FR3067177A1 - ELECTROMAGNETIC SHIELD FOR EXTREMITY OF BLIND CABLES - Google Patents

Abstract

The invention relates to an electromagnetic shielding device for an end of at least two shielded cables (11, 12), each shielded cable comprising, on a shielded section, an inner conductor (111, 121) and a shielding sheath (112 , 122) enveloping the inner conductor, the shielded cables having no shielding sheath on an end portion. The invention also relates to an electrical connector for an end of a cable assembly. According to the invention, the electromagnetic shielding device comprises: a shielding retaining ring (31) through which the internal conductors are able to pass, a set of shielding recovery conductors (321, 322) each adapted to electrically connecting the shielding sheath (112, 122) of one of the shielded cables to the shielding retaining ring (31), and ▪ a connecting element (41) electrically connecting all of the shielding conductors ( 321, 322) in the vicinity of a junction between the shielded section and the end section so as to form an electromagnetic shield between the connection element and the shielding retaining ring.

Description

ELECTROMAGNETIC SHIELDING FOR THE END OF ARMORED CABLES

DESCRIPTION

TECHNICAL AREA

The invention lies in the field of electromagnetic shielding and, more specifically, in the field of electromagnetic shielding of the ends of shielded cables. It relates to an electromagnetic shielding device for one end of a set of cables comprising at least two shielded cables. The invention also relates to an electrical connector for one end of a cable assembly and to an electrical connection assembly comprising a cable assembly and an electromagnetic shielding device.

The invention applies in particular to the resumption of shielding of cables on board an aircraft but more generally finds an application for any electrical connection which must ensure continuity of the electromagnetic shielding.

PRIOR STATE OF THE ART

A shielded cable comprises at least one internal conductor for transporting a so-called useful signal and a shielding sheath enveloping the internal conductor (s) in order to ensure electromagnetic isolation of the internal conductor (s) from the environment outside and vice versa. In many electrical systems, the number and variety of electrical signals to be transported increases considerably. This is particularly the case in the aeronautical field and, more particularly, for the power supply and the control of motors which require both low and high voltage signals and which are subjected to a harsh environment (high temperature, vibrations) . For reasons of assembly and maintenance convenience, the cables carrying data are often grouped together with the cables carrying the appropriate power, for example in the form of a harness. The electromagnetic shielding between the different cables must be effective over the entire frequency band of the signals transported. A particular difficulty lies in the resumption of shielding at the connectors of the shielded cables. Indeed, in order to allow the electrical connection of the internal conductors on a connector connection part, the shielding sheaths must be removed at the end of the cables. This results in a loss of the electromagnetic shielding on these ends.

Different solutions have been proposed to ensure the continuity of the electromagnetic shielding at the level of the electrical connectors. Application WO 2015/145059 A1 proposes, for example, to pass the internal conductors of the cables through a sleeve made of conductive material and to connect the two ends of the sleeve to the electrical ground. The sleeve thus forms an electromagnetic protective envelope, but no resumption of shielding is provided. The performance of the electromagnetic shielding on the portion of cable provided with the shielding sheath is therefore greatly degraded. In addition, the sleeve consists of a solid piece with a fixed internal diameter. Adapting the electromagnetic shielding to the number of cables and their diameter therefore involves the manufacture of a sleeve having an adequate internal diameter. This adaptation of the dimensions is all the more important as the free space between the internal conductors and the internal wall of the sleeve has the effect of amplifying the spurious signals. This free space must therefore be reduced as much as possible. Connectors with individual shielding recovery have also been proposed. These connectors integrate different shielding recovery parts intended to individually connect each shielding sheath to the electrical ground. However, these connectors have the disadvantage of having many parts and making connection and maintenance operations difficult. For example, application FR 2915323 A1 describes such a connector comprising a shielding recovery disc and a clamping disc each provided with openings which cooperate with the shielded cables to electrically and mechanically connect the shielding sheaths. Such a connector is complex to produce. It also has a determined number of openings, thus limiting the number of cables that can be connected to it.

