DE1043429B - Coupling device on a high-frequency line - Google Patents

Description

The invention relates to a coupling device for electrical waves and, more particularly, to assemblies for coupling waves between electrical circuits. Often the task arises to be electrical To couple waves between two circuits, e.g. B. for the purposes of comparison, a Measurement, control, etc. For example, in certain applications it is sometimes desirable to a small amount of high frequency power of a wave guide, especially a hollow pipe, for the purpose of the measurement can be found.

Numerous coupling arrangements have been proposed. Such an arrangement is known for coupling microwave ribbon cables with cavity resonators. The band management is there coupled via a hole with a cavity resonator, which consists of several chambers. The continuation the total energy then takes place again via a ribbon line. Trained as a band line The high-frequency line is therefore interrupted by a cavity resonator connected in between. Energy is not diverted here.

In another known coupling arrangement, the energy from one arm is used as a ribbon line in the form of the printed circuit technology executed hybrid ring coupled to a cavity resonator. Here the tape line has on the side facing the resonator a hole for coupling out the total energy.

Furthermore, microwave branching arrangements are known in which the energy of a strip conductor with With the aid of a coupling pin, it is coupled into a waveguide or a coaxial cable run.

Especially when it comes to extracting small amounts of energy for the purpose of measurement, the arrangements previously used for these purposes are disadvantageous. They are relatively unwieldy and expensive and cause considerable difficulties in production and also have certain operational limits.

The aim of the invention is therefore to provide a new and simple arrangement for coupling which eliminates the above-mentioned disadvantages.

Here, the arrangement can, for. B. by decoupling a small amount of energy for a measuring circuit for measuring wave resistances are used. It can also be used in receivers to be used.

A coupling device with a high-frequency line having a shielding jacket (Main line), which has at least one coupling opening that branches off part of the through the main line is used to transmit energy to a further high-frequency line (secondary line)

Coupling device
on a high-frequency line

Applicant:

General Electric Company,
Schenectady, NY (V. St. A.)

Representative: Dr.-Ing. B. Johannesson, patent attorney,
Hanover, Göttinger Chaussee 76

Claimed priority:
V. St. v. America December 14, 1954

Stanley Ray Fitzmorris,

Baldwinsville, Onondaga, N.Y. (V. St. A.),

has been named as the inventor

according to the invention designed so that the secondary line

as from one the coupling opening (s) under intermediate layer a preferably layered dielectric covering, strip-shaped conductor and the opposite shielding jacket of the main line.

The invention is explained in more detail below on the basis of exemplary embodiments.

Fig. 1 shows in schematic form an arrangement according to the invention;

FIGS. 2 and 3 show further developments of the arrangement according to FIG. 1;

Fig. 4 shows a so-called "sandwich arrangement", in which the teaching according to the invention is applied;

Fig. 5 shows the application of the teaching according to the invention to a circular hollow pipe Cross-section.

An application of the arrangement according to the invention is the coupling element for the extraction of a desired amount of energy, which is in a main wave guide spreads, for coupling into an electrical circuit, for example can be designed as a measuring circuit by means of an auxiliary transmission line. For the auxiliary transmission line is the so-called strip construction used together with impedance matching elements. The design is such that the auxiliary transmission line is from a coupling circuit Receives energy, which includes openings or slots in the wall of the main shaft guide.

S09 678/240

Fig. 1 shows an arrangement in which a stripline with a hollow pipe is rectangular Cross-section is coupled, namely for the transmission of small amounts of energy between the rectangular Hollow pipe and another circuit. For example, assume that the Rectangular hollow pipeline or main transmission line 1 is used to transmit high-frequency energy of a circuit arrangement 2, such as. B. a high frequency source or a transmitter a load circuit 3 such as an antenna. It is the task before, a certain amount, the transmitted through the hollow pipe 1 for high frequency energy the use in another circuit 4 can be found. The amount withdrawn will be, for example used for frequency or power measurements etc. To get a desired proportion of high frequency waves, which proceed from the source 2 to the load circuit 3, to be decoupled into the circuit 4 and at the same time unwanted waves, these are waves that are in the load circuit 3 in the Main line 1 are reflected, to be kept away from the circuit 4, are in. The wide wall side 6 of the hollow pipeline 1 shaft coupling slots 5 provided. The number, the dimensions and the spacing or arrangements of these slots are selected according to the desired coupling and directional properties. An auxiliary transmission line in the strip construction enables the required coupling with the circuit 4. This stripline 7 consists of a strip of electrically conductive material 8, which extends along a section the main line 1 extends and from the wall 6 by dielectric material, such as. B. a P'olyäthylen-Tetrafluorid leaflets, known as is separated from the trade name »Teflon«. In order to prevent undesired radiation from the slots 5 prevent, the slots, as shown in FIG. 1, are to be arranged under the strip-shaped conductor 8. To prevent radiation from the stripline to the outside, it is advisable to use the width of the strip-shaped conductor 8 is at least approximately equal to one third of the width of the base area select, that is the width of the wall 6 of the main hollow pipe 1 in the present case.

