vacuum insulated pipe is reduced, thereby providing a flange structure and a vacuum insulated pipe including the same, which can reduce the size of equipment related to the piping equipment such as chambers. It is for.

In addition, as the length of the female bayonet and male bayonet is reduced, it is to provide a flange structure and a vacuum insulation pipe including the same to improve the ease of maintenance, such as installation, separation, movement of the vacuum insulation pipe.

According to an embodiment of the present invention, a flange structure positioned between an inner tube and a double tube formed of an outer tube, comprising: a female flange and a male flange that can be mutually fastened; A female bayonet connected to the female flange and formed along a longitudinal direction of the inner tube and coupled to the inner tube at one end thereof; A male bayonet positioned adjacent to the female bayonet along a longitudinal direction of the inner tube and coupled to the inner tube at one end; The arm flange includes at least a portion of the inner tube side of the arm flange extending along the longitudinal direction of the inner tube and including a flange extension connected to the other end of the arm bayonet, wherein the flange extension includes the arm bayonet; An indentation portion which is a space formed by indenting one end surface of the flange extension portion from one end of the connection portion side to the other side; And a first path extension positioned to enclose the indentation and at least a portion of which defines a bypass to bypass the heat transfer path between the arm flange and the arm bayonet.

The indentation may be a space of thermal insulation formed along the longitudinal direction of the inner tube.

The first path extension part may form an outer wall of the indentation part.

Each of the heat transfer path between the female flange and the female bayonet and the heat transfer path between the male flange and the male bayonet may be bent at least twice in the longitudinal direction of the inner tube.

The male bayonet may include a second path extension extending to the other side based on the female flange and the male flange coupled to each other, and may further include a connection portion connecting the male flange and the male bayonet.

A predetermined space may be formed between the second path extension part and the connection part, and the flange extension part may be positioned in an inserted state in the predetermined space.

The length of the heat transfer path between the female bayonet, the bypass portion and the female flange may correspond to the length of the heat transfer path between the male bayonet, the connection portion and the male flange.

The first path extension part and the indentation part may be located in one direction of the female bayonet with respect to the female flange and the male flange fastened.

One end of the male bayonet and the female bayonet may be connected to the inner tube through an O-ring or a seal.

According to another embodiment of the present invention, it is possible to provide a vacuum insulated pipe including the flange structure according to any one of claims 1 to 9 described above, in which a cryogenic liquefied gas flows into the inner tube.

1 is a view showing a conventional bayonet type vacuum insulated pipe
2 is a view showing a vacuum insulated pipe including a flange structure according to an embodiment of the present invention
3 is a view showing an upper portion of a vacuum insulated pipe including a flange structure according to an embodiment of the present invention.
Figure 4 is a view showing the heat transfer in the vacuum insulated pipe including the flange structure according to an embodiment of the present invention
5 is a view showing an upper portion of a vacuum insulated pipe including a flange structure according to another embodiment of the present invention.
6 is a view showing a heat transfer in the vacuum insulated pipe including the flange structure according to another embodiment of the present invention

Hereinafter, specific embodiments of the present invention will be described with reference to the drawings. However, this is only an example and the present invention is not limited thereto.

In describing the present invention, when it is determined that the detailed description of the known technology related to the present invention may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted. In addition, terms to be described below are terms defined in consideration of functions in the present invention, which may vary according to the intention or custom of a user or an operator. Therefore, the definition should be made based on the contents throughout the specification.

The technical spirit of the present invention is determined by the claims, and the following embodiments are merely means for efficiently explaining the technical spirit of the present invention to those skilled in the art.

The vacuum insulated pipe 100 according to the embodiment of the present invention is a pipe connected when the cryogenic liquefied gas is transferred to another chamber or device. Piping for minimizing the amount of liquefied gas is lost when vaporizing the cryogenic liquefied gas to another pipe or chamber, consisting of an inner tube 10 and the outer 20, between the inner tube 10 and the outer 20 By forming a heat path in the (heat path) it is possible to minimize the heat intrusion into the inner tube 10 through which the cryogenic liquefied gas passes. The vacuum insulated pipe 100 may include a flange structure positioned between the inner tube 10 and the double tube formed of the outer tube 20 to form a heat passage. The flange structure may include a female bayonet 31 and a male bayonet 41 to form a heat passage. In this case, the above-described heat passage may represent a heat transfer path through which heat transfer is performed from the inner tube 10 to the flanges 30 and 40 on the outside.

