WO2008138292A1 - Method for permanent connection of a first rf coaxial cable to a second rf coaxial cable - Google Patents

Abstract

A method is described for permanent connection of a first RF coaxial cable to a second RF coaxial cable, of which the first coaxial cable provides a hollow inner conductor and an outer conductor that is radially separated from the hollow inner conductor by a dielectric, and of which the second coaxial cable has an inner conductor with an inner conductor external diameter which is less than or equal to the internal diameter of the first hollow inner conductor, and an outer conductor, which is separated from the inner conductor by a dielectric and has an outer conductor diameter which is less than the outer conductor diameter of the outer conductor of the first coaxial cable. The method is distinguished by the following method steps: production of a freely accessible cross-sectional area in each case by the first and the second RF coaxial cable at which in each case the inner conductor, the dielectric and the outer conductor currently end, cutting the outer conductor and dielectric of the second coaxial cable to length relative to the inner conductor, and additionally cutting the dielectric to length relative to the outer conductor, thus resulting in the outer conductor projecting axially with respect to the dielectric, cutting the hollow inner conductor and the dielectric to length relative to the outer conductor of the first coaxial cable thus resulting in the outer conductor projecting axially with respect to the dielectric and the hollow inner conductor, provision of a dielectric adapter piece and axial joining of two coaxial cables such that, on the one hand, the inner conductor of the second coaxial cable is inserted into the hollow inner conductor of the first coaxial cable forming an electrical contact and such that the dielectric adapter piece makes contact between the dielectrics of the two coaxial cables, and deformation and joining of the projecting outer conductors of the two coaxial cables in order to produce at least an electrical connection between the two outer conductors.

Description

 A method for permanently connecting a first RF coaxial cable to a second RF coaxial cable

Technical area

The invention relates to a method for permanently connecting a first RF coaxial cable to a second RF coaxial cable, of which the first coaxial cable provides a hollow inner conductor and a radially spaced by a dielectric to the hollow inner conductor outer conductor and of which the second coaxial cable an inner conductor with an inner conductor outer diameter which is smaller than or equal to the inner diameter of the first hollow inner conductor, and an outer conductor spaced by a dielectric to the inner conductor, which has an outer conductor diameter which is smaller than the outer conductor diameter of the outer conductor of the first coaxial cable.

State of the art

To connect two RF coaxial cables are used in a conventional manner suitable prefabricated plug socket units, each electrically connected to the ends of the RF coaxial cable, ie the respective outer and inner conductor of a coaxial RF cable is in consideration of mutual electrical insulation on the plug side or on the socket side correspondingly provided line structures in the way of a clamping, soldering, adhesive or welded joint joined. However, such connectors raise both a material as well as labor-intensive and ultimately cost-intensive effort, which it is necessary to avoid for the production of a permanent connection between the at least two RF coaxial cables. For this purpose, in DE-OS 1 940 908 a plug or socketless connection technology between two RF coaxial cables has been proposed, in which the hollow respectively formed inner conductor of both coaxial cables are flush assembled via an inner conductor sleeve and soldered or welded together. The outer conductors of both coaxial cables to be connected in each case are reset in the connection region and are gripped from the outside by means of two composable, electrically conductive half shells and finally joined firmly by soldering or welding.

In DE-AS 2,222,440 a method for gas-pressure-proof connection of two coaxial high-frequency cable is described in which the respective ring-waved inner conductor of the axially opposite coaxial cables are brought into mutual overlap and connected to each other by means of brazing. The outer conductors of the respective coaxial cables have been correspondingly shortened in the connection region and have mutually parallel flanged edges, between which an annular cover is introduced, which is compressed by means of a suitably designed nut construction gas-tight with the flanged edges.

The known plugless, permanently formed connections between two RF coaxial cables has the disadvantage that specially trained and thus connection components are to stockpile, which must be integrated for the realization of the cable connection in a suitable manner as connecting or intermediate pieces between the end face opposite cable ends.

Presentation of the invention

The invention has the object of developing a method for permanently connecting a first RF coaxial cable with a second RF coaxial cable such that the realization of a permanent cable connection no additional or only minor components, but in their Design are simple and inexpensive, are required. So it is as fast as possible, cost-effective and permanently connect two RF coaxial cable, each with different cable diameter in a technically reliable manner. In particular, it should be possible to easily and safely perform the cable connection under difficult conditions, for example on construction sites.

Solutions to the problem underlying the invention are set forth in claims 1, 17 and 26. The methods according to the invention which advantageously provide further developments are the subject matter of the subclaims and the further description, in particular with reference to the exemplary embodiments.

