KR20190009935A - Dually adiabatic connected structure pipe - Google Patents

Abstract

According to the present invention, in a dually adiabatic connected structure pipe, when a dually adiabatic connected outside pipe and a dually adiabatic connected inside pipe couple a first flange and a second flange with each other, a radius of a first adiabatic outside pipe is larger than that of a second adiabatic outside pipe from the concentric axis, and a radius of a first adiabatic inside pipe is smaller than that of a second adiabatic inside pipe from the concentric axis.

Description

DUALLY ADIABATIC CONNECTED STRUCTURE PIPE}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a double vacuum piping, and more particularly, to a double heat insulation connection pipe for reducing a thermal conductivity by forming a vacuum on a flange.

Cryogenic liquids such as liquefied nitrogen, liquid oxygen, liquid hydrogen, liquid helium and the like generally have a temperature of at most 100K under atmospheric pressure and are stored in a container capable of maintaining such a cryogenic condition.

In order to transport the cryogenic liquid stored in the storage container to the transfer container or to transfer it from the transfer container to another storage container, a transfer pipe is required to transfer the cryogenic liquid between the storage container and the transfer container.

A known vacuum transfer tube is composed of an inner tube and an outer tube that surrounds the inner tube and forms a vacuum layer between the inner tube and the inner tube. The vacuum layer prevents heat transfer such as convective heat transfer and air heat conduction between the inner tube and the outer tube so that the cryogenic liquids delivered to the inner tube can maintain a cryogenic temperature.

However, since the conveyance pipe is a double pipe, when the conveyance pipe is installed horizontally, the inner pipe is deflected in the direction of gravity according to its length, and when it is installed vertically, the pipe bending The inner tube may be deviated from the center of the outer tube due to the external force. In this case, an adverse effect may occur that the heat penetration becomes active on the side where the inner tube faces toward the outer appearance.

In addition, for long-distance transmission of cryogenic liquids, a special device for the connection between the transfer tubes is required, and a rigid structure is further required while reducing the thermal conductivity.

Korean Patent Publication No. 2015-0095514

SUMMARY OF THE INVENTION The present invention has been conceived in order to solve the above-mentioned problems, and it is an object of the present invention to provide a vacuum double tube structure having an inner tube to which a cryogenic liquid is actually transferred and an outer tube that surrounds the inner tube and forms a vacuum layer therebetween, And it is an object of the present invention to provide a vacuum double-adiabatic connection structure pipe for cryogenic liquid transfer capable of minimizing the transfer.

In order to achieve the above-described object, the present invention provides a display device comprising: a first appearance; A first inner tube formed concentrically with the first outer tube; A first heat insulating inner tube positioned between the first outer tube and the first inner tube; A first heat insulating inner pipe positioned between the first heat insulating inner pipe and the first outer pipe; The first outer tube, the first inner tube, the first outer tube, and the first inner tube are fixed to the first flange, the first outer tube, the other inner tube is opened, And the first flange portion is closed from the first outer pipe to the first outer heat pipe and is opened from the first heat insulating outer pipe to the second heat insulating inner pipe and is closed from the second heat insulating inner pipe to the first inner pipe, It is characterized by appearance.

Also, a second appearance; A second inner tube formed concentrically with the second outer tube; A second heat insulating inner pipe positioned between the second outer pipe and the second inner pipe; A second heat insulating inner pipe positioned between the second heat insulating inner pipe and the second outer pipe; The second outer tube and the second inner tube are fixed to one side of the second flange portion while the other side of the second outer tube and the second inner tube is opened and one side of the second heat insulating inner tube and the second inner tube are fixed to the second flange portion The second flange portion is closed from the second outer pipe to the second heat insulating outer pipe and is opened from the second heat insulating outer pipe to the second heat insulating inner pipe, and the other end of the second heat insulating inner pipe is connected to the second heat insulating inner pipe, And the second inner tube is closed from the second inner tube to the second inner tube, wherein a double heat insulating connection tube is formed by the combination of the double heat insulating connection inner tube and the double heat insulating inner tube.

According to the present invention, heat transfer from the inner pipe through which the cryogenic liquid is actually transferred to the outside through the outer pipe is actually blocked. The formation of the first and second heat insulating portions and the first and second heat insulating portions in the longitudinal direction provides a sufficiently long heat transfer time and a sufficient heat transfer.

