DE966961C - Electron tube arrangement for fanning ultra-high frequency electrical oscillations, preferably in the decimeter or centimeter wave length range - Google Patents

Description

Issued on the basis of the First Overhead Line Act of July 8, 1949

(WiGBL p. 175)

FEDERAL REPUBLIC OF GERMANY

ISSUED SEPTEMBER 19, 1957

GERMAN PATENT OFFICE

PATENT LETTERING

CLASS 21a ⁴ GROUP 9oi INTERNAT. CLASS H 03b; f; j

B 4843 VIII a j 2i a *

r. = $ ng. Friedrich Wilhelm Gundlach, Darmstadt

has been named as the inventor

Pintsch Bamag Aktiengesellschaft, Berlin

Electron tube assembly for fanning ultra-high frequency electrical oscillations, preferably the decimeter or

Centimeter wavelength region

Patented in the territory of the Federal Republic of Germany on August 13, 1942 The period from May 8, 1945 up to and including May 7, 1950 is not counted towards the patent term

(Ges. Of July 15, 1951)

Patent application published May 29, 1952 Patent issued September 5, 1957

The invention relates to electron tube assemblies for fanning (producing, enhancing, receiving) ultrahochfrequenter electrical oscillations, preferably the decimeter or centimeter wavelength region, under \ ^r SE OF cavity resonators as Anfach- and / or Steuerresonator.

First and foremost, the invention relates to generators (for sending or generating Auxiliary vibrations during superimposition reception) and high-frequency amplifiers in the sense of long-wave technology (when sending or receiving). In particular, the invention extends to such Arrangements in which the stimulating electron flow into the cavity resonator or passed through it and thereby causes the fanning of the fanatic resonator and parts the walls of the or each cavity resonator

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act as two electrodes (e.g. two grids or grids and anode).

The purpose of the invention is in particular to assemble electron tubes with a cavity resonator in multiple stages while maintaining the cavity principle, namely as a single or multi-stage externally controlled transmitter, as a multi-stage high-frequency amplifier for reception purposes or as Heterodyne receiver, preferably foreign heterodyne receiver with high frequency amplification. A single stage electron tube assembly is used for this purpose or an arrangement consisting of several levels designed so that its operation, at least the adjustment of the coordination and, if necessary, the coupling of the individual or the various cavity resonators takes place on the front of a front panel, the tube or tubes with cavity resonator or Hohlao on the back as a mounting wall Room resonators are arranged to be easily exchangeable (by inserting or plugging in).

According to the invention, the tube with the cavity or resonators is easily exchangeable arranged with respect to a faceplate so that the tuning device connected to the faceplate and the coupling device for coupling a radiator or a subsequent one Amplifier stage can be separated from the cavity resonator.

To further explain the inventive concept, those illustrated in the drawings may be used Embodiments serve.

In Fig. Ι is a mounting plate, which is shown in the following also called the front panel, denoted by 1. 2 is the actual high frequency amplifier tube, the internal structure of which can be seen in more detail in Fig. 3.

The tube has a control resonator and a fan-up resonator, both as cavity resonators are trained. The expensive resonator is externally (in the case of external excitation) or from the fan-up resonator (in the case of feedback) ultra-high-frequency control voltages fed. The expensive resonator lies between the cathode and a grid (control grid) and the fan-up resonator between the anode and one between the anode and the control grid provided grid (acceleration grid). In each of the two cavity resonators, the associated electrodes parts of its lateral surfaces (boundary surfaces J. Each of the cavity resonators consists essentially of a piece of a concentric Lecher line and a Plate capacitor-like part of the cathode and the control grid or the anode and the acceleration grid is formed.

