DE1591392B2 - Arrangement for tuning the resonance frequency of a coaxial line circuit, especially for single or multi-chamber klystron - Google Patents

Description

1 2

The invention relates to an arrangement extending around the klystron chamber. This advantage for tuning the resonance frequency of a co- has the effect that the radial Ausaxialleitungskreises, especially for expansion or expansion, ζ. B. a multi-chamber klystron, essential multi-chamber klystron, in which the vote can be reduced. Through the with it a self-contained metallic sleeve connected higher resonance resistance can which, in the space between the interior and the power amplification of the klystron, are increased. Outer conductors of the coaxial line circuit arranged, The Andes mentioned above in the prior art Inner conductors of the coaxial line circle surrounding orders are not applicable if one and their spatial position can be adjusted from the outside. axial displacement, such as B. in klystron resonance

It is known, because coaxial line circuits in the fre- io gates lead to very great difficulties sequence to be matched by the fact that either the above and below the resonators Length of the line or one within the circle pole plates are arranged, which have an axial movement intended capacitive load is changed. would not allow it unless the conven-one Arrangement in which structures of the klystron, borrowed as a capacitive load, would unite allow the inner conductor of the coaxial line circuit and redesigned it to a considerable extent. It at least partially surrounding metallic sleeve is used, an arrangement would be conceivable in which in the show z. B. the German patent specification 1202 847 and resonator outer walls axial slots vorgedie USA.-Patent 2,945,156. Be seen in the known, but then escapes through this one Arrangements is the sleeve in the axial direction of the significant proportion of the high-frequency energy, so that Coaxial line circle arranged displaceably. A 20 in turn additional measures for sealing such an axial displacement with a large amount would be required at the same time.

However, frequency tuning is only possible. According to a development of the invention, the

borrowed when there is sufficient space in the axial direction in the resonator sleeve on an end wall of the coaxial line circuit and the implementation of an actuating rod 25 on at least one end face and in galvanic contact with it. The sleeve can also be made in a simple manner. In the case of klystrons, this is the case at a correct distance close to an end wall of the cone, because the chambers are arranged in an axial directional circle. The spatial direction have only small expansions, the axial position of the sleeve can be adjusted by at least one displacement of frequency-determining parts with only ceramic rod, which is possible through the outer conductor of the coaxial small strokes and which is then passed through, required axial opening of the resonator - This ceramic rod can become problematic after further elaboration. Therefore, up to now, designs of the invention have been used with a swiveling device as an upward swiveling device, the known swiveling metal sheets, in which each ceramic rod is wound up, being provided for the frequency choke acting conductors.
Because the relevant line section is close to the circuit, the characteristic impedance is reduced and maintained in the largest possible tuning range, the sleeve can be designed and the resonance frequency can be displaced with a fixed circular length so that the resonance frequency is increased in one of the end positions, also the disadvantage of the low The outer jacket of the sleeve applies to the inner jacket of the hub. Outer conductor of the coaxial line circle touches and

The difficulty in forming a vacuum 40 at the same time the inner jacket of the sleeve and the outer seals Implementation for actuating the inside jacket of the inner conductor of the coaxial line circuit. arranged metallic objects on the other hand for the deformable sleeve can to achieve the shows e.g. B. the USA. Patent 2,945,156. A same purpose, so to obtain a possible Exercising buckling or similar movement is a large frequency swing, the sleeve is designed in this way with the simultaneous need for a vacuum seal 45 and be deformable that in one of the end positions of the very difficult to carry out. Here, too, the outer jacket of the sleeve is the inner jacket of the outer one Disadvantage of the known arrangements. head of the coaxial line circuit on two each other

