DE3322405A1 - Pressure-proof connection between the ends of two pipelines - Google Patents

Abstract

In a pressure-proof connection between the ends of two pipelines, like a male-female connection, consisting of at least two pipes which are arranged concentrically with respect to one another, in which the annular space between the pipes, or at least one of the annular spaces in the case of more than two concentric pipes, is vacuum-insulated, the outer pipe ends are detachably bracketed to one another with interposition of an O-ring seal, and the inner pipes are firmly pressed against one another by the bracketing, the sealing of the inner pipes being achieved by means of annular ceramic discs which are fitted to the inner pipe ends.

Description

Pressure-tight connection between the ends of two conduits

The invention relates to a pressure-tight connection between the ends two conduits in the manner of a male-female connection, consisting of at least two pipes arranged concentrically to one another, in which the annular space between the tubes or, if there are more than two concentric tubes, at least one of the annular spaces is vacuum insulated.

The connection of vacuum-insulated lines for liquid helium to Various types of apparatus and also for connecting the vacuum-insulated lines with each other has so far been done with the help of screw or clamp couplings. For applications like sliding superconducting magnets, sliding superconducting generators or non-stationary cryostats, always form a deep-frozen solid connection Obstacle to handling.

So far one has helped by connecting the connection through a made looped flexible conduit. When the cryostat is rotated or of the generator, the amount of rotation was recorded by the loops, i. H. the twist has been converted into a bend in the conduit.

The present invention is based on the object of a connection between two conduits in the manner of a male-female connection, the is rotatable and in which the leakage losses are nevertheless reduced to a minimum.

In the case of a pressure-tight connection, this task is the one at the beginning mentioned type solved in that the outer pipe ends with the interposition of a O-ring seal are releasably clamped together and by the clamp the inner pipe ends are pressed tightly against each other, the sealing of the inner pipes by means of ring-shaped ceramic disks attached to the inner tube ends. The O-ring seal creates a seal against the outer annular space the atmosphere ensured, but rotatability is maintained. The ceramic disks provided on the inner tube ends seal due to their contact pressure against each other the interior of the inner tube towards the outside, with a rotation allow.

The ceramic disks sit on the inner tube ends with particular advantage on, protrude beyond the inner pipe end and are held in a chamber. These structural design is characterized by a particular simplicity at full Effectiveness. The ceramic rings are expediently through in the chamber Adhesive held. This is beneficial in making the connection off, d. H. the ceramic rings cannot fall out of the chamber. About that In addition, the bond creates a seal in the area of the chambers. L) ie against each other The surfaces of the ceramic rings are expediently ground flat, so that they lie against each other over a large area.

This achieves a tightness that is less than in the area 1 dr x l / (gt. In order to be able to control the contact pressure for the ceramic disks, is furthermore provided that in the immediate vicinity of the ceramic rings at least one Inner tube a bellows generating or regulating the contact pressure is arranged. In the installed state, the metal bellows is compressed and pushes due to the spring action, the ceramic disks against each other. The contact pressure can can be varied by different bellows or additional springs.

The O-ring seal is advantageously counteracted by a support ring Moving secured. This also simplifies the assembly of the pressure-tight Link. Greasing the O-ring seal ensures that the rotation in this The area is particularly easy to move, the greasing also ensures a improved sealing. The outer tube ends are clamped together with a clamping ring reached, the preload can be changed. Usually one gets the bias Choose as high as possible to avoid leakage losses in the area of the inner pipe ends and the Keep the outer pipe ends as low as possible. A slight decrease in preload increases the losses slightly, but makes turning much easier.

Since the pipes described are usually only for transport used by deep-frozen media is to the material that makes up the inner tube ends to seal, an increased requirement is made.

When transporting liquid helium, for example, there is prevailing in the inner tube and thus a temperature of around 4 ° K on the inner pipe wall as well. Normal Sealing materials, such as plastics or rubber, break at this small amount Temperatures very easily due to their brittleness. Pottery has opted for this Purpose proven to be particularly beneficial.

The invention is shown schematically on the basis of FIGS. 1 and 2 Embodiments explained in more detail.

FIG. 1 shows a lateral section through a connection according to FIG the teaching of the invention. FIG. 2 shows an enlarged representation of the inner pipe connection.

The invention is described using the example of a pipeline that consists of consists of four concentrically arranged corrugated metal tubes, which for example used to transport helium. The corrugated tubes 1, 2, 3 and 4 are held in a concentric position to one another by spacers (not shown). For establishing a connection between two such pipes or for connection such a line to a pipeline system consisting of four concentric pipes the tubes 4, 3 and 2 are first set down opposite the tube 1. On the ends the tubes 1, 2, 3 and 4 are screwed on screw sockets 5, 6, 7 and 8 and on the face side welded to the ends of tubes 1, 2, 3 and 4. The screw socket 5 is then a pipe section 9 is welded on and the screw sockets 5 and 6 via a pipe section 10 connected to each other in a pressure-tight manner. A pipe 11 is welded onto the screw socket 7, a closing ring 12 is welded to its free end. On the locking ring 12 becomes a further pipe section 13 with the formation of an annular space between the pipes 11 and 13 aufgeschweilit, the other end of which is welded to a flange ring 14 is.

