FR2667921A1 - Metal tube with helix or ring-shaped corrugations - Google Patents

Abstract

Metal tube welded lengthwise with ring or helix shaped corrugations for transporting a liquid or gaseous medium, with a layer adjacent to the wall of the tube which is located inside the corrugated tube (1, 7), bears on the troughs of the corrugations and consists of a flexible tubular product extending over the entire length of the tube (6, 8), for example made of a metal braid or a strip of metal wound with its edges overlapping and forming a tube. This layer decreases the noise of the flow.

Description

NETAILIC TUBE WITH RINGS IN THE FORM OF PROPELLERS OR RINGS
The invention relates to a metal tube welded lengthwise with corrugations in the form of rings or helices for transporting gaseous or liquid medium with a layer adjacent to the wall of the tube serving to reduce the noise of the flow.

Corrugated tubes because of their many advantages such as flexibility, transverse stiffness as well as the possibility of manufacturing and transporting them in great length find very numerous applications where gas and liquids have to be transported. Corrugated pipes have additional important advantages, namely that they can be installed without great expense of infrastructure in great length without numerous connecting stations and that the provisions to compensate for variations in temperature or expansion are superfluous because corrugated tubes can compensate for variations in length themselves.

Because of the advantages indicated, corrugated pipes are preferred in concentric flexible pipe systems, for example as pipes for cryogenic media, preferably used as leak monitoring pipes or as pipes for remote heat transport.

A known drawback of corrugated tubes is that at a determined flow speed the flowing medium gives rise to longitudinal oscillations which can cause premature destruction of the corrugated tube. The cause of these longitudinal oscillations is a vortex which begins in the ripple. At high flow speeds, the ribbons detach from the hollows of the corrugations, which is linked to the creation of an unpleasant noise. We tried to eliminate this disadvantage by placing a knitted fabric on the corrugated tube which must stop or oppose the longitudinal oscillations.

Another solution to this problem is to thread and fix from the inlet of the flow into the corrugated tube pieces of short and smooth tube.

Both solutions decrease the flexibility of corrugated tubes. The second solution also has the disadvantage that it can only be applied effectively for short tube lengths
The purpose of the invention is therefore to provide a solution to the problem which makes it possible to prevent the generation of longitudinal oscillations in corrugated tubes without the flexibility of the tube being significantly reduced and the possibility of manufacturing long lengths of tube. be prevented.

This problem is solved thanks to a layer which is inside the corrugated tube and which rests on the hollows of the corrugations and which is constituted by a flexible tubular product extending over the entire length of the tube. Thanks to the smooth-walled layer which covers the profile of the corrugated tube, any generation of vortices is prevented in the corrugations.

According to a particularly advantageous improvement of the invention, the tubular product consists of a wire mesh. Such metal mesh is known in itself as a reinforcing layer for corrugated tubes. They can be in the form of a hose and can be threaded through the finished tube. However, this is only possible up to lengths of 30 meters. For longer lengths it is useful that the mesh or fabric pipe is continuously wrapped by the metal strip which must form the tube. A lattice or fabric strip can also be formed at the same time as the metal strip into a tube.

It is particularly advantageous if the layer consists of a fabric or mesh strip which is formed into a tube with its overlapping sides directed in the longitudinal direction of the corrugated tube. This embodiment goes quite well with the manufacture of corrugated tubes. However, care must be taken to ensure that the fabric or mesh forms a smooth tube and is not wavy when making the corrugations.

When choosing the fabric or mesh, care must be taken that the average free opening area is less than 25%, preferably less than 10%. This dimensioning is advantageous because with lattices or fabrics with large meshes, one cannot prevent the birth of vortices. It is particularly advantageous to use trellises or fabrics with practically 100% overlap, in which the wires constituting the trellis or the fabric are directed at an angle of 30 to 600 with the longitudinal axis of the tube. In this case one should not fear a decrease in the flexibility of the corrugated tube because of the mesh or the fabric.

According to another embodiment, the internal layer may consist of a metal strip wound in a helix with its edges overlapping.

The covering is necessary so that during a curvature of the corrugated tube we continue to have a closed layer. For this reason the recovery must be at least 25%.

It is especially advantageous if the corrugated tube is made of stainless steel. Likewise the inner layer, that is to say the mesh, the fabric, etc., where the rolled up metal strip must then be made of stainless steel. So that the internal layer during a vertical displacement is not displaced, this one is forcibly bonded with the corrugated tube. This is advantageously carried out by bringing the trellis pipe or the trellis strip into the tube with a longitudinal tension during the continuous manufacture of the tube. The rolled-up tube is advantageously put with pre-tension in the form of a tube with a diameter smaller than the corrugated tube and the pre-tension after the corrugation step is released so that the turns of the metal strip are supported on the internal surfaces of the corrugated tube.