The object of the invention was to touch a diametrically opposite surface lines Arrangement for tuning the resonance frequency and at the same time the inner jacket of the sleeve to create a coaxial line circuit in such a way that 50 outer sheath of the inner conductor of the coaxial line der Tuning range as large as possible and the circle required on two diametrically opposite each other Vacuum-tight lead through if possible on the surface lines. The sleeve can also be used in one is designed. To solve this problem suggests the non-evacuated section of the coaxial line Invention can be arranged in the arrangement of the input circle.

mentioned type before, the sleeve in a to the axis of the 55 embodiments of the invention are in the Coaxial line circle perpendicular direction shown in the drawing and are shown in the following to make slidable and / or deformable. described in more detail. It shows

Must this sleeve in an evacuated room F i g. 1 shows a longitudinal section through a coaxial bed, the lead-through for the rod is very introductory with a sliding sleeve,
times producible and has a long service life 60 F i g. 2 shows a partial view on an enlarged scale. However, if the sleeve is similar to the section from an arrangement similar to FIG. 1, with known short-circuit slide in klystron resonators, which brings the sliding sleeve into contact with the adjacent Ln in a non-evacuated resonator chamber, which is an end wall of the coaxial line circuit in the electrical part of a klystron chamber,

the advantage that this resonator space compared to 65 F i g. 3 shows a section along the line III-III of the known rectangular waveguide resonators essential- Fig. 1,

borrowed can be made smaller if he is F i g. 4 the analogous cut as in FIG. 3 with the

z. B. in a ring around the drift sections and the sliding sleeve in an end position,

3 4

F i g. 5 one of the F i g. 3 corresponding section times from the circular cylindrical inner conductor of the

by a coaxial line circuit with a deforming axial line circuit and the oval inner jacket

outer sleeve, the sleeve, on the other hand from the oval outer

F i g. 6 shows the analogous cut as in FIG. 5 with the jacket of the sleeve and the circular cylindrical outer

the deformable sleeve in an end position, 5 head of the coaxial line circuit exist. Through the

7 shows an arrangement corresponding to the approach of the deformable sleeve to the inner

F i g. 1, in which the coaxial line circuit is used as the klystron and the outer conductor of the coaxial line circuit

circle is formed. an increasing increase in the capacity coverage

According to the invention, it is proposed to achieve one which is equivalent to a corresponding lowering of the coaxial line resonator with no-load or IO characteristic impedance of each sub-line and thus the weak capacitive load on the one hand and the impedance of the coaxial line circuit in the short circuit on the other in the resonance sleeve area. A change in the frequency can be detuned by changing a line impedance from Z = O (simultaneous contact section near the short-circuit end in the stanchions of the deformed sleeve on the inner and outer impedance, in which either 15 conductors of the coaxial line circuit) to Z _max vertical direction shifted inner and outer conductor of the coaxial line circuit or a coaxial to the inner and 20 is possible. In the practical implementation, it may be sensible to design the outer conductor and thin outer conductors arranged between them not to form the deformable sleeve with a conical, initially cylindrical, metallic sleeve of constant wall thickness, but, for example, also by riveting sheet metal strips to the axis of the coaxial line circle while maintaining its axis position Vertical stiffening of predetermined bending points is deformed in the direction of oval. 25 see.