According to the solution, a method for permanently connecting a first RF coaxial cable with a second RF coaxial cable, of which the first coaxial cable provides a hollow inner conductor and an outer conductor radially spaced by a dielectric to the hollow inner conductor and of which the second coaxial cable has an inner conductor with a Inner conductor outer diameter, which is smaller than or equal to the inner diameter of the first hollow inner conductor, and provided by a dielectric to the inner conductor spaced outer conductor having an outer diameter which is smaller than the outer conductor diameter of the outer conductor of the first coaxial cable, by the following method steps:

In a first step, it is necessary to create a freely accessible cross-sectional area at the two RF coaxial cables to be connected to one another, for example by separating the respective cables by a simple cut, whereby in each case the inner conductor, the dielectric as well as the outer conductor of the cable together the cut surface, which corresponds to the freely accessible cross-sectional area through the RF cable, end. For the preparation of each end free end, cross-sectional area, it is useful to use per se known cutting, squeezing or sawing tools that are as user-friendly as possible to handle. In addition, the individual differently dimensioned RF coaxial cables, each separated along a cross-sectional area, are to be prepared for permanent insertion or joining in the following manner:

The RF coaxial cable, which is smaller in cross section and corresponds to the second coaxial cable according to the above description convention, is first cut to length with respect to its outer conductor and the dielectric surrounding the inner conductor so that the unbacked inner conductor extends axially beyond the outer conductor and the dielectric , For this process, it is advantageously advisable to separate the outer conductor and the dielectric by a cut along the peripheral edge of the second RF coaxial cable with a depth of cut extending to the inner conductor from the rest of the coaxial cable and to remove the cut material axially along the remaining inner conductor. Thereafter, it applies the relative to the inner conductor recessed dielectric selective without affecting the inner and the remaining outer conductor to cut or ablate another piece axially, thereby forming an opposite to the dielectric axial projection of the outer conductor.

The additional material removal of the dielectric which is to be carried out selectively is preferably carried out by means of a peeling process, but it is also conceivable to use a heating medium which converts the dielectric, which is usually made of thermoplastic material, into a plastically flowable state in which the dielectric can be removed in a suitable manner. Of course, the specialist market further known Materialabtragetechniken are available to carry out the cable pre-fabricating outlined above.

Furthermore, it is the case in the cable diameter larger sized RF coaxial cable, which corresponds to the first Koaxialkabel according to the introduced formulation convention also prefabricated, starting from the already produced freely accessible cross-sectional area, at the respective hollow inner conductor, the dielectric and the outer conductor together end, the hollow one Inner conductor and the dielectric are cut to length by the same amount relative to the outer conductor, so that an axial projection of the outer conductor is formed relative to the relocating dielectric and hollow inner conductor. This Ablängvorgang can be done for example by means of an abrasive or machined Materialabtrages, especially since the hollow inner conductor of a metal, preferably aluminum or copper. In principle, other material removal methods known to the person skilled in the art are also available for this purpose. The aim is to form the first RF coaxial cable with an outer conductor projecting axially over the hollow inner conductor and the dielectric. In this case, it is particularly advantageous that, after cutting to length, the hollow inner conductor and the dielectric form a uniform inner, axially freely accessible, annular contact surface surrounding the outer conductor, which coincides with a cross-sectional plane through the HF coaxial cable.

Both of them would be connected by coaxial joining in the above-described pre-assembled RF coaxial cable in a manner in which the inner conductor of the second RF coaxial cable is inserted into the hollow inner conductor of the first RF coaxial cable, thereby establishing an electrical contact between both inner conductors Although the outer conductors would come into electrical contact with each other in axial superimposition and after corresponding radial deformation, the annular cut surfaces of the dielectrics provided in the interior of the respective coaxial cables would still be axially spaced apart from each other by appropriate cutting. Exactly this, between the two cut surfaces of the dielectrics of both RF coaxial cable limited space applies it with a dielectric transition piece, preferably completely filled, so that the transition piece comes in bilateral physical contact with each frontally facing dielectrics of both RF cables. The choice of shape and arrangement of the dielectric transition piece is made under the aspect of producing a substantially invariable characteristic impedance along the connection region between the two RF coaxial cables. For this purpose, on the one hand, there is an intimate contact, which is as complete as possible, between the annular end face the dielectric within the second coaxial cable with the dielectric transition piece to produce, on the other hand, however, it is also true as complete as possible intimate body contact between the dielectric transition piece and the equally annular end face of the dielectric within the first coaxial cable produce. Since the respective ring-shaped faces of the dielectrics of both RF cables have different ring diameters, it makes sense to form the dielectric transition piece conical or truncated cone, and this with two axially opposite different sized, annular shaped frustoconical surfaces, which are largely in shape and size are formed as accurately as possible to the respective end faces of the dielectrics within the interconnected RF cables.

The dielectric transition piece is preferably to be made of the same dielectric material that also constitutes the dielectric within the RF coaxial cables. It would be conceivable to fabricate the dielectric transition piece locally from those portions of material which are obtained by means of the above-described cable cuts with respect to the piecewise removal of the cable-side dielectric. Since the dielectric mostly consists of a moldable plastic material, it can possibly be shaped by additional heat treatment on site.

