EP0503129A1 - High frequency electric coaxial cable - Google Patents

Abstract

In the case of a coaxial electrical high-frequency cable with a spacer arranged between the inner conductor (1) and the outer conductor, this consists of a profile helix (2) or of individual shaped pieces made of glass or ceramic materials, even at elevated ambient temperatures. <IMAGE>

Description

The present invention relates to a coaxial electrical high-frequency cable with a spacer arranged between the inner and outer conductors.

A coaxial high-frequency power cable is already known, in which a spacer made of individual pieces is provided between the inner conductor and outer conductor, which are made of ceramic. These individual pieces are arranged offset on the inner conductor in the axial direction and individually screwed to it (DE-OS 33 04 957). Although these known cables are also suitable for being largely ready for operation under the influence of fire, this construction is very expensive to manufacture, apart from the fact that the fastening screws used for fastening the individual pieces to the inner conductor are often undesirable for electrical reasons.

Based on this prior art, the invention has for its object to provide a coaxial high-frequency cable that is operable even under the influence of fire, its production is inexpensive and free of additional materials in the dielectric, in particular metals, which adversely affect the transmission quality.

This object is achieved according to the invention in that a profile helix is used as a spacer, which consists of glass or ceramic materials or predominantly contains them. Such a helix is with the Conventional machine systems available today in cable technology can be applied without problems, an electrical influence on the transmission properties by foreign materials is excluded, the cable according to the invention is also operable under the influence of fire. This is particularly important e.g. B. when supplying an emergency transmitter or a so-called radiating high-frequency cable used for control or reporting purposes, which is used for train monitoring and is arranged in a tunnel, but also for those supply or control cables that are on oil platforms or those for offshore Purposes installed and specially protected against the effects of fire.

The same advantages result in a variant according to the invention in which ceramic shaped pieces are used for the spacing and are held on the inner conductor by their shape.

The profile spiral made of the refractory materials according to the invention can be designed in any way, so it can be a profile strand which is helically wrapped around the inner conductor of the high-frequency cable. Based on the idea of keeping the air content of the dielectric in the space between the inner and outer conductors of the fire-protected cable according to the invention as high as possible, the profile strand will be made from braided single strands of round cross-section or from individual threads. Several such profiles can in turn be stranded or interwoven with one another, for example when it comes to bridging larger distances between the inner and outer conductors of the cable, without adversely affecting the flexibility.

It can also be advantageous if the Profile helix from the refractory materials receives an additional refractory coating, for example in the form of a braid or fabric, this applies in particular if the helix itself consists of individual strands stranded or knitted together.

Another expedient embodiment of the invention results when the profile helix consists of a plurality of profile bodies made of glass or ceramic materials arranged one behind the other on a support. The profile body itself can be, for example, balls, rollers or rollers, which are fastened on a corresponding refractory carrier thread or strand or are braided with refractory threads.

In addition to the glass, known ceramics can also be used as the material for the spacers according to the invention. These can optionally be mechanically reinforced by embedded glass fibers.

If, as also provided for by the invention, ceramic shaped pieces are used instead of the described profile helix, then these will advantageously be attachable transversely to the inner conductor. Such profile bodies can be, for example, hollow cylinders with longitudinal slots leading from the ends to the center and offset by more than 90 ° with respect to one another. A preferred construction is that the longitudinal slots are offset from one another by 180 °. This means that the profile bodies, which are prefabricated elements, are plugged in the transverse direction onto the inner conductor of the coaxial high-frequency cable and then rotated into the longitudinal axis. This state of the profile body is fixed on the inner conductor by the outer conductor of the cable.

Another embodiment of the shaped pieces are radially slotted disks which are placed transversely on the inner conductor, it being possible for the stability of these spacers on the inner conductor to turn adjacent disks evenly against one another. The molded bodies thus reliably hold the inner conductor in its central position and are finally fixed in their position on the inner conductor by the outer conductor.

A further expedient embodiment of the invention is obtained when the shaped pieces are injection molded pieces completely surrounding the inner conductor. As with other known cable constructions of the generic type, in which disks made of plastic are discontinuously sprayed onto the inner conductor during manufacture, an injection molding machine filled with the appropriate ceramic mass can be used in the implementation of the invention for the manufacture of the ceramic injection molded pieces The shape of the disc is sprayed onto the continuous inner conductor and each disc is then sintered or fired or, if necessary, reworked. The usual further processing of the inner conductor prepared in this way and provided with the spacers can then be carried out in a known manner.

Known ceramics can be used as material for the spacers according to the invention, which may also be interspersed with glass fibers, that is to say additionally reinforced. Also suitable in this context are foam ceramics, such as those used for. B. are known under the trade name POROTON. Since these materials are hygroscopic, it is advisable to provide the moldings with a moisture-repellent coating after sintering, which can be a varnish or a glaze.

