EP2371028A1

EP2371028A1 - Microwave rotating coupling for rectangular waveguide

Info

Publication number: EP2371028A1
Application number: EP09803735A
Authority: EP
Inventors: Norbert Nathrath
Original assignee: Dr Nathrath Truemper Partnerschaft Ingenieure
Current assignee: Dr Nathrath Truemper Partnerschaft Ingenieure
Priority date: 2008-12-30
Filing date: 2009-12-29
Publication date: 2011-10-05
Also published as: DE202009006651U1; WO2010076016A1; DE202009018591U1

Abstract

The invention relates to a rotating coupling (10, 40) for rectangular waveguides for connecting high-frequency components, comprising an input component (12, 42) and an output component (14, 44), wherein each component (12, 14, 42, 44) has a rectangular connecting piece (16, 18 46, 48) at one end and a circular waveguide (28, 30, 54, 56) at the other end. Both components (12, 14, 42, 44) are arranged such that the circular waveguides (28, 30; 54, 56) facing each other are rotatably mounted in a coupling transition coaxially about the common axis (A) thereof. The invention is characterized in that a polarizer (20, 22, 50, 52), by which at least one linearly polarized wave can be converted into a circularly polarized or at least one circularly polarized wave can be converted into a linearly polarized wave, is provided between the rectangular connecting piece (16, 18; 46, 48) and circular wave guide (28, 30, 54, 56). Furthermore, the rectangular connecting pieces (16, 18, 46, 48) are arranged axially to the circular wave guides (28, 30, 54, 56) and at least one rectangular wave guide can be connected in parallel to the axis (A).

Description

Microwave rotary joint for rectangular waveguide

The invention relates to a microwave rotary joint for rectangular waveguide according to the type specified in the preamble of claim 1.

For the transmission of energy or signals it is possible to use high-frequency radiation, in particular microwaves.

Microwave rotary joints are needed to the guided in waveguides microwaves between relatively rotatable / pivotable high-frequency devices, such. B. between antenna and transmitter or receiver forward. Typical requirements for such couplings, which are made for terrestrial applications, are two input and output ports, which allow operation with one or two decoupled linearly polarized waves. Furthermore, a broadband transmission behavior and the possibility of transmitting high electrical power is desirable, with low electrical losses are required so that a low local heat generation can be ensured in the transmission case and a good signal / noise ratio is maintained in the case of reception. In addition, it is important in combined transmit / receive operation to minimize (no) interference signals, eg. B. by passive intermodulation.

For RF antennas on satellites or space stations, which are rotatable about at least one axis, the following requirements must also be met:

• space-saving design,

• low weight,

• Perform unlimited rotation angles. US 4,757,281 A1 discloses a microwave rotary joint having two axial circular waveguide components rotatably supported relative to each other. At each a circular waveguide component close rectangular waveguide, which are orthogonal to the circular waveguide and orthogonal to each other. This microwave rotary joint meets essentially all requirements for terrestrial applications, but is unsuitable for space applications in most cases, since the requirements for satellites are not or not sufficiently met. The disclosed in the above publication rotary coupling has the disadvantage that the space required by the necessary orthogonality of the waveguide and thus the mass of both the rotary coupling itself, as well as the mass of the matching pivoting mechanism is very large, so that use on satellites in most cases can not be realized.

The problem becomes even clearer in view of a biaxial panning mechanism to track the antenna in elevation and azimuth, for example. In this case, the resulting size and mass of the Gesamtschwenkmechanismus can be an exclusion criterion, especially for small to medium sized antennas.

It is an object of the invention to provide a rotatable connection with a large, preferably unlimited rotation angle, between two rectangular waveguides, by a high-frequency wave with very low losses and correspondingly low heat generation and noise figure can be transmitted broadband, thereby taking up a small space and very light weight having.

The object is solved by the characterizing features of claim 1 in conjunction with its preamble features.

The dependent claims form advantageous developments of the invention.

