DE1046690B - Electron tube arrangement with temperature compensation - Google Patents

Description

NOTICE THE REGISTRATION DND ISSUE OF EDITORIAL:

DECEMBER 18, 1958

This invention relates to electron tube assemblies, which work on the principle of speed modulation, in which cavity resonators be used, for example on klystron tubes for use as an oscillator, amplifier, Modulator, frequency multiplier, etc.

While the present invention is generally applicable to klystrons, it is particularly applicable Advantageously used with reflex klystron tubes, in which a resonator consists of an inner evacuated cavity consists, which is connected via a vacuum seal with an outer vacuum frekm cavity which has a simple and reliable means of tuning the tube.

Since the use of klystron tubes for extremely high frequencies, the physical quantity of the internal cavity resonators were constantly on the decline. Today's klystrons for extreme high frequencies have very small internal mechanical dimensions. The ambient temperature has a significant influence on the resonance frequency of the same. Various working with bimetal parts Temperature compensation systems are successful for the relatively large cavity resonators lower frequencies have been used.

There is already known an electron discharge device with a cavity resonator in which this is taken care of is that when heated, the external dimensions of the cavity and thus the resonance frequency remain as constant as possible. One wall of this cavity is designed to be flexible for the purpose of coordination and, roughly speaking, runs parallel to an opposing, fixed wall that is led by Supports is held rigidly. The flexible wall is at its edges with the outer edge of the fixed wall connected, which is angled before its entry into the support and thereby a further outer surface of the cavity forms. As a result of this connection, when the support expands due to heating the entire cavity shifted a short distance, the flexible wall at the same time of a sleeve which is rigidly attached to the reflection electrode is performed. The reflection electrode is held in such a way that it is displaced conformally with the cavity resonator when heated.

The disadvantage of this device is that the parts used for temperature compensation are outside of the cavity and therefore from the outside on its position in relation to the electron source and the reflection source act. In addition, the position of the reflection electrode is temperature-compensated, so that with larger temperature differences there are differences in the position of the Parts that influence electrons (walls of the -hollow-

Electron tube assembly
with temperature compensation

Applicant:

Varian Associates,

Palo Alto, Calif. (V. St. A.)

Representative: Dr.-Ing. W. Reichel, patent attorney,
Frankfurt / M.-Eschersheim, Lichtenbergstr. 7th

Claimed priority:
V. St. v. America October 21, 1955

Donald Lawrence Snow, Palo Alto, Calif.,
Peter Henry Kafitz, Mountain View, Calif.,
and Clifton Guy Rockwood, Los Altos, Calif. (V. St. A.), have been named as inventors.

space or grids that are supported by the walls, reflection electrode) occur to each other.

In the subject matter of the invention, however, the dimensions of the cavity resonator when it is heated not controlled from the outside, but by the parts of the resonator themselves, adding for these materials with a special coefficient of thermal expansion and special shapes can be used.

At very high frequencies, despite the considerable reduction in size of the Cavity the need for the temperature compensating parts to achieve the required corrective differential expansions still have to be chosen from a certain size. The present invention there is also a device for temperature compensation for klystrons with small resonator dimensions at.

The subject of the invention is a new, provided with bimetallic temperature compensation hollow

* 5 space resonator with a new front part of the cavity resonator, by which the electrical dimensions of the cavity resonator are sufficiently small for high frequencies can be made, but still have a sufficient size of the temperature-compensating Parts allows to allow adequate temperature compensation.

An electron tube arrangement in the manner of a reflex klystron with a cavity resonator and with means to keep the natural frequency constant

809 699/388

in the case of temperature-related changes in volume of the cavity resonator contains according to the invention a drift tube widening from the acceleration electrode (anode) to the gap of the resonator Made of a conductive material with a low coefficient of thermal expansion, one end of which is rigid the accelerating electrode is attached and the other end of the everted part of the cavity and forms the inner gap electrode. The assembly also includes a flexible, electrically conductive one Disc, which is transverse to the longitudinal axis of the expanding tube about - ". In the middle outside is fixed between the two ends and forms an end wall of the cavity resonator; aside from that the assembly includes a second transverse wall having a central opening, the opposite Forms the wall of the cavity resonator and the gap electrode facing the reflector. That The material of the tube casing has such a (large) coefficient of expansion that the gap distance enlarged with increasing physical size of the cavity resonator so that an im essential constant natural frequency of the cavity resonator is maintained.

