DE1128569B - Time-of-flight tubes whose collecting electrode is connected to the adjacent end of the high-frequency tube part through a shunt capacitor at high frequencies - Google Patents

Description

GERMAN

PATENT OFFICE

kl. 21g 13/17

INTERNATIONAL KL.

H01j; H03f

E12761IXd / 21g

REGISTRATION DATE: AUGUST 2, 1956

NOTIFICATION OF REGISTRATION
ANDOUTPUTE
LAUNCHED: APRIL 26, 1962

The invention relates to time-of-flight tubes such as klystrons and traveling wave tubes, and in particular to a means of maintaining the operational stability of such tubes by eliminating their inclination to improve swing. It relates in detail to time-of-flight tubes in which the electron gun at one end of the tube, the collecting electrode at the other end of the tube and the high-frequency tube part between the electron gun and the collecting electrode and where the collecting electrode DC-wise separated from the high-frequency tube part and at an axial distance is arranged by this. Is it a transit time tube in the manner of a two-chamber or Multi-chamber klystrons, the invention relates above all to tubes in which the high-frequency leading The tube part following the last resonator chamber creates a coaxial flow of electrons enclosing and with the last resonator chamber conductively connected tubular part.

Such klystrons have proven to be inherently unstable at higher powers, d. that is, they tend to oscillate uncontrollably.

In studying the problem of these deleterious klystron vibrations, it was found to be in mainly caused by feedback of high frequency energy coming from the collector originates because the high frequency energy of the bundled electron beam is not completely at the coupling gap the output cavity is withdrawn; there remains a certain amount of energy, which is fed to the collector. As a result, the collector acts like an "antenna" and induces it such an unwanted feedback.

In the case of a time-of-flight tube of the type mentioned at the outset, this disadvantage is characterized according to the invention eliminates that the collecting electrode with its adjacent end of the high-frequency tube part by a shunt capacitor acting as a concentrated switching element, which is dimensioned in this way is that it represents as small a resistance as possible for the high-frequency current, in terms of high frequency connected is.

Time-of-flight tubes are already known in which the collecting electrode (collector) with the high-frequency leading Tube part more or less short-circuited via a capacitor in terms of high frequency is. In these known tubes, however, the collecting electrode forms one at the same time Part of the decoupling device, so it belongs to the high-frequency tube part, so that forced transit time tube, their collecting electrode with the adjacent end of the high frequency leading Part of the tube is connected in terms of high frequency by a shunt capacitor

Applicant:

Eitel-McCullough Inc., San Carlos, Calif. (V. St. A.)

Representative: Dipl.-Ing. H.Marsch, patent attorney, Schwelm (Westphalia), Westfalendamm 10

Claimed priority: V. St. v. America, December 12, 1955 (No. 552 576)

George M. W. Badger, San Bruno, Calif. (V. St. Α.), Has been named as the inventor

A high-frequency short circuit between the collecting electrode and the rest of the high-frequency carrying electrode is usually present Tube part is necessary. It is also known per se to provide a 2/4 choke on the collecting electrode side, to prevent high frequency energy from escaping.

In the drawing, an embodiment of the invention is shown for example, namely is Fig. 1 is an axial section through a klystron with three

Cavity resonators incorporating the bypass capacitor according to the invention, and Figure 2 is an enlarged view showing details of the bypass capacitor of Fig. 1 reproduces.

1 shows a multi-chamber klystron which is known in terms of its structure. The tube has a jet generator 3 at one end, a collector 4 at the other end and a high frequency carrying one Part 5 between the beam generator 3 and the collector 4. The connecting part which forms part of the tubular casing 6 has the essential feature of the invention: it also serves as a shunt capacitor.

The beam generator 3 has a cathode 8 and a cylindrical focusing electrode 12, which are in a

209 577/341

Cup-shaped anode 9, preferably made of copper, are accommodated. The one from the cathode emitted electrons run through the anode opening 11 to the collector 4 at the other end of the Tube. The cup-shaped collector 4 is preferably made of copper and is provided with an outlet tube 15 and a (not shown) cooling device.

Each of the interaction gaps 20 is formed by a preferably tunable cavity resonator surround. One of these resonators, the output cavity resonator, is indicated by the dashed lines Lines 28 indicated. The ceramic cylinders 24 are used for vacuum-tight closure of the tube in the area the cavity resonators. The tubular parts 17 and 18 represent the drift tubes.

