DE1491389B1 - WHEEL DESIGN MAGNETRON - Google Patents

Description

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The invention relates to a magnetron that expands more than the adjacent segments.

Radbauart whose around a cathode approximately this uneven expansion of neighboring

symmetrically arranged anode segments together - segments are transferred to the connecting rings,

men with one surrounding the anode segments which consequently deform and even, as above

Anode block, the electrically conductive wall parts 5 run, with frequent changing loads

of the cavity resonators, at which min- can break.

At least one wall part of one or more of these further changes in the case of the different heat from cavity resonators the position of the inner cathode is provided with at least one expansion. turned ends of the adjacent segments towards one another.

Such breakthroughs can vary in magnetrons; because this location increases the capacitance of the resonators known design z. B. be necessary if the decisive factor determines the person concerned Temperature of the magnetron cathode in operation of the resonator compared to the others. Since in a measure should be observed. The wheel type anode gnetron all resonators on the same The anode block carrying the segments is then given a frequency that must be tuned to come through the Bore with a clear window after 15 detuning the above mentioned electronic is closed vacuum-tight on the outside. Because of the interference. This phenomenon also occurs The window is between the resonator gap and that of a wheel-type magnetron that does not have a connecting cathode facing segment ends through a formation rings between the segments has on; are Part of the cathode surface visible. There are connecting rings, so the phenomenon occurs

In a further known magnetron, the wheel 20 has an even greater effect, since due to the unequal construction, the high-frequency energy is coaxially decoupled from two moderate thermal expansion at the relevant Seg-neighboring resonators. For this purpose, the position of the connecting rings to each other is in the middle of a segment on which the and thus their capacity is influenced.
In addition to the mechanical disturbance, there is also an electronic disturbance that extends from the attachment point of the segment 25 due to the various thermal expansion adjacent to the anode block into the segment of the bartered segments. The inner conductor of the coaxial Auskopp- measure of the changing load of the Magnelung is dependent on this segment through the anode block trons. In addition, however, it has also been firmly carried out and made in the opening of the segment that simply by attaching it to a crosspiece or a double loop that serves for coupling and extends across the 3 ° of an opening in the segment facing away from the cathode, parts of a resonator have an electronic resonator Disturbance connected. The ridge «Jer the loop reach after can occur, which is independent of the temperature both sides into the neighboring resonators of the segments. This disturbance stems from the supply and its outer ends are connected to a suitable tuning of the resonator in question, which is connected to the inner wall of the resonator. 35 stems from the breakthrough itself. Through the development

It has been shown that on magnetrons that this distant part of a segment or a Type of coupling, certain mechanical parts of the anode belonging to the resonator and electronic interference can occur. So blockes increases the incapacity at this point z. B. in magnetrons, in which the straight ductility of the resonator because of the through-number and odd segments respectively, e.g. B. 40 fracture-related current and field displacement, with rings (so-called strap rings), electrical lei- One increased inductance leads to another tend to be connected to each other, resonance frequency and a different impedance im observed that after frequent changes-the operating conditions- resonator gap. To ensure optimal operating behavior gen, ζ. B. after frequent switching on or off in the interaction space between the cathode and Performance, the rings bend or even break. 45 to reach the resonator columns, however The electronic disturbances expressed themselves z. B. equal to the gap impedances of each resonator Deviations in vibration behavior, jumps in being; in the event of inequality, those mentioned above occur Vibration mode, excessive load dependency and similar electronic disturbances which, as already

Similar electronic phenomena could be thought to have also been observed in magnetrons,

also attached to the magnetrons described above, in which an observation is only made in the anode block.

that an observation breakthrough is attached in the breakthrough.

Have anode block. The known prior art now also shows

The invention is based on the knowledge that even arrangements in which for a magnetron these disturbances in a connection with the wheel type of the segments, in particular at the one-breakthroughs in the coupling point facing away from the cathode, one from the other segments one or more resonators are available. Have a deviating cross-section. Such a one the well-known magnetron, in which the high frequency arrangement is z. B. in Fig. 7 of the U.S. Patent Quenzenergie from two adjacent resonators 2 816 248 shown as well as in Fig. 1 of the USA.-decoupled is, as described above, the patent 2,972,085. In both mentioned arrangement breakthrough at the end 60 facing away from the cathode, however, those described in more detail above occur of the middle segment attached, which causes the disturbances, because precisely with this Auf of the segment over part of its structures due to the different thicknesses of the cross-sections Length is reduced. This has the consequence that in the segments there is a different thermal loading and oscillation operation, in which all segments must be equally loaded, in particular, at their end faces facing the cathode by 65 when the magnetron is at the upper limit of its Electron impact are loaded, which is operated by power. The F i g. 1 the last broken Segment because of its lower heat- named USA. Patent shows that at the conduction a higher temperature is reached and the break point 18 in the anode block 12 has no