On the other hand, the vacuum insulated pipe 100 including a flange structure according to an embodiment of the present invention in the drawings may be symmetrical with respect to the longitudinal center of the inner tube (10).

2 is a view showing a vacuum insulated pipe 100 including a flange structure according to an embodiment of the present invention, Figure 3 is specifically showing an upper portion of the vacuum insulated pipe 100 including a flange structure according to an embodiment Drawing.

2 and 3, the flange structure according to an embodiment of the present invention is disposed between the inner tube 10 and the inner tube 10 through which the cryogenic liquefied gas flows and the outer tube 20 to prevent external heat intrusion Can be. At this time, the above-described exterior 20 may be spaced apart from each other to form an insulating space on the outer peripheral surface of the inner tube 10, by having a flange structure according to an embodiment of the present invention to the inner tube 10 through which liquefied gas flows. Minimizes heat intrusion.

In addition, the female flange 30 and the male flange 40 can connect the pipes to each other. Specifically, the female flange 30 and the male flange 40 may serve as joints connecting different components such as pipes and chambers to each other. The female flange 30 and the male flange 40 may be installed to protrude outside the exterior 20 between the inner tube 10 and the exterior 20. At this time, since the female flange 30 and the male flange 40 protrude outwards, external heat may enter the exterior 20 by the female flange 30 and the male flange 40. When heat enters into the double pipe through the female flange 30 and the male flange 40, the cryogenic liquefied gas flowing in the inner pipe 10 may be vaporized.

Therefore, the female bayonet 31 and the male bayonet 41 may be arranged so that heat penetrating through the female flange 30 and the male flange 40 is not transferred to the inner tube 10.

Specifically, the flange structure according to an embodiment of the present invention may include a female flange 30 and a male flange 40 that can be fastened to each other. And, the flange structure is connected to the female flange 30, and formed along the longitudinal direction of the inner tube 10 of the female bayonet (female bayonet) 31 and the inner tube 10 coupled to the inner tube 10 at one end. It may include a male bayonet 41 positioned adjacent to the female bayonet 31 along the longitudinal direction and coupled to the inner tube 10 at one end.

In addition, the above-described arm flange 30 is at least a portion of the inner tube 10 side of the female flange 30 is formed extending along the longitudinal direction of the inner tube 10, the flange extension portion connected to the other end of the arm bayonet 31 And (32). That is, the flange extension part 32 may be positioned adjacent to the female bayonet 31 in a shape surrounding at least a portion of the female bayonet 31 in a state connected to the other end of the female bayonet 31.

At this time, the above-described flange extension portion 32 is an indentation portion 321 which is a space formed by indenting one end surface of the flange extension portion 32 in the other direction from one end of the connection portion side with the female bayonet 31 and at least Some may include a first path extension 322 that defines a bypass 3220 that bypasses the heat transfer path between the arm flange 30 and the arm bayonet 31.

Specifically, the above-described first path extension part 322 may form an outer surface of the flange extension part 32 and may be formed in a shape surrounding the indentation part 321 inside. In addition, as the arm flange 30 and the arm bayonet 31 described above are connected through the first path extension 322, all or part of the first path extension 322 may be the arm flange 30 and the arm. It is possible to bypass the heat transfer path between the bayonet 31.

In this case, the above-described indentation part 321 may be formed by indenting a central portion of one end surface of the flange extension part 32 to a predetermined length, which may be a vacuum space formed along the longitudinal direction of the inner tube 10. have.

In detail, the first path extension part 322 is formed in a shape surrounding the indentation part 321 to form an outer surface of the flange extension part 32, thereby forming an outer wall of the indentation part 321. In addition, as described above, the indentation part 321 is formed by indenting a predetermined length from one end of the flange extension part 32 to the other side, and the first path extension part 322 surrounding the indentation part 321 is an arm bay. After extending to the other side in the portion connected to the other end of the on-net 31 may be formed to extend to the side to the female flange 30 and the male flange 40 is fastened again. That is, the longitudinal cross section may be formed in a “U” shape.

