FR2916089A1 - Connector e.g. male connector, for e.g. global system for mobile communication network, has arms presenting diameter higher than internal diameter of core such that insertion of core provokes bending of arms and radial stress of arms' ends - Google Patents

Abstract

The connector (48) has a connection element with an intermediate conductive piece connected with a male/female contact terminal (22) of an internal conductor assembly. The piece has flexible arms (66) and a central region that is housed in an axial region of an inelastic clamp (50). The arms present a diameter higher than internal diameter of a cylindrical hollow core (14) of a coaxial cable (12) such that insertion of the core provokes bending of the arms during penetration of the arms in the core and punctual radial stress of ends of the arms against opposite surfaces of the core.

Description

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  The invention relates to connectors for mounting at the end of a hollow core coaxial cable. Coaxial cables with hollow core are used in particular in the field of radiotelephony (GSM, UMTS, etc.) for the connection of equipment relay stations and other organs of terrestrial and aerial parts of the network. They are also used in other applications, for example for cable television networks. All these connectors, whether male or female, have a side called "interface side" corresponding to their free end intended to come plug on another connection member (connector or base), and an opposite side or "side cable "which is that of the end of the coaxial cable where they are mounted. A soul can be full (for smaller diameters) or hollow. The hollow core makes it possible, besides economy of material, to give a larger diameter to the core, which ensures a good centering of the latter in the dielectric despite external constraints, in particular due to the various expansions experienced by the cable. In addition, a hollow core may itself be smooth or helical, the latter form ensuring better mechanical strength of the core and a better adaptation from the point of view of radio frequencies. In the case of a solid core, the core of the cable is mounted on the inner conductor of the connector by crimping, brazing or clamping. But these techniques are not usable on a hollow soul. To establish the connection with the inner conductor of the connector, the technique generally used is to introduce an insert into the hollow core. This insert is generally in the form of a turned part or "clamp" of bronze or other suitable noble alloy, with a cylindrical body whose outer diameter corresponds to the inner diameter of the hollow core to allow a close fit between these two rooms. The body is split axially so as to define a plurality of parallel fingers capable of radial flexion when the clamp is introduced into the hollow core. As the quality of the contact between the inner conductor of the connector and the central core directly conditions the radioelectric performance of the connection, especially in terms of intermodulation product,

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  it is necessary to have a very strong point contact between the fingers of the clamp and the inner surface of the hollow core. With a smooth core, this contact is along generators, but with a helical core it is made in a pointwise manner between localized points of the top of the helical profile. To be certain of a good contact, it is therefore important to ensure it for a sufficient length, which leads to a relatively large size clamp, with correlatively affect the size and size of the connector. It is also necessary, in order to have good radio performance, that the contact be established as close as possible to the end of the coaxial cable, and maintained in spite of the various stresses, in particular of expansion, that the The connector may be damaged after mounting on the end of the coaxial cable. To further promote the electrical contact, it is possible to provide a knurling, and an elastic prestressing outwardly of the fingers of the clamp. It will be understood that the machining of the clamp and its mechanical properties are critical elements to achieve the desired performance from the radio point of view. These parts that must be machined with great care obviously have a significant impact on the cost of the connector. Another difficulty lies in the fact, particularly with smooth-core coaxials, that for the same type of cable, the inside diameters of the core can vary from one manufacturer to another. These differences, which go beyond simple manufacturing tolerances, require the provision of as many different clamps as inner diameters. In other words, the connector is not universal and it will be necessary to machine clamps with a different dimensioning according to the cable supplier, with here again a significant impact on the total cost of the connector. All these constraints require a clamp which is a relatively expensive element of the connector: low-profile part, use of specific alloys, control of the elasticity of the fingers, specificity of the clamp for a given type of cable, etc. The invention proposes a new type of connector for coaxial cable hollow core, indifferently smooth or helical, which overcomes all the disadvantages that have just been exposed.