In the embodiment of FIG. 1, the circuit 4 is connected to the strip line by means of a coaxial line 9 switched on. To achieve a desired coupling and impedance matching at the same time Elbow training, in particular rectangular bend training, is the stripline 7 with a protrusion 10 is provided which is at the desired angle for aligning the main line runs. The projection 10 consists of a base plane in the form of an electrically conductive plate 11. This electrically conductive plate 11 can optionally also by a projection of the wall 6 of the Hollow pipe can be formed or by a conductive metal plate that is welded to the main line 1 or soldered or by a conductive coating that is on the underside of the dielectric Material 12 is applied in section 10. The strip conductor 8 is in the projection 10 with adequate Curvature transferred in order to avoid any impedance mismatch caused by the curvature. The coupling between the projection and the coaxial line 9 takes place in a manner known per se Way by means of a coaxial transition in the form of an opening in the conductive part 11 and the plate-shaped dielectric portion 12. as shown in FIG.

It is known per se that radiating slots in the two adjacent transmission lines connecting wall, coupling high frequency energy between the two lines, and that through appropriate Choice of the spacing of the shape and the orientation of the individual slots can be achieved can that the extracted high-frequency energy, based on the original energy flow, only in spreads in a certain direction. In the illustrated arrangement it is assumed that the slots are arranged so that the high-frequency energy from the circuit arrangement 2 is absorbed is coupled out essentially only in one direction, namely along the strip line 7 to the circuit 4, and that furthermore energy taken from the circuit 3 is, along the stripline 7 after the

ao ren end 13 spreads out. If it is desired that the energy coming from 3 be absorbed, is a corresponding absorption device 14 for this Provide radio frequency power at the end 13. In the special embodiment shown,

a5 is the absorption device from one layer or Layer of resistance material in sufficient proximity to the end of the strip-shaped conductor 8 in such a way is arranged to absorb the required amount of undesirable radio frequency power.

The radio frequency energy absorber 14 can optionally also be replaced by a projection similar to projection 10, which is to be provided with a corresponding coupling or transition piece, for example a like the coaxial line 9, so that the extracted high-frequency energy is sent to a control loop for further processing of the unwanted waves or the waves picked up by the load circuit can be, in a similar'Weise as indicated with respect to parts 4 and 9, which refer to the projection 12 are fed. For example, such a training can be used in radar systems find, since there the transmitted waves with those in the device between the transmitter and the antenna arrangement reflected waves must be compared to the mismatch of the particular coupling arrangement to be able to determine between the transmitter and antenna.

FIG. 2 shows a further arrangement designed according to the teaching of the invention, wherein for coupling of the circuit 4 a steadily curving projection 10 is provided to the desired To enable coupling of the coaxial line 9 to the stripline. The leading ground level for the plate-shaped projection 10 is expediently made of a metallically conductive coating 11, that is to be provided on the dielectric intermediate layer 12 opposite the strip-shaped conductor 8 is. The other details of the arrangement correspond to those of FIG. 1, so that with regard to these details reference is made to the description there.

Another embodiment of an arrangement according to the teaching of the invention is shown in FIG. 3, in which a transition device for the coaxial line 9 in the form of a block of conductive material 15 is provided. This block 15 contains a bore or cavity 16 lying at a right angle to the axis of the main line 1, through which the inner conductor 17 of the coaxial line 9 is guided up to the connection to the strip conductor 8. In some cases it is

advantageous, the opening 16 in the direction 18 over to continue a certain length to thereby reflections caused by angular training are to reduce. Disturbing mismatches can be caused by the usual stub lines and Stub lines, d. H. be compensated by short-circuited or open matching lines at the end.

Furthermore, there can be a mismatch between the coaxial line 9 and the corresponding connection end of the stripline by the usual continuous stepping of the strip-shaped conductor achieve. In the embodiment of FIG. 3, this is carried out in section 19 of strip conductor 8, which feeds the transition element 15.

A compensation line in the form of a dummy line or a branch line can also be carried out by continuing the strip-shaped conductor 8 over the Connection point of the coupling line are also formed. In the embodiment of FIG. 3, this is the case dashed with indicated.

In the arrangement according to FIG. 4, the strip-shaped conductor 8, which is assigned to the main hollow pipeline 1, is separated from it by a first layer 20 of dielectric and from an electrically conductive part 21 by a second layer 22 of dielectric. The part 21 serves to hold the stripline 8 to the hollow pipeline 1 and presses the dielectric layer 22 and thus the stripline 8 and the dielectric 20 against the broad side 6 of the hollow pipeline 1 via the screw bolts 23, 24 and the counter bearing provided on the hollow pipeline 1 at. This creates a so-called "sandwich line" which comprises parts 6, 8, 20, 21 and 22. The slot 5 or the slots 5 are used for the desired coupling between the hollow pipe 1 and the "sandwich pipe".

5 shows the application of the teaching according to the invention to a hollow pipeline of circular cross-section reproduced. The hollow pipeline 25 of circular cross-section is provided with two "sandwich" Line sections 26 and 27 are provided which are similar to the line type described with reference to FIG and which are attached to the hollow pipeline 25 at points distant from one another. In any case is the strip-shaped conductor 8 by means of the wall of the hollow pipeline of circular cross-section dielectric material 20 and from the electrically conductive plate-shaped part 21 by means of dielectric Materials 22 separately.