The tube is designed to be rotationally symmetrical to an axis, in the direction of which the electron flow runs. The electrodes are accordingly designed as flat (planar) electrodes. The anode is designated with 31, the acceleration grid or tension grid with 45, the control grid with 48 and the carrier of the emitting layer of the oxide cathode indirectly heated by a wire spiral 50 with 49 '. The anode 31 is formed by a metal disk which closes the tube 23 at one end in a galvanic connection. The acceleration grid 45 is formed by a metal mesh and is in galvanic connection via the metal parts 43 and 46 with the metal tube 24 arranged concentrically to the metal tube 23. In a corresponding manner, the control grid 48, which also consists of a metal mesh (wire mesh), is in galvanic connection with the metal tube 34. The tin can 49 is covered on its top surface 49 'with an emitting layer; 49 'thus forms the actual cathode. The tin box 49 contains the spiral heating wire 50. It is also galvanically connected to the metal tube 33, which is concentrically surrounded by the metal tube 34. A high vacuum-tight seal is formed between the metal tubes 23 and 24 with the aid of a ceramic disk 25 which is shaped in the manner shown. The lower pointed surface of the ceramic disk 25 forms, together with the adjoining surfaces of the tubes 23, 24, two grooves into which the glass flux 26 is melted. A high vacuum-tight seal between the tubes 33 and 34 is produced in a corresponding manner. The melt flows used there to connect the ceramic disk 25 'to the metal pipes 33 and 34 are z. B. denoted by 41 and 54. A glass cylinder 30 is provided concentrically to the pipe axis and is fused at its end faces with the tapered edges 29 and 36 'of the metal parts 28 and 36, respectively. The metal parts 28 and 36 are by \ ^r erschweißen via the metal parts 27 and 35 connected to the pipe 24 'and 34'. The metal pump nozzle 17 is attached to the inner surface of the tube 23, which is provided with some very small through-holes to enable evacuation. A metal part 52, 37 through which the power supply line 38 for the heating coil 50 is passed is attached to the inner surface of the tube 33. At the end of the metal tube 37, this is fused to the power supply wire 38 by a glass bead 39 and in this way the high vacuum-tight seal is achieved at this point. In the interior of the tube 34, a ceramic web 51 is mounted on a metal flange located below. The ceramic web 51 is used to guide and center the power supply wire 38. The metal tube 33 represents the second power supply line for the heating coil 50. Instead, two heating current supply wires can be provided and led accordingly to the outside. The metal tubes 24 and 34 are connected to one another at their ends facing each other by a metal tube 40 (made of nickel) filled with getter material, which is open at its ends and optionally provided with a slot in its outer surface. For the purpose of evaporation of the getter material, a voltage source is applied between the tubes 24 and 34 and a current is applied through the metal tube 40

clever and in this way causes the evaporation of the getter material. Eventually that will thin metal tubes 40 melted through by increasing the current passed through accordingly will. In order to prevent the getter substance from getting onto the electrodes, a shielding plate is provided 42 provided.

In order to supplement the parts 31, 45, 23, 24 and 48, 49, 33, 34 each with a cavity resonator (fan or control resonator), the tubes 23 and 24 or the free ends of the tube parts 23 ', 24 'The pipes 3 and 4 (made of copper) and the pipes 3' and 4 '(made of copper) are joined to the pipes 33 and 34 or their parts 33' and 34 'by soldering. The diameter of the tubes 3, 4 and 3 ', 4' are chosen so that they together with the tubes 23, 24 or 33, 34 form a piece of a concentric Lecher line with constant wave resistance (see. Fig. Ι and 4). At the outer ends, the tubes 3, 4 and 3 ', 4' are short-circuited in terms of high frequencies by metal surfaces. In the case of FIG. 1, the tubes 3, 4 (and likewise, if appropriate, also the tubes 3 ′, 4) are galvanically short-circuited at their outer end by a metal washer 21. The plate capacitor formed by the anode 31 and the acceleration grid 45 and the Lecher line short-circuited at the other end and formed by the tubes 23, 3 and 24, 4 together form the fan-up resonator. The plate capacitor formed by the control grid 48 and the emitting surface 49 'of the cathode and the Lecher line short-circuited at their ends and formed by the tubes 33, 3' and 34, 4 'together form the expensive resonator. Instead of the galvanic short circuit, a capacitive short circuit through metal surfaces can be provided at the outer end of the pipes 3, 4 or the pipes 3 ', 4' or the pipes 3, 4 and 3 ', 4' , which is shown in Fig. 4 for the latter case is shown. The short-circuit capacitance at the outer (upper) end of the tubes 3, 4 is determined by the metal ring disk 18 galvanically attached to the tube 4 and the metal ring disk 20 galvanically attached to the tube 3 and the insulating material 19 (e.g. mica disk) located between the two metal ring disks. educated. In a corresponding manner, the short-circuit capacitance at the outer (lower) end of the tubes 3 ', 4' consists of the metal ring washer 18 'galvanically attached to the tube 4', the metal ring washer 20 'galvanically attached to the tube 3' and the insulating material 19 '(mica washer ). If the galvanic short circuit is used, two electrodes or two electrodes each receive the same potential in terms of direct current.

