DE1051348B - Arrangement for coupling a helical cable to a conventional high-frequency cable - Google Patents

Description

The invention relates to an arrangement for coupling a helical line to a conventional high-frequency line, in particular according to patent 936 882.

In the main patent 936 882 a coupling arrangement of the aforementioned type is specified, the special feature of which is that a metal structure comprising the helix end is designed and arranged to the helix end in such a way that both its radial distance from the helix and the immersion depth of the helix end is of the order of magnitude Helix slope. When designed as a hollow pipeline, the high-frequency line is connected at least in terms of high frequency both to the metal structure comprising the helical end and also to a wide metal structure connected to the helical end. The facing end faces of the two metal structures mostly merge into the corresponding walls of the hollow pipeline. When such a coupling device for connecting the spiral line of a traveling wave tube to an out of the vacuum envelope of the tube hollow pipe is usually seen, the wall of the vacuum vessel in the transition region from the metal structures to the walls of the hollow pipe ^{in front of} ". In practice, now shows that the Wall of the vacuum vessel can under certain circumstances have a significantly worsening effect on the adaptation of the hollow pipeline to the helical line.

To compensate for the disruptive effect of insulation material in Ankopplungshe.reiph, it is already known to adjust the dimensions of the high-frequency line and / or the AnkqpoppelSYorrichtung near or at the location of the as. Vacuum cover. serving material to enlarge. For example, in the known arrangement, in a case in which a hollow pipeline is coupled to the helical line, the. The end face of one coupling pot is stepped, or the end of the waveguide on the coupling side is provided with additional shoulders. However, in addition to the increased fine mechanical precision, this arrangement requires a somewhat elongated construction of the tube and, in the case of the hollow pipeline provided with shoulders, an additional adaptation of the focusing coil to the geometric dimensions of the coupling arrangement.

There are further Ankgpplungsanordnungen of waveguides to traveling wave tubes are known in which the height dimension of the waveguide is reduced to achieve a capacitive load, thus also a reduction of the characteristic impedance of the waveguide is effected while for achieving the object of the present invention an increase in the wave resistance of the waveguide in Ankoppelbereieh is strived for.

arrangement
for coupling a helical cable
em. a common high frequency; line

Supplements to the patent Θ36 882

Applicant:

Telefunkeii Q. m. B, H "
Berlin NW 87, Sickmgenstr. 71

Dr. Lothar Brück and Apton Lauer, Ulm / Danube, have been named as founders

The object of the invention, gugrun.de, is to show a way which makes it possible, in a particularly simple manner, to reduce the disruptive effect of dielectrics located in the coupling area or, under certain circumstances, to eliminate it completely.

In one arrangement sur coupling a helical = line to a conventional Hoehfrequen ^z Ieitungj in which a high-frequency line on the one hand the end of the spiral comprehensive metal structure and the coil end connected to the second metal structure is connected to at least hochffe.quenzmäßig other hand with a Sil and γόη in the region of the crossing points with the Metal structures on the high-frequency line the wall of a vacuum vessel is given, in particular according to patent 936 882, and in which the increase in transverse capacitance caused by the dielectric material of the wall is compensated, it is proposed according to the invention that when the high-frequency line is designed as a hollow pipe, in the wide side surfaces d ' The mentioned metal structures pass over, the diameter of the vacuum vessel in the longitudinal direction of the hollow pipeline is selected to be approximately equal to a quarter of the mean operating wavelength or an odd multiple thereof and / or that the transverse dimension of the Hoh The oil pipeline at the coupling point is reduced.

The invention is explained in more detail below on the basis of two exemplary embodiments,
Fig. 1 shows a traveling field tube amplifier with a traveling field tube 1, which is surrounded by a magnetic coil 4 in the space between the coupling hollow pipe 2 and the decoupling hollow pipe 3. The beam generation system 5 of the Lauffeld tube