In most cases, as far as the shape, size and also the cable materials are concerned, it is possible to store standardized HF coaxial cables, to which, according to the solution, correspondingly prefabricated dielectric transition pieces can be stored. A correspondingly dimensioned transition piece is placed on the inner conductor of the second coaxial cable at the end before the mutual axial joining of the two prefabricated RF coaxial cables and is pushed in the correct position against the dielectric. Subsequently, both cables are pushed axially into each other until the dielectric transition piece establishes the above-described contact with the dielectrics of both RF coaxial cables, ie the dielectric transition piece touches the dielectrics of both coaxial cables on both sides intimately. Finally, it is necessary to deform or project the projecting outer conductor of both coaxial cables so that they come into mutual overlap and also into intimate contact. Since, as mentioned above, the RF coaxial cable to be interconnected have different sized cable diameter, it is the outer conductor of the smaller sized second coaxial cable funnel-shaped radially widen, whereas the protruding outer conductor of the larger-sized RF coaxial cable is funnel-shaped radially narrow inward, so that both outer conductors touch intimately. The operations concerning both the deformation and the mutual joining of the outer conductors of both RF coaxial cables is also advantageously supported by the frusto-conical outer surface of the inner dielectric transition piece by firmly pressing the outer conductors, usually made of ring-corrugated metal pipe, against the outer contour of the dielectric transition piece can. In addition, or finally, the outer conductors brought into overlap by means of a welding or soldering permanently permanently connected to each other, whereby also the junction experiences a kind of gas-tight seal. For further protection against external influences, the connection region can additionally be provided with a protective casing, for example in the form of a heat-shrinkable material consisting of heat-shrinkable material.

If the RF coaxial cables to be interconnected deviate too much from one another with regard to their diameters, it can at least not be ensured that electrical contact between the inner conductors of both coaxial cables is achieved merely by joining them together, as described above. In this case, an electrical contact means in the form of a metallic expansion element is placed on the free end of the inner conductor of the first coaxial cable to form the electrical contact after insertion of the inner conductor of the second coaxial cable to the free end of the inner conductor of the second coaxial cable uniformly conforms to the hollow inner conductor and thus produces the desired permanent electrical contact between both inner conductors. The provision as well as the Assembly costs for the electrical contact means represent only an insignificant additional expense, so that with the aid of the method according to the invention a cost-effective and in particular without further technical aids feasible connection technology for two RF coaxial cable is available.

The above statements provide for the substantial omission of additional components for the preparation of a connection between two different sized RF coaxial cable. On the other hand, another alternative method of connecting two RF coaxial cables in accordance with the solution provides an additional provision of a so-called outer conductor sleeve, by means of which the outer conductors of both RF coaxial cables, which are axially spaced from one another, can be brought into electrical contact with one another at their outer circumference. The preferably made of copper, aluminum or other electrically highly conductive material outer conductor sleeve is prefabricated in a suitable form, taking into account the different diameters of both to be joined together RF coaxial cable. Such outer conductor sleeve typically has two sleeve end sections axially spaced apart from one another by a conically or stepped transition region whose sleeve inner cross sections are respectively adapted to the outer dimensions of the coaxial cables to be connected to one another. By using such a prefabricated outer conductor sleeve, the material exceptions to be made separately for the production of axially projecting outer conductor regions, as described above, are not required. To connect two RF cables, it is only necessary, for example by means of a cutting, squeezing or sawing process, each produce a frontally freely accessible cross-sectional area of the RF coaxial cables to be joined together, where it is still necessary for the electrical contacting of Inner conductor quasi in the case described above in each smaller sized RF cable, ie the second coaxial cable, cut off the outer conductor and the dielectric together to obtain a frontally projecting inner conductor section, by axial joining in the hollow inner conductor of the first coaxial cable for purposes of electrical Contacting can be inserted. The axially non-overlapping in the assembled state outer conductor of both coaxial cables, which are also due to the existing between two RF coaxial cross-section jump radially spaced from each other, are electrically contacted by the above-designated, additionally provided outer conductor sleeve and interconnected. The contact surfaces existing between the outer conductor sleeve and the respective outer conductor regions are additionally provided for producing a permanent connection by means of welding or soldering technology. It would also be conceivable, however, to detachably connect the outer conductor sleeve to the outer conductor of both HF coaxial cables. For example, this could serve a threaded connection between the outer conductor sleeve and the Außenleitem.

Likewise, it makes sense to provide a dielectric transition piece between the two coaxial cables, which is as it were radially encompassed by the outer conductor sleeve in the assembled state. Alternatively, it is also possible to form the dielectric transition piece in the form of a perforated disc, which is pushed onto the front side of the dielectric of the second RF coaxial cable and in the joined state, the dielectric transition piece can be formed in the same manner as in the above-described method Dielectric of the first RF coaxial cable contacted. The transition region of the outer conductor sleeve is preferably stepped in this case, so that the outer conductor sleeve fits snugly against the outer contour of the perforated disc. Further details can be found in the relevant embodiments with reference to the figures shown below.

