JPH045838Y2 - - Google Patents

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to a transfer tube for supplying liquid helium, and more specifically, to a heat exchanger for cooling an object to be cooled to a cryogenic temperature or a heat exchange device for cryogenic cooling. etc.,
This invention relates to a transfer tube for supplying and recovering liquid helium.

[Conventional technology]

Liquid helium has an extremely low temperature of 4.2K, and when used as a refrigerant, it is easy to obtain extremely low temperatures, but on the other hand, it is very expensive.

Therefore, in order to send these liquid helium as a refrigerant from a supply source to a user side such as a heat exchange device, a multi-tube structure equipped with various insulation means is required to suppress temperature rise and vaporization during the delivery process. A transfer tube is used which is equipped with a recovery pipe for used gas-liquid helium.

As a prior example of a transfer tube for liquid helium supply having this multi-tube configuration, for example,
FIG. 4 is a cross-sectional view of the same, and A-A in FIG.
There is one shown in FIG. 5, which is a sectional view.

This conventional transfer tube for liquid helium supply is provided with a supply pipe 20 in the center for transmitting liquid helium to the user side and a recovery pipe 21 for recovering gas-liquid helium after use. , the shield pipe 22, and the shield pipe 2
It has a multi-tube structure in which a heat insulating material 23 that covers the outside of the heat insulating material 2, a holding tube 24 that holds the heat insulating material 23 from the outside, and a vacuum pipe 25 are sequentially arranged on the outside.

Then, the feeding pipe 20 and the recovery pipe 21
are supported by the shield pipe 22 at a distance from each other via retaining plates 26 which are arranged at a constant pitch in the axial direction within the shield pipe 22. Furthermore, upper and lower cooling pipes 28 and 29 are provided on the outer peripheral surface of the shield pipe 22 to circulate liquid nitrogen.

On the other hand, the holding tube 24 is supported by the vacuum pipe 25 at intervals through four support rods 27 provided radially in the outer circumferential direction in the same cross section and at constant pitches in the axial direction.

The conventional transfer tube for liquid helium supply having the above configuration creates a vacuum inside the vacuum pipe 25, while cooling the shield pipe 22 by circulating liquid nitrogen in the upper and lower cooling pipes 28 and 29. The insulation effect of the layer and the heat insulating material 23 suppresses heat intrusion from outside the system, and the cooling energy of gas-liquid helium recovered in conjunction with cooling with liquid nitrogen is used to cool the feed pipe 1 in a low-temperature environment. This suppresses the temperature rise and vaporization of the liquid helium being supplied.

Note that the holding plate 26 and the support rod 27 are made of fiber-reinforced resin with low thermal conductivity, while the heat insulating material 23 is made of a laminate such as super insulation, which has a high heat insulating effect. It is said to suppress heat intrusion through .

When liquid helium is sent to the user side using this transfer tube, the shield pipe 22 is first cooled with liquid nitrogen to a temperature of about 80K, and then the liquid helium at a temperature of 4.2K flows inside the feed pipe 20. While helium is sent, gas-liquid helium, which has been heated to about 20K through heat exchange within the recovery pipe 21 on the user side, is sent back.

[The problem that the idea attempts to solve]

However, in the above-mentioned conventional transfer tube for liquid helium supply, the supply pipe and the recovery pipe inside the shield pipe are supported by the shield pipe through the same holding plate, which prevents heat exchange. However, there is a drawback that the heat on the recovery pipe side that recovers the heated gas-liquid helium is directly transmitted to the feeding pipe side via these holding plates.

Furthermore, the lower part of the insulation material provided to cover the shield pipe is compressed by the weight of the shield pipe, supply pipe, and recovery pipe, and is no longer able to maintain the gap between the layers. There is a drawback that the heat insulating effect in the lower region is reduced due to close contact.

In view of the above-mentioned problems, the present invention prevents the heat from the recovery pipe that collects gas-liquid helium from being directly transmitted to the supply pipe, and also uses the shield pipe to exclusively transfer the cold heat of the gas-liquid helium to be recovered. It can be used for cooling, and the liquefied helium to be delivered can be placed in a lower temperature environment.Furthermore, the load on the insulation material covering the outside of the shield pipe can be reduced, and the insulation material can be reduced. It is an object of the present invention to provide a transfer tube for supplying liquid helium that can maintain its effectiveness and ensure suppression of heat intrusion from outside the system.

[Means to solve the problem]

In order to achieve the above object, the present invention has the following configuration. That is, the transfer tube for liquid helium supply according to the invention described in claim 1 includes a cooling medium circulation pipe outside the liquid helium supply pipe and the liquid helium recovery pipe, which are arranged at a distance from each other. A shield pipe provided along the outer peripheral axis direction, a heat insulating member covering the outside of the shield pipe, a holding pipe holding the heat insulating member from the outside, and a vacuum pipe provided outside the holding pipe. The holding tube is supported by the vacuum pipe via a plurality of rod-shaped supporting members arranged radially in the outer circumferential radial direction in the same cross section and at equal pitches in the axial direction. On the other hand, the supply pipe and the recovery pipe are integrated into a transfer tube for liquid helium supply, which is held by the shield pipe through retaining plates arranged at equal pitches in the axial direction within the shield pipe. The holding plate is of two types, one for holding the feeding pipe and one for holding the recovery pipe,
Moreover, these two types of holding plates are arranged alternately in the axial direction.