The flange ring i4 is connected to the screw socket via a pipe section 15 8 welded. The end just described is the so-called male end of a quadruple coaxial line, in which the space between pipes 1 and 2 and 3 and 4 is vacuum insulated, whereas cold gas flows through the space between pipes 2 and 3. On the So-called female ends become the screw sockets after appropriate preparatory work 5 a, 6 a, 7 a and 8 a screwed on and in the same way with the Pipes 1, 2, 3 and 4 welded. The attachment of the parts 9 a, 10 a and 15 a is done in the manner described above. In contrast to the male ending, however, there is only one Tube 16 is welded onto the screw socket 7 a and welded to the flange part 14 a. It is essential that the inner diameter of the tube 16 is only slightly larger than the outside diameter of the tube 13, so the male end into the female end can be easily pushed in without causing large losses of cold in this area comes. The two ends are fixed against each other by a so-called Clamping ring 17, which comprises the flange parts 14 and 14 a.

To make such a connection rotatable, as for example is desirable for displaceable superconducting magnets, for superconducting generators or non-stationary cryostats, is provided between the flange parts 14 and 14 a to provide an O-ring seal 18 to increase the rotatability and the Seal is greased.

A support ring 19 is intended to prevent the O-ring 18 from shifting.

The connection of the inner tubes 1 to one another is achieved by dalf at the end of the pipe sections 9 and 9 a chambers 20 and 21 are provided, in which ceramic rings 22 and 23 are arranged, which over the end of the pipe sections 9 and 9 a protrude. The required contact pressure to create the seal in this Ensure area is applied by the clamping ring 17. One in the pipe section 9 welded bellows 24 ensures the necessary contact pressure of the ceramic disks 22 and 23. The ceramic disks 22 and 23 are glued in the chambers 20 and 21, on the one hand to prevent falling out when joining the two ends, on the other hand however, to ensure the tightness at this point. A particularly high sealing effect is achieved when the mutually contacting end faces of the ceramic disks 22 and 23 planned are ground, which also makes it possible to rotate is increased in this area. Since inside the tubes 1 a temperature of approximately 4 0K prevails and thus the ceramic disks 22 and 23 are approximately the same Assume temperature is a special material for sealing in this area necessary. Ceramic has proven to be a sealing material for such low temperatures proven to be excellent. The tightness of the ceramic discs pressed flat on top of one another 22 and 23 is in the range less than 10-1 mbar x ljs. Do you want rotatability? increase in the area of the flange parts 14 and 14 a, so you can expediently the clamping ring train so that a loosening between the flange 14 and 14 a possible without the leakage losses increasing in this area in an impermissible manner.

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Claims (8)

Claims 4 .; Pressure-tight connection between the ends of two Line pipes in the manner of a male-female connection, consisting of at least two concentrically arranged tubes, in which the annular space between the Pipes or, if there are more than two concentric pipes, at least one of the annular spaces is vacuum-insulated, characterized in that the outer pipe ends are interposed an O-ring seal (18) are releasably clamped together and by the clamp the inner pipe ends are pressed tightly against each other, the sealing of the inner pipes achieved by attached to the inner tube ends annular ceramic disks (22, 23) is. 2. Pressure-tight connection according to claim 1, characterized in that that the ceramic disks (22, 23) sit on the inner tube ends, over the inner tube end protrude and are held in a chamber (20, 21). 3. Pressure-tight connection according to claim 1 or 2, characterized in that that the ceramic rings (22, 23) held in the chamber (20, 21) by adhesive are. 4. Pressure-tight connection according to claim 1 or one of the following, characterized in that the surfaces of the ceramic rings pressed against one another (22, 23) are ground flat. 5. Pressure-tight connection according to claim 1 or one of the following, characterized in that in the immediate vicinity of the ceramic rings (22, 23) at least a bellows (24) generating the contact pressure is arranged on an inner tube. 6. Pressure-tight connection according to claim 1 or one of the following, characterized in that the O-ring seal (18) is supported by a support ring (19) is secured against shifting. 7. Pressure-tight connection according to claim 1 or one of the following, characterized in that the O-ring seal (18) is greased. 8. Pressure-tight connection according to claim 1 or one of the following, characterized in that the clamping of the outer pipe ends by a clamping ring (17) is reached, the bias of which can be changed.