EP0037309A1 - Travelling-wave tube with coupled cavities and with periodic permanent magnet focussing, and amplifier unit with such a tube - Google Patents

Abstract

In a traveling wave tube in which the delay line (1) consists of a series of double resonant cavities (15), alternating with the pole pieces (3) of the focusing system, provision is made, to limit the interception of electrons by the line, to increase the diameter of the flanges (30 and 40) of magnetic material which terminate these parts, as well as the wall (16) of the cavities, on the side of the axis of the tube: this increase takes place in stages, a collar (30) having the same diameter as the collar (40) which follows it in the direction of propagation of the beam. Application to amplifier sets for telecommunications in particular.

Description

The invention relates to a traveling wave tube.

The invention relates to a traveling wave tube (TOP) with coupled cavities, the beam focusing of which is ensured by a system of permanent magnets of the "PPM" type, namely "Periodic Permanent Magnet".

Such a focusing system known as "alternating permanent magnets" consists, as known in the art, of rings tight against each other around the axis of the tube, alternately consisting of magnets and pole pieces. In this case, the polar masses made of soft iron, or any other material with low reluctance, are incorporated into the walls of the cavities, made of copper, so as to conduct the magnetic flux as close as possible to the electron beam.

The thermal conductivity of soft iron being approximately 6 times lower than that of copper, the thermal resistance between the bundle and the cooling circuit of the tube is at least 6 times higher when polar masses are incorporated in the walls of the cavities. If, on the other hand, we admit that the current intercepted by the delay line is, all other things being equal, two to four times greater in the case of focusing by permanent magnets than in that of focusing by a solenoid, the continuous power which it is possible to apply to the tube and, consequently, the maximum high frequency (HF) power available at the output of such a tube is significantly lower than in the case of 'a focus by solenoid. The high frequencies in question are those corresponding to decimetric and centimeter waves; they range from a few gigahertz to more than 10 gigahertz. Towards the HF outlet of the tube; the increase the diameter of the beam may be such, under the influence in particular of the high frequency field of the cavities, that the spouts of the latter melt under the impact of the intercepted electrons. This imperatively limits the power applied to the tube.

Despite this, the traveling wave tube technique is frequently oriented towards the permanent magnet solution for focusing the beam, because of the conveniences which it brings, in particular from the point of view of the positioning of the focusing pieces and operation of the tube, by removing the continuous source necessary to supply the solenoid.

The invention therefore relates to a traveling wave tube focused by permanent magnets and pole pieces.

It relates to a traveling wave tube having a structure which makes it possible to avoid, or at least to reduce appreciably, the preceding drawback with regard to the maximum power applicable to the tube.

The invention also relates to high frequency amplifier devices using a tube according to the invention.

• Figure 1 et 2 : deux vues schématiques en coupe de la partie centrale de tubes à ondes progressives à cavités couplées de l'art antérieur ;
• Figure 3 : une vue analogue relative à un tube à ondes progressives à cavités couplées de l'invention.

The invention will be better understood by referring to the description which follows and to the attached figures, which represent, with the same references designating the same elements:

• Figure 1 and 2: two schematic sectional views of the central part of progressive wave tubes with coupled cavities of the prior art;
• Figure 3: a similar view relating to a traveling wave tube with coupled cavities of the invention.

Figure 1 shows a first embodiment of a traveling wave tube with coupled cavities of the prior art.

This figure, like the following, represents the central part of the tube, constituted by the delay line 1, seat of the electromagnetic wave which, in operation, is in interaction with the electron beam, not shown, propagating along of the axis Z'Z, between a cathode assembly by which it is produced, situated on the left of the figure, and a collector by which it is received situated beyond the delay line 1, on the right of the figure. These elements have not been shown in these figures, as not necessary for understanding the invention.

As can be seen in the drawing, the delay line 1 is made up of coupled cavities 10 arranged in a regular succession along the Z'Z axis. These cavities are resonant volumes, of the re-entrant type known in microwave frequencies, of revolution around of the axis and open at 11, in the vicinity of this one, for coupling with the beam. As for the means for coupling the cavities together, they do not appear in the sectional views of the figures; these means fall within the known art. The permanent magnets 2 are arranged around these cavities and the pole pieces 3 between them, as shown in the drawing; these parts, which have the shape of washers, are provided with a collar 30; these aligned flanges delimit the space in which the beam propagates and form the reentrant of the cavities 10; their edges, generally tapered in reality, constitute the spouts 31 of these cavities; these spouts can also be with straight edges as in the case of the figures. The part 3, including the collar 30, is made in one piece from a material with low reluctance for the magnetic field of the magnets 2, soft iron for example. As shown in the drawing, the magnets are alternately oriented south north and north South. Finally two pieces 20 and 21 limit the focusing assembly at its two ends.