In view of the above, the inventors have set themselves the goal of providing an electrical connector for one end of a set of cables which provides a shield recovery in a simple and effective manner. They have also set themselves the goal that the electrical connector can be adapted to different configurations of cable assemblies, in particular in terms of number of cables and diameter of these cables.

STATEMENT OF THE INVENTION

To this end, the invention provides an electromagnetic shielding device creating an electromagnetic shield around the end section by arranging a set of shielding recovery conductors around the internal conductors and by electrically connecting these sets of shielding recovery conductors to their two ends.

More specifically, the invention relates to an electromagnetic shielding device for one end of a set of cables. The cable assembly comprises at least two shielded cables, each shielded cable comprising, on a shielded section, an internal conductor and a shielding sheath enveloping the internal conductor. The shielded cables do not have a shielding sheath on an end section, also called an unshielded section. According to the invention, the electromagnetic shielding device comprises:

a shielding recovery ring through which the internal conductors are able to pass, a set of shielding recovery conductors, each shielding recovery conductor being able to electrically connect the shielding sheath of one of the shielded cables to the shielding recovery ring, and a connection element electrically connecting all of the shielding recovery conductors in the vicinity of a junction between the shielded section and the end section, so as to form an electromagnetic shielding between the element shield connection ring.

The pooling of the shields of the set of shielded cables makes it possible to form an electromagnetic shield enveloping the entire volume located between the shield recovery conductors.

Advantageously, the shielding recovery conductors extend between the connection element and the shielding recovery ring while being disposed at the periphery of the internal conductors of the shielded cables. Thus, the internal conductors are protected from external electromagnetic disturbances by the electromagnetic shield formed by the shield recovery conductors.

For better efficiency of the electromagnetic shielding, the shielding recovery conductors are advantageously distributed uniformly around the periphery of the internal conductors of the shielded cables.

At least one of the shielding recovery conductors can be wound around the internal conductors of the shielded cables. Preferably, all the shielding recovery conductors are wound in the same direction around the internal conductors of the shielded cables. They form coils around the internal conductors.

The shielding recovery conductors may each include one or more conductive wires. They may in particular each comprise a braid of electrically conductive material. A simple lead wire can also be used. Alternatively, the shielding recovery conductors may each consist solely of the shielding sheath of a shielded cable. In such a case, the shield recovery sheath no longer envelops the internal conductor of this shielded cable.

According to a particular embodiment, one end of each shielding recovery conductor is mounted in abutment on an external surface of the shielding recovery ring. For example, the external surface of the shielding recovery ring forms a cylinder of revolution on which the ends of the shielding recovery conductors can come to bear. The electromagnetic shielding device may further comprise a clamping collar for fixing the ends of the shielding recovery conductors to the shielding recovery ring.

The electromagnetic shielding device may further comprise, for each shielding recovery conductor, a self-welding sleeve, also called a heat-shrinkable device. Each self-welding sleeve is capable of enveloping the shielding sheath of one of the shielded cables in the vicinity of the junction between the shielded section and the end section, and is connected to the shielding conductor. In other words, each self-welding sleeve is able to wrap one end of the shielding sheath and electrically connects the shielding conductor. The self-welding sleeves thus form means of connection between the shielding sheaths and the shielding recovery conductors.

The function of the connection element is to electrically connect all the shielding recovery conductors in the vicinity of the junction between the shielded section and the end section. It can include at least one of the following elements: a crimp ring, an electric wire, a clamp, a strip of electrically conductive material. The connection element is for example a copper strip.

The connection element can be arranged on the end section. It then comes directly into contact with the shield recovery conductors.

Advantageously, the connection element encloses the shielding recovery conductors. It then serves both as an electrical connection element and as a mechanical holding element.

The invention also relates to an electrical connector for one end of a set of cables. The cable assembly comprises at least two shielded cables, each shielded cable comprising, on a shielded section, an internal conductor and a shielding sheath enveloping the internal conductor. The shielded cables do not have a shielding sheath on an end section, also called an unshielded section. The electrical connector comprises a connection part to which the internal conductors of the shielded cables can be connected, and an electromagnetic shielding device as described above.