ORIGINAL INSPECTED

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To compensate for the detuning of the enclosed segment or anode block caused by this breakthrough, the increase in cross-section of a pierced point, the resonator chamber is designed to be so large. The cross-sectional be det that its thermal conductivity α precisely the gain of the segments at the locations 14 and the other non-apertured segments and 14 b serve only corresponds to a guide of the coupling-block parts 5 Anode. As a result, loop 28 and, as a result of their reinforcement, ensure that the dissipation of the heat is dissipated from the heat better than the remaining segments 14. Cathode over to the anode block of the magnetron

While most known magnetrons are the size of the magnetron is uniform everywhere. Wheel design from symmetrically to each other arranged on the other hand, according to the invention of the transverse

ten and also completely identical to one another io section of a perforated section of the anode segment the state of the tech-blocks shows by shifting the cavity resonance also magnetrons of the wheel type, in which nator facing surface of the section of the approximately symmetrically around the cathode resona anode block in the direction of the cathode are arranged, the cross-sections of which are enlarged. This version relates in particular may differ. So is z. B. a so-called 15 more on an observation breakthrough between »Rising sun« resonator system in the »VALVO Be two segments, through which the oscillation behavior of the align «Volume VII, Heftl, p. 4, Fig. 4 shown. A magnetron does not change when using the invention Magnetron also shows the USA.

3 032 681 in Fig. 2 or »Philips' Technical Furthermore, according to the invention, a compensation

Rundschau «1952, p. 69, fig. 19 and 20. Also with 20 of the resonance detunings of cavity resonances Magnetrons are the cross-sections in radial gates due to a cross-sectional enlargement of a Direction is always the same, but anode segments can also be cross-sections through a corresponding cross-section be present, the strength of which in the radial displacement of the cavity facing the cavity resonator Direction is different. One below the other are the surface of the section of the anode block in radi-segments then again the same. To be done namely in 25 aler direction. This execution relates Each resonator chamber has the same initial oscillation or the segments, their transverse oscillation conditions To realize, the sectional enlargements must be due to adaptation of the ther-resonator chambers mixed with each other formed equal conductivity must be driven so far, be. that at the same time a disgruntlement of the

In all previously known arrangements 30 adjoining resonator parts is effected. To thefor However, magnetrons of the wheel type are not dimensionally detuned of the resonator chamber or chambers Taken to compensate for the breakthroughs, the correct tuning can thereby resulting upsets of the adjacent re-established that z. B. in the case in which Sonator rooms and the openings through the openings result in these openings at the coupling-in or coupling-out point standing different thermal conductivities 35 of the magnetron lies, the inner surface of the to balance the adjacent parts somehow. Anode block is changed. To z. B. the induction

The object of the invention is therefore to increase the activity of the resonator, the must the detuning of the resonators at the or the cross-section of the adjacent anode block part ver-breakthrough points to be avoided and also to be reduced, i.e. the resonator space is to be enlarged, a thermal overload of the reverse 40 must increase the inductance place or breakthrough points electrically adjacent to the resonator with a reduction in the size of the resol conductor Avoid parts. nator space must be countered. In that case will

In order to provide a remedy here, that is to say, the above - that is, the cross-section of the anode block at the above-mentioned disturbances in the mechanical and electrical points - is enlarged, namely z. B. by Irish behavior of a magnetron of the initially 45 soldering an additional flat middle part,
To avoid the type described, the invention suggests The invention is based on an embodiment

tion now that individual perforated walls are explained on the basis of the drawing. It shows
fertilization parts in comparison to corresponding not Fig. 1 schematically the partial view of a

perforated wall parts in their transverse magnetron anode body, from which the lateral sections are removed at least in the vicinity of the opening 5 ° end plates,
place are changed in such a way that, on the basis of FIG. 2, a section through the anode body

Breakthrough resulting detuning of the according to FIG. 1 along the lines -B.
speaking cavity resonator and change in the case of the anode body according to FIG. 1 is in one

thermal load capacity of the wall parts annular anode block 1 an even number of be like. 55 segments 2 and 3 arranged to run radially. Around

In this case, the cross section of an openwork can be a fixed coupling of the segments 2 Wall part (anode segment or part of the and 3 and the enclosed by them Anode blocks). As a result, it is attached to the resonance formed in the section of the anode block 1 possible to obtain the reduction of the thermal gates are connecting rings 4 to 7 with conductivity at the breakthrough point by the 60, the even-numbered or the un-cross-sectional enlargement to balance again. Connect even-numbered segments to one another. On the other hand, the inner ends of the segments can remain free even in the event of a detuning When a breakthrough point is made in the circular opening, the cathode 8 of the is seated Mood can be balanced again, so that also magnetrons.

