DE893811C - Microwave transmission system - Google Patents

Description

The invention relates to a microwave transmission system and in particular a surface waveguide and means for coupling such Surface waveguide with other microwave transmission lines .

In addition to the transmission of microwave energy over radio links, coaxial Another very broadband transmission option is cables and dielectric waveguides for microwave energy in the so-called surface waveguide, which is a metallic wire with an insulation layer. Due to the insulation covering of the wire, the electromagnetic The field around the wire is very limited in its extent and is concentrated around the wire. To the For example, an ordinary, No. 12, enameled copper wire has an electromagnetic field concentration, which extends within a 75 to 100 mm radius around the wire and wherein the all radio frequency energy propagates in this field. This surface wave guide has very small losses and is practically free from electrical and other interference as long as that is concentrated electric field around the conductor is not disturbed.

An object of the invention is to provide a special surface waveguide for microwave transmission and the provision of a coupling device between the surface waveguide and other microwave transmission lines.

One of the features of the invention is to vary the distribution of insulation along the Surface wave transmission. It is known that a conductor covered with insulation is used as a waveguide

can serve for microwave energy. One feature

893'Si 1

the invention now consists in a special distribution of the insulation coverage of the surface waveguide. The distribution consists in the arrangement and attachment of a number of pearls or Disks made of insulating material with gaps ■ along a wire conductor. Another way of distribution consists in a continuous covering of the wire conductor with insulating material, on which in addition with space between beads or discs ίο in the form of enlarged parts of the insulating material are upset. A similar wave propagation as with a conductor with distributed insulation can also be achieved with a bare wire, which has a finite specific resistance compared to an ordinary copper wire. Such a wire with an insulation covering causes a stronger field concentration around the Wire surface.

Another feature of the invention is a coupling arrangement for coupling a Surface waveguide with the outer conductor of coaxial lines or the wall of dielectric Waveguides. The end portion of a hollow conductor made up of part or continuation of the Wall of a dielectric waveguide or the outer conductor of a coaxial line, will gradually decrease in conductivity after the end. The purpose of this terminal resistor is primarily to absorb termination losses and thus an improved transmission adaptation · to produce. This decrease in conductivity can be caused by various arrangements can be effected. For example by tapering the thickness of the end part of the hollow conductor under the effective thickness of the skin line and secondly at constant thickness of the hollow conductor by decreasing the conductivity thereof until the conductivity is at the terminating end is practically reduced to zero. A third example is injection molding of resistive material on both the inner and outer surface of the end portion of the hollow conductor, the resistance gradually decreasing from the end of the conductor inward.

The insulating material at the end portion of the hollow conductor is preferably increased in quantity and / or quality to restrict the field to a radius equal to or less than the radius of the hollow conductor, regardless of whether the conductor is has a terminating resistor or not. This insulating material is reduced in amount from the terminal end of the same over a distance to the outside along the line and can be , e.g. B. consist of a solid body of dielectric material or a number of beads or discs of insulating material selected size and spaced apart to produce the desired change in the dielectric property. The beads or disks can vary in their cross-sectional dimensions, or in their width dimension, or both. The insulation quality of the terminating insulation material can also decrease a certain distance along the line within the outer hollow conductor. All of these arrangements serve to concentrate the electromagnetic field closely around the waveguide for the transmission of microwave energy with a minimum of interference along the line and between the line and the walls of microwave transmission devices.

Examples of implementation of the invention are shown in the drawing.

Fig. Ι is a longitudinal section of a coupling device for the coupling of a surface waveguide with a coaxial line;

FIG. 2 is a cross-section along line 2-2 of FIG.

Fig. 3 is a longitudinal section of another coupling device which beads or disks are made from Insulation material · used, which is applied at a distance along the (line at the coupled end of the same are;

Figure 3a is an enlarged cross-section of one of the disks shown in Figure 3;

Fig. 4 is a longitudinal section of another embodiment of the invention showing the distribution of insulating material on the line in, in the form of beads or disks, and in which the Line is coupled to a dielectric waveguide;

Fig. 5 and 6 show other Ausführungsbeispiek of coupling devices in longitudinal section.