The electrical connector may include a body. The body forms, for example, an electrical mass of the electrical connector. The shielding recovery ring can then form part of the body of the electrical connector. For example, the shield take-up ring can form a cylindrical surface of revolution of the electrical connector.

The invention finally relates to an electrical connection assembly comprising a set of cables and an electrical connector as described above. The cable assembly comprises at least two shielded cables, each shielded cable comprising, on a shielded section, an internal conductor and a shielding sheath enveloping the internal conductor, the shielded cables being devoid of shielding sheath on an end section .

The cable assembly can also include one or more unshielded cables, that is to say cables without shielding sheath over their entire length. Preferably, each unshielded cable is placed inside a volume delimited by the set of shielding recovery conductors. Unshielded cables are also protected from the external electromagnetic environment.

The cable assembly can form a harness, for example a cable harness for supplying and controlling an aircraft engine.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will be better understood with the aid of the description which follows, given solely by way of nonlimiting example and made with reference to the appended drawings in which:

- Figure 1 schematically shows, in a longitudinal sectional view, an example of an electrical connection assembly comprising a set of shielded cables and an electrical connector;

- Figure 2 shows the transfer impedance of two sets of electrical connection according to Figure 1;

- Figure 3 shows schematically, in a longitudinal sectional view, a first example of an electrical connection assembly comprising an electromagnetic shielding device according to the invention and shielded cables;

- Figure 4 illustrates the principle of limiting the effects of current loops using the device of Figure 3;

- Figure 5 shows the transfer impedance of two electrical connection assemblies according to Figure 1, and a third electrical connection assembly according to the invention;

- Figure 6 schematically shows, in a longitudinal sectional view, a second example of an electrical connection assembly comprising an electromagnetic shielding device according to the invention and both shielded and unshielded cables.

DETAILED PRESENTATION OF PARTICULAR EMBODIMENTS

FIG. 1 schematically represents, in a longitudinal section view, an example of an electrical connection assembly 1 comprising a set 10 of cables and an electrical connector 20. In this example, the assembly 10 comprises two shielded cables 11 and 12. On a shielded section, the shielded cables 11, 12 each comprise an internal conductor 111, 121 and a shielding sheath 112, 122 respectively enveloping the internal conductor 111 or 121. On an end section, also called "unshielded section" , the shielded cables 11, 12 are devoid of shielding sheath. On the other hand, they can include an electrical insulation sheath. The shield sheath 112, 122 has been removed on the end section in order to allow the connection of the internal conductors 111, 121 on the electrical connector

20. In FIG. 1, only part of the electrical connector 20 is shown. The electrical connector 20 comprises a connection piece 21 and connection terminals 22 integral with the connection piece 21. The connection terminals 22 are each arranged to receive one or more internal conductors 111, 121 in order to connect them electrically and to fix them to the electrical connector 20. The electrical connector 20 further comprises a shielding recovery ring 31, shielding recovery conductors 321, 322 and self-welding sleeves 331, 332. The shielding recovery ring 31 is mounted on the part. connection 21 by a screw connection. In particular, the shielding take-up ring 31 comprises an external thread 311 and the connection piece 21 comprises an additional internal thread 211. The shielding recovery ring 31 includes an axial opening 312 through which the internal conductors 111, 121 can pass. The shielding recovery ring 31 is made of an electrically conductive material, for example copper. The self-welding sleeves 331, 332, also called “heat-shrinkable devices”, are electrical connection elements comprising a heat-shrinkable sheath making it possible to mechanically hold two conductors to be connected with a ring of tin ensuring the electrical connection. The self-welding sleeve 331 is mounted on the shielding sheath 112, in the vicinity of the junction between the shielded section and the end section. It comes to connect the shielding sheath 112 to a first end of the shielding recovery conductor 321. The self-welding sleeve 332 is mounted on the shielding sheath 122, in the vicinity of the junction between the shielded section and the end section. . It comes to connect the shielding sheath 122 to a first end of the shield recovery conductor 322. A second end of each shield recovery conductor 321, 322 is mounted on the shield recovery ring 31. More precisely, the second end of each shielding recovery conductor 321, 322 bears on an external surface 313 of the shielding recovery ring 31. The second ends of the shielding recovery conductors are held in position by a crimping ring 314.