In both cases it can be assumed that the cylindrical sleeve as well as the oval deformation of the coaxial line circle in the area of the respective thin-walled circular cylindrical sleeve can be used to explain the we- Both the lateral displacement of a circular sleeve insert through this in two sub-lines, for example by ceramic push rods, which in turn (even if from 30, e.g. from kallite, reach. As movement stroke h , the sleeve insert to the adjacent end wall is still a gap open with optimal dimensioning of the sleeves for Z of 0) to the adjacent end wall up to Z _max only half the clear space between the inner and outer conductors of the coaxial can count as practically closed by a short circuit. At the other end of the circle line circle required, so
are the two 35 D - d formed by the sleeve insert
Partial lines to be viewed as open (idling). Since h = —-—.
If the partial lines are of the same length, the coaxial line circuit in the area of the sleeve insert can be connected to a galvanic connection, e.g. B. to be assigned to line wave resistances. In the outer conductor of the coaxial line circuit, the laterally displaced sleeve will point to the case, so the characteristic impedance of an inner "eccentric thin wire" can be wound around a ceramic push rod given microwave outer "eccentric coaxial line" added. frequencies hardly alternating current can flow, so that according to the well-known relationship of the wave resistance through this galvanic connection the resonator stand of such eccentric lines is practically not disturbed by the field,
Increasing eccentricity of the inserted sleeve The sleeve can with the adjacent end wall partial line impedance smaller, so that also the coaxial line circuit are in galvanic contact sum of the two partial line wave resistances, whereby the aforementioned wire winding and consequently also the wave resistance of the co-50 development are on a ceramic Push rod unnecessary, axial line circuit in the sleeve area. This means that a defined gap can be opened up to this end wall by lateral displacement of the (originally coaxial. In both cases, the sleeve can be displaced axially to the inner and outer conductor of the coaxial bung or deformation also by means of a metallic or conductor circle arranged) sleeve (highest possible dielectric Pins are made, which are changed by radially verlicher wave resistance) the wave resistance of the 55 running slots in the adjacent end wall of the coaxial line circle. If the coaxial line circle protrudes outwards and the sleeve diameter is selected in such a way that the sleeve is connected to the sleeve. When dimensioning the circumference of the coaxial line circle and the sleeve at the same time the inner and outer conductor of the diameter is affected by the lateral displacement in one end position, the possibility of disruptive coaxial line circuit is affected, a total of 60 cavity and circumferential waves can be taken into account and wave resistance range from zero to Z _max be crossed out accordingly for the operating frequency range, where Z _{max is} the characteristic impedance of the small diameter according to known dimensioning of the coaxial line circuit in the case of a coaxial sleeve position to circumvent regulations.

is. In the case of thin-walled sleeves, Z _{max is} practical. FIG. 1 shows a coaxial line circuit which can be matched according to the invention to the wave resistance of the coaxial line 65, its outer conductor with a 1, circle in the absence of a sleeve. its inner conductor with 3 and its as a short circuit

In the case of the oval deformable sleeve, the same acting end wall is denoted by 2. The interior

Explanation, only that now the two sub-lines 1-conductor 3 is surrounded by a metallic sleeve 4,

which is laterally displaceable by a push rod 5. An end plate 6 is attached to the push rod 5 attached vacuum-tight, which is vacuum-tight with the outer conductor via a bellows-like metallic part 7 1 is connected. The electrical connection between the sleeve 4 and the end plate 6 is made by a conductor 9 wound around a ceramic rod 8. This ceramic rod 8, which is passed through the outer conductor 1, forms the extension of the push rod 5 and lies within the vacuum.

Fig. 2 shows an enlarged view as Short-circuit acting end wall 2 and the attached inner conductor 3 with the surrounding one Sleeve 4. At its end adjacent to the end wall 2, a clamping ring 10 is pulled onto the sleeve 4. Between the clamping ring 10 and the end wall 2, a spring ring 11 is clamped, which for a good electrical contact between the end wall 2 and the sleeve 4 ensures. Compared to the embodiment According to FIG. 1, the sleeve 4 is directly above in the embodiment according to FIG. 2 the spring ring 11 is connected to the end wall 2, while in the embodiment of FIG the sleeve 4 is arranged at a certain distance from the end wall 2.

3 shows how the sleeve 4 is eccentric between the outer conductor 1 and the inner conductor 3 for a certain frequency to be tuned may lie. The ceramic rod 8 is indicated by dashed lines.

Fig. 4 shows an extreme position, a so-called end position, for the sleeve 4, in which the outer jacket the sleeve 4 in contact with the inner jacket of the outer conductor 1 and at the same time the inner jacket the sleeve 4 is in contact with the outer jacket of the inner conductor 3. The ceramic rod 8 is completely pulled out.