So if both the control resonator and the fan-up resonator are galvanically short-circuited at the end, on the one hand the anode 31 and the acceleration grid 45 have the same (positive) DC voltage, while, on the other hand, the cathode 49 'and the control grid 48 are also DC-wise are at the same potential. Instead, you have it in your hand, at the outer end of the fan-up resonator or to use the capacitive short circuit at the outer end of the control resonator and thus to achieve that z. B. cathode and control grid or acceleration grid and Anode can receive different DC voltages. This is particularly important when e.g. B. the control grid is to receive a negative DC bias voltage with respect to the cathode or else z. B. the acceleration grid and the anode receive different high positive DC voltages should.

The plate capacitor formed by the two grids 45, 48 represents a structure that compared to the operating frequency or the natural frequency of the control resonator and fan-up resonator out of tune, and tuned to a much higher frequency. For the operating frequency the capacitor formed by the two grids practically represents a short-circuit capacitance, so that the The space between the two grids is practically free from high frequency fields. Do you want complete the high-frequency short-circuit between the two grids, so can metal parts or metal surfaces are provided at the edge of the grid, which provide additional capacity form with each other.

A sleeve 5 made of metal (»shielding go sleeve «) firmly connected, which engages in a resilient sleeve 6 formed by slots, which in turn is firmly connected to the front panel 1 (see. Fig. ι and the associated top view Fig. 2). The tuning and coupling elements are located inside the shielding sleeve 5. Takes place at the same time the tube with the cavity resonator is held on the front plate 1 by means of the sleeve 5 or their back. The tube with cavity resonator is therefore easily exchangeable and is by inserting the sleeve 5 into the resilient sleeve 6 in its operational position. In the same way, on the outer conductor 4 'of the cavity resonator serving as a control resonator a shielding sleeve may be provided, which is in a correspondingly attached to the front panel 1 resilient The sleeve is detachable. In this way a second support is achieved. The dem Control resonator sleeves, for example, assigned to them expediently have the same diameter as that of the fan-up resonator assigned sleeves of different diameters to avoid incorrect insertion of the tube to avoid in the device (distinctiveness). There are two openings in the outer conductor 4 of the fan-up resonator (83, 84 in Fig. 4) for the passage of the tuning screw 7 and the coupling pin ii ' intended. The tuning screw 7 is operated from the outside by the rotary knob 8, which is on the other side of the front panel 1. By operating the rotary knob 8 the free end of the tuning screw 7 more or less far into the field space of the cavity resonator (between 3, 4) protrudes, the tuning (natural frequency) of the fan-up resonator can be changed or set. The end protruding into the field space of the fan-up resonator

the tuning screw 7 can be made of metal or insulating material.

In the same way, the cavity resonator serving as a control resonator can be set up so as to be tunable be. In some cases it is useful to use the tuning means of the fan-up resonator and S expensive resonator to be coupled with each other in such a way that by operating a single handle or The tuning of the control resonator and fan-up resonator is effected at the same time with the rotary knob. in the the rest of the time it is not the execution of the tuning of the cavity resonators indicated in Fig. 1 bound, even if this is particularly advantageous in many cases. Instead of the adjustable screws7 you can z. B. provide a displacement body known per se in the field space of the cavity resonator, the one for the purpose of changing the natural frequency of the cavity resonator from a point larger electrical field energy (in the axial direction) towards a point of greater magnetic field energy or vice versa. Also the adjustment or setting of the displacement body can then (preferably by a rotary movement using a suitable coupling and translation if necessary) by means of an operating handle located on one side the front panel 1 is located, while the tube with the cavity resonators is on the other side the front panel is arranged.