The arrangement according to FIG. 5 can advantageously be used for polarization measurements. if z. B. the E field in the hollow pipeline 25, as indicated by the vector 28, is oriented, couples, provided that the two coupling devices 26 and 27 at right angles and expediently lie in the same cross-sectional plane of the line 25 to one another, the slot 29 in the direction of the vector 30 oriented component of the Ε field and the slot 31 that in the direction of the vector 32 lying component. The through the slots 29 and 31 in the associated "sandwich lines" 26 and 27 decoupled signals or energy components can then by means of the usual amplitude comparison circuits, such as B. a power bridge measuring arrangement can be compared. 6g

Claims (19)

Patent claims: 1. Coupling device with a high-frequency line having a shielding jacket (Main line), in which the shielding jacket has at least one coupling opening that the Diverting part of the energy transmitted through the main line into another High-frequency line (secondary line) is used, characterized in that the secondary line from one the coupling opening (s) with the interposition of a preferably layered dielectric covering, strip-shaped conductor and the opposite shielding jacket of the Main line exists. 2. Arrangement according to claim 1, characterized in that several coupling openings are provided are, whose dimensions, distribution and orientation are chosen such that at a Unidirectional energy transport in the main line also in the secondary line reflection-free closure a unidirectional energy transport occurs. 3. Arrangement according to claim 1 or 2, characterized in that the strip-shaped conductor together with the layered dielectric, pointing away from the shielding jacket of the main line, is curved around the broad side, and that the side facing the shielding jacket of the layered dielectric is provided with an electrically conductive coating, which is at least merges into the shielding jacket of the main line at the beginning of the bend. 4. Arrangement according to claim 1, 2 or 3, characterized in that the strip-shaped Conductor together with the layered dielectric is continued tangentially from the shielding jacket of the main line and that the dem Shielding jacket facing side of the layered dielectric with an electrical conductive coating is provided, at least at the beginning of the tangential continuation in the shielding jacket the main line passes. 5. Arrangement according to claim 3 or 4, characterized in that the electrically conductive covering is firmly applied to the dielectric in the form of a surface layer, for example by means of Vapor deposition, brushing on, rolling on, etc. 6. Arrangement according to claim 3 or 4, characterized in that the electrically conductive covering consists of a solid metal part, for example a sheet metal. 7. Arrangement according to claim 6, characterized in that the solid metal part is rigid is attached to the shielding jacket of the main line, for example by screwing on, soldering, Welding, etc., or that the solid metal part is part of the shielding jacket of the main line forms. 8. Arrangement according to one of claims 1 to 7, characterized in that the width of the strip-shaped conductor is selected to be at least approximately equal to one third of the width dimension of the shielding jacket of the main line, which is decisive for the secondary line formation. 9. Arrangement according to one of claims 1 to 8, characterized in that the strip-shaped Conductor on its side facing away from the shielding jacket of the main line with another, preferably also strip-shaped conductors with the interposition of a further strip-shaped conductor Dielectric is covered. 10. Arrangement according to claim 9, characterized in that the inner strip-shaped Conductor is embedded in dielectric. 11. Arrangement according to one of claims 1 to 10, characterized in that at least at one end of the secondary line a transition to a conventional high-frequency line, ζ. Β. a coaxial line, hollow pipeline, double line, etc. is provided. 12. Arrangement according to one of claims 1 l> i.> 11, characterized in that a secondary kit end by means of wave-absorbing material, preferably formed in the manner of a film or layer Material is completed without reflection. 13. Arrangement according to one of claims 1!) Is 11, characterized in that means are provided for compensating for reflection points lying in the secondary line and / or in the connections. 14. Arrangement according to claim 13, characterized in that that the strip-shaped conductor at least towards one end in the width dimension is designed to run conically. 15. Arrangement according to claim 13 or 14, characterized in that for compensation Stiehl line or stub line sections are provided are, which preferably consist of a section of a strip-shaped conductor and of the The main line has a shielding jacket with a dielectric in between. 16. Arrangement according to one of claims 1 to 15, characterized in that the strip-shaped Head consists of a solid metal strip. 17. Arrangement according to one of claims 1 to 15, characterized in that the strip-shaped Conductor made of a firmly applied to the dielectric in the form of a surface layer Strip consists, e.g. B. from a galvanic or by means of vapor deposition or brushing or rolling etc. applied strips. 18. Arrangement according to one of the preceding claims, characterized in that the main line is designed as a hollow pipe of rectangular cross-section and the strip-shaped Head runs along the wide side of the hollow pipeline. 19. Arrangement according to one of claims 1 to 17, characterized in that the main line consists of a hollow pipe of circular cross-section, on which, preferably two, strip-shaped conductors are arranged with the interposition of dielectric, which to each other lie at a right angle. Legacy Patents Considered:
Patent Nos. 958396, 965 141, 1014183. 1 sheet of drawings © H »67« / 240 11.58