As a result, it is possible to minimize the invasion of the outside normal temperature to the cryogenic temperature of the inner tube.

1 is a cross-sectional view of a double insulation connection structure according to the present invention.
Fig. 2 is an exploded view of discrete components of the double insulation connection structure according to the present invention.
FIG. 3 is a view showing an assembly of individual components of the double insulation connection structure according to the present invention. FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will now be described in detail with reference to the accompanying drawings.

1 is a cross-sectional view of a double adiabatic connection structure for connecting dual pipes composed of an outer tube 100 and an inner tube 200 to each other. The double insulation connection structure is composed of a double insulation connection appearance and a double insulation connection inner pipe, which can be coupled through a flange or the like to integrate the insulation connection appearance and the double insulation connection inner pipe together. First, the outer appearance of the double heat insulating connection includes a first outer tube 10, a first inner tube 20 concentric with the first outer tube 20, And a first heat insulating outer pipe (40) and a first heat insulating inner pipe (30). The first adiabatic outer tube (40) is located between the first outer tube and the first inner tube. The first outer tube 10, the first inner tube 20, the first outer tube 40 and the first inner tube 30 are fixed to one side of the first flange 50. Further, the other side of the first outer tube and the first inner tube is opened, and the other side of the first heat-insulating tube (40) and the first inner tube (30) are interconnected. The first heat insulating inner tube 30 has a first radius from the concentric axis of the double tube or the first inner tube and the second inner tube, and the radius of the first heat insulating outer tube 40 is variable from the concentric axis. More specifically, one side of the first adiabatic outer tube and the first inner tube is fixedly coupled to the first flange, while the other side has the same radius as the first radius, And may be a position farthest from the first flange as an end of the first heat insulating inner tube and the first heat insulating inner tube. As the distance from the first flange increases, the distance between the first external heat pipe and the first internal pipe is narrowed or a certain distance may be maintained between the first external pipe and the first internal pipe. The first inner tube from the concentric axis has the same radius as the inner tube, and the first outer tube from the concentric axis is larger than the outer tube by the thickness of the outer tube.

This double insulation connection appearance is used in combination with the double insulation connection inner pipe.

The double insulated connection inner pipe includes a second outer pipe (12), a second inner pipe (22) concentric with the second outer pipe and a second outer pipe (42) forming a longitudinal extension of the heat pipe, 32). The second adiabatic outer tube (42) is located between the second outer tube and the second inner tube. The second outer tube 22 and the second inner tube 22 are fixed to one side of the second flange 50. On the other hand, the second heat insulating outer pipe 42 and the second heat insulating inner pipe 32 are fixed to the other side of the second flange. Further, the other side of the second outer tube and the second inner tube is opened, and the other side of the second heat-insulating tube 42 and the second heat-insulating tube 32 are interconnected. The second insulated inner tube 32 has a second radius from the concentric axis of the double tube or the second inner tube and the second inner tube and the second insulated outer tube 42 has a radius varying from the concentric axis. More specifically, one side of the second adiabatic outer tube and the second inner tube is fixedly coupled to the second flange, while the other side has the same radius as the second radius so that they are connected to each other. As the distance from the second flange increases, the distance between the second external heat pipe and the second internal pipe becomes narrower or a certain distance may be maintained between the second external pipe and the second internal pipe. The second inner tube from the concentric axis has the same radius as the inner tube, and the second outer tube from the concentric axis is larger than the outer tube by the thickness of the outer tube.

The double insulated connection appearance and the double insulated connection inner pipe are designed so that when the first flange and the second flange are fastened to each other, the radius of the first insulation appearance from the concentric axis is larger than the second insulation appearance and the radius of the first insulation inner pipe from the concentric axis And may be smaller than the second heat insulating inner tube. The second flange portion facing the first flange has a seal formed in the closed region from the second outer tube to the second outer tube and in the closed region from the second inner tube to the second inner tube.

The first flange and the second flange may be fastened by bolt connection, but the present invention is not limited thereto and various fastening means may be included within an equivalent range such as jointing.

