DE2349550C2 - Cold transport line - Google Patents

Description

The invention relates to a Käi ^ transport line with two side-by-side extending källetransportmittelrohre, a Strahlungsscb m, which the two Surrounds refrigerant pipes and by means of a spacer made of plastic at a distance is held by the tubes, two coolant tubes extending adjacent to the radiation shield, the lie on the outside of the radiation shield and thus are in thermal contact, and a vacuum jacket, which surrounds the radiation shield and the two coolant tubes and by means of a spacer device made of plastic is held at a distance from them.

A cold transport kit of the type to which the present invention relates is shown in FIG US-PS 33 64 687 known.

In the known cold transport line, the cold transport pipes flow through high pressure helium, the on the one hand in heat exchange with a liquid helium bath and on the other hand with an object to be cooled. while liquid nitrogen through the coolant tubes for cooling the radiation shield surrounding the cold transport medium pipes at a low temperature to be led.

Instead of a liquid helium bath as a cold source, z. B. also a single or multi-stage gas refrigerator are used, as described in US-PS 34 73 341, in which then also helium under Pressure can flow through the K coolant pipes.

In known cold transport lines of the present type, the cold transport tube, the Radiation shield, the coolant tubes and the vacuum jacket are rigid components that also pass through Spacers are kept at a distance. Such cold transport lines are normally made of Metal pipes made, mostly from steel or copper. For the refrigerant pipes is also used Invar is used because of its low coefficient of expansion.

The rigid cold transport lines have different Disadvantages on.

Although they are made pretty well on-site for certain laboratory setups if the overall arrangement is known they are less suitable for factory production Dk in one

κι factory production of rigid cold transport lines, which in practice often have lengths of about 5 to 15 m, must because of the transport be done in parts. The assembly of the parts is a time consuming, complicated and costly affair-

i. ness and therefore undesirable

In use, the rigid cold transport lines are difficult to handle and their freedom of movement is extremely limited.

In addition, there is a great risk that vibrations,

J »those from the cold source (ζ. Β a cooling machine) originate, as well as shocks easily over the rigid cold transport line transferred to the object to be cooled (e.g. a measuring instrument such as an infrared cell) and exert a disruptive influence.

. '■ Now, in cryogenic technology, there are different Kiiltetransportleitung for simple applications and thus with a simpler structure with an inner and an outer tube known, which consist of flexible bellows (US-PS 32 40 234. GB-PS 12 74 285).

ω application of flexible bellows for the entirety of the both cold transport medium pipes. the radiation shield, the two coolant pipes and the vacuum jacket of the present cold transport line larger Length would, however, lead to great structural complications

B nen. too large diametrical dimensions and too lead to large cold losses. High mean pressures in the refrigerant and coolant bellows in the Vacuum jacket would require additional structural measures because of the expansion of these bellows due to the large pressure differences above it.

The present invention aims to provide a cold transport line of the indicated kind / u create the. while maintaining the structural simplicity, perfect is flexible, as a result it can be manufactured in large lengths and in the factory production Cryogenic applications offer a particularly great freedom of installation, the low diametrical Dimensions and relatively light in the

■ so is weight. which has minimal cold losses and withstands high mean pressures in the refrigerant and coolant pipes without additional measures.

The cold transport line according to the invention is

characterized in that the refrigerant pipes, the radiation shield and the coolant tubes are made of plastic, with the refrigerant tubes are suspended from the radiation screen via flexible wires or straps made of plastic and wherein the radiation shield is connected to the coolant tubes via flexible wires or strips made of plastic Support rings is suspended, which are arranged coaxially in the vacuum jacket designed as a flexible bellows and their atissen-major knives at least is almost equal to the inner diameter of the bellows,

Although it is often claimed in the literature that Plastics are generally quite brittle at low temperatures, it has surprisingly been found pointed out that good quality refrigeration

gen can be realized.

An embodiment of the invention is described below with reference to the drawing, which is schematic and not is to scale, explained in more detail. It shows

Fig. I an embodiment of the invention Cold transport line in cross section,

F i g. 2a shows, in longitudinal section, the coupling of a flexible plastic pipe to a stelf-walled connecting pipe,

Fig.2b shows a cross section at the point of the line II6-IIZ) according to Fig.2a.

In Fig. 1, the reference number 1 is a cold transport line indicated, which is constructed as follows. Two refrigerant pipes 2 made of nylon are in the Distance through a Strablungsschirm 3 made of polytetrafluoroethylene surround. On the outside of the radiation shield 3 there are two coolant pipes 4 Nylon, which are in thermal contact with the radiation shield 3. The radiation shield 3 with the two Coolant pipes 4 are spaced apart by the flexible bellows 5 made of stainless steel as a vacuum jacket surrounded, which means that the space in the flexible bellows 5 can be evacuated.