5 and 6 show the corresponding positions for a thin-walled deformable sleeve 4, which according to the representation of Fig. 5 is elliptically deformed by two ceramic rods 8, while in Fig. 6 the elliptical deformation has been driven so far that the outer jacket of the sleeve 4 is in contact with the inner jacket of the outer conductor 1 and the inner jacket of the sleeve 4 in contact with the outer jacket of the inner conductor 3 stands, namely on two diametrically opposite surface lines in each case. Here, too, the ceramic rods 8 are again shown in dashed lines.

7 finally shows a practical embodiment for a klystron. A chamber of a multi-chamber klystron is shown, which consists of the evacuated chamber part 12 and the non-evacuated chamber part 13. In the evacuated chamber part 12 there is the interaction gap 14 between the two drift tubes 15 and 16. The evacuated chamber part 12 is surrounded by a ceramic ring 17 which is attached to the plate-shaped metallic parts 18 and 19 in a vacuum-tight manner. In the non-evacuated chamber part 13 there is the sleeve 4 around the drift tube 16, which can be displaced perpendicular to the axis of the drift tube 16 and thus the coaxial line circuit through the ceramic rod 8, which is passed through the outer conductor 1, and thus can be used to adjust the resonance frequency of the coaxial line circuit allowed. The end wall acting as a short circuit is corresponding to FIG. 1 with 2, the outer conductor of the coaxial line circuit according to FIG. 1 with 1. In this embodiment, the drift tube 16 takes over the function of the inner conductor 3 according to FIGS. 1 to 6.

Claims (9)

Patent claims: 1. Arrangement for tuning the resonance frequency of a coaxial line circuit, in particular for single- or multi-chamber klystron, in which the vote is carried out by a self-contained metallic sleeve takes place, which, in the space between the inner and the outer conductor of the coaxial line circuit arranged, the inner conductor of the Koaxialleitungskreis surrounds and their spatial Location is adjustable from the outside, thereby characterized in that the sleeve (4) in a perpendicular to the axis of the coaxial line circle Direction is displaceable and / or deformable. 2. Arrangement according to claim 1, characterized in that the sleeve (4) on an end wall (2) of the coaxial line circuit and is in galvanic contact with it is. 3. Arrangement according to claim 1, characterized in that the sleeve (4) in a certain Distance near an end wall (2) of the coaxial line circuit is arranged. 4. Arrangement according to one of the preceding claims, characterized in that the spatial position of the sleeve (4) by means of at least one ceramic rod (8), which is passed through the outer conductor (1) of the coaxial line circuit is passed through, is adjustable. 5. Arrangement according to claim 4, characterized in that the ceramic rod (8) with a acting as a high-frequency choke conductor (9) is provided. 6. Arrangement according to claim 5, characterized in that the conductor (9) on the ceramic rod (8) is wound up. 7. Arrangement according to one of the preceding claims with a displaceably arranged Sleeve, characterized in that the sleeve (4) is designed and displaceable in such a way that that in one of the end positions the outer jacket of the sleeve (4) meets the inner jacket of the outer conductor (1) of the coaxial line and at the same time the inner jacket of the sleeve (4) touches the outer jacket the inner conductor (3) of the coaxial line circuit (Fig. 4). 8. Arrangement according to one of the preceding claims with a deformable one Sleeve, characterized in that the sleeve (4) is designed and deformable in such a way that in one of the end positions of the outer jacket of the sleeve (4) the inner jacket of the outer conductor (1) of the Koaxialleitungskreises touches on two diametrically opposite surface lines and at the same time the inner jacket of the sleeve (4) the outer jacket of the inner conductor (3) of the coaxial line circuit on two diametrically opposite surface lines (Fig. 6). 9. Arrangement according to one of the preceding claims, characterized in that the Sleeve (4) is arranged in a non-evacuated section of the coaxial line circuit. 1 sheet of drawings