FIG. 2 is a perspective view after disassembling the double heat insulating connection inner surface and the double heat insulating connection inner surface from the first flange 50 and the second flange 52, respectively. The outer surface of the double heat insulating connection includes a first outer tube 10, a first inner tube 40 having a double tube shape of the first inner tube 20 concentric with the first outer tube and a longitudinal extension of the thermal insulating tube, 30). A second outer tube (12), a second inner tube (22) concentric with the second outer tube and a second outer tube (42) and a second inner tube (32) forming a longitudinal extension of the thermal insulating part. The second adiabatic outer tube (42) is located between the second outer tube and the second inner tube. Particularly, the second flange of the double heat-insulating connection inner pipe is integrally formed by inserting the second heat-insulating outer pipe 42 into the hollow space in such a shape that a hollow space is formed at a certain distance from the concentric shaft.

Fig. 3 is a double-adiabatic connection structure tube integrated with the combination of a double-adiabatic connecting appearance and a double-adiabatic connecting inner pipe.

100 Appearance
200 inside
10 First appearance
20 1st Inner
30 1st insulating inner pipe
40 1st insulation appearance
50 1st flange
12 Second appearance
22 2nd Inner
32 2nd heat insulating inner pipe
42 Secondary Thermal Appearance
52 2nd flange

Claims (10)

A first appearance;
A first inner tube formed concentrically with the first outer tube;
A first annular outer tube positioned between the first outer tube and the first inner tube;
A first adiabatic outer tube positioned between the first inner tube and the first outer tube;
The first outer tube, the first inner tube, the first outer tube, and the first inner tube are fixed to the first flange,
The first outer tube, the other side of the first inner tube is opened,
The first heat insulating outer tube and the other side of the first heat insulating inner tube are mutually connected,
Wherein the first flange portion is closed from the first outer pipe to the first outer heat pipe and is opened from the first outer heat pipe to the second inner heat pipe and is closed from the second inner heat pipe to the first inner pipe. Double insulation connection appearance. The method according to claim 1,
Said first inner tube having a first radius from said concentric axis,
Wherein the first adiabatic outer surface has a radius variable from the concentric axis. The method according to claim 1,
And the other end of the first insulated inner tube and the first outer heat insulating tube are tapered to each other. Connecting the inner tube and the outer tube
The double-walled joint structure pipe according to any one of claims 1 to 3,
Wherein the first inner tube from the concentric shaft has the same radius as the inner tube,
Wherein the first outer tube from the concentric axis is larger in thickness by the outer tube than the outer tube. A second appearance;
A second inner tube formed concentrically with the second outer tube;
A second heat insulating inner pipe positioned between the second outer pipe and the second inner pipe;
A second adiabatic outer pipe positioned between the second inner heat pipe and the second outer pipe;
One of the second outer tube and the second inner tube is fixed to one side of the second flange portion while the other side of the second outer tube and the second inner tube is opened,
One side of the second heat insulating inner tube and the second heat insulating inner tube is fixed to the other side of the second flange portion,
And the other side of the second heat-insulating inner tube and the second heat-insulating inner tube are mutually connected,
Wherein the second flange portion is closed from the second outer pipe to the second outer heat pipe and is opened from the second heat insulating outer pipe to the second inner heat pipe and is closed from the second inner heat pipe to the second inner pipe. Double insulation connection internals. 6. The method of claim 5,
Said second inner tube having a second radius from said concentric axis,
Wherein the second insulated outer tube has a radius variable from the concentric axis. 6. The method of claim 5,
Said second inner tube having a second radius from said concentric axis,
Wherein the second insulated outer tube has a radius variable from the concentric axis. Connecting the inner tube and the outer tube
8. The double-ended joint structure tube according to any one of claims 5 to 7,
Wherein the second inner tube from the concentric shaft has the same radius as the inner tube,
Wherein said second outer tube from said concentric shaft is larger in thickness by said outer tube than said outer tube. A double insulation connection appearance according to any one of claims 1 to 3 and /
The double-layered heat-insulating pipe according to any one of claims 5 to 7, wherein when the first flange and the second flange are fastened to each other,
Wherein a radius of the first adiabatic outer tube from the concentric axis is larger than that of the second adiabatic outer tube,
And a radius of the first heat insulating inner tube from the concentric shaft is smaller than that of the second heat insulating inner tube. 10. The method of claim 9,
And the second flange portion facing the first flange is formed with a seal in a closed region from the second outer tube to the second outer tube and a region closed from the second inner tube to the second inner tube. Double insulation connection structure pipe.

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