The female bayonet 31 and the male bayonet 41 may serve as heat passages through which the invaded heat passes. Therefore, the intrusion of heat from the outside can be prevented so that the liquefied gas in the cryogenic state can be smoothly transferred to the liquid state without vaporizing.

The female bayonet 31 may be coupled to the inner tube 10 at one end thereof and may be in contact with at least a portion of the arm flange 30 at the other end thereof and may be formed along the longitudinal direction of the inner tube 10. The male bayonet 41 may be coupled to the inner tube 10 at one end and may be formed along the longitudinal direction of the inner tube 10 so as to be close to the female bayonet 31.

Meanwhile, the male bayonet 41 has a second path extension part extending in the other direction opposite to one end connected to the inner tube 10 based on the female flange 30 and the male flange 40 which are fastened to each other ( 411). In addition, the vacuum insulated pipe 100 including the flange structure according to an embodiment of the present invention may include a connection portion 42 connecting the other end of the male flange 40 and the male bayonet 41. That is, the male flange 40 and the other second path extension part 411 of the male bayonet 41 may be connected through the connection part 42 described above, and the heat penetrating from the male flange 40 may be connected to the connection part 42. May be conducted to male bayonet 41.

At this time, the above-described connection portion 42 may be formed extending from the male flange 40 or the appearance 20, may be formed in a separate configuration and then bonded to each other. In addition, the length corresponding to the longitudinal direction of the inner tube 10 in the connecting portion 42 may be formed in a length corresponding to the length of the second path extension portion 411 of the male bayonet 41, the second path extension portion A side end contacting 411 may be bent to be in contact with the second path extension 411.

Meanwhile, the length of the heat transfer path between the female bayonet 31, the bypass portion 3220, and the female flange 30 is the length of the heat transfer path between the male bayonet 41, the connection portion 42, and the male flange 40. It may be formed to correspond to. For example, when the length of the female bayonet 31 and the length of the male bayonet 41 except for the second path extension 411 correspond to each other, the second bayonet 31 is connected to the female bayonet 31. The length of the bypass portion 3220 of the first path extension portion 322 and the length of the second path extension portion 411 and the connection portion 42 of the male bayonet 41 may be formed to correspond to each other.

In addition, the length of the extension of the flange extension portion 32 and the length of the second path extension portion 411 of the male bayonet 41 may include a heat transfer path at the female bayonet 31 side and the male bayonet 41 side. It may be determined depending on the length to be formed. That is, since the length of the heat transfer path required for thermal insulation for each cryogenic liquefied gas is present, it may be determined according to the type of liquefied gas flowing in the inner tube 10.

For example, liquid nitrogen should have a length of at least 600 mm and liquid helium at least 800 mm to minimize the amount of vaporization. At this time, when the liquid helium flows in the inner tube 10, the heat transfer path through the female bayonet 31, the bypass portion 3220, and the female flange 30, the male bayonet 41, and the connection portion 42. And the heat transfer path through the male flange 40 may be formed to have a length of at least 800mm or more.

At this time, the flange structure according to an embodiment of the present invention through the bypass portion 3220 and the connecting portion 42, even if the length of the female bayonet 31 and the male bayonet 41 is shorter than in the prior art Since a sufficient length of the heat transfer path is secured, the length of the entire vacuum insulated pipe 100 may be reduced, thereby freeing space constraints, and the size of equipment related to the piping equipment such as the chamber may be reduced together. In addition, the ease of maintenance, such as installation, separation and movement of the vacuum insulated pipe 100 can be improved.

On the other hand, in the vacuum insulated pipe 100 including a flange structure according to an embodiment of the present invention, the heat transfer path between the female flange 30 and the female bayonet 31 and the male flange 40, the connecting portion Each of the heat transfer paths between the 42 and the male bayonet 41 may be formed to be bent at least twice with respect to the longitudinal direction of the inner tube 10.