As already mentioned, the refractory cables according to the invention find a particularly advantageous use in the form of so-called radiating high-frequency cables, which are coaxial electrical cables whose outer conductors have regular openings in the form of slots, holes, cutouts and the like. If metal foils are used as outer conductors, which are placed around the refractory spacers in a longitudinal direction, then these are generally not self-supporting, especially if the strip edges leave a longitudinal slot between them. In such or similar cases, it has therefore proven expedient to completely or partially fill the spaces between the inner and outer conductors that are free of the spacers with an insulating material.

For refractory training, the insulating material is then advantageously through a refractory film or a tape, for. B. covered a glass mica tape.

Deviating from this, however, one can also proceed in such a way that the refractory spacers according to the invention, profile helix or molded body, are enclosed by a plastic tube which is covered on the outside by a refractory film or a corresponding tape. Then the outer conductor of the cable, also in a non-self-supporting form, is arranged.

But also for cables with a self-supporting outer conductor, where there is no need for support elements in the form of insulating materials, for example as a support hose, it can often be advantageous to use a spacer, a profile coil or molded body with a closed layer made of a fire-resistant film or a corresponding one Band around. This measure is particularly important if the self-supporting The outer conductor is subsequently provided with slots or bores and there is a risk that metal splinters, chips and the like can get into the dielectric.

The invention will be explained in more detail with reference to the exemplary embodiments shown in FIGS. 1 to 10.

In Fig. 1, 1 designates the inner conductor of a coaxial high-frequency cable, around which is placed a helix 2, which consists of a glass cord made of simple glass yarn, which is twisted, twisted or intertwined, in order to provide a certain distance between the inner conductor and outer conductor necessary cross-sectional dimensions to come. As indicated schematically, this glass cord is surrounded by an outer braid 3, for example to increase the mechanical strength of such a helix.

If, for example, larger distances are to be bridged between the inner and outer conductors of the high-frequency cable, several of the cords shown in FIG. 1, with or without braiding, can also be brought together to form a strand of larger cross-section, as shown in FIG. 2. For this purpose, for example, according to FIG. 2, three individual cords 2 are stranded or knitted together to form the strand 4, which in turn is then applied as a spacer for the concentric outer conductor on the inner conductor 5 of the high-frequency cable.

For the invention, it is important that, in contrast to previously used spacers, exclusively made of polymeric materials, at least for. T. those are used that can withstand elevated temperatures and do not melt away, so that the functionality of the cable is retained at least for a certain time even in the event of a fire. In addition to those in FIGS. 1 and 2 The profile helices described are therefore also suitable for embodiments such as those shown in an example in FIG. 3. Here are e.g. B. spherical glass or ceramic body 8 attached to or on a carrier thread 7, which is placed together with the balls for spacing the outer outer conductor, not shown, as a spiral around the inner conductor 6.

4 shows a spacer helix, which consists of spherical glass or ceramic bodies 9, which in turn are surrounded by a braid 10 made of glass or ceramic threads.

The spaces between the inner conductor and the outer conductor (not shown) of the high-frequency cable, which are free of the spacers, can be filled with conventional materials, in particular if the outer conductor is not self-supporting, that is to say, for example, consists of a metal strip around the spacers, for example with materials based on foamed polyethylene or other extrudable materials.

As already explained, coaxial high-frequency cables are used, for. B. also used in the supply of an emergency transmitter or as a so-called radiating high-frequency cable used for control or reporting purposes, which is used for train monitoring and is arranged in tunnels. Such cables must still be operational even if high ambient temperatures occur near the cable after a fire has broken out. While the operability of the known cables with spacers made of polymeric materials is not guaranteed due to the melting away of the spacers between the inner and outer conductors at elevated temperatures, the spacers provided according to the invention issue Ceramic materials ensure that the distance between the inner and outer conductors necessary for cable operation is maintained even in the event of a fire.

In order to ensure the function of the cable even in such a case, FIG. 5 shows a shaped piece 11 serving as a spacer, which is attached to the inner conductor 12 of the high-frequency cable by being plugged on. In order to achieve this, the hollow cylindrical shaped piece 11 has two longitudinal slots 13 and 14 which run from the ends towards the center and which allow the inner conductor 12 to be passed through and end in a central region 15 which allows free passage from top to bottom in the selected representation allows. By means of the longitudinal slots 13 and 14 and the central recess 15, it is possible to push the shaped piece 11 transversely onto the inner conductor and then to bring it into the position shown by rotating it in the axial direction of the inner conductor 12.

So prepared, d. H. inner conductors already provided with the spacers can then, as usual, be enclosed by the outer conductor, which is applied, for example in the form of a longitudinally extending copper strip or a corrugated tube, to the shaped pieces 11 concentrically with the inner conductor 12.

6 shows an embodiment of the invention in which disk-shaped spacers 17 are attached to the inner conductor 16 of the refractory coaxial high-frequency cable. These disk-shaped spacers have a gap or an opening 18 which are adapted to the dimensions of the inner conductor 16. The ends 19 and 20 of the spacer formed by the opening or the gap are arranged offset in the direction of the inner conductor 16. This results in a the spacer is held securely on the inner conductor of the high-frequency cable.