Finally, investigations have shown that a permanent connection between two differently dimensioned RF coaxial cables with quite acceptable electrical transition properties can be realized when, on the one hand, the inner conductors are brought into contact with each other in the manner described above, and, on the other hand, the dielectrics of both coaxial cables facing each other However, without any dielectric transition piece at least in places touch directly and ultimately an electrical Connection between the outer conductors of both RF coaxial cables is made by appropriate assembly of their outer conductor such that they have after having a mutual axial overlap region, along which the outer conductors can be firmly connected to each other by means of a soldered or welded connection. In order to achieve an adapted characteristic impedance for a low-loss or attenuation-free RF signal transmission along the connection region in this connection technology, it is appropriate to form the outer conductor or conductors in the transition region between the two RF coaxial cables in a suitable manner. Preferably, a correspondingly large gap between the outer conductor in the transition region and the end face of the end face of the dielectric of the respective larger-sized RF cable is enclosed for impedance matching.

The further description, which refers to the exemplary embodiments illustrated in the figures, is intended to show possible connection variants, all of which can be subsumed under the uniform solution concept, as described above.

Brief description of the invention

The invention will now be described by way of example without limitation of the general inventive idea by means of embodiments with reference to the drawings. Show it:

Fig. 1a to d longitudinal sectional views through interconnected coaxial cable according to the method according to the solution, Fig. 2 a, b longitudinal sectional views through interconnected coaxial cable by means of outer conductor sleeve and Fig. 3 longitudinal sectional views through interconnected coaxial cable by merely connecting the outer conductor. Ways to carry out the invention, industrial usability

In the schematic longitudinal sectional images according to the figures. 1a to d, in each case, the connection region between two coaxial cables 1, 2 is shown, which have been connected by the method according to the invention. In all the longitudinal sections shown, the introduced reference numbers each refer to the same components, so that in order to avoid repetition, the longitudinal sectional view of FIG. 1a is described in detail, to which reference can be made for further interpretation of the longitudinal sectional views of FIG. 1 b to 1 d ,

In Fig. 1a, the connection region between two differently dimensioned diameter RF coaxial cable 1, 2 is shown. It is assumed that the RF coaxial cable 1 larger in cross-section extends to the left side, whereas the smaller in cross-section dimensioned RF coaxial cable 2 extends to the right side of the image display. Both RF coaxial cables typically each have a metallic outer conductor 11, 21 which, in the exemplary embodiment shown, is in each case annularly corrugated. Inside, the RF coaxial cables 1, 2 each provide a dielectric 13, 23, which respectively surrounds an inner conductor 12, 22 lying inside. In the case of the larger-sized RF coaxial cable 1, the inner conductor is formed as a hollow inner conductor 12, whereas the inner conductor 22 of the smaller-sized RF coaxial cable 2 may be formed solid. Both RF coaxial cables 1, 2 may additionally be surrounded by a sheath, not shown, for protection against external influences, which apply to the production of the connection between the two RF coaxial cables at least end to remove each cable.

In order to produce the connection between the two RF coaxial cables 1, 2 shown in FIG. 1a, it is necessary to pre-assemble them correspondingly at their end faces to be joined together. In the simplest case, the RF coaxial cable with a cutting blade or a corresponding equivalent cutting or cutting tool is used to produce the required for the connection free cable ends cut through, so that in each case a free cross-sectional area is obtained by the cable to which the outer conductor, the dielectric and the inner conductor ends flush.

For further pretreatment of the first coaxial cable 1, it is necessary to process the free cable end such that the hollow inner conductor 12 as well as the dielectric 13 with respect to the end face outer conductor 11 is cut to length axially, i. be shortened. The geometric dimension with which the cutting is made basically depends on the size ratios of the RF coaxial cable 1, typically the dielectric 13 and the hollow inner conductor 12 are set back relative to the outer conductor 11 by several millimeters up to a few centimeters. It can be seen from the longitudinal sectional view of FIG. 1 that, once cut to length, the dielectric 13 and the hollow inner conductor 12 terminate at a common cross-sectional plane through the RF coaxial cable 1, i. the dielectric 13 has a flat, annular end face 122, on which also the hollow inner conductor 12 opens at the end.

In contrast to the prefabrication of the cable end on the first RF coaxial cable 1, the second RF coaxial cable 2, starting from a running perpendicular to the longitudinal axis of the cable common interface, in which the outer conductor 21, the dielectric 23 and the inner conductor 22 frontally open together, first cut to length with respect to the outer conductor 21 and the dielectric 23, in order to obtain in this way an inner conductor 22 projecting axially over the RF coaxial cable 2. In a subsequent step, the dielectric 23 is cut to length relative to the outer conductor 21, so that the outer conductor 21 extends axially beyond the dielectric 23.