Specifically, the flange structure according to an embodiment of the present invention is the first bend bent at least twice in the heat transfer path connected to the arm bayonet 31, the first path extension 322 and the arm flange 30 It may include a portion 33. More specifically, the first bent portion 33 described above is about outside the inner tube 10 with respect to the longitudinal direction of the inner tube 10 in the process of entering the first path extension 322 from the arm bayonet 31. The first-first bent portion 331 bent by 180 ° and the other end (end in the direction of indentation) of the indentation portion 321 is bent by about 180 ° outside the inner tube 10 with respect to the longitudinal direction of the inner tube 10. It may include a 1-2 bending portion 332. In addition, the first-first bent by about 90 ° to the outside of the inner tube 10 with respect to the longitudinal direction of the inner tube 10 in the process of connecting to the outer exposed portion side of the female flange 30 in the first path extension 322. Three bent portion 333 may be further included.

In addition, the heat transfer path connected to the male bayonet 41, the connecting portion 42, and the male flange 40 may also include a second bent portion 43 bent at least twice, and the second bent portion 43 Is bent by about 180 ° outwardly of the inner tube 10 with respect to the longitudinal direction of the inner tube 10 in the process of connecting from the second path extension 411 of the male bayonet 41 to the connecting portion 42. 2-1 2-2 bends bent by about 90 ° to the outside of the inner tube 10 with respect to the longitudinal direction of the inner tube 10 in the process of being connected to the male flange 40 in the bent portion 431 and the connecting portion 42 It may include a portion 432.

As described above, the heat transfer path of the vacuum insulated pipe 100 including the flange structure according to an embodiment of the present invention includes a first bent portion 33 and a second bent portion 43 bent at least twice. Bar, even in the pipe of the same length as before, it is possible to further ensure a heat transfer path that the heat conduction occurs, it is possible to effectively block the heat intrusion into the inner tube 10 from the outside.

In the flange structure according to the exemplary embodiment of the present invention, the above-described flange extension part 32 may include a second path extension part of the male bayonet 41 based on the female flange 30 and the male flange 40 which are fastened to each other. 411 and the opposite side of the connection 42.

Meanwhile, a gas layer may be formed in the space between the female bayonet 31 and the male bayonet 41. When the cryogenic liquefied gas flows into the inner tube 10, a very small amount of liquefied gas may flow into the female bayonet 31 and the male bayonet 41. At this time, the liquefied gas introduced between the female bayonet 31 and the male bayonet 41 can be vaporized by a temperature difference, and the space between the interfaces facing the female bayonet 31 and the male bayonet 41 faces. (Ie, including the indentation 321), a vaporization layer may be formed.

As described above, a vaporization layer is formed between the female bayonet 31 and the male bayonet 41, and the formed vaporization layer may have a predetermined pressure to form a thermal insulation space that serves as a thermal barrier. In addition, as the vaporization layer having a predetermined pressure is formed between the female bayonet 31 and the male bayonet 41, additional liquefied gas inflow and leakage may not occur even when liquefied gas flows through the inner tube 10. have.

Furthermore, an O-ring or a seal may be disposed at the lower ends of the female bayonet 31 and the male bayonet 41. Specifically, the o-ring 50 prevents the gas between the female bayonet 31 and the male bayonet 41 from leaking, and at the same time, the inner tube described above for each of the female bayonet 31 and the male bayonet 41. Can be combined with (10). In addition, the inner tube 10, the female bayonet 31 and the male bayonet 41 may serve as a guide so that the fastening can be made smoothly.

Furthermore, the o-ring 50 is disposed between the inner tube 10 and the female bayonet 31 and includes a portion inserted between the inner tube 10 and the male bayonet 41. The bayonet 31 and the male bayonet 41 can be closed. Therefore, gas between the female bayonet 31 and the male bayonet 41 may not leak.