In a known manner, the rotary coupling for rectangular waveguide comprises an input and an output component. Each component has a circular waveguide, wherein both components are connected to each other such that the circular waveguides of the two components are coaxial and are rotatable about the common axis to each other. The two circular waveguides form a coupling transition on the mutually facing end faces. In addition, a square connection piece for one or two rectangular waveguides is provided at each component remote from the coupling transition. According to the invention, the connection piece for the rectangular waveguide axially adjoins the circular waveguide via a correspondingly optimized transition. This allows the connection of at least one rectangular waveguide parallel to the axis of the circular waveguide. Between the rectangular waveguide and the circular waveguide or in the circular waveguide of each component, a polarizer is further provided, which enters a linearly polarized wave, which enters the rotary coupling via a rectangular waveguide in a circularly polarized wave, or a circularly polarized wave passing through the circular waveguide in a converts linearly polarized wave, which emerges accordingly from the rectangular connector of the output component. Two rectangular waveguides can be connected to each connecting piece, which in particular has a square cross section.

This arrangement has the advantage that it allows a significantly space-saving and weight-saving design of the rotary joint. The rotary joint can be installed in a system for both directions of propagation of the shaft. Due to the coaxial arrangement of the waveguide, an extremely compact design of the rotary joint can be ensured. Especially the area of the circular waveguide can be realized with a very small clearance, which reduces the formation of disturbing resonances.

In a particularly advantageous manner, the circular waveguides of the input component and of the output component at the coupling transition can be separated by air, vacuum or a dielectric. The corresponding ohmic separation of the two components reduces the risk of generating unwanted spurious signals, such as passive intermodulation products - PIM -.

According to a further embodiment, the rotary coupling is formed two channels. Two parallel rectangular waveguides connect to the square connector of the rotary joint. The two-channel design has the advantage that two decoupled linearly polarized waves can be transmitted, and thereby a combined transmission-reception operation in separate cable trains is possible. Due to the parallel position of the rectangular waveguide, the space requirement is significantly reduced. In addition, the flexibility of integration into a wide variety of applications is ensured.

In particular, the polarizer is designed as a septum polarizer in particular as a septum orthogonal mode transformer - septum OMT - and comprises a shape-optimized septum sheet, which is integrated into a waveguide with a defined cross-section. Advantageously, the septum polarizer of the input component following the connector is integrated in a rectangular waveguide. In this embodiment, a transition element connects to the square waveguide to the subsequent circular waveguide. The transition element connects directly to the end of the septum polarizer to the square waveguide. The structure of the output component is designed analogously to the input component. For the output component, a transition element is provided in the transition between circular waveguide and Quadrathohlleiter. Subsequent to the transition element, a septum polarizer is integrated in the rectangular waveguide, which converts the circularly polarized waves back into linearly polarized waves. In particular, the waveguide has a square cross-section.

This embodiment has the advantage that the transmission behavior is broadband by the transformation of the waves in a rectangular waveguide than in a circular waveguide. In a further alternative embodiment, the connection piece is followed by a circular waveguide in which the septum polarizer is arranged. The arrangement of the septum polarizer in the circular waveguide can lead to a further reduction in length of the rotary joint.

The coupling transition of the two components can be designed so that at least one, to the axis of rotation concentric, annular Anformung in the axial extension is provided on the end face of the wall of the circular waveguide of the input component, which engages in at least one corresponding annular groove on the end face of the circular waveguide of the output component , In this way, a connection is achieved, which is tight for microwaves and allows the rotations in unlimited numbers and generates no or only very small torques. Groove and annular formation may be separated by air, vacuum or a dielectric.

According to a further embodiment of the invention, a rotary coupling arrangement is also specified, which consists of several rotary joints according to the invention, which are connected in series. In this arrangement, the axes of rotation are preferably orthogonal to each other. This allows a pivotable about multiple axes joint, with broadband transmission behavior with low electrical losses. In addition, high powers can be transferred.

Further advantages, features and possible applications of the present invention will become apparent from the following description in conjunction with the embodiments illustrated in the drawings. In the description, in the claims and in the drawings, the terms and associated reference numerals used in the list of reference numerals below are used. In the drawing mean:

1 shows a microwave rotary joint with a septum polarizer in the rectangular waveguide.

2 is a sectional exploded view of a rotary coupling with septum polarizer in a rectangular waveguide.

Fig. 3 is a sectional view of the two intermeshing components of the coaxial coupling;

4 is a perspective view of a rotary joint with polarizer in the circular waveguide.

5 is a sectional exploded view of the rotary joint with polarizer in the circular waveguide. and

Fig. 6 two interlocking components of the rotary joint in sectional view.

