FR2528240A1 - Semi-rigid aluminium waveguide for microwave transmission - comprises corrugated metallic strip joined by folding and crimping and has dual flanges for clamping terminating ends. - Google Patents

Abstract

A strip of aluminium (1) has a corrugated (2) cross section and is wound to form a rectangular cross section guide about the lengthways axis (00'). The cross section has a radius of half the depth (b) of the guide. The edges of the strip are hooked and crimped (4) to avoid a solder join to the next section of strip. The two ends of the guide are terminated by flanges (7) which can be aluminium or of another metal. Aluminium flanges may be welded to the guide while other metal live flanges comprise double flanges which clamp the ends of the guide. A flexible sealing cover is applied over the guide. The semiflexible guide may be coupled directly to rigid guide sections to form bends or T joins without intermediate flange connections.

Description

SEMI-RIGID WAVEGUIDE
The present invention relates to a semi-rigid waveguide.

 So-called flexible waveguides are known in the prior art. These waveguides have the advantage of being easily deformable. They are used in assemblies comprising a certain number of elements such as waveguides, but also, for example, microwave tubes, phase shifters, attenuators, couplers; all these elements are connected to each other by flanges.

 The installation of one of the assembly elements or its replacement is easier if using flexible waveguides therefore deformable.

Among the flexible waveguides, there are:
- the semi-rigid waveguides which are for example obtained from a corrugated and wound brass band, generally in a helix. The edges facing the strip are connected by a welded joint;
- the flexible waveguides which can also be obtained from a strip of corrugated brass wound in a helix. The neighboring edges of the strip have a seal that is not welded but is provided with a contact wire. It is possible without damaging them to impart to the flexible waveguides a torsional deformation, while the semi-rigid waveguides do not support this type of deformation.

 The present invention relates to a semi-rigid waveguide of any section which consists of at least one ribbon of alto minium, of corrugated cross section, which is wound, along said section, along an axis constituting the guide axis. The edges facing the ribbon are made integral by stapling and crimping.

 The guides according to the invention have great advantages over known semi-rigid guides.

Among the advantages of the guides according to the invention, there may be mentioned:
- The low cost of production which is due to the fact that the guides according to the invention are made of aluminum, while the guides according to the prior art are generally made of more expensive materials, such as beryllium copper. In addition, the guides according to the prior art comprise a finishing layer, in silver for example, which protects them against corrosion; while the guides according to the invention, made of aluminum, are covered with a layer of alumina which is not a nuisance and does not require a finishing layer. In addition, it should be noted that the guides according to the invention can be obtained from commercial heating ducts;
- the possibility of producing guides of large dimensions and low weight because of the use of aluminum.

 Flexible guides made of aluminum are not known in the prior art. In fact, unlike other materials such as beryllium copper, aluminum does not have interesting elasticity properties. However, experience has shown that the semi-rigid aluminum guide according to the invention, thanks to the present corrugations and the small thickness of the tape, could undergo a very significant elongation along its axis.

 Furthermore, it is considered as a surprising effect recorded in the laboratory that the microwave losses presented by the waveguide according to the invention are acceptable. The way in which the connections are made eritre the vis-à-notice edges of the ribbon by stapling and crimping, and without welding, and the presence of undulations of fairly variable dimensions could raise fears, a priori, of much greater losses.

Other objects, characteristics and results of the invention will emerge from the following description, given by way of nonlimiting example, and illustrated by the appended figures which represent;
- Figure 1, a perspective view of an embodiment of the guide according to the invention;
- Figures 2 and 3, diagrams showing the connection between the neighboring edges of the aluminum tape;
- Figures 4 to 7, diagrams showing the association of a guide according to the invention with various other elements.

 In the different figures, the same references designate the same elements, but, for reasons of clarity, the dimensions and proportions of the various elements are not observed.

 FIG. 1 represents a perspective view of an embodiment of the guide according to the invention.

 This guide has a section that will be referred to as pseudo-rectangular. This section consists of two line segments, equal and parallel, which are connected by two arcs of deer.

 To make the guide as flexible as possible, the radius of the arcs of circle which close the section of the guide is taken equal to b / 2, where b is the height of the guide.

 It can be seen in the figure that this guide consists of an aluminum strip 1 whose cross section carries corrugations 2.