In Figs. 1 and 2 there is a single conductor 1 shown, which has a continuous covering of insulating material 2 made of enamel, polystyrene, Polyethylene or other insulating material. However, the cover 2 can be omitted when the conductor has the required electrical resistivity to achieve the • Concentrate the electromagnetic field within a sufficient radius around the conductor. Of the Conductor 1 extends into a hollow conductor 3 a Coupling device consisting of the terminating end of a coaxial line 4 with a solid dielectric can exist. The conductor 1 is continued as a continuation of the central conductor 5 of the coaxial line. The hollow conductor 3 can of course also be the wall part of a dielectric waveguide like this is shown in FIG. The insulating covering 2 preferably merges into an insulating body 6, 7 or enters the same, and the insulating body 6,7 is inside the end part of the hollow conductor 3 arranged. The insulating body can consist of one piece or two or more parts, which are separated in the longitudinal direction and which by a solvent or binder and / or by the Sheath of the hollow conductor 3 are held together. In Figs. 1 and 2, for. B. consists of Body from the two halves 6 and 7, the grooves have to accommodate the conductor 1. Where the conductors 1 and 5 are of different size is the connecting part is preferably designed to be tapered. The hollow conductor 3 has an extension 8, which preferably overlaps the body ■ and whose conductivity gradually decreases to zero by ■ nde 9. These. Extension 8

can be formed by tapering the thickness of the conductor 3 so that the conductivity thereof gradually decreased below the normal skin conductivity until it reaches zero. Part 8 S can also be formed by spraying conductive material onto the body 6, 7, the Coverage - gradually thinning up to point 9, on which only separate particles of conductive material are present. The part of the - 10 body 6, 7, which extends further outward from the end part 9, is gradually down to the Covering 2 thickness is tapered.

In Fig. 3, the insulating covering 2 carries out a number of beads or discs 10, 11, 12, 13 Insulating material which are arranged at a distance from one another along the conductor 1. These disks 10, 11, 12 and 13 vary in diameter, with the largest disc 10 is arranged at the end 9 of the hollow conductor 3. The thickness or length of this Discs, is preferably much smaller than the wavelength of the transmitted microwave energy. The disk 10 closes off the end of the link 3 and the disks 11, 12 and 13 have a progressive one smaller diameter, which is in the disc 13 the. Covering diameter 2 approaching. The cover 2 can be between the first disk 13 and the end disk 10 and if desired may also be interrupted along the conductor, but in Fig. 3 the coverage is over the whole Ladder length available. The cover 2, which is preferably in its thickness by an additional Enamel layer is reinforced, is used to attach the discs or pearls as well as for concentration of the electromagnetic field close to the conductor i. The number of pearls or discs 10 to 13 as well as their distance, if desired, can also be varied. The center conductor 5 is secured by spacer washers 14 in the case of coaxial lines usual way worn.

4 shows a dielectric waveguide 15 which consists of a hollow conductor 16 in which the conductor i ^A extends. The conductor i ^A is connected to a support, not shown, for tensioning via a tensioning device 17. The conductor i ^A is electrically connected to the end cap 20 on the waveguide 16 by a gripper 18 of a tubular sleeve 19.

The ¹ sleeve 19 ensures an exact coaxial position of the conductor. A dielectric waveguide 21 is connected to the waveguide 16 for the transmission of microwave energy to the conductor i ^A , which may or may not be free of its insulation covering with respect to the waveguide 21. Furthermore, a connection 22 is provided for a direct connection or possibly also capacitive coupling with the conductor.

The conductor x ^A is shown as a bare wire, which has a distributed insulation in the form of beads or disks 23, the distance 6 "of which is preferably such that ten disks are accommodated per wavelength. At the coupling point, the disks have different radial dimensions, similar as shown in FIG. 3.

The largest disk 24 is preferably attached to the end of the waveguide and closes the same away. In order to reduce a disturbance of the wave propagation at the transition point, others are Disks 25 of decreasing size are provided which extend along the conductor within the hollow conductor 16 are attached at a distance from each other. The end portion 26 of the waveguide 16 has in this embodiment a constant thickness different from the tapered thickness of the end part 8 in FIGS Fig. Ι and 2. The material of the part 26 is chosen so that its conductivity is about its Length varies until the conductivity of the part is on. The end is practically zero. This can be done by spraying resistive material on the inside and / or outside of the waveguide are effected, the resistance layer at the terminating end is the strongest.

In FIG. 5, the conductor i ^A is constructed in the same way as in FIG. 4. The distributed insulating material is also applied in the form of disks 23. By precisely spacing these disks, the same concentration effect of the electromagnetic field around the conductor is brought about as by a continuous covering 2 in FIGS. 1 and 2. In the area 27 where the conductor i ^A approaches the waveguide 16 and enters it the disks are applied with ever closer spacing until the smallest distance is reached at the end of the waveguide. In order to keep the conductor in a coaxial position to the waveguide, the usual center conductor spacers 14 are used. This concentration of the insulating material at the coupling end effectively limits the electromagnetic field to a cross section which corresponds to the cross section of the waveguide 16.

