DE1061849B - Tuning device for waveguides and cavity resonators - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

PATENT 1 061 INTERNATIONAL KL.

H 01p; H 03 j

REGISTRATION DATE: AUGUST 30, 1958

NOTICE THE REGISTRATION AND ISSUE OF THE INTERPRETATION:

ISSUE OF PATENT LETTERING:

JULY 23, 1959 DECEMBER 31, 1959

AGREES WITH EXIT 1 061 849 (V 14967 VIII a / Zl> a ')

The invention relates to a tuning device for radio frequency equipment, and more particularly to a tuning device that provides the use of a probe body and the impedance of waveguides or to change hollow resonators.

It is already known to use cavity resonators and waveguides using probe bodies to vote. With such probe bodies it was often provided that spring force in the radial direction is present, so that between the probe body and the side walls of the waveguide in which the probe body is to be inserted for which there is good electrical contact at high frequency; in particular, there is good electrical contact between the probe body and the inner wall of the waveguide necessary. In known arrangements, the probe bodies are firmly attached to a screw, which, if desired, a displacement of the probe body within the waveguide arrangement causes. The screws have longitudinal slots, so that the actual screw through a plurality of radial resilient longitudinal parts is formed, which are pressed outwards, so that more secure contact with the Internal thread of a sleeve results, which was firmly provided on the outer wall of the waveguide.

The invention shows a new tuning device in which the probe body in the waveguide in is conducted in a different way.

The invention is particularly characterized in that the leadership of the probe body and the Arrangement on the waveguide is extremely simple.

With a tuning device for waveguides and cavity resonators, consisting of a probe device, which is introduced into the same through an opening in the wall of the waveguide and which Characteristic properties of the waveguide changed, pushes the probe body according to the invention against a bearing body provided in the wall of the waveguide under friction, and the probe body is fastened in a hollow screw bolt, which has threads on its outside, and a sleeve provided with an internal thread is provided on the outer wall of the waveguide arrangement, in which the screw bolt is screwed and the internally threaded sleeve is compliant in the radial direction and springs under friction against the external thread of the screw bolt.

The sleeve is advantageously of non-circular cross-section and resilient in the radial direction; the The inner diameter of the sleeve in the relaxed state is smaller than the outer diameter of the Screw so that a resilient. Storage between tuning device for waveguides and cavity resonators

Patented for:

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

Claimed priority: V. St. v. America 6 September 1957

Bernard Clifford Gardner, Los Altos, Calif. (V. St. A.), has been named as the inventor

the sleeve and the screw, which ensures good and reliable contact.

Expedient embodiments of the invention are shown in the drawing. It shows

1 shows a partially sectioned side view of a tuning device according to the invention in use at a klystron,

Fig. 2 is a side view of part of the arrangement shown in Fig. 1,

Fig. 3 shows a cross section of the arrangement shown in Fig. 1, wherein in Fig. 1 the section line and Viewing direction is indicated by the line 3-3 with arrows,

FIG. 4 shows a plan view of part of the arrangement according to the invention, FIG. 1 showing the plan view characterizing line is indicated by 4-4.

In the drawings, an embodiment of the tuning device according to the invention is shown applied to the tuning of the outer cavity of a reflex klystron, although the invention is also generally applicable to waveguides and cavity resonators. 1 denotes the reflex klystron, which is only partially shown and has an outer hollow space resonator which is closely coupled to a rectangular cavity 2. This cavity has a window 3 for the purpose of energy extraction and a connecting flange 4. A displaceable probe is provided for tuning the cavity 2,

909 683/180

Claims (7)