In addition, in the transfer tube for liquid helium supply according to the invention described in claim 2, at least two rod-shaped support members disposed downward in the same cross section of the holding tube each support the holding tube. A pipe that penetrates the pipe in the inner and outer radial directions, and is attached to the holding pipe at the middle part, with the outer end in contact with the inner circumferential wall of the vacuum pipe, and the inner end in contact with the outer circumferential wall of the shield pipe. It is.

〔Example〕

Embodiments of the present invention will be described below with reference to the drawings.

First Embodiment FIG. 1 is a cross-sectional view showing a transfer tube for supplying liquid helium according to a first embodiment of the present invention, and FIG. 2 is a cross-sectional view taken along the line AA in FIG. 1.

In Figures 1 and 2, 1 is a feed pipe, and 2 is a recovery pipe, which are made of stainless steel (JIS; SUS316L TD) pipes. On the other hand, the recovery pipe 2 is for recovering gas-liquid helium after heat exchange on the user side to a cooling liquefaction device.

The feed pipe 1 and the recovery pipe 2 are provided at a distance from each other, and a highly thermally conductive material A1 (JIS; A1050) is placed on the outside of these pipes.
TD) A shield pipe 3 made of a tube, a heat insulating material 4 made of a super insulation laminate made of a polyethylene sheet with A1 vapor-deposited covering the outside of the shield pipe 3, and a heat insulating material 4 held from the outside. A holding tube 5 made of a stainless steel (JIS; SUS304) plate and an airtight vacuum pipe 6 made of a stainless steel (JIS; SUS304) plate that surrounds the holding tube 5 at intervals are successively moved outward. They are arranged in multiple tubes.

7 is a feeding pipe holding plate, and 8 is a recovery pipe holding plate, which are made of fiber reinforced resin (FRP-G10) plates with low thermal conductivity, and as shown in FIG. are arranged alternately and at a constant pitch in the axial direction.

In addition, the feed pipe holding plate 7 and the recovery pipe holding plate 8 have both ends attached to the shield pipe 3.
The feed pipe 1 is fitted into two axial through holes, that is, the feed pipe holding plate 7, which is supported by the shield pipe 3 in contact with the inner wall surface and between both ends thereof. a holding hole 12 for supporting the
An idle hole 1 through which the recovery pipe 2 is passed through at intervals.
On the other hand, the recovery pipe holding plate 8 is provided with a holding hole 14 into which the recovery pipe 2 is inserted and supported, and an idle hole 15 through which the feeding pipe 1 is passed through at a spaced interval. . The feed pipe 1 and the recovery pipe 2 are held by the shield pipe 3 at a distance from each other via the feed pipe holding plate 7 and the recovery pipe holding plate 8.

9 is a support rod, and the support rod 9 is made of a fiber reinforced resin (FRP-G10) rod with low thermal conductivity,
Four pipes are provided on the outer periphery of the holding tube 5 in the same cross section of the holding tube 5 radially in the outer periphery radial direction and in pairs at a constant pitch in the axial direction, and their outer ends are brought into contact with the inner wall of the vacuum pipe 6. Holding tube 5
are supported by the vacuum pipe 6 at intervals.

On the other hand, on the upper and lower outer peripheral surfaces of the shield pipe 3,
Upper and lower cooling pipes 10 and 11 made of stainless steel (JIS; SUS316L TD) pipes for circulating liquid nitrogen are provided along the axial direction of the outer peripheral surface thereof, respectively.

The transfer tube for liquid helium supply of this embodiment with the above configuration maintains the inside of the vacuum pipe 6 in a vacuum, and its vacuum insulation effect suppresses heat intrusion from outside the system, while insulating the outside of the tube. The shield pipe 3 covered with the material 4 is connected to the upper and lower cooling pipes 1.
Liquid nitrogen is circulated and cooled within the pipes 0 and 11, and due to their cooling and insulation effects, the heat that enters from the outside is blocked and absorbed, suppressing the heat from entering the inside, and the internal supply pipe 1. in a low-temperature environment,
This suppresses the temperature rise and vaporization of the liquid helium being supplied.

In the transfer tube for supplying liquid helium of this embodiment, there is a supply pipe that supplies cryogenic liquid helium to the user side, and a gas-liquid helium heated by heat exchange on the user side. The recovery pipe that is sent back is different from the conventional one mentioned above.
Since each shield pipe is held by a separate holding plate, the heat from the recovery pipe side is not directly transferred to the supply pipe side, but rather is connected to the shield pipe, which is hotter than the gas-liquid helium being recovered. It is used exclusively for heat exchange, that is, to further cool the shield pipe.

