DE1161600B - Star circulator - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Boarding school Cl .: H Ol p;

Number:
File number:
Registration date:
Display day:

H 03 h

German class: 21 a4 - 74

B 62842 IXd / 21 a4

June 9, 1961

January 23, 1964

In the technology of very high frequencies, the task sometimes arises of creating a diversion in a common connection between several waveguides (waveguides or coaxial cables) in such a way that the energy supplied to the connection via one of the conductors only leaves it via a certain other conductor . Are z. B. A three conductors are present, to escape ₁ B and C supplied through A power via B, supplied via B via C and supplied via C over A.

For this purpose devices known as star circulators (or if only three Heads are present, referred to as Y-circulators) and those to effect the desired selective diversion, the anisotropic magnetic properties of certain ferrimagnetic substances (such as ferrite or garnet). If an electromagnetic Wave is a material magnetized from such a material by a suitable magnetic field penetrates existing obstacle, arises between the spin of the atoms of these substances and the electromagnetic wave such an interaction that the wave experiences a twist and in the desired direction is diverted.

A star-shaped circulator is used for this purpose, which has a conductive member with radial directed strip-like arms and which contains a magnetized perpendicular to the surface of the member Pairs of elements made of magnetically anisotropic material, which are circular and in the middle is arranged on both sides of the link, the link and the pair of elements in a cylindrical Chamber are arranged by two parallel spaced apart plates as well an annular body is formed.

The object of the present invention is to provide a circulator of the type described create that has an improved transmission bandwidth that is easy to manufacture, is robust and which has small dimensions. This improvement takes place on both sides.

In the case of a star circulator of the embodiment described above which fulfills these conditions, according to the invention dielectric spacers between each arm and the plates within the chamber and spaced from the ring body.

According to an expedient development of the invention, the arms are over part of their length from the middle of the link essentially in the area covered by the anisotropic elements reduced in width.

Furthermore, according to the invention between star circulator

Applicant:

The Bendix Corporation,

Detroit, me. (V. St. A.)

Representative:

Dr.-Ing. H. Negendank, patent attorney,
Hamburg 36, Neuer Wall 41

Claimed priority:

V. St. v. America June 10, 1960

(No. 35 281)

each element made of magnetically anisotropic material and the adjacent base of the housing thin elements made of dielectric material are arranged in relation to the dielectric spacers will.

Such a device has significantly improved properties compared to the known devices: The presence of the dielectric elements, which are arranged between the arms of the star-shaped conductor and the housing surfaces, causes local changes in the capacitance and the magnetic field and allows the discontinuities resulting therefrom to suppress the otherwise existing reflections of the usable waves almost completely. The exact radial position of the interposed dielectric elements has a great influence on the input losses and the transmission bandwidth. On the other hand, reducing the width of the arms in the area of the ferrite or garnet elements has the effect of compensating for the local reduction in impedance caused by the presence of these elements.
From the figures shows

F i g. 1 is a partially sectioned plan view of a device according to the invention,
F i g. FIG. 2 shows a longitudinal section along the line 2-2 of the FIG. 1 shown device,

3 shows a plan view of the star-shaped conductor 56.

The device shown consists of a housing 20, which is screwed together from two

So panels 22 and 24 are put together. These two plates are preferably made of aluminum hollowed out on their inner surfaces so that between

309 780/173

3 4

a cylindrical, flattened chamber 26 ge arm (z. B. 60) is deflected to them, which is illustrated in one is, the two transverse walls, the z. B. a correct sense of rotation follows the first-mentioned arm. Have a distance of 6.35 mm from each other, the two only a very small fraction of the arriving mass areas 27 and 27 form a. Each of the two shafts goes to the other adjacent arm Plates 22 and 24 have an outer coaxial configuration 5 (e.g. 62). Will the magnetic field between recording with a cylindrical recess 28, the pole pieces 36, 37 reversed, the changes in each of the two directions of rotation lying one above the other, d. that is, in the example mentioned Discs 32 and 34 formed magnet is used. the wave arriving via the arm 58 will open The disks preferably consist of one redirected to the arm 62.

ceramic material magnetized to saturation. As FIG. 1 clearly shows, the narrow part coincides. In the exemplary embodiment described here, each of the three arms 58, 60, 62 has a diameter of 27.41 mm garnet disks 66 and 68 with the radius of each magnetic disk. The property and a thickness of 6.35 mm. Each of the two integrated by these discs changes the impedance of the magnets, the two disks formed further includes transmission line in which a pole shoe of these disks 36 and 37 of soft iron on which i _5-covered area. The described narrowing rests against the inner disk of the magnet and causes the arms to compensate, which securely creates a further recess 38 or 40 at the bottom, which means that the resulting impedance is embedded in approximately cylindrical recesses 28. is uniform and keeps reflection low. Furthermore, on three each offset by 120 ° from one another, a very low entry loss is ensured via flattened areas of the housing 20, three identical 20 a wide frequency band. Screwed tightly between the connecting pieces 42, 44 and 46. In the ground area 27 and 27 "of the housing 20 and each connection piece, a small insulating disk recess 70 is arranged in a disk 66 or 68, which is preferably made of tetrafluoroethylene insulating disk 48, a tubular plug 50. The relative dielectric constant of this mounted, the outer part of which is split, so that 25 material is 2.1 and the tangent of the loss two fingers 53 are formed, of which in the angle 0.0002.