what is known per se; Such an arrangement serves the purpose of changing the oscillation frequency of the reflex klystron 1. The tuning device has a thin-walled tubular probe part 5 made of a flexible material, for example beryllium bronze. The thin-walled, flexible tube 5 has a non-circular cross-section, so that four flat surfaces are obtained which are offset from one another by approximately 90 ° at the periphery, as can be seen in FIG. The tubular probe body 5 extends into the outer cavity 2 through an opening in the side wall thereof. A cylindrical bearing 6 is provided on the inner wall of an opening in the side wall of the cavity and is fastened to the same by flanging. The bearing 6 is essentially cylindrical and consists of a resistant material, for example phosphor bronze. The inner diameter of the cylindrical bearing 6 is slightly larger than the maximum outer diameter of the tubular specimen 5, so that when the tubular probe body 5 is inserted into the bearing 6, the probe body is deformed in view of its non-circular cross-section so that it clings to the cylinder wall. In this way, good electrical contact is brought about between the bearing element 6 and the probe body in view of the elasticity of the latter. The inner end of the probe body 5 is slightly rounded for the purpose of making the thin-walled probe body resistant to twisting: this also facilitates the insertion of the probe body 5 into its bearing 6 during assembly. The probe body 5 is fastened coaxially in a hollow cylindrical screw bolt 7, so that the probe body 5 moves in a straight line into the cavity. The screw bolt 7 has an inner diameter which corresponds essentially to the dimension of the outer diameter of the tubular probe body 5; the probe body 5 is cylindrical at its outer end. A substantially cylindrical insert body 8, which can be made of steel and is also hollow, is inserted into the hollow probe body 5 at its outer end. A ball 9, for example a steel ball, the outer diameter of which is slightly larger than the inner diameter of the bore of the insert part 8, is pressed into the same. When the ball 9 is pressed into the insert body 8, the walls of the latter are bulged, and a reliable fastening of the hollow cylindrical probe body 5 in the hollow screw 7 is effected. In this way, a tuning device is obtained which forms a component which is assembled extremely precisely and yet does not require the use of a hard solder connection between the tuning screw 7 and the probe body 5. The external thread of the tuning screw 7 corresponds to a similar thread on the inner wall of a mounting sleeve 11, which is fastened to the outer wall of the cavity 2 by spot welding, for example. The sleeve consists of an originally cylindrical thin-walled tube, for example made of a nickel alloy, which can be hardened by heat treatment. The original outer diameter of this pipe is slightly larger than the outer diameter of the external thread of the screw 7. The pipe is deformed out of round at its upper end, so that a plurality of flat wall surfaces results, for example three wall surfaces. The middle parts of the essentially flat wall surfaces have internal threads which correspond to the external thread of the screw 7. This three-sided, thin-walled Hulsell has flexibility in the radial direction and is deformed so that the inner diameter of the sleeve at the threaded end is smaller than the outer diameter of the outer thread of the screw 7; therefore, when the screw is screwed into the sleeve, the side walls of the sleeve press against the screw 7 with considerable friction. The fact that only the central portions of each side wall of the sleeve are threaded, while the remaining portions of the surfaces are unthreaded, a greater elasticity of the sleeve is achieved, since cutting a thread makes the sleeve itself more rigid. One method of making the sleeve is to use a threaded mandrel similar to screw 7 but of a slightly larger diameter. The nickel tube is placed over the mandrel, and a three-part internally threaded outer mold is pressed around the tube so that in this way the sleeve 11 is pressed around the mandrel and the thread is created. The sleeve is then hardened, for example by means of artificial aging. In certain forms of application, it can also be expedient to provide the threads on the sleeve all around before the sleeve is deformed. The probe body 5 is held in each position in view of the elastic bearing force which the inwardly pressing, threaded sleeve exerts on the screw 7; in addition there is the resilient mounting between the bearing part © and the flexible parts of the probe body 5. It should be noted that the inventive tuning device, which consists of the probe part 5 and the screw bolt 7, is attached to the cavity 2 under friction in two separate flexible resilient bearings is held; The first bearing point is at the contact point of the bearing part 6 and the probe body 5, and the second bearing point is at the point of contact of the inwardly resilient, threaded section of the sleeve 11 and the tuning screw 7. The distance between the bearing points is at every setting of the probe body the same. The bearings retain their spring action for a long time, and it has been shown that a tuning device according to the invention is resistant to shocks and vibrations during prolonged operation. In addition, the construction according to the invention is characterized by low manufacturing costs. It should be pointed out that the above description and the drawings are not intended to constitute a restriction of the subject matter of the invention, that rather, deviations from the construction shown are possible in various ways for the person skilled in the art without departing from the basic concept of the construction according to the invention. Patent claims: 1. Tuning device for waveguides and cavity resonators, consisting of a probe device, which is introduced into the waveguide through an opening in the wall of the waveguide and the characteristic properties of the Höh! changed conductor, characterized in that the probe body against one in the wall of the Waveguide provided bearing body presses under friction and that the probe body in one hollow screw bolt is attached, which has threads on its outside, and that a provided with an internally threaded sleeve on the outer wall of the waveguide arrangement is in which the screw bolt is screwed, and that the one with an internal thread provided sleeve is compliant in the radial direction and under friction against the external thread of the screw bolt springs. 2. Arrangement according to claim 1, characterized in that the distance between the Contact point of the probe body in the bearing body in the side wall of the waveguide arrangement and the point of contact of the threaded sleeve with the screw bolt is larger than the diameter of the bolt. 3. Arrangement according to claim 1, characterized in that the sleeve consists of a cylindrical, thin-walled tube, which obtained non-circular cross-section by deformation has, so that there is a plurality of flexible side walls, and that each side wall Has internal threads which coincide with the threads of the screw bolt act, and that the threaded side walls of the sleeve inward springs and exert a frictional resilient pressure on the tuning screw. 4. Arrangement according to claim 3, characterized in that the width of the flexible side wall the sleeve is larger than the diameter of the screw bolt. 5. Arrangement according to claim 4, characterized in that only the middle parts of each flexible side wall of the sleeve are provided with threads adapted to the screw bolt. 1 sheet of drawings © 909 578/302 7.59 (909 683/180 12. 59)