The collector 4 is from the tubular part 19 arranged separately; there is a gap 30 between these parts. The connecting part 6 is used to to attach the collector 4 to the part 19. As best shown in Fig. 2, the connecting part 6 has a metal flange 31 which protrudes outwardly from the part 19, and a metal one Flange 32, which protrudes from the collector 4 to the outside. These two flanges are preferred Made of copper and brazed

33 held in place. A ceramic insulating cylinder 34 is between the flanges 31 and 32 provided, the end faces of the cylinder 34 connected to the flanges 31 and 32 in a vacuum-tight manner are, so that the connecting part 6 forms part of the tubular casing. It can be of the most varied Types of arrangements used to connect the ends of cylinder 34 to flanges 31 and 32 to connect vacuum-tight. The connection shown in Fig. 2 has outer rings 36 and inner rings 37 on. These rings are preferably made of copper. The outer rings 36 are flanged 31 and 32 connected by brazing. The inner rings 37 are bent inwards Parts provided which overlap the ends of the cylinder 34 and at the ends of the ceramic cylinder 34 are welded on. About the welding of the inner rings 37 to the ceramic cylinder

34, the ends of the cylinder 34 are metallized. To the rings 36, 37 from the axial compressive force to relieve due to the atmospheric pressure, the flanges 31, 32 are with annular projections 38 and 39, respectively, which abut the inwardly bent parts of the inner rings 37.

In the embodiment shown, the shunt capacitor between the collector 4 and the tubular part 19 of the high-frequency carrying tube part 5 from the connecting part 6 educated. The inner and outer surfaces of the ceramic cylinder 34 are to, as at 40 and 41 indicated, metallized. The metallization layers 40 and 41 are on the inside and outside Outer sides of the ceramic cylinder 34 applied at the same time that the end faces of the Cylinder 34 are covered with the metallization layer. There is thus a good electrical flow path from the inner metallization layer 40 to the metallization layer on the right end face of the cylinder 34 and further over the inner ring to the flange 32 available. Similarly, a good electrical flow path is from of the outer metallization layer 41 to the flange. It should be noted that none of these Metallization layers 40 and 41 extend the full axial length of the cylinder 34 so that there is no path through which direct current can flow between the flanges 31 and 32. Preferably the inner metallization layer almost completely overlaps the outer metallization layer 41 and vice versa, as shown in FIG. That of the metallization layers 40, 41 and the shunt capacitor formed by the ceramic cylinder 34 is of course not open to use limited in the case of klystrons, but can be used for any transit-time tubes of the initially mentioned Kind be used.

The required characteristics for a shunt capacitor, as formed by the metallized ceramic cylinder 34 are that the shunt capacitor has a sufficiently high DC resistance to prevent the flow of To prevent direct current from the part 19 to the collector 4 (or vice versa), as well as a sufficient low impedance to allow virtually unrestricted flow of high frequency current between the part and the collector 4 to enable.

Even if the metallized ceramic type of FIG. 2 is used as the preferred type of capacitor any other type of capacitor, other than those mentioned above, may be used Has characteristics in order to reduce the collector feedback recognized as harmful and thus improving the operational stability of the tube. For example, a capacitor can be used in which the metallization layers 40 and 41 are replaced by metal cylinders.

Claims (5)

PATENT CLAIMS: 1. Time-of-flight tube in which the electron gun is located at one end of the tube, the collecting electrode at the other end of the tube and the high-frequency tube part between the electron gun and the collecting electrode and in which the collecting electrode is DC-separated from the high-frequency tube part and is arranged at an axial distance therefrom , characterized in that the collecting electrode is connected to the adjacent end of the high-frequency tube part by a shunt capacitor acting as a concentrated switching element, which is dimensioned so that it represents the lowest possible resistance to the high-frequency current, high-frequency connected. 2. Time-of-flight tube in the manner of a two-chamber or multi-chamber klystron, in which the electron gun at one end of the tube, the collecting electrode at the other end of the tube and the high-frequency tube part, in the connection to the last resonator chamber, the electron flow coaxially enclosing tubular part that is conductively connected to the last resonator chamber has, lies between the electron gun and the collecting electrode and in which the collecting electrode is separated from the high-frequency tube part in terms of direct current and is arranged at an axial distance therefrom, characterized in that the Collecting electrode with the end of said tubular part adjacent to it by an as concentrated switching element acting shunt capacitor, which is dimensioned so that he represents a resistance as small as possible for the high-frequency current, in terms of high-frequency connected is. 3. Time tube according to claim 1 or 2, characterized in that the shunt capacitor forms part of the tube envelope. 4. Time tube according to claim 3, characterized in that the shunt capacitor is formed by an internally and externally metallized ceramic ring, which is placed between two in axially spaced, flange-shaped metallic parts attached and on its likewise metallized end faces with these metallic parts via a solder or Weld connection is conductively connected (Fig. 2). 5. Runtime tube according to claim 4, characterized in that that the metallizations on the inner and outer surfaces of the ceramic ring almost completely overlap. Considered publications:
Swiss Patent No. 216 058;
French Patent No. 1012,374;
British Patent No. 592 493. 1 sheet of drawings