To the tuning (natural frequency) of the cavity resonator independent of the actual ("continuous") tuning means (tuning screw 7 or rotary knob 8) to be able to set and thereby in particular the production-related Differences between the individual resonators (e.g. from exciter and main transmitter) or from resonators to compensate for different tubes and also z. B. when replacing the tube or the or To always achieve the same scale calibration of the cavity resonators, the fan-up resonator is still provided with an additional screw 9 which is held in place by a lock nut 10. Ever after whether the free end of the screw 9 more or less far into the field space of the cavity resonator protrudes, this in turn has a different natural frequency. This on The resonator or the screw attached to its outer conductor is unique after the tube has been manufactured permanently set. Of course, after inserting the tube in the device or on the Corrections can still be made to the front panel by means of screw 9. The actual operation of the device (during operation or during commissioning) can only be done by Actuation of the rotary knob 8 and therefore take place from the front of the front panel. Also the The control resonator can be opened with a screw corresponding to screw 9 of the fan-up resonator (the can also be viewed as a kind of "rough adjustment").

To couple the fan-up resonator to another resonator, e.g. B. the control resonator one following high-frequency amplifier stage or to a radiator, the coupling pin 11 'is used, which is shown in the field space of the cavity protrudes and in the example shown from the continuation of the inner conductor 11 of a concentric power line (with the outer conductor 12) which, expediently by means of its outer conductor 12, is attached to the front panel 1. In the same Way, the control resonator can be provided with a coupling through which it can be, for. B. with a Radiator (receiving antenna) or coupled to the fan-up resonator of a previous amplifier stage will. As can be seen from Fig. 1, the tuning element and the coupling element through the shielding sleeve 5 and the parts adjoining it towards the front panel I. completely metallic shielded by the resilient metal sleeve 6 on a bolt-like, from Metal existing part 85 is attached, which also at the same time to form the outer conductor of the concentric energy line 11, 12 is used and in turn rigid on the rear of the front panel 1 is appropriate.

For the purpose of supplying the operating voltages (heating, anode and grid voltages) the tube carries an annular disk 16 made of insulating material on which a row of contact pins 13 are attached, which in turn z. B. by connecting wires with the relevant electrodes in Connected. Leaf springs 14, which are screwed onto the insulating strip 15, press against the pins 13 are. Instead, blade contacts can also be used. The insulating strip 15 is on the front panel 1 attached so that they are on the same Side of the front panel 1 like the tube. The power supply wires for the two The grid and the anode are expediently placed outside the field space of the cavity resonator or the cavity resonators lying surface parts of the Resonatqrwandungen connected, the then in turn convey the metallic connection to the electrodes, e.g. B. is the lead wire for a possible DC bias in the case of the control grid 48, it is expedient to apply it to the outer surface of the tube 34, in the case of the acceleration grid and the anode, to the outer surface of the tube 24 or the inner surface of the tube 23 connected. The anode direct current can be via the Drain the inner surface of the tube 33 (from the cathode 49 '). The corresponding connecting wire is therefore expediently attached to the inner surface of the pipe 33 or the pipe part 33 'or connected to the outer surface of the pipe 37. In a similar way In the same way as the tuning of the resonators, the coupling (the Power line 12, 11) to the fan-up resonator and a corresponding coupling to the control resonator be set up adjustable, z-. B. in the Way that the pin 11 'can be moved like a trumpet and the displacement by a screwing process can be effected. This can also be done with the help of one on the outside of the mounting plate arranged operating handle take place in

in a similar way to this in Figs. i, 2 for the adjustability of the tuning of the fan-up resonator is specified.