In order to connect the cable ends of the RF coaxial cables 1, 2, which have been prefabricated in the above manner, both electrically and mechanically permanently, the connection having as negligible a damping as possible to an HF wave guided through the RF coaxial cable, it is important to consider the characteristic impedance of the transition region to those of the RF coaxial cable adapt. For this purpose, it is necessary to bring the end surfaces 131 and 231 of the dielectrics 13, 23, which have different dimensions in the cross-sectional area, into intimate mutual physical contact. 1 a, a dielectric transition piece 3 is provided between the end faces 131 and 231, which is preferably made of the same dielectric material from which the dielectrics 13, 23 of the RF coaxial cables 1, 2 are made. The dielectric transition piece 3 is truncated cone-shaped and has a shape and size of the end face 231 modeled truncated cone 31 and a ring-shaped end face 131 largely reproduced annular frustum surface 32. In addition, the transition piece 3 has a conically shaped lateral surface 33, which, as will be described below, serves as a support surface for the outer conductors 11, 21 to be connected to one another.

Before the aforementioned prefabricated RF coaxial cable ends are joined together, it is the dielectric transition piece 3, which has a central recess which is adapted to fit the cross section of the inner conductor 22, to slide along the inner conductor 22 in the position shown in Figure 1a in which the truncated cone surface 31 directly adjoins the annular end face 231 of the dielectric 23. Furthermore, an electrical contact means 4 designed as an expansion element is placed on the free end of the inner conductor 22, which ensures a secure contact with the hollow inner conductor 12. Now only the joining of the two end-fitted cable ends of the RF coaxial cable 1, 2 takes place such that the inner conductor 22 opens into the interior of the hollow inner conductor 12, wherein the electrical contact means 4 resiliently hugs against the inner wall of the hollow inner conductor 12. Furthermore, there is an intimate physical contact of the dielectric transition piece with the end face 131 of the dielectric 13, so that a materially largely continuous transition between the dielectric 23 via the dielectric transition piece 3 to the dielectric 13 is created.

The respective projecting ends of the outer conductors 11, 21 are deformed in the manner shown in Fig. 1a and along the lateral surface 33 of the dielectric Transition piece 3 brought into mutual contact. For this purpose, the outside of the RF coaxial cable 1 outer conductor 11 is annularly formed radially inwardly, whereas the corresponding superior outer conductor of the RF coaxial cable 2 is radially expanded annularly. In the case of the embodiment shown in FIG. 1a, both outer conductors 11, 21 abut against each other along the lateral surface 33 without mutual overlap. For safe and firm connection of both outer conductors 11, 21, the joint seam is welded accordingly to produce a permanent electrical connection between the two outer conductors 11, 21. Moreover, the weld also represents a gas-tight connection form, which is able to protect the interior of the cable connection from external influences.

Finally, a protective sheathing 5 is applied around the connection region, for example in the form of a known per se, consisting of thermoplastic material shrink tube.

The further exemplary embodiments according to FIGS. 1 b to 1 d differ from the connection point described in FIG. 1 a by the differently shaped shape and connection of the outer conductors 11, 21 coming into contact along the outer surface 33 of the dielectric transition piece 3.

Thus, according to the embodiment in Fig. 1b, the adjacent end faces of the outer conductors 11, 21 are deformed to form a respective flanged edge 6 and brought into mutual contact. For permanent connection, the flanged edges of both outer conductors 11, 21 are also welded as in the above-described embodiment of FIG. 1a.

According to the longitudinal sectional illustration in FIG. 1c, the front ends of the outer conductors 11, 21 along the lateral surface 33 of the dielectric transition piece 3 undergo an interlocking fold 7, which are soft soldered to form a permanent connection. In Fig. 1d, the ends of the outer conductor 11, 21 along the lateral surface 33 of the dielectric transition piece 3 slightly in mutual overlap and are also soldered soft.

The further description with reference to FIGS. 2 a and b also refers to previously introduced reference numerals, which in each case designate components whose already described function, in order to avoid repetitions, will not be explained again.

Thus, the longitudinal sectional representations according to FIGS. 2a and b respectively show the connection region between the two coaxial cables 1 and 2 arranged together. In FIG. 2a, the first coaxial cable 1 is cut off smoothly at its end, i. the outer conductor 1, the dielectric 13 as well as the hollow inner conductor 12 end face in a common cross-sectional plane. In contrast, the second coaxial cable 2 has a common frontal cross-sectional area, at which the dielectric 23 and the outer conductor 21 terminate together. Opposite this cross-sectional plane of the inner conductor 22 projects beyond the embodiments of the above-described connection possibilities and opens into the interior of the hollow inner conductor 12 of the first coaxial cable.