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  The connector of the invention is of the general type, in itself known, comprising: an inner conductive assembly, comprising interface side a contact pin, male or female, and cable side an element of electrical connection to the soul coaxial cable; and an outer conductor metal body including a cavity housing the inner conductive assembly, and means for electrically contacting the ground conductor of the cable and mechanically mooring the cable to the connector. The electrical connection element at the core of the coaxial cable comprises a clamp capable of being introduced into the hollow core of the coaxial cable and comprising a cylindrical body having a diameter substantially corresponding to the inside diameter of the hollow core of the coaxial cable for allow the recess inside the latter, the cylindrical body being shaped with a plurality of parallel fingers extending axially cable side.

  In a characteristic manner of the invention, the connecting element further comprises a conductive intermediate piece in electrical connection with the contact pin of the inner conductive assembly. This intermediate piece comprises a central region, housed in the axial region of the clamp, and a plurality of arms adjoining the central region. These arms extend radially therefrom through the gaps between the fingers of the clip, protruding radially beyond the body of the clip. They are flexible and have in the free state an overall diameter greater than the inner diameter of the hollow core of the coaxial cable. In this way, the insertion into the hollow core of the assembly formed by the body and the intermediate part causes a deflection of the arms during their penetration into the hollow core, and the point radial stress of the ends of these arms against surfaces vis-à-vis the hollow core. According to various advantageous subsidiary features of the invention: the clamp is a substantially inelastic piece; the radially projecting arm portion has a curvature directed in a direction opposite to the cable side; the arms comprise a proximal region oriented radially, protruded by a curved median region and terminated by an axially oriented distal region; the clamp comprises a shoulder of diameter greater than the diameter of the core of the coaxial cable, to allow the insertion into the hollow core of the assembly formed by the body and the intermediate piece up to the stop of the shoulder against the free end face of the coaxial cable core; preferably, the central region of the intermediate piece then extends substantially in a plane offset from the plane of the shoulder, so that the end of the arms, in the bent configuration, does not go beyond the plane the shoulder; the overall diameter of the arms is smaller than the diameter of the shoulder of the body of the clamp; the inner conductive assembly further comprises means for electrical and mechanical connection of the central region of the intermediate part with the contact pin; the arms are angularly distributed uniformly; The intermediate piece comprises four to ten arms, preferably six or eight arms; the material of the intermediate piece is an alloy of bronze or cuproberyllium. An embodiment of the device of the invention will now be described with reference to the appended drawings in which the same reference numerals designate identical or functionally similar elements from one figure to another. FIG. 1 is a longitudinal sectional view, in an axial plane, of a known type connector mounted at the end of a coaxial cable with a smooth hollow core. Figure 2 is a longitudinal sectional view, in an axial plane, of a connector according to the invention. FIG. 3 is an exploded perspective view illustrating the manner in which the essential components of the connector of the invention illustrated in FIG. 2 are arranged, at its end at the end of a helical hollow core coaxial cable. FIG. 4 is a partial longitudinal sectional view in an axial plane showing the manner in which the clamp and the intermediate contact piece according to the invention provide contact with the helical hollow core of a coaxial cable. Figure 5 shows in isolation, in perspective, the clamp and the conductive intermediate piece of the invention, mounted one in the other. Figure 6 shows in isolation, in perspective, the conductive intermediate part of the invention.

  FIG. 1 is a longitudinal section through an axial plane of a known type connector mounted at the end of a coaxial cable with a hollow cylindrical core. The connector 10 is mounted at the end of the coaxial cable 12, which comprises a cylindrical hollow core 14, smooth in this example, and an outer conductor of mass 16 annealed, with a dielectric 18 interposed between the central core 14 and the ground conductor 16. The cable also comprises an insulating sheath 20 covering the ground conductor 16. The end of the cable introduced into the connector has been cut in a radial plane, and stripped (unlike a coaxial core full, the core 14 does not protrude beyond the plane of section). The connector has interface side (on the left in the figure) a contact pin 22, which can be male or female. This is mounted on an inner conductor 24 terminated in the form of clamp cable side (right in the figure). The clamp, which is made of an elastic material such as a bronze or other specific alloy, comprises a plurality of elastic fingers 26 defined by slots 28 formed in the cylindrical body of the clamp 24. It is introduced into the hollow core so that the fingers 26, because of their elasticity, exert a radial support against the inner surface 32 of the core 14. To reinforce this point contact, it is possible to subject the fingers 26 to a prestress during the manufacture of the clamp, and provide a knurling of the outer surface of the clamp which will come into contact with the wall of the hollow core. The ground contact is established by the metal body 30 of the connector, separated from the central conductor by a dielectric 34. The contact with the ground conductor 16 of the coaxial cable is provided, on the cable side, by a