In the example, the airways 10 are limited, at their periphery, by the cylindrical wall 12 in contact with the magnets 2 and, laterally by the flat walls 13 and 14, all made of copper, good electrical and thermal conductor, the pole pieces 3 being inserted between two successive side walls. These walls are shown without hatching in the drawings for clarity.

This arrangement ensures, thanks to the copper parts, good evacuation of the heat generated in operation in the tube, towards an external cooling system, not shown, arranged variously, according to the embodiments, around the tube,

On the other hand, it has the drawback of reducing, all things being equal, the height H of the cavities, of the thickness of the copper side walls 13 and 14, and obliges, at a given frequency, to increase their internal diameter, c ' that is to say the diameter of the flange 30, which reduces, at its most, the coupling of the cavities with the bundle, and the performance of the tube.

In another arrangement of the prior art shown in FIG. 2, this drawback is avoided by constituting the side walls of the cavities 10 by the pole pieces 3 themselves, thus reducing the reduction in height H, but making it more difficult thermal evacuation of the delay line. To reduce the amount of heat to be evacuated, the diameter of the collars 30 is then increased as one approaches the end of the tube situated on the side of the collector, so as to reduce the interception of the beam by these, in particular by their edges or nozzles 31 which, are areas having a great resistance to thermal flow. The space offered the beam flares towards the collector, following the oblique lines. One is however limited in this way by the need to preserve a good coupling between the wave and the beam. The necessary increase in the diameter of the flanges 30 is generally, in this case, between 10 and 25 /.

In another arrangement known from the prior art, the pole pieces such as 3 twinned are separated by two cavities such as 10; a soft iron collar is then also provided on the wall common to the twin cavities placed between two successive pole pieces. In this new arrangement, the evacuation of heat is made easier by the greater proportion of copper used in the constitution of the delay line. As for the collar which terminates the copper wall in question, it constitutes a floating pole piece which enriches in harmonic 3 the magnetic field in the space where the electron beam propagates. The magnetic field produced in the center of the tube by the system of magnets and pole pieces described has a value which is a periodic function of the abscissa along the axis Z'Z; the harmonic in question is the harmonic of this periodic spatial distribution. This has the effect, under certain conditions, of reducing the undulations affecting the diameter of the beam along its path and, consequently, the risks of interception of the beam by the delay line.

Figure 3 shows an exemplary embodiment of the delay line of the tubes of the invention. As in the example just mentioned, the cavities between which the pole pieces 3 are clamped are double; they are marked 15 on the drawing, and their central wall is marked 16.

The pole pieces and central wall each carry a collar like the collar 30 of the preceding drawings, a collar made of soft iron or of material with low reluctance. The magnets 22 are provided with lengths in proportion between two pole pieces 3. These flanges are designated in the case of the figure by the same reference 30 for those belonging to a pole piece 3, and by 40 for those located at the end copper walls 16.

To reduce the interception of electrons, the diameter of the collars 30 also increases in the direction of propagation of the beam and in particular in. the last part of the line.

According to the invention, this increase takes place in stages, both flanges, the flange 30 of one of the pole pieces and that 40 of the central wall of the two cavities which follow it, on the beam path, having even diameter. Thus is widened the space offered to the beam in its path to the collector, space whose diameter varies, in the section shown, from Ø ₁ to Ø. Each of the flanges 30 is protected against the interception of electrons by the washer 40 which precedes it. Such a washer 40 carries shadow, in a way, on the washer 30 which follows it.

The maximum of the interception occurs on the parts 40, in contact with a copper part 16, generally thick, which allows a good evacuation towards the outside of the heat received by the line.

In centimeter waves, we noted, all other things being equal, an improvement of 1 dB on the output level of a delay line tube according to the prior art of FIG. 2 provided with the improvement of the invention.

The invention finds an application in amplifier sets with traveling wave tubes for telecommunications, in particular by satellite.

Claims (2)

1. 1. Traveling wave tube composed of a cathode assembly producing a beam of electrons propagating along an axis ( _Z ′ _Z ) and of a collector by which the beam is captured, and, arranged around this axis, between the cathode assembly and the collector, a delay line (1) composed of successive resonant cavities (15) of reentrant shape centered on this - axis and coupled together, said tube being provided with a beam focusing system 'electrons, with alternating permanent magnets (22), composed of washers. magnetized, surrounding the outer wall of the cavities, and pole pieces (3) clamped between the cavities and alternate with them, at the rate of one pole piece every two cavities, these pole pieces being terminated on the side of the axis by a flange (30) centered on this axis, the common wall (16) with two successive cavities being itself terminated on the same side by a similar flange (40), made of magnetic material, these flanges constituting the re-entrant part of the cavities resonant, all of these flanges limiting, transversely to the axis, the space in which the beam propagates, characterized in that the internal diameter of these flanges increases in the direction of propagation of the beam, in particular in the last part of the line, this increase taking place in stages, both flanges, the flange (30) of a pole piece and that (40) of the common wall which follows it having the same diameter. 2. Amplifier assembly comprising at least one tube according to claim 1.

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