DE1070252B - - Google Patents

Description

The invention relates to an oscillating circuit for ultrashort waves in the manner of a weighted cup circle with a coiled inner conductor and a loading capacity designed as a cylinder capacitor. The invention relates to an improved design of such a cup circle.

For ultrashort waves, for example for frequencies of more than 100 MHz, is used as Oscillating circuit often so-called pot circles, which consist of a cylindrical, pot-shaped outer jacket made of metal and an inner conductor attached concentrically in the outer sheath. The inner conductor is on one end conductively connected to the outer jacket. To the dimensions of such a pot circle to reduce the size, you can load it capacitively. For that purpose, that's not the case with the outer jacket connected end of the inner conductor formed so that it is together with the outer sheath or a part of the outer jacket represents a weighting capacity. For example, this end of the inner conductor be a ring that forms the inner electrode of the cylinder capacitor, its outer electrode is part of the outer jacket.

Another known measure for reducing the dimensions of the cup circle exists in that the inductance of the inner conductor is artificially increased by the Shape of a helix.

Both measures, namely the arrangement of a weight capacity and the increase in inductance of the inner conductor by coiling can also be carried out together. You then get to find Cup circle has a basic shape as indicated schematically in FIG. 1. In the cup-shaped, cylindrical one Outer jacket 1 is concentrically arranged the coiled inner conductor 2, which at its one End is connected to the outer jacket 1, while at its other end a pot-shaped extension 3 whose ring-shaped jacket forms the inner electrode of the weighting capacity.

With these known pot circles, high quality circles, for example in the order of magnitude of Q = 300, can be achieved. In contrast, the mechanical design of these pot circles creates considerable difficulties. The resonance frequency of the pot circle depends on its mechanical constancy. However, it is not at all easy to build up the cup circle according to FIG. 1 in such a way that the inner conductor 2 and the loading capacity 3 do not change their position slightly in the event of mechanical vibrations or temperature changes. Any change in this position, no matter how small, influences the resonance frequency of the pot circle and thus leads to a detuning. Also give the unavoidable resonant circuit for ultrashort waves

Applicant:.

Deutsche Elektronik G.m.b.H., Berlin-Wilmersdorf, Forckeribeckstr. 9-13

Wolfgang Lange, Berlin, has been named as the inventor

Screw connections and soldering points within the cup circle and the possible corrosion Changes in Q factor in the long run.

The invention is based on the object, a pot circle of the type shown in Fig. 1 in his To improve the structure mechanically in such a way that its properties are also improved in the event of strong mechanical vibrations can not change. The influences of temperature fluctuations should also be affected by the Invention to be minimized. Finally, the invention aims to further downsize the mechanical dimensions of the cup circle. However, the quality of the circle of the pot should be are not adversely affected.

With a pot circle of the version mentioned in the introduction According to the invention, a hollow tubular, solid, dielectric body is provided, its metallized Outer wall the outer jacket of the cup circle and which forms an electrode of the weighting capacity, while on its inner wall the 'coiled inner conductor and the other electrode of the weighting capacity are attached .. The main advantage of the invention is seen in the fact that the hollow tubular, dielectric, solid bodies provide a mechanically absolutely rigid support for the metallic parts of the pot circle. In this way it is prevented that these metallic parts, i.e. the outer jacket, Inner conductor and electrodes of weighting capacity, change their mutual position in the event of mechanical vibrations or temperature fluctuations. The dielectric body can, for example, be made of an electrically high-quality plastic, ceramic, Consist of glass or similar insulating material.

It is already known, cavity resonators, in which, in contrast to that of the invention oscillating circuits self-induction and capacitance

909 68T / 291

are not separated from each other and which, because of their dimensions, are only suitable for centimeter and at most decimeter waves, to be filled with a magnetically and electrically conductive medium, which is a much larger one. Has permeability and / or dielectric constant than air. A suitable medium is manganese-zinc-ferrite with a permeability of 500 to 2000 and a dielectric constant of 10 ² to 10 ⁵ . The resonator is thus a body formed from this medium, which is provided with a metal layer on the outside.

Since the medium filling the cavity of the resonator is the carrier of the electromagnetic field, can in this way the size of the cavity resonator according to the high permeability and large dielectric constant of the medium can be reduced. But this increases the quality of the resonator deteriorated quite considerably.

In contrast, the solid dielectric body in the resonant circuit according to the invention, which for ultrashort waves, i.e. for wavelengths for which raw space resonators would already be too unwieldy, is intended, only mechanical, but no electrical tasks. The magnetic field is within of the coiled inner conductor, i.e. in air, the electric field between the electrodes of the weighting capacity concentrated so that the dielectric body, except between the electrodes of the Weighting capacity, is practically field-free. His material is therefore exclusively from the point of view not to worsen the quality of the oscillating circuit compared to air, and has therefore chosen in usually, such as B. glass or electrically high-quality plastic, a small dielectric constant. Ferrites for example are completely useless for the purpose of the invention.