A preferred field of application for the corrugated tube according to the invention consists of the pipes for the transport of cryogenic medium
For these coaxial tube systems consisting of two corrugated tubes in which the annular space between the tubes has been emptied and is provided with a super-insulating layer, the corrugated tube according to the invention constitutes the lower tube.

Between the metal tube and the internal layer, it is advantageous to provide an additional layer which, preferably, is a metal layer. This additional layer must prevent the internal layer from coming into direct contact with the corrugated tube. For metals which have the disadvantage of sticking, this additional layer serves as a separating layer or a lubrication layer.

The invention will be described more precisely with the aid of the exemplary embodiments shown diagrammatically in FIGS. 1 to 3.

In Figure 1 is shown a pipe for the transport of cryogenic medium which consists of an inner tube 1 with corrugations in the form of helices, preferably made of V2A steel, of a layer wound with aluminum foil, d 'a spacer 3 wound in a helix, with a super-insulating layer 4 between the turns of the spacer 3 as well as an outer tube 5 which is also a metal tube with corrugations in the form of a helix. The annular space between the tubes 1 and 5 is evacuated.

Unpleasant noises and oscillations can occur at high flow velocities.

 To eliminate these drawbacks, a metal mesh 6 which has the shape of a tube and which rests on the internal wall of the tube 1 is placed in the lower tube 1 which conducts the medium. The metal mesh 6 can be braided in a tube or formed into a tube from a strip with its sides overlapping. The trellis 6 is preferably made with special steel wires. It has a free opening area of less than 10%. The individual wires form an angle of approximately 450 with the longitudinal axis of the tube 1.

Figure 2 shows a corrugated tube 7 in which is arranged a propeller 8 consisting of a rolled metal strip. The metal strip is wound with edges which overlap so that the closed inner layer also remains maintained during the bending of the tube 7.

The trellis tube 6 like the coiled tube 8 is applied to the internal wall of the coiled tube 1 or 7 so that a longitudinal displacement of the internal layer 6 or 8 inside the tube 1 or 7 is hardly possible.

 Additional security against the longitudinal displacement of the layer 6 or 8 is constituted by its attachment to the end of the tube system.

In Figure 3 there is shown a partial view of the wall of the tube on which it can be seen that between the corrugated tube 1 or 7 and the inner layer 6 or 8 is provided a layer 9 of metal which must prevent welding to cold or seizure between layer 6 or 8 and corrugated tube 1 or 7.

Such a danger exists in particular when both the corrugated tube and the inner layer 6 or 8 are made of stainless steel. Cold welding can be prevented by means of a layer 9 of a copper foil wound in the form of a helix.

Claims (10)

CLAIMS: 1. Metallic tube welded lengthwise with corrugations in the form of rings or helices (1) for the transport of a gaseous or liquid medium, with a layer adjacent to the wall of the tube serving to reduce the noise of the flow, characterized in that the layer is a flexible tubular product (6,8) extending over the entire length of the tube inside the corrugated tube (1,7) and resting on the hollows of the corrugations. 2. Metal tube according to claim 1, characterized in that the tubular product (6,8) consists of a wire mesh. 3. Metal tube according to one of claims 1 or 2, characterized in that the layer consists of a fabric, lattice, knit (6) or other strip which is formed into a tube with its overlapping sides directed in the longitudinal direction of the corrugated tube (1). 4. Metal tube according to one of claims 1 to 3, characterized in that the internal layer forming the mesh fabric, knitted fabric (6) etc., has an average free opening area of less than 25% and preferably of less than 10%. 5. Metal tube according to claim 1, characterized in that the tubular product (6,8) consists of a metal strip (8) wound in a helix with its edges overlapping. 6. Metal tube according to claim 5, characterized in that the metal strip (8) is wound with an overlap of at least 25%. 7. Metal tube according to one of claims 1 to 6, characterized in that the metal tube (1,7) as well as the inner layer (6,8) is made of stainless steel.  8. Metal turbine according to one of claims 1 to 7, characterized in that the internal layer (6,8) is forcibly bonded with the corrugated tube (1,7). 9. Metal tube according to one of claims 1 to 8, characterized in that the corrugated tube (1) provided with the internal layer (6) constitutes the inner tube of a pipe made up of two corrugated tubes (1,5) arranged concentrically with respect to each other, in which a super-insulating layer (4) is arranged in the annular space between the tubes (1,5), said space having been evacuated. 10. Metal turbine according to one of claims 1 to 9, characterized in that between the metal tube (1,7) and the internal layer (6,8) is arranged an additional layer (9) preferably a metal layer .