DE2351390C3 - Coaxial magnetron - Google Patents

Description

The invention relates to a coaxial magnetron, the resonance cavity of which coaxially surrounds the anode body and which can be influenced by an electric current Having tuning arrangement.

Such a coaxial magnetron is described in US-PS 33 148. To change the natural frequency, tuning devices made of a ferrite material are arranged in the resonance cavity surrounding the anode body. Through an outside of the resonance cavity arranged, ring-shaped pulse transformer, the permeability of the ferrite material can be changed, so that a Change in the natural frequency of the coaxial magnetron occurs. The disadvantage here is that because of the The time constant given by the inductance of the pulse transformer only results in a change in frequency can be done quite slowly. The electrical control of the pulse transformer is also relatively complex. Because the natural frequency of this known coaxial magnetron depends on the one hand on the permeability of the ferrite material and, on the other hand, of the influence of this permeability by the magnetic field of the Pulse transformer is determined, can affect the frequency constancy and also the accuracy of a Frequency change no great demands are made.

In certain application systems, e.g. B. in radars, however, transmitters are required that very quickly, even aperiodically, between selected ones Frequencies can be switched, with the The highest demands are placed on the accuracy of the reproduction of these frequencies.

From DT-OS 22 21 916 a magnetron oscillator is also known, the frequency of which changes as a result can be that a separate resonance cavity is coupled to the anode-cathode assembly, and that a multipactor discharge device is arranged in this resonance cavity. Since this resonance cavity is coupled to the magnetron, the Frequency of the magnetron to a predetermined, different from the natural frequency of the magnetron Frequency pulled. The frequency change takes place here by changing the energy transfer between this resonance cavity and the anode Cathode cavity of the magnetron if one Multipactor discharge is ignited or extinguished in the separate resonance cavity. Is disadvantageous with this arrangement, that in this case energy losses through decoupling and an influence on the resonance frequency sequence by controlling the bias of the Multipactor discharge device can occur. But most of all it affects the delay Frequency switching, which is due to the necessary energy transfer between the anode-cathode Cavity and the resonance cavity when erasing or ignition of the multipactor discharge occurs, unfavorably to the level of the possible switching frequency. In the DTPS 20 56 398 there is a tunable

Magnetron described, the frequency of which by a A plurality of mechanically movable tuning vanes arranged in the resonance cavity can be influenced is These tuning wings are mechanically Complicated gear transmission in the manner of a planetary gear connected to one another and shared controllable. Here, too, there is only a slow change in frequency due to the mechanical inertia possible. The reproducibility of different frequencies is due to the unavoidable mechanical Tolerances low.

The DT-OS 23 GO 753 already has a multipactor discharge device described, which consists of three spaced apart electrodes, whereby two multipactor discharges connected in series occur.

The object on which the invention is based is to develop a coaxial magnetron of the type mentioned at the beginning Kind of creating that with high speed and great accuracy between discrete frequencies can be switched.

According to the invention, this object is achieved in that as a tuning arrangement at least one Multipactor discharge device is provided, the is arranged so that the multipactor discharge in Direction of the electric field component that exists in the resonance cavity during operation electromagnetic wave passes.

The change in the natural frequency is achieved in this arrangement by increasing the dielectric constant is changed in the area of the multipactor discharge so that the electric field lines locally are quasi short-circuited and thus the resonance frequency of the surrounding resonance cavity changed the structure and the extinction of the multipactor discharge and thus the switching between discrete fixed frequencies takes place at a very high speed and can be via a direct current bias can be controlled easily and in any time sequence. It proves to be particularly advantageous that the fixed frequencies practically only depend on the resonance cavity itself and on the geometry of the mechanically rigid arrangement of the Multipactor discharge devices is dependent. The mechanical structure is simple, since there are no mechanically movable parts required are.

Advantageous further developments of the coaxial magnetron according to the invention are set out in the subclaims marked.

The invention is illustrated below on the basis of exemplary embodiments with reference to Drawing explained in more detail, it shows

1 shows a schematic sectional view of a coaxial magnetron according to the invention,

2 shows a sectional view along the line AA of FIGS

3 is a partial sectional view of a further embodiment.

The shown in Fig. 1 and 2 coaxial magnetron has an anode body 1, the from an outer Wall 2 is surrounded. Between the anode body 1 and the outer wall 2 there is a coaxial one Resonance cavity 3, which maintains waves of f / oi mode in the area. The resonance cavity 3 and the Anode bodies I are enclosed by an upper wall 4 and a lower wall 5, of which the the latter is made in one piece with the outer wall 2 A coaxial magnetron of the preceding The type described is known per se, so that a more detailed description is not necessary electric field within the resonance cavity 3 in the direction of FIG. 1 shown arrows 6.

