EP0932217A1 - E-plane waveguide circulator - Google Patents

Abstract

The E-plane circulator comprises a height-reduced branching area (7), in which a ferrite rod (11) is arranged, which extends over the entire height of the branching area. One or more bridges (8, 9, 10) extend preferably into the branching area, and a permanent magnet (12, 13) is preferably arranged on at least one front side of the ferrite rod.

Description

State of the art

The present invention relates to an E-plane Waveguide circulator that has a reduced height Has branching area in which one of one Magnetic field penetrated ferrite body is arranged.

Such an E-plane waveguide circulator is out Microwave & HF magazine, Vo. 16, No. 2, 1990, pages 168 known until 173. The are in the branching area three waveguide arms one or two ferrite discs inserted. The thickness of the ferrite disc (s) corresponds to only one Fraction of the total height of the branch area. Furthermore the height of the branching area is reduced, that on its top and bottom one Metal disc is inserted. The advantage of the E-levels Circulator versus the H-level circulator is that it an extremely low one even at high frequencies Has passage loss. However, E levels are Circulators relatively narrowbanding (bandwidth of not more than 1%). In addition, previously required e-levels are required Circulators for the generation of the necessary Magnetization of the ferrite material large magnets. At high Frequencies affect the height of the ferrite discs very much critically on the microwave behavior of the circulator. If you do not need to adjust the circulator, is a tolerance of for the height of the ferrite discs less than 0.01 mm.

These disadvantages mentioned should be due to the inventive Design of an E-level waveguide circulator largely be reduced.

Advantages of the invention

Such an E-plane waveguide circulator according to the invention has according to the features of claim 1 in his Branching area on a ferrite body that acts as a rod is formed, which extends over the entire height of the its height reduced branching area extends.

With such a rod-shaped ferrite body arises in Branch area a field distribution that in a symmetrical plane perpendicular to the longitudinal axis of the Ferrite rod running parting plane no wall currents lets flow. This means that the circulator can consist of two shells be assembled, which is the manufacture of the Circulator significantly simplified. In addition, it is now possible one or more permanent magnets directly on the end faces of the ferrite rod. So there is none Waveguide wall more between the magnets and the Ferrite material, which is why for the required magnetization of the ferrite material, smaller magnets are required.

Appropriate developments of the invention go from Sub-claims emerge.

So you can enter the branching area of the circulator or several bridges protrude through their suitable Sizing increases the bandwidth of the circulator can be. The circulator can consist of two shells, a depression is embedded in a bowl for Picking up one end of the ferrite rod. On the valley opposite side is one in the other shell Opening provided through which the ferrite rod from the outside is insertable into the branching area. Here is the Sink with close tolerance to the cross section of the ferrite rod adjusted and the opening faces the cross section of the A game on. The fixation of the ferrite rod in the opening by means of a around the ferrite rod placed elastic ring. This arrangement of the Ferrite rod together with magnets on the front of the Ferrite rod leaves a temperature expansion of the different materials in the longitudinal direction of the ferrite rod to and also facilitates the construction of the entire circulator, because the ferrite rod with the magnets in a simple way from inserted and fixed outside in the branching area can be.

Description of an embodiment

Figur 1 einen Querschnitt B-B parallel zu den Schmalseiten eines Hohlleiter-Zirkulators und

Figur 2 einen Querschnitt A-A parallel zu den Breitseiten des Hohlleiter-Zirkulators.

Based on an embodiment shown in the drawing, the invention is explained in more detail below. Show it:

1 shows a cross section BB parallel to the narrow sides of a waveguide circulator and

Figure 2 shows a cross section AA parallel to the broad sides of the waveguide circulator.

In Figures 1 and 2 are two mutually orthogonal Cross sections A-A and B-B of an E-plane waveguide circulator shown. 1 shows one Cross section B-B parallel to the waveguide narrow side b and the Figure 2 shows a cross section A-A parallel to Broadside waveguide a.

Manufacturing technology advantages for the circulator can be achieve by having two separately manufactured Shells 1 and 2, which, as Figure 2 shows, for complete circulator. The Partition plane 3 between the two shells 1 and 2 runs in a plane of symmetry parallel to the waveguide narrow sides b. Since the cross-section B-B lies in the parting plane, the shows Figure 1 is a plan view of the lower shell 2 of the Circulator.

The waveguide circulator has three as usual Waveguide branch arms 4, 5 and 6. All three Waveguide branch arms 4, 5, 6 open in the center of the Circulator in a branch area 7. Characteristic for an E-plane waveguide circulator is that Narrow sides b of all waveguide branch arms 4, 5, 6 in same parallel planes are in contrast to the H planes Circulator in which the broad sides of all Waveguide branch arms lie in parallel planes.

As FIG. 2 shows, the branch area 7 is in its Height reduced. Also protrude, as can be seen in FIG. 1 is, laterally in the branching area 7 webs 8, 9 and 10 inside. Deviating from the illustrated embodiment there can be fewer than three webs. The fact that the Branch area 7 is designed as a bar waveguide, increases with appropriate dimensioning of the webs 8, 9, 10 the bandwidth of the waveguide, because of the webs the usual disturbance modes are greatly reduced become.