The advantages of this invention will become apparent on reading the description in conjunction with the accompanying drawing become clear.

The figure shows a longitudinal section of a new reflex klystrons which _r: embodying features of the present invention.

In the drawing is a hollow, open at the ends, cylindrical, metallic tube casing 1 is shown. A cathode assembly 2 closes one end of the Tubular envelope 1, the other end of the tubular envelope is closed by a reflector assembly 3. Between the cathode arrangement 2 and the reflector arrangement 3 there are three metallic ones in the tube casing 1 Transverse walls arranged with central openings of disk shape, namely the anode disk 4, the cavity disk 5 and the reflector disk 6. The anode disk 4 has thicker walls than the other disks 5 and 6, and its central opening is inside with a plurality of gradations with increasing provided inside diameter. Over the central opening of the anode disk is opposite the cathode assembly 2 a honeycomb-shaped acceleration grid 7 securely attached.

An inverted, expanding drift tube 8 made of a material with a low coefficient of expansion, e.g. B. molybdenum, is attached to the stepped inner edge of the anode disk 4 with the widening end. The outer edge of the cavity disk 5 is connected to the tubular casing 1, where it also rests against the anode disk 4. The inner circumference of the cavity disk 5 is connected to the expanding tube 8 approximately in the middle of the longitudinal extension thereof by brazing. A honeycomb-shaped resonator grille 9 is attached to the free end of the drift tube 8. At a short distance from the resonator grating 9 there is a second resonator grating 11 which is fastened in the central opening of the reflector disk 6. The cavity resonator 12 is delimited by the reflector disk 6, the tube casing 1, the cavity disk 5, the free end of the narrowing tube 8 and by the resonator grids 9 and 11.

A rectangular outer cavity resonator 13 is adjacent to the inner cavity resonator 12 provided and held in this position by a plurality of bolts which extend through a U-shaped Extend clamping device. Two rings 16 made of soft metal enclose the outer wall of the Tubular casing and are held in this position by two externally attached V-shaped grooves 17, and one ring at each end of the inner cavity resonator 12. The outer cavity 13 and the U-shaped clamping devices are pressed firmly against the rings 16 made of soft metal and thus form a tight seal.

ίο A decoupling diaphragm 18 is in the tube wall 1 cut and allows energy to be transferred between the inner cavity 12 and the outer cavity 13. A window 19 permeable to wave energy, e.g. B. consists of mica,

is covers the aperture 18 and enables Maintaining a vacuum inside the tubular vessel 1. Outside the window 19 is a Ballast element 21 for adjusting the degree of coupling between the inner and outer hollow space attached. A flange part 22 is used to close off the outward end of the outer cavity with a second coupling screen 23 for transmitting the energy from the outer cavity to the Consumers provided. A simple capacitive tuning screw'24 is used to tune the outer one Cavity.

When the tube is in operation, electrons are emitted from the cathode assembly and become one Bundled beam. A potential that is positive in relation to the cathode is applied to the tube envelope and at the same time applied to the anode disk 4 provided with an opening. This positive potential accelerates the Electrons and pulls them through the drift tube 8 in the direction of the reflector arrangement 3 Negative potential with respect to the anode is applied to the reflector, causing the electrons to reverse their direction experienced and driven through the inner resonator 12 a second time. During the The electrons receive their first flight through the inner resonator by interacting with the in the internal resonator forming electromagnetic fields a speed modulation. During the runtime of the electrons until they reach the turning point and when they return through the inner resonator 12, the electrons have formed spatially defined groups and contribute energy the second flight transmitted through the inner cavity resonator to this. In the docked inner and outer cavity creates an alternating electromagnetic field, which is sent to the consumer is emitted through the decoupling diaphragm 23. A tuning of the tube can be done by rectilinear Shifting a simple tuning screw 24 can be accomplished.