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  split ring 38 of "chimney" type (also visible in FIG. 2) cooperating with a shoulder 40 formed on the rear ring 42 of the connector. This ring 38 is mounted on the body 30 by screwing at 44. A seal 46 also ensures the sealing of the connector vis-à-vis the outside environment. The screwing of the rear portion 42 moves the shoulder 40 axially relative to the body 30, which has the effect of pinching the fingers of the ring 38 against the outer surface of the ground conductor 16. The invention proposes to overcome disadvantages related to the central clamp 24, 10 drawbacks that have been discussed above in the introduction of the present application. The connector of the invention has the structure illustrated in FIGS. 2 to 6, where the identical or functionally equivalent elements bear the same references as in the case of FIG. 1, in particular as regards the establishment of contact with the driver of the mass of the coaxial cable (which is not part of the present invention). On the other hand, the invention will be explained by taking as an example a coaxial cable helical hollow core, whose profile is visible in particular Figures 3 and 4, but it will be understood that the invention applies both to a smooth core cable. On the cable side, the connector 48 of the invention comprises, like the connector 10 of the prior art, an insert 50 in the form of a clamp comprising a cylindrical body 52 provided with longitudinal slots 54 extending in a generally axial direction, so as to define a plurality of fingers 56 adapted to be inserted into the hollow core 14 of the coaxial cable (as illustrated in FIGS. 3 and 4). On the interface side, the clamp 50 comprises a shoulder 58, with a diameter greater than the diameter of the core 14 of the coaxial cable, so as to abut against the end face 60 (FIGS. 3 and 4) of the core 14 of the cable 30 coaxial. Unlike the clip 24 of the prior art connector shown in FIG. 4, the clip 50 of the invention connector has no elastic function.

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  It can therefore be made in a relatively ordinary material from the point of view of its mechanical properties, so inexpensive, for example brass. The elastic function is provided by a piece 62 (shown in combination with the clip in FIGS. 2 to 5, and in isolation in FIG. 6). This conductive intermediate piece comprises an annular central region 64, intended to be housed inside the cylindrical body 52 of the clamp 50. The part 62 also comprises a plurality of arms adjoining the central region and extending radially from this through the notches 54 formed between the different fingers 56 of the clamp 50, projecting radially beyond the body of the clamp, as shown in particular in Figure 5. The arms 66 of the intermediate piece 62 are re angularly distributed in the same way as the notches 54, so as to cross the latter, and are for example six in number or eight. The intermediate piece 62 is provided with a central opening 68 allowing, after insertion into the clamp 50, to fix it by means of a central screw 70 to an axial element 72 of the inner conductive assembly, electrically and mechanically connected to the contact pin 22 (see Figure 4, in particular). Unlike the clamp 50 which has no elastic function, the intermediate piece 62 is an elastic piece made of a suitable material such as bronze or cuproberyllium. But its simple shape makes it all the time much cheaper to manufacture than the elastic clamps connectors of the prior art. The arms 66 are curved arms, turning their concavity opposite to the coaxial cable, so that they can be flexed naturally when the clamp assembly 50 + intermediate piece 62 is introduced into the hollow core 14 of the coaxial cable. Each arm 66 has for example a proximal region 74 extending in the same plane as the annular central region 64, and a distal portion 76 shifted at right angles (thus axially directed) and connected to the proximal portion 74 by a transition portion 78 in the form of a circular arc. The width of the arms is preferably constant throughout their length.