A ferrite rod 11 is like this in the branching region 7 arranged that it extends over the entire height of the Branch region 7 extends (see FIG. 2). With like this a ferrite rod 11 is such that such Field distribution in the circulator trains that in the Partition level 3 no wall currents flow. That's why it is possible that between the two shells 1 and 2 of the Circulator no galvanic contact can be made got to. There may even be a gap between the two shells 1, 2 exist without the electrical properties of the circulator can be influenced. So there is no electrical Contacting the shells 1, 2 is required, needs the manufacturing process is not based on a high flatness of the parting plane to be respected. This also means that it doesn't need to be that big Care is taken to connect the shells; i.e. there will be fewer screws for the non-positive Connection of the shells required.

The ferrite rod 11, which is preferably a round but also any other cross-sectional contour can be related to to dimension its cross-sectional dimensions so that in bushings 14 and 15, explained below for the ferrite rod 11 in the shells 1, 2 no wave Operating frequency of the circulator is spreadable. As a result, the magnetization of the Ferrits required permanent magnets 12 and 13 directly on the end faces of the ferrite rod 11 are applied without that this the microwave behavior (generation of additional losses) of the circulator. The Using a long thin ferrite rod 11 also brings following advantage. At high frequencies have namely Ferrite materials have a high saturation magnetization, and it is very difficult to get the necessary magnetic field strength applied by an external magnet. A physical property of a long thin ferrite rod is that its demagnetization factor is almost zero. That is why even very small magnets can do the necessary Generate field strength in the ferrite. Because the magnets 12th and 13 can be applied directly to the ferrite rod, and no waveguide walls between the ferrite and the Magnets 12, 13 lie, the magnetic field increases in Ferrite rod 11.

Instead of two magnets on both ends of the ferrite rod can only be a magnet on one end of the Ferrite rod can be arranged. Then there is none current-free parting plane, so that the advantage of a double-shell construction of the circulator is not required.

Thin ferrite rods are preferably produced from small cuboids sawn from large blocks this manufacturing process is easy to automate and therefore inexpensive to carry out.

The ferrite rod 11 with those fixed on its end faces Magnets 12 and 13, advantageously the same Cross-sectional contour, like the ferrite rod 11, are on in the following way into the branch region 7 of the circulator introduced and fixed there. In the bowl 2 of the Circulator is a depression 14 (in the form of a blind hole) embedded for receiving one end of the ferrite rod 11 with the magnet 13. The depression 14 is as narrow as possible Tolerance on the cross section of the ferrite rod 11 and Magnets 13 adapted to the ferrite rod 11 an exact To give position within the branch area 7. The depression 14 opposite is one in the shell 1 Opening 15 provided through which the ferrite rod 11 with its magnets 12 and 13 from the outside in the Branch area 7 of the already assembled shells 1 and 2 can be introduced. The opening 15 faces compared to the ferrite rod 11 a certain game, so the ferrite rod 11 with its magnets 12 and 13 also can be inserted unhindered into the branch area 7 can, even if the two shells 1 and 2 of the circulator joined together with a slight offset have been.

To the ferrite rod 11 with its magnet 12 and 13 despite the Play in the opening 15 centered in the branch area 7 to keep is around the end of the opening 15 in the Ferrite rod 11 or the magnet 12 an elastic ring 16th placed. For receiving the ring, the opening 15 is in the upper Area provided with a cross-sectional expansion 17, wherein the elastic ring 16 (e.g. silicone ring) between the Outer periphery of the magnet 12 and the inner wall of the cross-sectional area 17 of the opening 15 is pressed is. So that the ferrite rod 11 with its magnets 12 and 13 fixed in the branch area 7. Towards the However, the longitudinal axis of the ferrite rod 11 is a mechanical one Expansion is quite possible, namely through different coefficients of expansion of the ferrite rod 1, the magnet 12, 13 and the waveguide walls.

Claims (5)

E-plane waveguide circulator, one has reduced branching area in which a arranged by a magnetic field penetrated ferrite body is characterized in that the ferrite body (11) as a rod is formed, which extends over the entire height of the Branch area (7) extends. Circulator according to claim 1, characterized in that one or more webs (8, 9, 10) protrude. Circulator according to claim 1, characterized in that on at least one of the two end faces of the ferrite rod (11) a permanent magnet (12, 13) is placed. Circulator according to one of the preceding claims, characterized in that it consists of two shells (1, 2) exists, the parting plane (3) transverse to the longitudinal axis of the Ferrite rod (11) runs in a shell (2) Sink (14) is recessed to receive one end of the Ferrite rod (11) that the sink (14) opposite in the other shell (1) is provided with an opening (15), through which the ferrite rod (11) from the outside into the Branch area (7) is insertable, and that the valley (14) with close tolerance to the cross section of the ferrite rod (11) is adapted and the opening (15) relative to the Cross section of the ferrite rod (11) has a game. Circulator according to claim 4, characterized in that the ferrite rod in the opening (15, 17) by means of a Ferrite rod (11) placed elastic ring (16) fixed is.

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