In Fig. 5 is an embodiment of the invention shown in which several tubes of the type shown on the basis of Fig. ι to 4 on the Front panel are attached and form an externally controlled transmitter with two amplifier stages. The tube 58 with control resonator 58 'and fan-up resonator 58 "represents the control transmitter in Its control cavity 58 'and its fan cavity 58 "are through two concentric energy oil lines 62 and 61 with one Coupled cavity resonator 63, via which the feedback takes place. The resonator 63 determines the frequency at which the exciter vibrates. He is of the cylindrical metal housing 65 and formed by this enclosed inner conductor 64, which galvanically with its one end which is placed on a cover plate of the housing 65. The coupling of the power lines 61 and 62 to the fan-up resonator 58 ″ or the control resonator 58 ′ takes place in that shown in FIG Way, by adding the inner conductor of the concentric power line a certain, possibly very small piece protrudes into the field space of the cavity resonator (corresponding to the pin ii '). In The energy lines 61, 62 can be coupled to the cavity resonator 63 in the same way. Using the same type of coupling, the exciter resonator 58 ″ of the control transmitter is now the control resonator 59 ′ first high frequency amplifier stage by a concentric Power line 66 coupled. This first high-frequency amplifier stage or its tube is denoted by 59. Your fan-up resonator 59 is by a concentric energy line 67 in the same Coupled with the control resonator 6o ′ of the second amplifier stage 60. To the fan-up resonator 60 ″ of the second amplifier stage 60 is coupled to a concentric power line 68, whose other end 69 leads, for example, to a radiator. The tubes 58, 59 and 60 are so with respect to one another arranged so that resonators of different stages to be coupled face one another. In this way you can have a particularly clear structure and the shortest possible power lines achieve. The cavity resonator 63 can also be equipped with tuning devices (such as shown in Fig. 1 for the fan-up resonator) and again made the device be that the tuning means is adjustable from the front of the faceplate. The resonator 63 can be designed or provided with special means such as a thermostat that through Temperature fluctuations as far as possible, no expansion of the conductor occurs, which is an undesired one Change the natural frequency of this resonator. The operating voltages are the individual Tubes from a connector strip 70 expediently embedded in the front of the front panel fed. From the connector strip 13, a cable harness 71 leads to the various tubes in order to them to supply the operating voltages. If the transmitter is to be modulated, it is amplitude modulation expedient to modulate one or both amplifier tubes (59, 60), but not the Control transmitter tube 58, specifically for the purpose of keeping the transmission frequency constant as far as possible. at Frequency modulation, the exciter can be modulated.

The Stetter resonators and the fan-up resonators the tube can be operated individually by means of an operating handle located on the front of the front panel be tunable. Instead, the device may be such that two or, if necessary, several operating handles or the axes corresponding to the operating handles or drives, expediently on the back of the front panel, are coupled to one another in such a way that the tuning of two or more and possibly all of the resonators by a single one Operating handle can be done. This allows the number of on the Reduce the number of operating handles on the front of the front panel. In a corresponding way the degree of coupling of the various resonators with one another in the manner already mentioned be adjustable from the front of the mounting plate.

As a further embodiment of the invention, a heterodyne receiver with external superimposition and high-frequency amplification is shown in FIG. 6, again using tubes of a type as explained in more detail with reference to FIGS. In terms of its structure, this arrangement is also very similar to the arrangement according to FIG. 5. The tube 72 serves as a high-frequency amplifier, the tube 73 as a mixing tube and the tube 74 as an auxiliary transmitter (oscillator). The tube 74 operates in a feedback circuit together with the cavity resonator 63 'in the same way as this is shown in FIG. 5 for the case of the control transmitter. The cavity resonator 63 'is formed by a cylindrical metal housing 65' and an inner conductor 64 'which is concentrically enclosed by this and which is galvanically fastened at one end to a cover plate of the housing 65'. The control resonator and the fan-up resonator of the tube 74 are in turn coupled to the cavity resonator 63 'via concentric lines 61' and 62 ', so that the tube 74 operates in a feedback circuit. The auxiliary frequency generated in this way is fed to the control resonator of the mixing tube 73 via the concentric energy line 75. The vibrations to be received are fed from the radiator via input sockets 76 and the concentric power line Jj to the control resonator 72 'of the amplifier tube J2 . The amplified high-frequency energy arrives from the fan-up resonator ^ 2 " via the concentric energy line 78 into the control resonator 73 'of the mixing tube 73. The fan-up resonator 73" of the mixing tube must be tuned to the much lower intermediate frequency. It is therefore a wire