For the largest possible physical contact between the dielectrics 13, 23 of both coaxial cable is already described a dielectric transition piece 3, as described above, is provided. In contrast to the embodiments described above, an outer conductor sleeve 8 contacts both axially and radially spaced outer conductors 11, 21. For this purpose, the outer conductor sleeve 8 encloses the formed with different diameters outer conductor 11, 21 of both RF coaxial cable 1, 2. In between transition region has the outer conductor sleeve 8 has a conically shaped transition region, which rests as flush as possible on the likewise conical side flank 33 of the transition piece 3. The outer conductor sleeve 8 is made of a highly electrically conductive metallic material, preferably copper or aluminum and to form a permanent connection between the two RF coaxial cables soldered or welded to the respective outer conductor portions of the RF coaxial cable. In addition, the connection point together with outer conductor sleeve 8 is surrounded by a protective casing 5, for example in the form of a heat-shrinkable tube.

In the embodiment according to FIG. 2b, the outer conductor sleeve 8 has a stepped transition region and, moreover, has the same end-to-end configuration as the previously described exemplary embodiment with its outer sleeve sections, for example by way of a soldered or welded connection.

In contrast to the embodiment of FIG. 2a, the outer conductor sleeve 8 is stepped in the transition region between the cut end faces of both RF coaxial cables 1, 2. Furthermore, the axially opposite end faces of the dielectrics 131, 231 of both RF coaxial cables 1, 2 abut with an at least minimum radial overlap 10 immediately without providing a dielectric transition piece. The stepped contour of the outer conductor sleeve 8 encloses with the dielectrics of both RF coaxial cables 1, 2 a defined volume 9, which is dimensioned and shaped under as favorable as possible inductive and capacitive electrical conditions, i. Due to the stepped shaping of the outer conductor sleeve 8, transition impedance ratios can be created which ensure as low-loss or even loss-free signal transmission along the transitional area. All other measures are identical to those of the embodiment described above and therefore require no repetition.

In the embodiment shown in FIG. 3, the end faces of the dielectrics 131 and 231 of both RF coaxial cables 1, 2 also meet as in the embodiment described above. Fig. 2 b with a minimum radial overlap 10 directly together. However, in the case of FIG. 3, no outer conductor sleeve is provided. Rather, in this case, the outer conductor 11 of the first RF coaxial cable 1 projects beyond the cut-to-length regions of the dielectric 13 and of the hollow inner conductor 12 such that the overhanging part of the outer conductor 11 axially overlaps the outer conductor 21 of the second coaxial cable after joining both RF coaxial cable. Thus, both outer conductors 11, 21 can be brought into direct contact with each other and soldered or welded to produce an intimate, permanent connection.

In the deformation of the protruding part of the outer conductor 11 of the first coaxial cable 1, it is particularly important to ensure that electrical, ie capacitive and inductive conditions are created so that a nearly lossless RF signal transmission between the two contacted coaxial cables is possible. To ensure this, a kind of perforated disc 14 of dielectric material is pushed over the end of the dielectric 23 of the second RF coaxial cable 2, which on the one hand ensures large-area physical contact between the two dielectrics 13, 23 and also a support surface for the outer conductor to be deformed 11 offers that hugs the outer contour of the perforated disc 14 from the outside. It is helpful for the front-side sliding of the perforated disc 14 on the dielectric 23 of the second RF coaxial cable 2, when the outer conductor 21 of the second RF coaxial cable 2 is cut somewhat frontally.

LIST OF REFERENCE NUMBERS

, 2 RF coaxial cables 1,21 outer conductor 2 Hollow inner conductor

Inner conductor, 23 Dielectric 1,231 Annular surface of the die

Dielectric transition piece 1.32 Ring-shaped frustoconical surface

lateral surface

Electrical contact agent

protective sheathing

flanging

fold

Outer conductor sleeve

volume

Radial overlap

perforated disc

Claims

claims

A method for permanently connecting a first RF coaxial cable to a second RF coaxial cable, the first coaxial cable providing a hollow inner conductor and an outer conductor radially spaced by a dielectric to the hollow inner conductor, and the second coaxial cable having an inner conductor with an inner conductor outer diameter, which is smaller than or equal to the inner diameter of the first hollow inner conductor, and provides an outer conductor spaced apart by a dielectric from the inner conductor, which outer conductor diameter is smaller than the outer conductor diameter of the outer conductor of the first coaxial cable, characterized by the following method steps:

Producing a freely accessible cross-sectional area in each case by the first and second RF coaxial cable to the respective inner conductor, the dielectric and the outer conductor ends together, cutting the outer conductor and dielectric of the second coaxial cable relative to the inner conductor and additional cutting of the dielectric relative to the outer conductor, so in that an axial projection of the outer conductor is produced in relation to the dielectric,

Cutting the hollow inner conductor and the dielectric relative to the outer conductor of the first coaxial cable, so that an axial projection of the outer conductor is formed, as compared with the dielectric and the hollow inner conductor,

Providing a dielectric transition piece and axially joining both coaxial cables such that on the one hand the inner conductor of the second coaxial cable is inserted into the hollow inner conductor of the first coaxial cable to form an electrical contact, and that the dielectric transition piece between the dielectrics of both coaxial cables is brought into abutment, and Deforming and joining the projecting outer conductor of both coaxial cables for producing at least one electrical connection between the two outer conductors.