The resonance frequency of the cavity resonator 12 is determined by the dimensions of the cavity resonator and determines the width of the gap between the resonator grids. In general, an enlargement decreases the volume of the cavity determines the resonance frequency, while an increase in the width of the gap increases the resonance frequency elevated. When the temperature of the resonator parts increases, which is often the case during operation can, the volume of the resonator has a tendency to increase and thus the resonance frequency to humiliate the same. The new mechanism for temperature compensation dealt with here counteracts this decrease in frequency by increasing the gap distance.

Now consider the expansion properties the cavity treated here and the cavity

space-forming associated parts, it can be seen that the tubular casing 1 expands in the radial direction, but, what is more important for the mechanism of temperature equalization, is also in the Extends lengthways. The amount of longitudinal expansion between any two points, which lie on a longitudinal distance of a body, changes to the extent as the longitudinal distance between these two points. So in the present new temperature compensation mechanism, the Reference points for determining the change in the width of the resonator gap with changing temperature the anode disk 4 and the reflector disk 6, as part of the expanding tube part 8 is attached to the disc 4.

The expanding tube 8 is made of a material having a small coefficient of thermal expansion, z. B. made of molybdenum. To achieve a large amount of differential longitudinal expansion between the widening tube 8 and the tube envelope 1, this is made of a material with high temperature coefficients, z. B. steel made. If the temperature increases, the distance increases between the disks 4 and 6 according to the expansion behavior of the steel body 1. Simultaneously the length of the expanding tube 8 increases, but relatively less than the increase the distance between the discs 4 and 6; therefore, the resonator grid 9 is separated from the resonator grid 11 moves away and thereby carries out the necessary temperature compensation. When the cavity size on the other hand, determined by the volume between the anode disk 4 and the reflector disk 6 would, the cavity length would be too large for the frequency range of the tube in question.

To decrease the electrical length of the cavity and to bring the tube into the desired frequency range, the cavity disk 5 was provided.

The wall construction of the cavity disk 5 is thinner than that of the anode disk 4. The former serves as flexible diaphragm, which allows a relative movement between the drift tube 8 and the tube casing 1 in the event of temperature changes. Since the temperature compensation parts in the cavity need to absorb electrical currents, so the disks and the tube casing were with one sliding material, e.g. B. Copper, plated to keep energy losses low.

Claims (2)

Patent claims: 1. Electron tube arrangement in the manner of a reflex klystron with a cavity resonator and Means for keeping the natural frequency constant when the volume changes due to temperature Cavity resonator, characterized by one of the acceleration electrode (anode) to to the gap of the resonator widening drift tube made of a conductive material with low Coefficient of thermal expansion, one end of which is rigidly attached to the accelerating electrode and the other end of which forms the turned-in part of the cavity and the inner gap electrode (9), also by a flexible, electrically conductive disc (5) which is transverse to the longitudinal axis of the widening tube is attached approximately in the middle outside between the mentioned ends and forms an end wall of the cavity resonator, and through a second, a central opening having transverse wall (6), which the opposite wall of the cavity resonator and the forms the gap electrode (11) facing the reflector, and further characterized in that the Material of the tube casing (1) has such a (large) coefficient of expansion that the Gap distance (9, 11) with increasing physical Size of the cavity resonator increased so that a substantially constant natural frequency of the cavity resonator is maintained. 2. Electron tube assembly according to claim 1, characterized in that the metallic Tubular casing (1) consists of steel, which is covered with a highly conductive layer, and that the drift tube is made of molybdenum and is also covered with a highly conductive layer is. Considered publications: German Patent Specifications No. 807 957, 835 766. 1 sheet of drawings © 809 699J388 12.58