1 shows a microwave rotary coupling 10 which comprises an input component 12 and an output component 14. At the input component 12, a square connector for connection of two rectangular waveguides is provided. Analogously, the square connector 18 of the output component also has two channels, which can be used by the connection of two rectangular waveguide. The square connector 16 is followed by a septum polarizer 20. This has a square cross-section. Following the polarizer 20, the waveguide transition 24 is provided, which creates a transition from the square geometry of the polarizer 20 into a circular geometry of the circular waveguide 28. Furthermore, the circular waveguide has a round conductor transition 28, which engages with the circular waveguide 30 of the output component 14. The circular waveguide 28, 30 are rotatably mounted relative to each other. To the circular waveguide 30 of the output component 14 includes a waveguide transition 26, which converts the cross-sectional change to the polarizer in the square cross-section 22.

The outer bearing of the rotary coupling, which defines the two components in their axial alignment and the rotation of the two components against each other, is not shown in the figure for reasons of clarity. An entering into the connector 16 linearly polarized wave is converted in the polarizer 20 in a circularly polarized wave and transported via the waveguide transition 24 and the two mutually rotatable circular waveguide 28, 30 and the waveguide transition 26 of the output component to the polarizer 22 of the output component. About this the circularly polarized wave is converted back into a linearly polarized wave and emerges as such from the connecting piece 18 of the rotary coupling.

In this way, the two connecting pieces and the corresponding rectangular waveguide connected thereto without rotation angle restriction are rotatably mounted relative to each other with a small space.

Fig. 2 shows a sectional exploded view of the rotary coupling shown in Fig. 1 at the section line A-A. The rotary coupling comprises a first component 12 and a second component 14. The first component 12 has a square connection piece 16, a septum OMT - orthogonalmodentransformator - in the square waveguide cross section 20, a waveguide transition 24 and a circular waveguide 28. The output component 14 likewise has a square connection piece 18, a septum OMT in the square waveguide cross section 22, a waveguide transition 26 and a circular waveguide 30. In addition, the common axis of the circular waveguide 28 and 30 is shown. This is simultaneously the axis of rotation A, around which the input and output components 12, 14 rotate against each other. In this illustration, the waveguide transitions 24, 26, which are designed in such a way that the transition from the waveguide cross section of the septum OMT 22 to the circular waveguide 28 is ensured in a stepwise or continuous manner and with low losses, are particularly well seen. In addition, the septum plate 32 of the septum OMT is shown. This septum plate 32, which first separates the two rectangular waveguides, converts in the course of the linearly polarized waves of the input waveguide in counter-circularly polarized waves in the coupling transition. The septum OMTs 20, 22, allow the conversion of two parallel linearly polarized waves in counter-circularly polarized waves, and thus the substantially axial configuration of the rotary joint 10th

Both the input component 12 and the output component 14 are each symmetrical to the separation surface separating the two rectangular waveguides.

Despite a defined definition of input component 12 and output component 14, the rotary joint 10 can be operated without differences in both directions. Fig. 3 shows a rotary coupling 10 in a perspective sectional view, wherein the input component 12 and output component 14 are engaged. Between the input circular waveguide 28 and the output circular waveguide 30, a gap is provided which separates the two circular waveguides 28, 30 both mechanically and electrically. To the circular waveguide 28 includes an axially extending concentric Anformung 36. This engages in a corresponding annular groove 38 of the circular waveguide 30 a. A gap separates the two circular waveguides 30 and 28 both electrically and mechanically in the transition along the groove 38. In this way, an electrically optimized so-called "choke" is realized, which enables interference-free transmission despite the clutch components 12, 14 which can rotate relative to one another.

According to this embodiment, one component can be firmly integrated with a vehicle or satellite and the other component can be freely connected to an antenna, which is then rotatably mounted relative to the fixed component.

4 shows a microwave rotary coupling 40 which comprises two components 42 and 44 in a perspective view. The microwave rotary coupling has a square connection piece 46 which is fixedly connected to a polarizer in the circular waveguide cross section 52. The polarizer 52, in turn, goes directly into a circular waveguide 54. The circular waveguide 54 is rotatably supported coaxially to the circular waveguide 56. To the circular waveguide 56 in turn connects a polarizer in the circular waveguide cross section 50, which ends in a square connector 48. This embodiment is particularly compact. The further mode of operation essentially corresponds to the embodiment described in FIGS. 1 to 3.