The cup circle according to the invention thus consists, for example, of a ceramic tube, the top and is open at the bottom. A metallic helix is applied to the inner wall of the tube, which forms the inner conductor of the pot circle. The outer wall of the ceramic tube and its upper face are also covered with a metal layer, which represents the outer surface of the pot circle. The metallic The inner helix is conductively connected to the outer jacket via the metalized end face of the pipe. At its other end, the inner conductor is designed as a ring in a manner known per se, the acts as the inner electrode of the weighting capacity. To increase this weight capacity the wall thickness of the ceramic tube can be reduced in the area of the loading capacity, d. That is, the ring-shaped part forming the inner electrode at one end of the inner conductor has a larger one Diameter than the actual inner conductor.

So that the effect sought by the invention is achieved, it is important that the metallic Allocations on the hollow tubular dielectric body, the outer jacket, the inner conductor and the Form electrodes of weighting capacity, firmly adhere to the surface of the dielectric body. Therefore it is useful to use conductive metallic coverings, e.g. B. of silver, which is based on the dielectric Bodies are glued on, painted on, sprayed on, vaporized or galvanically applied. Through the Use of a dielectric body as a carrier for the metallic parts of the cup circle has nor the possibility of any temperature fluctuations due to the temperature constant of the material changes in the resonance frequency of the cup circle due to the metallic coverings in whole or in part to compensate by the fact that a material with a suitable temperature constant is used for the dielectric body used. The changes in the resonance frequency of a pot circle with temperature fluctuations namely depend on the temperature constants of the metal used for the cup circle, in particular of the metal from which the coiled inner conductor and the electrodes of the weight capacity are made exist, from. This temperature constant is generally weakly positive. One is therefore expedient for the dielectric body take a material that has a slightly negative temperature constant having. In this way, any changes in the resonance frequency in the event of temperature fluctuations largely compensate, since the material of the dielectric body is also the dielectric represents the weighting capacity, so that there is a certain balance of the positive temperature constants of the conductor material results.

The pot circle designed according to the invention can also be designed to be tunable. For the vote result z. B. two options. An inductive tuning results in a known per se Way by having a copper core or a core in the coiled inner conductor. High frequency iron shifts. This type of vote can be in the pot circle according to the invention in the Achieve way that a metal cover on the metalized front end facing away from the loading capacity is soldered to a hole, through which one can be displaced within the coiled inner conductor Tuning core from z. B. copper or high frequency iron bearing spindle adjustable out is.

Another possibility of coordination results from making the size of the weighting capacity changeable. This can be done in continuing education of the pot circle according to the invention happen approximately in such a way that the inner electrode is partially annular is and a rotatable around the axis of the pot circle, with metallic contact against the inner electrode placing ring segment an adjustable enlargement of the effective area of the inner electrode enables. For example, the inner electrode can be given the shape of a half-ring. By inserting a silver-plated bronze half-ring that clamps outwards and rotates around the axis of the ceramic tube can rotate, you can then turn this bronze half-ring, the effective area of the Increase the inner electrode continuously to almost the size of a complete ring. By The bronze half-ring has a galvanic connection with the firmly attached one semicircular inner electrode.

The mechanical fastening of the cup circle according to the invention in a device or on a device chassis can be done for example by means of a metal ring, which is on the outer metallization of the dielectric Body is soldered on. If this outer metallization consists of silver, for example, it is It is advisable to use a silver-plated brass ring for this.

The connecting cables to the coiled inner conductor or to the inner electrode of the weighting capacity are advantageously by approximately radial bores in the dielectric body guided inwards. The surroundings of these holes are expediently left free from the outer metallization.

Invention geIn the drawing are in Figs. 2 to 5 exemplary embodiments of the invention shown. In the drawing is.

1 shows a schematic representation of a pot circle with a coiled inner conductor and weighting capacity known design,

Fig. 2 is a corresponding, according to the
formed pot circle,

Fig. 3 is the same pot circle as in Fig. 2, but with an additional tuning device, which consists of a there is a movable core in the coiled inner conductor,

4 shows the coordination of the cup circle according to the invention by means of a variable loading capacity and

5 shows the feed of the connecting lines to the coiled inner conductor or to the inner electrode the complaint capacity.

The cup circle according to the invention (Fig. 2) consists of a hollow tubular dielectric body, z. B. a ceramic tube 4, of suitable dimensions. On the inner wall of the ceramic tube 4 is a Coiled inner conductor 6 in the form of corresponding metallic coverings by gluing, painting on, Spraying on, vapor deposition or applied to galvanic AVege. The outer wall of the ceramic tube 4 is also provided with a metallic coating 5, which forms the outer surface of the pot circle. With the outer sheath 5, the upper end of the coiled inner conductor 6 is also metallized upper end face of the ceramic tube 4 in galvanic connection, as indicated in FIG.