Furthermore, unlike the conventional type mentioned above, the holding plate that holds the feed pipe only needs to support the load of the feed pipe. By making , for example, smaller, it is possible to reduce heat conduction from the shield pipe side through the holding plate.

As described above, according to the transfer tube for feeding liquid helium according to the present invention, the feeding pipe can be placed in a lower temperature environment, and the temperature rise and vaporization of the liquid helium to be fed can be further suppressed. can do.

Second Embodiment FIG. 3 is a cross-sectional view showing a transfer tube for supplying liquid helium according to a second embodiment of the present invention. This embodiment is the same as the first embodiment described above, except for the difference in the structure of the support rod that supports the holding tube on the vacuum pipe.Here, we will explain the overlapping points. This will be omitted and only the differences will be briefly explained.

In Fig. 3, 1 is a supply pipe, 2 is a recovery pipe, 3 is a shield pipe, 4 is a heat insulator, 5 is a holding pipe, 6 is a vacuum pipe, 8 is a recovery pipe holding plate,
10 is an upper cooling pipe, and 11 is a lower cooling pipe, which are the same as those in the first embodiment described above.

Further, as in the first embodiment described above, support rods are provided to support the holding tube 5 on the vacuum pipe 6 at intervals, but in this embodiment, the holding tube 5 has the same cross section. The two upper support rods 16 located above had the same structure as that of the first embodiment described above, while the two lower support rods 17 located below had the following structure.

That is, the lower support rod 17 located below the holding tube 5 is provided so as to pass through the holding tube 5 in the inner and outer radial directions, and its middle portion is attached to the holding tube 5, and the outer end is attached to the inside of the vacuum pipe. The shield pipe is provided on the peripheral wall with its inner end in contact with the outer peripheral wall of the shield pipe. The upper support rod 16 and the lower support rod 17 are made of fiber-reinforced resin (FRP-G10) rods, and the outer end of the upper support rod 16 and both ends of the lower support rod 17 are hemispherical. By reducing the contact area of the parts, heat transfer through these parts is suppressed.

According to the transfer tube for liquid helium supply of this embodiment having the above configuration, the shield pipe 3
The load applied to the insulation material 4 covering the outside of the system can be reduced by being applied to the holding tube 5 and the vacuum pipe via the lower support rod 17, and the insulation effect of the insulation material 4 can be maintained and the load applied to the outside of the system can be reduced. It is possible to ensure the suppression of heat intrusion from the inside.

[Effect of idea]

As described above, the transfer tube for feeding liquid helium according to the present invention can effectively utilize the cold energy of the gas-liquid helium to be recovered, and can place the feeding pipe in a lower temperature environment. Furthermore, heat intrusion from outside the system can be further suppressed, and
This has a great economical effect as it can further reduce the temperature rise and vaporization of liquid helium during the feeding process and improve its efficiency as a refrigerant.

[Brief explanation of drawings]

FIG. 1 is a cross-sectional view showing a transfer tube for liquid helium supply according to the first embodiment of the present invention, FIG. 2 is a cross-sectional view taken along line A-A in FIG. 1, and FIG. FIG. 4 is a cross-sectional view showing a transfer tube for feeding liquid helium according to an embodiment, FIG. 4 is a cross-sectional view showing a conventional transfer tube for feeding liquid helium, and FIG. It is a diagram. 1...Feeding pipe, 2...Recovery pipe, 3...
Shield pipe, 4... Insulation material, 5... Holding pipe,
6... Vacuum pipe, 7... Feeding pipe holding plate, 8
...Recovery pipe holding plate, 9...Support rod, 10...
Upper cooling pipe, 11...Lower cooling pipe, 16...
Upper support rod, 17...lower support rod.

Claims (1)

[Scope of Claim for Utility Model Registration] (1) A shield pipe in which a cooling medium circulation pipe is provided along the outer axial direction on the outside of a liquid helium supply pipe and a liquid helium recovery pipe that are spaced apart from each other. a multi-pipe structure comprising: a heat insulating member covering the outside of the shield pipe; a holding pipe holding the heat insulating member from the outside; and a vacuum pipe provided outside the holding pipe; The tube is supported by the vacuum pipe via a plurality of rod-shaped support members arranged radially in the outer circumferential radial direction in the same cross section and at equal pitches in the axial direction, while the feeding pipe and the recovery pipe are A transfer tube for liquid helium supply that is held and integrated with a shield pipe through holding plates arranged at equal pitches in the axial direction within the shield pipe, the holding plate comprising:
Liquid helium supply device characterized by having two types of holding plates: one for holding the feeding pipe and one for holding the recovery pipe, and these two types of holding plates are arranged alternately in the axial direction. transfer tube. (2) At least two rod-shaped support members disposed downward in the same cross section of the holding tube are each provided to penetrate the holding tube in the inner and outer radial directions, and the intermediate portion thereof is provided between the holding tube and the holding tube. 2. The transfer tube for liquid helium supply according to claim 1, wherein the transfer tube is attached to a vacuum pipe, and is provided with an outer end in contact with an inner circumferential wall of a vacuum pipe and an inner end in contact with an outer circumferential wall of a shield pipe.