Fig. 5 shows a cutaway exploded view of the two components 42, 44. The view corresponds to the section line B-B of Fig. 4. This section line divides each component 42, 44 in its plane of symmetry. The waveguides adjoining the square fitting 46 remain separated until the beginning of the stages of the septum sheet 58 and are converted into circularly polarized waves along the length of the transformer. The circularly polarized waves are transmitted via the circular waveguides 54, 56 and converted back into linearly polarized waves in the septum OMT 52. The transmitted waves exit the connector 48 as linearly polarized waves.

6 shows a rotary coupling 40 whose two components 42, 44 are in engagement. At the circular waveguide 54 includes an axially extending concentric Anformung 62. This engages in one corresponding annular groove 64 of the circular waveguide 56 a. A gap separates the two circular waveguides 56 and 54 both electrically and mechanically in the transition.

LIST OF REFERENCE NUMBERS

10 microwave rotary coupling

12 input component

14 starting component

16 square connector

18 square connector

20 polarizer in square cross section

22 polarizer in square cross section

24 waveguide transition

26 waveguide transition

28 round waveguide

30 round waveguide

32 septum sheet

34 septum sheet

36 Forming

38 groove

40 microwave rotary coupling

42 input component

44 starting component

46 Square connector

48 square connector

50 septum OMT in round cross section

52 Septum OMT in round cross section

54 round waveguide

56 round waveguide

58 septum sheet 60 septum sheet

62 Forming

64 groove

A rotation axis

A-A cutting line

B-B cutting line

C-C cutting line

Claims

Patent claims

A rotary connector (10, 40) for rectangular waveguides for connecting high-frequency components, comprising an input component (12, 42) and an output component (14, 44), each component (12, 14, 42, 44) having at one end a rectangular connector (14). 16, 18, 46, 48) and at the other end a circular waveguide (28, 30, 54, 56), and the two components (12, 14, 42, 44) are arranged such that the mutually aligned circular waveguide (28, 30, 54, 56) are rotatably mounted in a coupling transition coaxially about their common axis (A), characterized in that between the rectangular connector (16, 18, 46, 48) and circular waveguide (28, 30, 54, 56) each have a polarizer (20, 22, 50, 52) is provided, by means of which at least one linearly polarized wave is convertible into a circularly polarized or at least one circularly polarized wave into a linearly polarized wave, and further the right-eckanschlussstücke (16, 18, 46, 48 ) axially to the circular waveguides (28, 30, 54, 56) are arranged, and at least one rectangular waveguide parallel to the axis (A) can be connected.

2. Rotary coupling according to claim 1, characterized in that the polarizer as a septum Orthogonalmodentransformator (20, 22, 50, 52) is formed, and converts linearly polarized waves of two input ports in counter-circularly polarized waves.

3. Rotary coupling according to claims 1 or 2, characterized in that the polarizer (50, 52) has a round cross-section.

4. Rotary coupling according to one of the preceding claims, characterized in that the polarizer (20, 22) has a rectangular cross-section.

5. Rotary coupling according to claim 4, characterized in that between the polarizer (20, 22) and circular waveguide (28, 30) of each component (12, 14) each have a waveguide transition (24, 28) is provided.

6. Rotary coupling according to one of the preceding claims, characterized in that the first

Component (12, 42) and second component (14, 44) are separated by a gap.

7. Rotary coupling according to one of the preceding claims, characterized in that the first component (12, 42) and the second component (14, 44) are in communication via a dielectric.

8. Rotary coupling according to one of the preceding claims, characterized by, two input and two output channels.

9. Rotary coupling according to one of the preceding claims, characterized by, a formation of the rotatable mounting, wherein the at least one concentric to the axis (A) annular Anformung (36) in axial extent to the circular waveguide (28) of the first component (12) in a annular groove (38) of the circular waveguide (30) of the second component (14) engages.

10. Rotary coupling arrangement according to one of the preceding claims, characterized in that a plurality of rotary joints (10, 40) are arranged in the wave propagation direction one behind the other and the axes of rotation of the rotary joints are aligned at an angle to each other.