In the embodiment of FIG. 1, a unitary shielding recovery is ensured for each shielded cable 11, 12 by means of the self-sealing sleeves 331, 332, the shielding recovery conductors 321, 322 and the resumption ring of shielding 31. However, a current loop is formed through each internal conductor 111, 121 and its associated shield recovery conductor 321, 322. The signals carried by the internal conductors 111, 121 are thereby disturbed. Furthermore, the end section of the cables 11 and 12 forms an opening on the shielding, making it possible to disturb the signals transported by the cables 11, 12 by the external environment.

The possibility that the external electromagnetic environment influences the signals transported by the cables 11, 12 is highly dependent on the particular arrangement of the shield recovery. FIG. 2 represents, in the form of a graph, the measurements of a transfer impedance of two separate electrical connection assemblies but of the same composition, each connection assembly comprising at least one shielded strand and an electrical connector as described in reference to FIG. 1. Each measurement was carried out by injecting a disturbing current on an injection line coming into contact with the shielding sheath of the shielded strand tested and of the connector. Each free end of the injection line and the connector is connected to a 50 Ω load. A first curve 51 represents the transfer impedance, as a function of the frequency, of a first connection assembly and a second curve 52 represents the transfer impedance, as a function of the frequency, of a second connection assembly. It can be observed that from the frequency of 2.10 ⁵ Hz, the transfer impedances of the two sets diverge strongly. The two shielded strands tested being identical, this divergence is due to the differences in electromagnetic properties at the connections.

FIG. 3 schematically represents, in a longitudinal section view, a first example of an electrical connection assembly 2 according to the invention. The electrical connection assembly 2 comprises a set 10 of two shielded cables 11 and 12 and an electrical connector 40. In an identical manner to the electrical connection assembly 1, the shielded cables 11 and 12 each comprise an internal conductor 111, 121 and a armor sheath 112,122 extending over an armored section but not over an end section. In Figure 3, only part of the electrical connector 40 is shown. The electrical connector 40 comprises a connection piece 21 and connection terminals 22 integral with the connection piece

21. Each connection terminal 22 is arranged to receive one or more internal conductors 111, 121. The internal conductors 111, 121 can thus be electrically connected and fixed to the electrical connector 40. The electrical connector 40 also includes a shielding take-up ring 31, shield recovery conductors 321, 322 and self-welding sleeves 331, 332. The shield recovery ring 31 is made of electrically conductive material. It is mounted on the connection piece 21 by a screw connection and includes an axial opening 312 through which the internal conductors 111, 121 are able to pass. More particularly, in the example of FIG. 3, the shielding take-up ring 31 comprises an external thread 311 and the connection piece 21 comprises an additional internal thread 211. Any other method of assembly can be envisaged in place of the screw assembly. Furthermore, the shielding recovery ring 31 can form a one-piece assembly with the connection piece 21. In any event, it must be arranged so as to allow the connection of all the shielding recovery conductors 331, 332 and the passage of the internal conductors 111, 121 towards the connection piece 21. Advantageously, the shielding take-up ring 31 is also arranged so that the internal conductors 111, 121 are all contained within a volume delimited by the shield recovery conductors 321, 322. Each shield recovery conductor 321, 322 extends between the end of the shield sheath 112, 122 of one of the shielded cables and the shield recovery ring 31. One end of each shielding recovery conductor 321, 322 is electrically connected to a shielding sheath 112, 122 by means of a self-welding sleeve 331, 332. Each self-welding sleeve 331, 332 encloses a shielding sheath 112, 122 and a shielding resumption conductor 321, 322 associated for ensuring the mechanical maintenance and the electrical connection. Another end of each shielding recovery conductor 321, 322 comes to bear on an external surface 313 of the shielding recovery ring 31. The mechanical retention of the shielding recovery conductors 321, 322 on the shielding recovery ring 31 is ensured by a crimp ring 314.