This ribbon is wound according to the pseudo-rectangular section along the axis of the oxo 'guide. The facing edges of the ribbon are made integral by stapling and crimping, and therefore without requiring soldering or contact wire.

 We see in more detail in Figure 2 how is made the connection 4 between the neighboring edges of the tape 1. There is first a stapling followed by crimping.

 This produces a seamless connection.

 Figure 3 shows how the connection 4 is made between the neighboring edges of the tape when the guide consists of two superimposed aluminum strips 5 and 6. There is stapling and crimping for each of the two ribbons.

 The use of two overlapping ribbons increases the solidity of the guide.

 In fact, for the guide to be flexible, the aluminum strip used must be thin, which makes the guide fragile.

 Guides according to the invention have been produced using an aluminum tape 30 / 100th of a millimeter thick. The ribbon used was approximately 35 mm wide and had nine undulations, approximately 2 to 3 millimeters in height.

 In other embodiments, the guide according to the invention may have a section other than pseudo-rectangular. It can thus have a circular or elliptical section for example. It may also have a pseudo-rectangular section slightly different from that which has been represented in FIG. 1 since it has the shape of a rectangle with rounded angles.

 These embodiments of the guide according to the invention have not been shown because they are easily understood from FIG. 1.

 In FIG. 1, the guide according to the invention is terminated by two flanges 7. These flanges consist of a metal such as copper, brass, or aluminum for example. When the flanges are made of aluminum, they can be welded to the guide. Otherwise the flanges can, for example, be fixed to the guide by placing two flanges on either side of a flange made at the end of the guide and by tightening the two flanges against each other.

 The guide according to the invention 10 may also have only a flange 7 at one of its ends and have its other end connected to a rigid guide 8, to an elbow 9, to a tee 10, or to a transition 11 as shown in Figures 4 to 7. The guide according to the invention may also have no flanges at all and have its two ends connected to an elbow, a tee, a transition ...

It has already been pointed out that the guide according to the invention has the advantage of being able to undergo a significant elongation along its axis.
OO'.This extension does not significantly change its performance such as transmission losses or the standing wave rate.

 It should be noted that the guide according to the invention must not be subjected to multiple lengthenings and compressions under penalty of damaging it. In the use which has been indicated, the guide according to the invention is entirely satisfactory because it has to be deformed only for the installation of the mounting elements or for the replacement of one of the elements, that is to say rarely.

 Experience has shown that the guide according to the invention has acceptable transmission losses.

 By way of example, we can cite figures recorded for a frequency of use of 2430 MHz. A standard rigid rectangular copper guide 86, 36mm X 43, 18mm had a transmission loss of 0.03dB / m. A circular guide according to the invention of diameter 82mm presented a loss of transmission of 0.033 dB / m and a pseudo-rectangular guide according to the invention of 52mm in height and 102mm in width presented a loss of transmission of 0.06 dB / m.

 It is of course possible to surround the guide according to the invention with any air, water, etc. cooling system.

 To use the guide according to the invention in a prayed suria medium, it is doubled with a tight and elastic envelope, made of rubber, or plastic, or it is surrounded by a metal membrane comprising bellows. This envelope also serves to protect the guide against shocks. It is of course necessary that all the elements which surround the guide do not make it lose its flexibility.

Claims (8)

 1. Semi-rigid waveguide of any section, characterized in that it consists of at least one aluminum strip (1), of corrugated cross section, this strip being wound along said section along an axis (00 ') constituting the axis of the guide, and the edges facing the ribbon being made integral by stapling and crimping (4).  2. Waveguide according to claim 1, characterized in that it consists of two superimposed aluminum strips (leaked, 6).  3. Waveguide according to one of claims 1 or 2, characterized in that it has a circular section.  4. Waveguide according to one of claims 1 or 2, characterized in that it has a substantially elliptical section.  5. Waveguide according to one of claims I or 2, characterized in that it has a pseudo-rectangular section.  6. Waveguide according to one of claims 1 to 3, characterized in that the aluminum strip (1) has a small thickness, of the order of 30 / 100th of a millimeter.  7. Waveguide according to one of claims 1 to 6, characterized in that it is surrounded by a cooling system.  8. Waveguide according to one of claims 1 to 7, characterized in that it is surrounded by a sealed and elastic envelope.