2. The method according to claim 1, characterized in that the production of the freely accessible cross-sectional areas by means of a cutting, crushing or sawing takes place at one point along the two coaxial cables.

3. The method of claim 1 or 2, characterized in that the cutting to length of the outer conductor and the dielectric of the second coaxial cable relative to the inner conductor is such that the inner conductor extends axially beyond the dielectric axially than the outer conductor.

4. The method according to any one of claims 1 to 3, characterized in that the cutting to length of the hollow inner conductor and the dielectric relative to the outer conductor of the first coaxial cable is such that the inner conductor and the dielectric are the end face in a common cross-sectional plane of the first coaxial cable.

5. The method according to any one of claims 1 to 4, characterized in that the cutting of the dielectric in the second coaxial cable is such that the dielectric is the end face in a cross-sectional plane of the second coaxial cable.

6. The method according to any one of claims 1 to 5, characterized in that after the cutting to length of the outer conductor and dielectric of the second coaxial cable relative to the inner conductor, the inner conductor forms a free end, via which an electrical contact means is joined.

7. The method according to claim 6, characterized in that as electrical contact means, a metallic expansion element is used, which inwardly spreads after insertion of the inner conductor of the second coaxial cable in the hollow inner conductor of the first coaxial cable to form the electrical contact to the hollow inner conductor.

8. The method according to any one of claims 5 to 7, characterized in that the cutting of the dielectric in each case takes place on both coaxial cables such that after the axial joining of both coaxial cables, the end faces of the dielectrics of both coaxial cables have an axial distance from each other.

9. The method according to any one of claims 5 to 8, characterized in that the end faces of the dielectrics of both coaxial cables each have an annular end face, wherein the end face of the first coaxial cable assignable ring diameter is greater than that of the second coaxial cable assignable end face, and that dielectric transition piece is formed and provided such that the axially opposite end faces are at least partially covered on both sides of the dielectric transition piece.

10. The method according to claim 9, characterized in that as a dielectric transition piece from a dielectric material, truncated cone-shaped molded body is selected with an axial recess, the front side has two annularly formed frustoconical surfaces, of which those frustoconical surface with the smaller ring cross-section largely the shape and size of the end face of the dielectric of the second coaxial cable corresponds.

11. The method according to any one of claims 1 to 10, characterized in that the dielectric transition piece from that dielectric material is formed, which is obtained by means of the cutting of the dielectric from at least one of the two coaxial cables.

12. The method according to any one of claims 1 to 11, characterized in that the deformation and joining of the projecting outer conductor of both coaxial cable is carried out by mutual application of the outer conductor along an outer contour predetermined by the dielectric transition piece.

13. The method according to any one of claims 1 to 12, characterized in that the deforming and joining the projecting outer conductor of both coaxial cable is performed by mutual application of the outer conductor such that the protruding outer conductor of the second coaxial cable radially spread in a funnel shape and the protruding outer conductor of the first coaxial cable is narrowed funnel-shaped radially.

14. The method according to any one of claims 1 to 13, characterized in that the deformation and joining of the projecting outer conductor of both coaxial cables by mutual folding or crimping of the outer layer placed in Au ßenleiterenden done.

15. The method according to any one of claims 1 to 14, characterized in that the outer conductor ends of both coaxial cables brought in axial overlap or blunt axially joined together and are brought by means of soldering welding technology in a permanent at least electrical connection.

16. The method according to any one of claims 1 to 15, characterized in that after producing the at least one electrical connection between the two outer conductors they are surrounded by a protective coating.

17. A method for permanently connecting a first RF coaxial cable to a second RF coaxial cable, of which the first coaxial cable provides a hollow inner conductor and an outer conductor radially spaced by a dielectric to the hollow inner conductor and of which the second coaxial cable has an inner conductor with an inner conductor outer diameter, which is smaller than or equal to the inner diameter of the first hollow inner conductor, and provides an outer conductor spaced apart by a dielectric from the inner conductor, which outer conductor diameter is smaller than the outer conductor diameter of the outer conductor of the first coaxial cable, characterized by the following method steps:

Producing a freely accessible cross-sectional area in each case by the first and second RF coaxial cable, in each case the inner conductor, the

Dielectric and the outer conductor end together,

Cutting the outer conductor and dielectric of the second coaxial cable relative to the inner conductor, so that with respect to the dielectric and the

Outer conductor creates an axial projection of the inner conductor,

Providing an outer conductor sleeve axial joining of both coaxial cable such that on the one hand, the inner conductor of the second coaxial cable in the hollow inner conductor of the first

Coaxial cable is introduced to form an electrical contact, and that the outer conductor sleeve projects axially beyond both the outer conductor of the first and the second coaxial cable, and

Add the outer conductor sleeve such that both outer conductor over the

External conductor sleeve enter an electrical connection.