Within the resonance cavity 3 is in the path of the electric field 6 occurring during operation Multipactor discharge device 7 is provided. This Multipactor discharge device has the task of to bring about a multipactor discharge in series with the electric field 6. The Multipactor discharge device 7 has two electrodes designed as wings 8 and 9, which extend radially over a Part of the width of the resonance cavity 3 extend. The two wings arranged at a distance from one another are made of a material with a high secondary electron emission coefficient One of the wings, in the present case the wing 8 is isolated from the lower wall 5 by an insulator 10 and has an electrical connection 11 via which a the multipactor discharge suppressing DC bias voltage can be applied; by switching off the preload the multipactor discharge between the blades 8 and 9 is initiated

Since the wings 8 and 9 extend radially through the resonance cavity 3 and as the electrical Field 6 has no axial and no radial components during operation, no energy is extracted from the blades decoupled from the coaxial magnetron The wings therefore have little or no influence on the Natural frequency of the coaxial magnetron, as long as there is no multipactor discharge between the wings Shutdown of the DC bias voltage is initiated. When the multipactor discharge between the Wings 8 and 9 is triggered, a frequency change occurs due to the dimensions of the wings and their distance from each other depends.

The multipactor discharge device 7 can be different from the axial, existing during operation DC magnetic field must be shielded. However, if it is not shielded, the distance can between the blades 8 and 9 are chosen so that this is axial, to operate the coaxial magnetron necessary direct current magnetic field supports the multipactor discharge. The support of multipactor unloading in the presence of the axial DC magnetic field arises because of the field the emitted secondary electrons strike the surfaces of the wings 8 and 9 at an angle so that the Yield of secondary electrons is increased. The distance between the two wings 8 and 9 is just not allowed be too large that the secondary electrons under the action of the axial direct current magnetic field to Return to the starting surface before they hit their target surface.

In the embodiment described, as shown in FIG. 1 shows another similar multipactor discharge device 12 provided radially opposite the multipactor discharge device 7. The task This further multipactor discharge device 12 consists firstly in an additional change to achieve the natural frequency of the coaxial magnetron that an additional multipactor discharge in Series occurs with the electric field within the resonance cavity 3 and secondly in that d> disturbances caused by the multipactor discharge are distributed in such a way that losses are reduced that could occur in an asymmetrical arrangement.

Normally, therefore, the multipactor discharge devices 7 and 12 are operated together, but they can also be operated independently of one another.

For further additional changes in the natural frequency of the coaxial magnetron, further multipactor discharge devices can be used as shown in FIGS. 7 and 12 illustrated type are arranged distributed in the resonance cavity 3. Again, the multipactor discharge devices are preferably operated in such a way that symmetry is maintained.

In the case of the FIG. In the embodiment shown in FIG. 3, each multipactor discharge device from FIG Blades 13, 14 and 15 made of a secondary electron-emitting material, so that two multipactor discharges occur in series. In this particular case the outer wings 13 and 15 are connected to the lower wall 5 of the coaxial magnetron, during the inner wing 14 is isolated therefrom and provided with a separate connection, as is the case for the wing 8 in FIG. 2 is shown in detail.

For this purpose 2 sheets of drawings

Claims (10)

Patent claims: 1. Coaxial magnetron, the anode body of which coaxially surrounding the resonance cavity through a has a tuning arrangement which can be influenced by an electric current, characterized in that the tuning arrangement is at least one Multipactor discharge device (7, 12) is provided, which is arranged so that the Multipactor ι ο Discharge in the direction of the electrical field component (6) of the electromagnetic field that is present in the resonance cavity (3) during operation Wave runs 2. Coaxial magnetron according to claim 1, characterized in that in the resonance cavity (3) at least two multipactor discharge devices (7, 12) are arranged distributed in such a way that their Multipactor discharges run symmetrically to one another. 3. coaxial magnetron according to one of claims J or 2, characterized in that each multipactor discharge device has two metallic wings (8, 9) which extend radially within the resonance cavity (3). 4. coaxial magnetron according to claim 3, characterized in that the wings (8, 9) consist of one Material with a high secondary electron emission coefficient exist. 5. coaxial magnetron according to claim 3, characterized in that on the wings (8, 9) a Material with a high secondary electron emission coefficient is attached or that whose surfaces are coated with this material. 6. coaxial magnetron according to one of claims 3 to 5, characterized in that one (9) of the metallic wings (8, 9) of each Multipactor discharge device is electrically connected to the walls (2) of the resonance cavity (3), during the other wing (8) is provided with a separate electrical connection to the suppression a bias voltage can be applied to the multipactor discharge 7. coaxial magnetron according to one of claims 1 or 2, characterized in that each multipactor discharge device has three metallic wings (13,14,15) 8. coaxial magnetron according to claim 7, characterized in that the two outer wings (13, 15) and the inner wing (14) made of a material with a high secondary electron emission coefficient exist. 9. coaxial magnetron according to claim 7, characterized in that on the wings (13,14,15) a Material with a high secondary electron emission coefficient is attached or that the inner Wing (14) facing surfaces of the outer wings (13, 15) and the outer wings facing surfaces of the inner wing (14) are coated with this material. 10. Coaxial magnetron according to one of claims 7 to 9, characterized in that the two outer wings (13, 15) of each multipactor discharge device are electrically connected to the walls (2) of the resonance cavity (3), while the inner wing (14) is provided with a separate electrical connection