drove the center conductor of the not further shown each of these disks has to be held at the selected coaxial cable. management example a diameter of 12.70 mm In the symmetry plane of the housing is a from and a thickness of 0.127 mm. These disks have conductive plate punched from three symmetrical 30 is also the task of the impedance curve equal see arms 58, 60, 62 (see Fig. F i g. 3) to make existing member even and arranged reflections to comparable 56 so that wrestle the ends of the three named.

Arms in notches 52 at the inner ends of the intermediate of each of the two opposite one another three plugs engage. The member 56 is the top of each of the arms 58, 60, 62 and the deserved one star-shaped ladder. With the selected 35 corresponding base area 27 or 27 a of the housing For example, each arm is 25.4 mm long and has a spacer or disk 72 made of tetraeine Width of 5.54 mm arranged over most of its fluoroethylene. The center of each of these Length. The width is then reduced to spacers that have a diameter of 6.96 mm 3.18 mm at a distance of 6.35 mm from and having a thickness of 2.44 mm is 13.85 mm Center of the limb. The portion where 40 moves away from the central axis of the device. According to these dielectric elements form the width from the stated largest value to that of the invention, said smallest value steadily decreased, has a wiez. B. 72, a suitable, strong and sensitive one radial length of 4.75 mm. This assessment means that a very small amount of information however, are only examples. Reduce the displacement of these elements along the arms tion of the width of the arms in the central region 45 significant change in the pass frequency band Star-shaped conductor 56 is intended in particular to effect that of the device. Further allow this Uniformity of impedance across the entire elements, when properly arranged, one Ensure the length of each arm to reduce the reflection of the signal to a very low level Reflections in these arms are reduced to a minimum and consequently the energy losses in the vorziert will. 50 direction, probably thanks to local information. 2, both sides of the equation are changes in the capacitance between the conductive ones des 56 symmetrically arranged two disks 66, 68, arms and the mass surfaces, made of a material with suitable anisotropic The mode of action already results from the pre-magnetic Properties, for example from ferrite or from standing description. It should be noted Garnet. In the case of the 55 described here, it is necessary to determine the direction of rotation between the In the example, the discs consist of yttrium- the incoming shaft and the outgoing shaft around and iron garnet. Reversing the saturation magnetization is sufficient to loosen the three cables, the pre-ses Material is 1880 Gauss and its field direction is to turn upside down and the cable again strength at 55 Örsted. The Curie point is 290 ° C. to be connected.

The disks have a diameter of 12.70 mm 60 The characteristics of the device according to the invention

and a thickness of 2.26 mm (+ 0.025, - 0). Thanks are extremely cheap. In the case of the

their anisotropic magnetic properties call an embodiment with a frequency band

the disks 66 and 68 when concentrating the between 4700 and 5700MHz is the isolation

between the two pole pieces 36 and 37 generated at least 20 db and a maximum of 35 to

magnetic field a circular rotation of the electro- 65 40 db. The ratio of the stationary waves is

magnetic field emerges, such that one is about at 1.15, and the ingress losses are less than

one of the arms (e.g. arm 58) of the limb 0.4 db. It can have an average power of 10W

of the 56 supplied electromagnetic wave can be transmitted on the peaks of 10 kW. The dimensions

Solutions are extremely small: 60.33 mm in diameter and 25.4 mm in height. The device weighs only 312 g and works satisfactorily at temperatures between -55 and + 125 ° C.

Claims (3)

5 claims: 1. Star circulator for redirecting high frequency electromagnetic waves from a selectable one Input channel to the following output channel, which is a conductive member with a the number of channels contains the same number of radially directed strip-like arms, one of which is connected to a channel and which one is perpendicular to the surface of the member has magnetized pair of elements made of magnetically anisotropic material which circular in shape and placed in the middle on both sides of the limb, wherein the member and the pair of elements are arranged in a cylindrical chamber which is divided by two plates that are kept at a distance from one another in parallel and an annular body are formed, characterized in that dielectric spacers (72) between each arm and the plates are disposed within the chamber and spaced from the ring body are. 2. Circulator according to claim 1, characterized in that the arms (58, 60, 62) over part of its length from the center (64) of the link (56) substantially in that of the anisotropic elements (66, 68) covered area are reduced in width. 3. Circulator according to claim 1 and / or 2, characterized by thin elements (70) dielectric material between each element of magnetically anisotropic material (66, 68) and the adjacent base area (27, 27 <z), in addition to the dielectric spacers (72) are attached. Considered publications:
Proceedings of the IRE, January 1960, p. 115
and 116. 1 sheet of drawings 309 780/173 1.64 © Bundesdruckerei Berlin