The nylon refrigerant pipes 2 made of nylon are with the help of nylon wires 6, which over part of their Length wrapped around these tubes, locally suspended on the radiation shield 3. The suspension is in such a way that the central position of the two refrigerant pipes 2 in relation to the radiation shield 3 remains retained.

The radiation shield 3 is together with the coolant pipes 4 via nylon straps 7 on aluminum support rings 8 suspended, a number of which over the length of the cold transport line 1 in the flexible Bellows 5 are distributed and arranged coaxially therewith. The outer diameter of the support ring 8 is almost the same the inner diameter of the flexible bellows 5. As a result, there is a tight fit of the support ring in the bellows and no other fasteners are required.

One of the two coolant tubes 4 lies over a contact layer 9 made of thermally conductive material or from a paste containing aluminum powder firmly on Radiation screen 3 on. Around the structure of the mentioned coolant pipe and the radiation shield is a Strip 10 wound from copper foil. The other coolant pipe is in one of the barked places where the strip cover passes over from the radiation brain / around tightly fitting coolant tube and presses there to the strip cover.

The thermally conductive Sc ^h maybe 9 and the copper foil strips provide fo. "Good thermal contact between the coolant tubes 4 and the third to be cooled radiation shield on cooling from room temperature to the low operating temperature, the nylon Kiihlmittelrohre shrink 4 more than the copper foil is OK. The good thermal contact The coolant pipe lying outside the envelope of copper foil strips then pushes the envelope further inwards so that it still rests firmly on both the radiation shield 3 and the coolant pipe in the envelope.

In order to reduce cold losses through radiation, is around the structure of the copper foil strip envelope 10 and the coolant pipe 4 lying outside this envelope a radiation reflective tape 11 wound, which consists of film made of the plastic Mylar, whose The outer surface is aluminized.

Between the aluminized mylar and the copper foil There is a layer of Verbaiidgaze 12 that prevents the mylar from getting through the sharp edges the Kupfc. foil is damaged. Another degradation of cold losses due to -on radiation is achieved in that the two refrigerant pipes 2 with a radiation reflective tape 13 are wrapped in aluminized mylar.

The cold transport line described has been implemented and successfully tested.

The length of the line was 10 meters and de ^r outer diameter of 75 mm.

The nylon refrigerant pipes had an inside diameter of 5 mm and an outside diameter of 7 mm. For the polytetrafluoroethylene radiation shield the outside diameter was 28 mm and the wall thickness 2 mm. The outside diameter of the Nylon coolant tubes were 8 mm; the wall thickness was also 2 mm.

Depending on the two refrigerant pipes on the radiation shield, the distance between the aluminum rings, on which the structure of the radiation shield and coolant pipes was suspended, was 20 cm. 40 cm bent.

t-'ig. 2 shows how one end 20 is one of the four Nylon pipes (refrigerant and refrigerant pipes) is coupled to a jet connecting pipe 21. That To this end, the end 20 is pushed onto the connecting tube 21 and then pushed into one another by conical ones Bushings 22 and 23 clamped. The inner sleeve 22 is cut lengthwise for better convenience To achieve clamping effect.

The connecting pipe 21 is. like the three other tubes, not shown, through the rigid end wall 24 of the flexible bellows 5 passed through to the outside.

1 sheet of drawings

Claims (1)

Claim: Cold transport line with two cold transport medium pipes extending next to one another, one Radiation shield, which surrounds the two tubes of refrigeration transport medium and by means of a spacer device made of plastic is held at a distance from the pipes, two coolant pipes extending next to the radiation shield, which are on the outside of the radiation shield and are thus in thermal contact, and one Vacuum jacket, which surrounds the radiation shield and the two coolant pipes and by means of a Spacer device made of plastic is kept at a distance from them, characterized in that that the refrigerant pipes (2), the radiation shield (3) and the coolant pipes (4) are made of a plastic, wherein the refrigerant pipes (2) via flexible wires or strips made of plastic (6) on The radiation shield (3) are suspended and the radiation shield (3) with the coolant pipes (4) is suspended via flexible wires or strips made of plastic (7) on support rings (8), which is coaxial in the as a flexible bellows (5) designed vacuum jacket are arranged and their outer diameter is at least almost equal to the inner diameter of the bellows (5).