On the other hand, in the vacuum heat insulating pipe 100 according to an embodiment of the present invention, except for the vaporized layer formed between the inner tube 10 and the female bayonet 31 and the male bayonet 41 through which the cryogenic liquefied gas passes. The space may be in a vacuum. For example, there may be a vacuum between the male bayonet 41 and the inner tube 10. Therefore, the outer circumferential surface of the inner tube 10 can be maintained in a heat insulating state by vacuum. Such vacuum insulation can suppress heat transfer by gas. Vacuum insulation is 10 times more excellent thermal insulation than conventional polyurethane insulation (polyurethane) foam or polystyrene foam (polystyrene foam). In addition, it is possible to obtain an excellent energy saving effect by vacuum insulation.

4 is a view showing the heat transfer in the vacuum insulation pipe 100 including a flange structure according to an embodiment of the present invention.

Referring to FIG. 4, heat introduced into the male flange 40 may be conducted to the inner tube 10 through the male bayonet 41 including the connection portion 42 and the second path extension 411. Heat introduced into the arm flange 30 may be conducted to the inner tube 10 through the bypass portion 3220 and the arm bayonet 31 of the first path extension 322.

The vacuum insulated pipe 100 including the flange structure according to an embodiment of the present invention is connected to the male flange 40 through the male bayonet 41 and the connection portion 42 including the second path extension 411. A heat transfer path of sufficient length can be secured to block the incoming heat, and a sufficient length to easily block the heat entering the arm flange 30 through the arm bayonet 31 and the bypass portion 3220. The heat transfer path of the can be secured.

That is, the male bayonet 41 and the female bayonet 31 are not directly connected to the male flange 40 and the female flange 30, but adjacent to the male bayonet 41 and the female bayonet 31, respectively. After passing through each of the first path extension 322 and the connecting portion 42 is positioned so as to be connected to the male flange 40 and the female flange 30, the heat transfer from the outside to the liquefied gas in the inner tube 10 It is possible to effectively reduce the length of the entire inner tube 10 and the exterior 20 while securing a heat transfer path that can be sufficiently blocked. That is, the length of the female bayonet 31 and the male bayonet 41 can be reduced while minimizing the amount of vaporized liquefied gas.

5 is a view showing an upper portion of the vacuum insulated pipe 100 'including the flange structure according to another embodiment of the present invention, Figure 6 is a vacuum insulated pipe 100' including a flange structure according to another embodiment of the present invention Is a view showing the heat transfer in the). Although the lower part of the vacuum insulated pipe 100 'is not shown in the drawing, the lower structure of the vacuum insulated pipe 100' is the same as the vacuum insulated pipe 100 according to the embodiment of the present invention described above, and the detailed description thereof Omit it.

5 and 6, the flange structure according to another embodiment of the present invention wraps the inner tube (10 ') and the inner tube (10') through which the cryogenic liquefied gas flows to the exterior (20 ') to prevent heat intrusion outside It can be placed in between. At this time, the above-described exterior 20 'may be spaced apart from each other to form an insulation space on the outer circumferential surface of the inner tube 10', and the inner tube 10 through which the liquefied gas flows by having a flange structure according to an embodiment of the present invention. Minimize heat ingress into ').

Specifically, the flange structure according to an embodiment of the present invention may include a female flange 30 'and a male flange 40' that can be fastened to each other. And, the flange structure is connected to the female flange 30 ', the female bayonet 31' (female bayonet) and the inner tube which are formed along the longitudinal direction of the inner tube 10 'and coupled to the inner tube 10' at one end. It may include a male bayonet 41 'which is positioned adjacent to the female bayonet 31' along the longitudinal direction of 10 'and is coupled to the inner tube 10' at one end.

In addition, the above-described arm flange 30 'is formed by extending at least a portion of the inner tube 10' side of the arm flange 30 'along the longitudinal direction of the inner tube 10', and the other of the arm bayonet 31 '. It may include a flange extension 32 'connected to the end. That is, the flange extension portion 32 ′ may be positioned adjacent to the female bayonet 31 ′ in a shape surrounding at least a portion of the female bayonet 31 ′ while being connected to the other end of the female bayonet 31 ′. have.

At this time, the above-mentioned flange extension part 32 'is an indentation part 321 which is a space formed by indenting one end surface of the flange extension part 32' in the other direction from one end of the connection part side with the female bayonet 31 '. And at least a portion may include a first path extension 322 'defining a bypass portion 3220' that bypasses the heat transfer path between the arm flange 30 'and the arm bayonet 31'. .