FIG. 7 shows another possibility for carrying out the inventive concept. Here, disc-shaped fittings 22 are applied to the inner conductor 21 of the refractory high-frequency cable at intervals, which completely enclose the inner conductor 21 and are applied by an injection or injection molding process. For this purpose, known techniques can be used, which consist, for example, in that a plurality of these disk-shaped spacers are simultaneously sprayed onto a continuous conductor, then sintered or hardened and optionally aftertreated, while at the same time, in a discontinuous working step, an equal number of new shaped pieces are applied to the inner conductor 21 are sprayed on.

In the event that the ceramic material used for the spacers according to FIGS. 5 to 7 is too hygroscopic to ensure the required transmission properties of the cable according to the invention, those already prepared according to FIGS. 5 and 6, but also those produced by an injection process 7 on the inner conductor attached profile body with a suitable coating or be provided with such protection after spraying.

8 and 9 show possibilities for executing a high-frequency cable according to the invention with a non-dimensionally stable outer conductor.

8, the inner conductor 23 is surrounded by the helix 24 made of refractory material. B. with a cell polyethylene 25 filled out. This insulating material also serves as a carrier for the outer conductor 26, the z. B. is designed as a slotted metal foil. In the event of a fire, e.g. B. and the prevailing high temperatures to prevent leakage of melting polyethylene from the outer conductor 26 is between insulating polyethylene 25 and outer conductor 26, a layer 27 of one or more layers of a refractory tape, such as a mica coated glass fabric tape.

In a departure from the exemplary embodiment according to FIG. 8, FIG. 9 describes a cable structure in which the inner conductor 28 is in turn surrounded by a helix 29 made of refractory material, and the extruded plastic hose 31, for example made of a suitable polyethylene. In order to ensure that molten polyethylene does not escape to the outside through radiation openings in the outer conductor 30 at elevated ambient temperatures, a refractory layer 32 is provided between the plastic hose 31 and the outer conductor 30. This consists, for. B. from a closed layer of mica or glass fabric tapes.

Finally, FIG. 10 shows a cable according to the invention with properties radiating high-frequency signals and self-supporting outer conductor. On the helix 34 surrounding the inner conductor 33 made of refractory material, the outer conductor 35 is supported, for. B. in the form of a closed and corrugated metal jacket. Since this metal jacket has radiation openings 36 which are subsequently, for. B. are produced by milling the crests on a surface line, according to the invention an additional layer 37 between the helix 34 and the outer conductor 35 Mica or coated glass fabric tapes are provided which, in closed form, prevent metal residues, which result from the production of the radiation openings 36, from penetrating into the space 38 between the inner conductor 33 and the outer conductor 35.

In a departure from the exemplary embodiments shown in FIGS. 8 to 10, the spacing molded articles according to FIGS. 5 to 7 can of course also be used instead of the refractory coils. It is essential for the invention that at elevated ambient temperatures, for. B. in the event of fire, the transmission of high-frequency signals is possible.

Claims (16)

Coaxial electrical high-frequency cable with a spacer arranged between the inner and outer conductors, characterized in that a profiled spiral is used as the spacer, which consists of glass or ceramic materials or contains these predominantly. Coaxial electrical high-frequency cable with a spacer arranged between the inner and outer conductors, characterized in that ceramic fittings are used as the spacer, which are held on the inner conductor by their shape. High-frequency cable according to claim 1, characterized in that the profile helix consists of stranded or braided single strands or threads. High-frequency cable according to claim 1 or 3, characterized in that the helix is braided. High-frequency cable according to claim 1, characterized in that the profile coil consists of a plurality of profile bodies made of glass or ceramic materials arranged one behind the other on a support. High-frequency cable according to claim 1 or one of the following, characterized in that the helix consists of a plurality of spherical or cylindrical profile bodies which are braided or wound with glass or ceramic threads. High-frequency cable according to Claim 2, characterized in that the shaped pieces are profile bodies which can be plugged on transversely to the inner conductor. High-frequency cable according to claim 7, characterized in that the profile bodies are hollow cylinders with longitudinal slots leading from the ends to the center and offset by more than 90 ° with respect to one another. High-frequency cable according to claim 2, characterized in that the shaped pieces are radially slotted disks. High-frequency cable according to claim 9, characterized in that the ends formed by the radial slot are offset in the axial direction of the inner conductor. High-frequency cable according to claim 2, characterized in that the shaped pieces are injection molded pieces completely surrounding the inner conductor. High-frequency cable according to Claim 1 or one of the following, characterized in that the spaces between the inner and outer conductors which are free from the spacers are completely or partially filled with an insulating material. High-frequency cable according to claim 12, characterized in that the insulating material is covered by a fire-proof film or a corresponding tape. High-frequency cable according to claim 1 or one of the following, characterized in that the spacers, profile helix or molded body, are enclosed by a plastic tube which is covered on the outside by a fire-resistant film or a corresponding tape. High-frequency cable according to claim 1 or one of the following, characterized in that the spacers, profile helix or molded body, is enclosed by a closed layer made of a refractory film or a corresponding tape. High-frequency cable according to claim 15, characterized in that the layer made of the refractory film or tape is enclosed by a self-supporting outer conductor in the form of a corrugated metal opening provided with openings.

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