809 767/382

Claims (1)

supplies an electron beam which passes through the interior of the delay line 6, which is designed as a helix. The helical line 6 is supported by means of a tubular carrier 7 made of insulating material, for example quartz or ceramic. A thin layer 8 made of loss-making material is applied to the tubular carrier 7 and serves to decouple the tube outlet and tube inlet via the helical line 6. In this running field tube amplifier, the arrangement for the transition from the helical line to the hollow pipelines is designed according to the main patent on both the input side and the output side, i.e. a metal structure 9 or 10 is provided which surrounds the end of the helical line, and there is a further metal structure 5 or 11 directly connected to the helix end and serves as a further connection for the high-frequency line, which is designed as a hollow pipe. As shown in FIG. 2, this hollow pipeline has a rectangular cross-section and is continued inside the vacuum piston 12 by the metal structures 5 and 9 , ie the metal structures merge into the broad side surfaces of the hollow pipeline. In order to eliminate the increased through the vacuum vessel 12 in the hollow pipe 2 shunt capacitance are reduced by the transverse dimensions used dish-shaped metal parts 13,14 in the hollow pipe. As is known, the wave resistance in a hollow pipeline is determined by the equation lower field strength than the points 17, 18 of the vacuum vessel 12 lying on the hollow pipe axis. In extreme cases, the shell-shaped metal structures 13, 14, as shown in Fig. in which the areas 17 and 18 of the vacuum vessel 12 are located, reduce the transverse dimension a of the hollow pipeline. If necessary, only a correspondingly designed and arranged diaphragm can be used. Fig. 4 shows a further possibility for eliminating the disruptive influence of the transverse capacitance of the vacuum vessel 12. In this case, the diameter of the vacuum vessel is selected to be approximately equal to a quarter of the operating wavelength, so that the reflection caused at point 17, for example, by the at a distance of A 'quarter operating wavelength caused reflection at' the point 18 is at least almost canceled. The mode of action of this "type of compensation" is roughly the same as that in a conventional high-frequency line with continuous wave resistance, in which two similar ones at a distance of a quarter operating wavelength Isolators are turned on. In purely theoretical terms, the disturbing influence would be in such a case of the isolators then compensate if the distance between them is exactly one quarter of the operating wavelength is, but in practice the theoretically determined value deviates due to the fact that it cannot be clearly determined Stray capacitances and the like always depend somewhat on the distance that is actually required. Z prop where a is the width dimension and b is the height dimension of the hollow pipeline, μ is the relative permeability constant and ε the relative dielectric constant. The introduction of the dielectric of the vacuum vessel 12 into the hollow pipeline consequently reduces the wave resistance at this point, which can be compensated for again by reducing the transverse dimension a of the hollow pipeline, as the above equation clearly shows When compensating for the effect of the transverse capacitance by reducing the transverse dimension a of the hollow pipeline, it should be noted that parts of the vacuum vessel 12 are in an area with a higher field strength than other parts of the vacuum vessel and that consequently the effect of the dielectric of the vacuum vessel 12 at the points of higher electrical field strength will be greater than in other places where the electric field strength has a lower value. It is therefore advisable to reduce the transverse dimension, as shown in Figs. 2 and 3, to a greater extent in the cross-sectional planes of the hollow pipeline in which the dielectric is in the area of higher electrical field strength than in the other places. In the arrangements shown in Fig. 2 and 3, an approximately sinusoidal field distribution in the interior of the hollow pipeline is assumed. As a result, the metal parts 13, 14 are approximately shell-shaped, since - as can be seen from the cross-sectional drawings in Fig. 3, in which the field distribution is also drawn - the two edge zones 15, 16 are located at Claim: . Arrangement for coupling a helical line to a conventional high-frequency line, in which a high-frequency line on the one hand with a metal structure encompassing the helical end and on the other hand with an. the second metal structure connected to the helix end is connected at least in terms of high frequency and the wall of a vacuum vessel is provided in the area of the transition points from the metal structures to the high frequency line, in particular according to patent 936 882, and in which "the increase in transverse capacitance caused by the dielectric material of the" wall is compensated, characterized in that when the high-frequency line is designed as a hollow pipeline, into whose broad side surfaces the metal structures mentioned merge, the diameter of the vacuum vessel - viewed in the longitudinal direction of the hollow pipeline - is selected to be approximately a quarter of the mean operating wavelength or an "odd multiple thereof and" d / or that the transverse dimension (a) of the hollow pipeline is reduced at the coupling point. Considered publications:
German Patent No. 853 017;
U.S. Patent No. 2,636,948;
British Patent No. 680,796. Cited older patents:
German Patent No. 955 699. 1 sheet of drawings