Specifically, the above-described first path extension part 322 ′ may form an outer surface of the flange extension part 32 ′ and may be formed in a shape surrounding the inner indentation part 321 ′. In addition, since the arm flange 30 'and the arm bayonet 31' described above are connected through the first path extension 322 ', all or part of the first path extension 322' may be arm flange ( 30 ') and the arm bayonet 31' can be bypassed. In addition, the bypass portion 3220 ′ of the flange structure according to another embodiment of the present invention is the bypass portion 3220 of the flange structure according to the embodiment of the present invention formed through the entirety of the first path extension 322 ′. Unlike this, only part of the first path extension 322 ′ may be formed.

Specifically, the bypass portion 3220 ′ is a flange extension portion 32 ′ which is a direction in which the indentation portion 321 ′ is indented at a portion connected to the other end of the female bayonet 31 ′ of the first path extension portion 322 ′. The heat transfer path may be formed directly to the female flange 30 'side from the other end of the). At this time, the details of the above-described indentation 321 ′ are the same as the vacuum insulated pipe 100 including the flange structure according to the exemplary embodiment of the present invention, and thus detailed description thereof will be omitted.

Meanwhile, a second path extension 411 'may be formed in the male bayonet 41' of the flange structure according to another embodiment of the present invention, and the flange structure according to another embodiment of the present invention may have a second path. It may further include a connection portion 42 'connecting the extension portion 411' and the male flange 40 '.

However, in the vacuum insulated pipe 100 'including the flange structure according to another embodiment of the present invention, the second path extension part 41' and the connection part 42 'are not included in the above-described embodiment of the present invention. The same bar as the vacuum insulated pipe 100 including the flange structure according to, specific description thereof will be omitted.

In addition, in the vacuum insulated pipe 100 'including the flange structure according to another embodiment of the present invention, a predetermined space may be formed between the second path extension part 411' and the connection part 42 '. The flange extension 32 'described above may be positioned in a predetermined space between the second path extension 411' and the connection portion 42 'of the male bayonet 41'. That is, the flange extension 32 'and the connection 42' may be located in the same lateral direction with respect to the fastened female flange 30 'and the male flange 40'.

Meanwhile, the flange extension part 32 'described above may be formed in a shape corresponding to a predetermined space formed between the male bayonet 41' and the connection part 42 ', and the female flange 30' is thereby formed. And the corresponding position in the fastening process of the male flange 40 'can be fixed to the fastening position.

Meanwhile, in the vacuum insulated pipe 100 'including the flange structure according to another embodiment of the present invention, the heat transfer path and the male flange 40 between the female flange 30' and the female bayonet 31 'described above. '), Each of the heat transfer paths between the connecting portion 42' and the male bayonet 41 'may be formed bent at least twice with respect to the longitudinal direction of the inner tube 10'.

Specifically, the flange structure according to another embodiment of the present invention is bent at least twice in the heat transfer path connected to the arm bayonet 31 ', the first path extension 322' and the arm flange 30 '. The first bent portion 33 ′ may be included. More specifically, the first bent portion 33 ′ described above may have an inner tube 10 with respect to a length direction of the inner tube 10 ′ in the process of entering the first path extension 322 ′ from the arm bayonet 31 ′. ') The inner tube 10 relative to the longitudinal direction of the inner tube 10' at the other end (end in the direction of indentation) of the first-first bent portion 331 'and the indentation portion 321' that are bent by about 180 ° outward. ') May include the first-second bent portion 332' bent by about 90 °.

In addition, the heat transfer path connected to the male bayonet 41 ', the connecting portion 42' and the male flange 40 'may also include a second bent portion 43' bent at least twice. The bent portion 43 'is the inner tube 10' with respect to the longitudinal direction of the inner tube 10 'in the process of being connected from the second path extension portion 411' of the male bayonet 41 'to the connecting portion 42'. In the forming order with respect to the longitudinal direction of the inner tube 10 'in the process of being connected to the male flange 40' from the 2-1 bend portion 431 'and the connection portion 42' bent by about 180 ° outward It may include a 2-2 bent portion 432 ′, a 2-3 bent portion 433 ′ and a 2-4 bent portion 434 ′ each bent by about 90 ° in different directions.