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  As illustrated in FIG. 4, during the insertion into the hollow core 14 of the clamp 50 equipped with the intermediate piece 62, the arms 66 flex and come into contact with the inner wall of the hollow core 14. Several very specific contacts strong are thus formed (as many contacts as arms 66). These contacts are also formed very close to the free end of the hollow core, an important condition for the connector to have excellent radio performance, especially in terms of intermodulation product. This location of the contacts near the end of the cable also makes it possible to reduce the length of the connector relative to a conventional configuration, as can be seen, for example, by comparing FIGS. 1 and 2. Indeed, to the extent that the contact is no longer along generators (smooth core) or at the top of the threads (helical core), the length of the connection element inserted into the hollow core can be reduced in significant proportions, so by way of consequence the congestion and the cost of the connector. The clamp has essentially a centering function of the conductive intermediate piece 62. Its depression is lirnité by the abutment of the shoulder 58 against the end face 60 of the hollow core of the coaxial cable, and the arms 66 have dimensions and a curvature such that these arms, in a bent configuration, do not exceed the plane of the shoulder 60. It will also be noted that the point contact is made particularly effective in the case of a helical core, the contact that can be formed both at the top or on the slopes of the helix, as in a smoother part of the core, between two successive nets (see in particular the example shown in Figure 4).

Claims (8)

  1. A connector for a coaxial cable (12) with hollow cylindrical core (14), this connector having an interface side adapted to be connected to a homologous connecting member, and opposite a cable side adapted to receive the end free strand of the coaxial cable, this connector (10) comprising: an inner conductive assembly, comprising interface side a contact pin (22), male or female, and cable side an electrical connection element to the core of the coaxial cable; and an outer conductor metal body (30) having a cavity housing the inner conductive assembly, and means (38) for electrically contacting the ground conductor (16) of the cable and mechanical anchoring of the cable to the connector. the electrical connecting element at the core of the coaxial cable comprising a clamp (50) adapted to be introduced into the hollow core (14) of the coaxial cable and comprising a cylindrical body (52) having a corresponding diameter substantially to the inner diameter of the hollow core (14) of the coaxial cable, to allow depression within the latter, the cylindrical body (52) being shaped with a plurality of parallel fingers (56) extending axially on the side cable, connector characterized in that the connecting element further comprises a conductive intermediate piece (62) in electrical connection with the contact pin (22) of the inner conductive assembly, this interstice medium (62) comprising a central region (64), housed in the axial region of the clamp, and a plurality of arms (66) adjacent the central region, extending radially therefrom through intervals (54) between the fingers (56) of the clamp, protruding radially beyond the body of the clamp, these arms being flexible arms having in the free state an overall diameter greater than the inner diameter of the hollow core of the coaxial cable, so that the insertion into the hollow core of the assembly formed by the body (50) and the intermediate piece (62) causes the arms (66) to bend as they penetrate into the hollow core, and the point radial stress of the ends of these arms against surfaces facing the hollow core. 10   The connector of claim 1, wherein the clip (50) is a substantially inelastic part.   The connector of claim 1, wherein the radially protruding portion (76, 78) of the arms (66) has a curvature directed in a direction opposite to the cable side.   4. The connector of claim 3, wherein the arms (66) corn-take a proximal region (74) radially oriented, extended by a central region (78) curved and terminated by an axially oriented distal region (76).   5. The connector of claim 1, wherein the clamp (50) corn-takes a shoulder (58) of diameter greater than the diameter of the core of the coaxial cable, to allow insertion into the hollow core of the assembly formed by the body (50) and the intermediate piece (62) until the abutment of the shoulder against the free end face (60) of the core (14) of the coaxial cable.   The connector of claim 5, wherein the central region (64) of the intermediate piece (62) extends substantially in a plane offset from the plane of the shoulder, so that the end (76) arms (66), in a bent configuration, do not go beyond the plane of the shoulder (58).   The connector of claim 5, wherein the overall diameter of the arms (66) is smaller than the diameter of the shoulder of the clip body.   8. The connector of claim 1, wherein the inner conductive assembly further comprises means (70, 72) for electrical and mechanical connection of the central region (68) of the intermediate piece (62) with the contact pin. (22). 35