In Fig. 6 the insulating material is also applied in the form of discs or beads 28, 29, 30 and 31, which in the vicinity of the waveguide 32 vary in both diameter and thickness and consequently even at a distance. The largest disk 28, which is less thick than the wavelength of the transmitted microwave energy is arranged in the end part 33. From there they take Strengths, the insulating washers 34 again down to the strength of the usual spacer washers 14.

Claims (28)

Patent claims: ι. Microwave transmission system characterized by a conductor for transmission of microwaves by means of an electromagnetic field formed around the conductor, one Waveguides in which the surface waveguide extends, and characterized in that, that around the surface waveguide at the transition point in the waveguide insulating material is also appropriate to concentrate the electromagnetic field at this point. 2. Plant according to claim 1, characterized in that the insulation gradually in the Insulating property for a given design distance to the outside along the line is reduced. 3. Plant according to claim 1, characterized in that the end part of the waveguide jacket is tapered in thickness, thereby increasing conductivity the same to gradually decrease. 4. Plant according to claim 1, characterized in that the end part of the waveguide jacket includes resistive material along its length, which after the end of the waveguide is too amplified so that the effective conductivity of the end part, gradually decreases. S system according to claim 1, characterized in that that the waveguide forms the outer conductor of a coaxial line, and that the surface waveguide © forms a continuation of the center conductor of the coaxial line. 6. Plant according to claim 1, characterized in that the surface waveguide with is covered by a continuous layer of insulation. 7. Plant according to claim 6, characterized in that at the coupling point a cylindrical Body made of insulating material is arranged in the end of the waveguide, which is after outwardly extending part to the thickness of the insulation covering of the surface waveguide rejuvenates. 8. Plant according to claim 7, characterized in that the end part of the waveguide a Includes a layer of conductive material extending over a portion of the insulating body and gradually decreasing in thickness towards the end. 9. Plant according to claim i, characterized in that that the conductor is covered with parts of insulating material that are mutual Have distance. 10. Plant according to claim 1, characterized in that that the insulating material is distributed in the form of sections with a gap are applied along the conductor at the coupling end with the waveguide. 11. Plant according to claim 10, characterized in that ' indicates that the parts are independent discs or beads of insulating material. 12 '. Plant according to claim 10, characterized in that that the distributed insulating material is a continuous support .aus insulating material includes and that the parts include discs, or beads, of insulating material. 13. Plant according to claim 10, characterized in that that the insulating material at the coupling end beads or discs of insulating material includes spaced along the portion of the conduit that extends into the said waveguide extends. 14. Plant according to claim 10, characterized in that that the named parts vary in size. 15. Plant according to claim 14, characterized in that that the parts mentioned vary in cross section. 16. Plant according to claim 14, characterized in that that the parts mentioned vary in strength. 17. Plant according to claim 14, characterized in that that the parts vary both in cross-section and in thickness. 18. Plant according to claim 10, characterized in that that the. Distance between said parts varies and that the distance is smaller where the insulation property is greatest. 19. Plant according to claim 10, characterized in that that the insulating material along said lines in the interior of the hollow conductor gradually in ■ the insulating property decreases. 20. Plant according to claim 1, characterized in that the hollow conductor through the wall a waveguide is formed. 21. Plant according to claim 1, characterized in that that the hollow conductor is the outer conductor of a coaxial line and that the center conductor the coaxial line is connected to the surface waveguide. 22. Plant according to claim 1, characterized in that the O, surface waveguide with Insulating material is covered and that the distribution of the insulating material over a given Line length is gradually increased to the electromagnetic field along the said Length to concentrate more, and that the increased distribution by insulating material parts is formed, which is applied to the conductor with gaps along said length are. 23. Plant according to claim 22, characterized in that the parts vary in size. 24. Plant according to claim 22, characterized in that the parts vary in cross-sectional dimensions. 25. Plant according to claim 22, characterized in that that the parts vary in width. 26. Plant according to claim 22, characterized in that the parts both in the cross-sectional dimension as vary in width. 27. Plant according to claim 22, characterized in that that. the distance between said parts varies, and that the distance becomes smaller where the insulation property should be greater. 28. Plant according to claim 22, characterized in that the distributed insulating material includes a continuous covering of insulating material ^1X 5 and that said parts consist of beads or discs of insulating material. 1 sheet of drawings © 5480 10.53