Meanwhile, as described above, as the flange extension part 32 'is positioned in a predetermined space between the male bayonet 41' and the connection part 42 ', the second-2 bent part 432' and One end of the flange extension portion 32 ′ may correspond to the bent surface side between the 2-3 bending portions 433 ′.

As described above, the heat transfer path of the vacuum insulated pipe 100 'including the flange structure according to another embodiment of the present invention is at least twice bent the first bent portion 33' and the second bent portion 43 '. The bar may further ensure a heat transfer path in which heat conduction occurs even in a pipe having the same length as in the prior art, and effectively block heat intrusion into the inner tube 10 ′ from the outside.

While the exemplary embodiments of the present invention have been described in detail above, those skilled in the art will appreciate that various modifications can be made without departing from the scope of the present invention with respect to the above-described embodiments. . Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined by the claims below and equivalents thereof.

10, 10 ': inner tube
20, 20 ': appearance
30, 30 ': female flange
31, 31 ': female bayonet
32, 32 ': flange extension
321, 321 ': indentation
322, 322 ': first path extension
3220, 3220 ': bypass
33, 33 ': first bend
331, 331 ': 1-1 bend
332, 332 ': 1-2nd bend
333: 1-3 bent portion
40, 40 ': male flange
41, 41 ': male bayonet
411, 411 ': second path extension
42, 42 ': connection
43, 43 ': second bend
431, 431 ': 2-1 bend
432, 432 ': 2-2 bend
433 ': 2-3nd bend
434 ': 2-4 bend
50: O-ring
100, 100 ': vacuum insulated pipe

Claims (10)

In the flange structure located between the inner tube and the double tube consisting of the appearance,
A female flange and a male flange that can be fastened to each other;
A female bayonet connected to the female flange and formed along a longitudinal direction of the inner tube and connected to the inner tube at one end thereof; And
And a male bayonet positioned adjacent to the female bayonet along a longitudinal direction of the inner tube and connected to the inner tube at one end thereof.
The arm flange,
At least a portion of the inner tube side of the female flange is formed extending along the longitudinal direction of the inner tube, and includes a flange extension connected to the other end of the arm bayonet,
The flange extension,
An indentation that is a space formed by indenting one end surface of the flange extension portion from one end of the connection portion side with the female bayonet to the other side; And
A first path extension positioned to enclose the indentation, at least a portion of which defines a bypass to bypass the heat transfer path between the arm flange and the arm bayonet;
The indentation is a space of thermal insulation formed along the longitudinal direction of the inner tube,
The male bayonet includes a second path extension extending to the other side with respect to the female flange and the male flange coupled to each other,
Further comprising a connection for connecting the male flange and the male bayonet,
A predetermined space is formed between the second path extension part and the connection part.
The flange extension is positioned in the state inserted into the predetermined space,
One end of the flange extension portion is located facing the bent surface perpendicular to the longitudinal direction of the inner tube of the connecting portion,
And the flange extension and the connection portion are located in the same lateral direction with respect to the female flange and the male flange fastened to each other.
delete The method according to claim 1,
And the first path extension forms an outer wall of the indent.
The method according to claim 1,
Wherein each of the heat transfer path between the female flange and the female bayonet and the heat transfer path between the male flange and the male bayonet is bent at least twice in the longitudinal direction of the inner tube.
delete delete The method according to claim 1,
And the length of the heat transfer path between the female bayonet, the bypass portion and the female flange corresponds to the length of the heat transfer path between the male bayonet, the connection portion and the male flange.
The method according to claim 1,
And the first path extension and the indentation are located in one direction of the female bayonet with respect to the female flange and the male flange fastened.
The method according to claim 1,
One end of the male bayonet and the female bayonet is connected to the inner tube through an O-ring or a seal.
Including the flange structure according to any one of claims 1, 3 to 4 and 7 to 9,
Cryogenic liquefied gas flows through the inner tube, vacuum insulated pipe.

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