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Oscillating circuit or a corresponding band filter formed. In the event that the intermediate frequency is sufficiently large, this resonator can also expediently be designed as a cavity resonator be. The intermediate frequency is fed via the line 79 to the sockets 8o, to which an intermediate frequency amplifier is attached usual form can connect. A terminal strip 81 is in turn used to Connection of the operating voltages which are fed to the tubes with the aid of the cable harness 82. All cables are expediently laid on the back of the mounting plate while all operating handles and, appropriately, the existing sockets are on the front the mounting plate or are accessible from this side. The connector strip or Terminal strip for connecting the operating voltages can also be on a side wall or the The rear wall of a box is located, the front of which is formed by the front panel 1. It can the arrangements customary for radio devices are used. To bridge a larger one The resonator 63 or 63 '(Fig. 5, 6) be exchangeable, or several resonators of different natural frequencies can be connected in parallel or optionally be switchable. Each partial wave range is then variable with the help of the By means of tuning means (corresponding to 7, 8 Fig. 1) bridged. If the resonators 63, 63 'are exchangeable should be, the mutually interchangeable parts are to be selected or designed so that they when used with the tuning device or coupling device in the desired Way to engage. In arrangements as shown in Figs. 1 and 4, is accordingly to take into account that in the interchangeable tubes 3.4 or 3 ', 4' the hole openings 83 and 84 (Fig. 4) all sit at the same height, so that accordingly through these hole openings the parts 7. or 11 'after inserting the tube without further ado lead through.

In the exemplary embodiments described, the cavity resonators partly consist of one Plate capacitor, partly from one piece of a concentric Lecher line. Instead are other forms of cavity resonators can also be used; z. B. the entire cavity resonator consist of a plate capacitor, in particular of the type that following the (middle) point where the plates of the capacitor act as electrodes that adjoin it Surfaces assume a larger plate spacing (offset) and the entire cavity resonator has the oscillation type of the plate capacitor owns. In this case, too, the device can be made so that the axes of the Cavity resonators parallel to each other and in parallel! to the front panel. Furthermore, the Cavity resonator as a whole have the shape of a concentric Lecher line. In this case concentric electrode arrangements are used in particular, in such a way that the fan-up resonator and the control resonator are nested. In arrangements of this type, the arrangement is expediently made so that the axis of the tube and thus the axis of the or the two cavity resonators on the front panel stand vertically. The operating handles are expediently chosen so that the Coordination and, if necessary, the creation of the coupling is carried out by a rotary movement. Appropriate translations are to be provided accordingly, through which a possible pushing movement is converted into a rotary motion. One with its axis perpendicular to the front panel concentric Lecher line can be changed in its natural frequency, for example, that through a cutout in the outer conductor through a conductor part more or less in the Field space of the concentric Lecher line can be turned in.

In the exemplary embodiments described, there is a particularly advantageous type of coordination the cavity resonators and also the coupling device shown. Because it offers the Advantage that these devices mechanically at all with the walls of the cavity resonator do not intervene. As already mentioned, z. B. the so-called Use displacement bodies as tuning devices, in which the mentioned advantage also, although not so largely, is given because the displacement body is within the cavity be arranged and must be moved back and forth in the axial direction. Instead of such voting devices other voting options may also come into question. For example, the coordination of a concentric Lecher line or a piece of such done by having its (short-circuited) end after Type of trumpet slide is movable; the high-frequency connection between the mutually displaceable parts expediently only takes place by capacitive short circuit. These Pushing motion must then be converted into rotary motion by a suitable translation will. After all, this type of tuning is generally less advantageous because the Wall parts of the cavity resonator have to be moved, which is associated with greater work performance is.

In the exemplary embodiments, all arrangements are shown in which the fan-up resonator lies between a grid and the anode. Instead, embodiments are within the scope of the invention possible in which the second electrode formed by the cavity resonator as Grid is formed and, seen in the direction of the electron flow, on this electrode Another fully-walled electrode follows, which serves as a collecting electrode. It is also within the scope the invention to use arrangements with two grids instead of the arrangement described in more detail, who only have a grid. In case of

Arrangements with only one grid can follow the designs completely on the above, by z. B. in a tube according to Fig. 3, the two grids collapse into one grid, leaves. The grid can then, if desired, be insulated in terms of direct current, which is achieved thereby can be that the grid with the other wall parts of the or each cavity resonator is not galvanically connected, but

ίο by short-circuit capacitances caused by metal surfaces are formed and expediently represent plate capacitors or cylinder capacitors. To the The control resonator can then restore the vibrations to be amplified from a previous one Stage or z. B. from the receiving antenna or in the case of feedback from the fan-up resonator are fed forth.