At its lower end, the ceramic tube 4 has a section 7 of reduced wall thickness. the Inner wall of this section 7 is provided with an annular metal coating 8, which with the the lower end of the coiled inner conductor 6 is in metallic connection. The ring-shaped Metal 1 lining 8 forms the inner electrode of the weighting capacitance, while the outer electrode forms the section the outer metallization 5, that of the inner electrode 7 opposite. The entire pot circle is a rigid and mechanically unchangeable structure.

The embodiment according to FIG. 3 differs from the cup circle. According to FIG. 2 only by one additional tuning device consisting of an axially displaceable core 11 made of copper, high-frequency iron or similar material. The displaceable core 11 is attached to a spindle 10 which is guided through a hole in a cover 9. The lid 9 is with its silver-plated bottom on the Silver-plated upper end face of the ceramic tube 4 is soldered on. The spindle 10 can through the bore of the cover 9 are moved. For this purpose, for example, the spindle 10 can be threaded be guided in a corresponding thread of the bore. In addition, a device for Fixing or clamping the spindle can be provided.

To show how the adjustment of the pot circle according to the invention by changing the loading capacity can take place, is in Fig. 4, another embodiment of the cup circle according to the invention shown in the view from below. In contrast to the embodiments according to FIGS. 2 and 3, this is the Inner electrode 8 of the weight capacity is only designed as a semicircle. Against the. semicircular Inner electrode 8 is placed around the axis of the inside under the pressure of a suitable spring force Cup circle rotatable bronze half ringl2. The bronze half-ring 12 can be rotated so that it completely coincides with the inner electrode 8. Then she has Weighting capacity their smallest A'Vert. Depending on how far the bronze half-ring 12 from the inner electrode 8 is turned out, the value of the weight capacity increases.

In Fig. 5 can finally be seen how the connecting lines at one end of the inner conductor 6 as well at the inner electrode 8 of the weighting capacity

ίο are attached. For this purpose are in the ceramic tube 4 approximately radial bores 14 and 16 are provided through the connecting lines 13 and 15 are. In the vicinity of the connecting lines 13 and is the outer wall of the ceramic tube 4 of the metal covering has been left free in order to avoid short circuits.

Claims (10)

Claims: 20 1. Oscillating circuit for ultrashort waves in the manner of a weighted cup circle with a spiral Inner conductor and marked with a loading capacity designed as a cylinder capacitor by a hollow tubular, dielectric, solid body, the metalized outer wall of which the outer jacket of the pot circle and: which forms an electrode of the weighting capacity, while on its inner wall the coiled inner conductor and the other electrode of the weighting capacity are appropriate. 2. Resonant circuit according to claim 1, characterized in that the dielectric body consists of an electrically high-quality plastic, ceramic, glass or similar insulating material. 3. resonant circuit according to claim 2, characterized in that the outer jacket, the inner conductor and the electrodes of the weight capacitance highly conductive metallic coatings, e.g. B. off Silver, are glued, painted, sprayed, vapor-deposited onto the dielectric body or galvanically applied. 4. resonant circuit according to claim 3, characterized in that the material of the dielectric Body has a temperature constant, which is possible with temperature fluctuations by the temperature constant the material of the metallic coverings caused changes in the resonance frequency of the Compensates the pot circle in whole or in part. 5. Resonant circuit according to one of claims 1 to 4, characterized in that one end of the coiled inner conductor as a ring-shaped or partially ring-shaped inner electrode of the weighting capacity is trained. 6. resonant circuit according to claim 5, characterized in that that the dielectric body is in the area of the ring-shaped or partially ring-shaped inner electrode has a reduced wall thickness. 7. resonant circuit according to claim 5 or 6, characterized in that the inner electrode is partially annular is and is rotatable around the axis of the cup circle, with metallic contact ring segment placed against the inner electrode provides an adjustable magnification of the effective Area of the inner electrode allows. 8. Resonant circuit according to one of claims 1 to 7, characterized in that on which the Loading capacity facing away from the metalized front end a metal cover with a hole on is soldered, through which a tuning core displaceable within the coiled inner conductor from z. B. copper or high frequency iron bearing spindle is adjustable. 9. resonant circuit according to one of claims 1 to 8, characterized in that the connecting lines to the coiled inner conductor or to the inner electrode of the weighting capacitance are guided through approximately radial bores in the dielectric body and the environment the holes are left free from the outer metallization. 10. Resonant circuit according to one of claims 1 to 9, characterized in that on the outer metallization of the dielectric body is used for mechanical fastening of the cup circle Metal ring is soldered on. Considered publications:
German patent specification No. 879 853. 1 sheet of drawings 909 687/291 11:59