18. The method according to claim 17, characterized in that the production of the freely accessible cross-sectional areas by means of a cutting, squeezing or sawing takes place at one point along the two coaxial cables.

19. The method according to claim 17 or 18, characterized in that the outer conductor sleeve each two provided by a conical or stepped transition region axially spaced sleeve end portions, each having a sleeve inner cross section, one of which the outer conductor cross section of the first coaxial cable and the other the outer conductor cross section corresponds to the second coaxial cable, and that prior to the axial joining a dielectric transition piece between the freely accessible cross-sectional areas of both coaxial cables is introduced such that the dielectric transition piece between the dielectrics of both coaxial cables is brought into abutment.

20. The method according to any one of claims 5 to 8, characterized in that the end faces of the dielectrics of both coaxial cables each having an annular end face, wherein the end face of the first coaxial cable assignable ring diameter is greater than that of the second coaxial cable assignable end face, and that dielectric transition piece is formed and provided such that the axially opposite end faces are at least partially covered on both sides of the dielectric transition piece.

21. The method according to claim 20, characterized in that as a dielectric transition piece from a dielectric material, truncated cone-shaped molded body is selected with an axial recess, the front side opposite two annular frusto-conical surfaces, of which those frustoconical surface with the smaller ring cross-section largely the shape and size of the end face of the dielectric of the second coaxial cable corresponds.

22. The method according to any one of claims 19 to 21, characterized in that the dielectric transition piece is formed from that dielectric material, which is obtained by means of the cutting of the dielectric from at least one of the two coaxial cables.

23. The method according to any one of claims 17 to 19, characterized in that the outer conductor sleeve each two provided by a stepped transition region axially spaced sleeve end portions, each having a sleeve inner cross section, one of which the outer conductor cross section of the first coaxial cable and the other the outer conductor cross section of the second coaxial cable, and in that the stepped transition region of the outer conductor sleeve is shaped and dimensioned such that the outer conductor sleeve encloses a volume, preferably air volume, with the dielectrics of both coaxial cables.

24. The method according to any one of claims 17 to 23, characterized in that after the cutting to length of the outer conductor and dielectric of the second coaxial cable relative to the inner conductor, the inner conductor forms a free end, via which an electrical contact means is joined.

25. The method according to claim 24, characterized in that a metallic expansion element is used as the electrical contact means, which inwardly spreads after insertion of the inner conductor of the second coaxial cable in the hollow inner conductor of the first coaxial cable to form the electrical contact to the hollow inner conductor.

26. A method of permanently connecting a first RF coaxial cable to a second RF coaxial cable, the first coaxial cable providing a hollow inner conductor and an outer conductor radially spaced by a dielectric to the hollow inner conductor, and the second coaxial cable having an inner conductor with an inner conductor outer diameter, which is less than or equal to the inner diameter of the first hollow inner conductor, and one through Dielectric to the inner conductor spaced outer conductor provides, the one

Outer conductor diameter, the smaller the outer conductor diameter of the

Outer conductor of the first coaxial cable, characterized by the following method steps:

Producing a freely accessible cross-sectional area in each case by the first and second RF coaxial cable to the respective inner conductor, the dielectric and the outer conductor ends together, cutting the outer conductor and dielectric of the second coaxial cable relative to the inner conductor, so that with respect to the dielectric and the outer conductor Axial projection of the inner conductor is formed, cutting the hollow inner conductor and the dielectric relative to the outer conductor of the first coaxial cable, so that a with respect to the dielectric and the hollow inner conductor axial projection of the outer conductor, axial joining of both coaxial cable such that on the one hand, the inner conductor of the second coaxial cable in the hollow inner conductor of the first coaxial cable is introduced to form an electrical contact, and that the protruding outer conductor of the first coaxial cable axially overlaps with the outer conductor of the second coaxial cable, and joining both outer conductor dera rt that the protruding outer conductor of the first coaxial cable from the outside contacts the outer conductor of the second coaxial cable.

27. The method according to claim 26, characterized in that prior to the joining of both coaxial cable frontally on the dielectric of the second coaxial cable, a kind of perforated disc of dielectric material is added, which produces an intimate physical contact between the dielectrics of both coaxial cable after joining both coaxial cable.

28. The method according to claim 27, characterized in that the perforated disc has an outer contour, which serves as a support surface for deforming the outer conductor of the first coaxial cable and to which the outer conductor of the first coaxial cable in the transition region is flush.