In this resonator chamber, the same initial oscillation 65 The segment 3, which the resonators 9 and 10 and oscillation conditions as in the other Resofc * is common, has abgenator chambers at its cathode are present. Furthermore, around the 'turned end a rectangular opening 11, Temperature compensation can also be carried out very precisely, through the one for decoupling the high-frequency

Energy serving web 12 runs, which at its ends with those adjacent to the segment 3 Segments 2 is connected.

The web 12 is in its center with the inner S, which is passed through an opening 13 in the anode block 1 head 14 of a coaxial coupling 15 connected; the inner conductor 14 is made of a ceramic, vacuum-tight soldered insulating body 16 carried. The outer conductor 17 of the coupling 15 is on Anode block 1 attached.

The reduction in the heat-conducting cross section caused by the opening 11 in segment 3 (seen in the longitudinal direction) of the segment 3 is due to an enlargement of the cross-section at least of the »5 parts of the segment that remained at the point of breakthrough in the direction of the interior of the Resonators 9 and 10 balanced. The cross-sectional enlargement is chosen so that in the longitudinal direction the thermal conductivity of the broken segment is equal to the thermal conductivity ao ability of the other segments. This ensures that in the event of thermal expansion In operation, the inner ends of the segments do not move radially against each other; as a result, the Connecting rings 4 to 7 no longer »5 at this point shifted against each other and can no longer break.

This also ensures that the resonators 9 and 10 do not deviate when heated of the other resonators of the magnetron are out of tune.

At the same time as the adjustment of the thermal expansion is due to the enlargement of the cross-section of the segment 3, the cross-sectional area of the resonators 9 and 10 has been reduced, whereby the counteracted the enlargement of the resonator inductance caused by the opening 11 in segment 3 will.

If this effect is insufficient or too great to compensate for the detuning, the Surfaces 18, which form the inner boundary of the resonators 9 and 10, receive a different position, such as this is shown, for example, by the dashed lines 19 and 20, respectively.

To observe the temperature of the cathode 8, the anode block 1 has an opening 21, which is melted to the outside through a sleeve 22 connected to the anode block 1 in a vacuum-tight manner Glass window 23 is complete. To increase the inductance of the resonator at the To compensate for the breakthrough, the cross-sectional area of the resonator is reduced by the Be The boundary surface of the resonator on the anode block 1 is no longer that shown by the dashed line 24 Location, but at 25.

The invention is not limited to the present embodiment of a wheel type magnetron; she can z. B. can also be used in a magnetron, the resonators by attachment a number of bores around the cathode space and a corresponding number of radial ones Slots that connect the cathode-anode space with these holes are made.

Claims (4)

Patent claims: 1. Magnetron of the wheel type, its approximately symmetrically arranged around a cathode Anode segments together with an anode block surrounding the anode segments the electrically Form conductive wall parts of the cavity resonators, in which at least one Wall part of one or more of these cavity resonators with at least one opening is provided, characterized in that individual perforated wall parts (1, 3) in comparison to corresponding non-perforated wall parts in their cross-section at least in the vicinity of the breakthrough point are changed in such a way that the on The reason for the breakthrough is the detuning of the corresponding cavity resonator and changes in the thermal load-bearing capacity of the wall parts are compensated for. 2. Magnetron according to claim 1, characterized in that the cross section of an openwork Wall part (anode segment or part of the anode block) is enlarged. 3. Magnetron according to claim 1 or 2, characterized in that the cross section of an openwork Part of the anode block by shifting the facing towards the cavity resonator Increased surface area of the portion of the anode block in the direction of the cathode is. 4. Magnetron according to one or more of the preceding claims, characterized in that that resonance detuning of cavity resonators due to a cross-sectional enlargement an anode segment by shifting the cavity resonator accordingly facing surface of the portion of the anode block balanced in the radial direction is. 1 sheet of drawings