If arrangements with planar electrodes are used, it is advantageous to use the

ac grid in a special way, namely in such a way that they are tensioned from a resilient Wire mesh. This measure is also general in the case of electron tubes with flat electrodes (without cavity resonators) can be used advantageously, since they are particularly small in this way Electrode spacings can be made operationally reliable.

Claims (12)

Claims ·. i. Electron tube arrangement for fanning (generating, amplifying, receiving) of ultra-high frequencies electrical vibrations, especially of the dm or cm wavelength range, in which two concentric conductors are used to form a cavity resonator, the passed through the tube walls in a high vacuum-tight manner by means of ring-shaped fusions are, and which is provided with tuning means outside of the vacuum, thereby characterized in that the tube together with the cavity resonator (s) as The unit is arranged so that it is easily exchangeable with respect to a front panel (1) serving as a holder and that the wall (s) of the cavity resonator (s) with such openings or approaches is or are provided that the tuning device connected to the front panel (7) and the coupling device (11 ') for coupling a radiator or a following amplifier stage can be easily separated from the cavity resonator. 2. Arrangement according to claim 1, characterized in that that at least the tuning device · of the cavity resonator, preferably by means of a rotary knob (8), from the front the front panel can be operated. 3. Arrangement according to claim 1, characterized in that that the tuning device from a displacement body ("tuning body") made of electrically conductive or dielectric Material is formed, the position of which changes in the area of the field space of the cavity resonator is, and that the device is made so that the tuning body (7) only by inserting the tube together with the cavity resonator into the corresponding holder the back of the front panel (through an opening provided in the resonator wall through) comes into engagement with the field space of the resonator. 4. Arrangement according to claim 3, characterized in that the tuning body (7) from consists of a screw, the free end of which according to the actuation of a rotary knob (8) more or less protrudes into the resonator field space (between 3 and 4). 5. Arrangement according to claim 1 or one of the following, characterized in that the Cavity resonator in addition to the aforementioned device connected to the front panel operational setting or change of its natural frequency with a second if necessary similar tuning device (9) is provided, which is fixed elsewhere with is connected to the cavity resonator. 6. Arrangement according to claim 1 or one of the following, characterized in that the The axis of the cavity resonator (s) runs parallel to the plane of the front panel. 7. Arrangement according to claim 1 or the following, characterized in that the holding device (85, 6) for the unit on the front panel the coupling device (11, 12) carries "and encloses the tuning device (7, 8) and together with one on the outer wall the metal sleeve (5) attached to the cavity resonator. 8. Arrangement according to claim 7, characterized in that a holding device on Fan-in resonator and a second appropriately designed holding device on the control resonator is provided. 9. Multi-stage tube assembly using combinations of assemblies according to claim 1 or the following, in particular according to claims 3 and / or 5, characterized through their use as a multi-stage high-frequency amplifier, externally controlled generator (Fig. 5) or heterodyne receiver (Fig. 6). 10. Arrangement according to claim 9, characterized in that that each cavity resonator including tube by placing this unit (s) on the back of the front panel with one or one coupling device each serving to extract or supply energy comes into engagement. 11. Arrangement according to claim 1 or the following, characterized in that the coupling of the various stages with each other and possibly the coupling of the radiator and possibly the feedback of the Tax sender via a (on the business fre- frequency-matched) cavity resonator is carried out with the help of concentric energy lines, whose inner conductor protrudes into the space to be coupled. 12. Arrangement according to claim i, 3 and 10, characterized in that tuning devices and optionally coupling devices different cavity resonators through a common operating handle (Rotary knob 8) are to be operated. Documents considered: Swiss Patent No. 216 058; French Patent Nos. 855 153, 85285s; U.S. Patent No. 2,153,728. For this 2 blarfct drawings! © 709 682/62 9.57