In addition to the electrical connector 20 of FIG. 1, the electrical connector 40 comprises a connection element 41 electrically connecting all of the shielding conductors 321, 322 in the vicinity of the junction between the shielded section and the end section . In the example of Figure 3, the connection element 41 is a crimp ring. In general, the connection element 41 must provide an electrical connection between all the shielding recovery conductors 321, 322 at the junction between the shielded section and the end section. It could thus be formed by other connection elements, for example a copper strip, a clamp and / or a simple electric wire. The connection element 41 is preferably positioned as close as possible to the screened section. It can possibly be positioned on this shielded section, for example around the self-welding sleeves 331, 332. The electrical connection of the shielding recovery conductors 321, 322 at each of their ends has the effect of creating an electromagnetic shield over their whole length. The connection element 41 thus forms, with the shielding recovery ring 31, the shielding recovery conductors 321, 322 and the self-welding sleeves 331, 332 of the electromagnetic shielding means of the end section.

The electrical connection of the shield recovery conductors at their two ends also has the effect of limiting the effects of current loops created through the internal conductors and the shield recovery conductors. FIG. 4 illustrates the principle of this limitation in the case of two shielding recovery conductors. The current flowing over a shielding sheath, for example the sheath 112 will be distributed between the shielding recovery conductors 321, 322 and will recombine at the level of the shielding recovery ring 31. If the shielding recovery conductors 321, 322 have the same electrical resistance, the electric current is distributed equitably between the two shield recovery conductors 321, 322. This results in two magnetic field loops Bi, B ₂ of the same intensity but in opposite directions between these two conductors. No parasitic current therefore flows in the internal conductors disposed between these two shield recovery conductors 321, 322. The more shield recovery conductors 321, 322, the greater the area of shielding protection effect.

FIG. 5 represents, in the form of a graph, the measurements of a transfer impedance of three separate electrical connection sets, two of which have the same composition as for FIG. 2. Each measurement was carried out by injecting a disturbing current on injection line coming into contact with the shielding sheath of the cable under test and the connector. The first curve 51 and the second curve 52 are identical to the curves in FIG. 2. They represent the transfer impedance, as a function of the frequency, of two sets of electrical connection 1 as described with reference to FIG. 1. In on the other hand, curve 53 represents the transfer impedance, as a function of the frequency, of an electrical connection assembly 2 as described with reference to FIG. 3. It can be observed that between 1.10 ⁷ and 3.10 ⁷ Hz, the transfer impedance of the connection assembly according to the invention is lower than that of the connection assemblies without connection element 41 at the junction between the shielded section and the end section. Furthermore, it has been observed that the transfer impedance remains identical for different electrical connection assemblies 2 according to the invention. The reproducibility of the electromagnetic shielding properties of an electrical connection assembly according to the invention is therefore greatly improved.

FIG. 6 schematically represents, in a longitudinal section view, a second example of an electrical connection assembly 3 according to the invention. The electrical connection assembly 3 comprises a set 30 of cables, including two shielded cables 11 and 12 and two unshielded cables 13 and 14, as well as an electrical connector 60. The unshielded cables 13 and 14 each include an internal conductor 131, 141 but have no shielding sheath over their entire length. The electrical connector 60 differs from the electrical connector 40 in that it has two additional connection terminals 22, in order to be able to connect the unshielded cables. In addition, the electrical connector 60 has dimensions adapted to the number of cables. It also includes a connection piece 21A, a shielding recovery ring 31A, a crimping ring 314A, shielding recovery conductors 321, 322, self-welding sleeves 331, 332 and a connection element 41A. The shield recovery conductors 321, 322 each extend between one end of a shield sheath 112, 122 and the shield recovery ring 31A. They come to bear at one of their ends on an external surface 313A of the shielding take-up ring 31A and are held by the crimping ring 314A. In this exemplary embodiment, the internal conductors 131, 141 of the unshielded cables 13, 14 are arranged inside the shield recovery conductors 321, 322. They thus benefit, like the internal conductors 111, 121, from a electromagnetic protection against the external electromagnetic environment. Likewise, internal conductors 131,141 benefit from a reduction in stray currents.

Claims (14)

1. Electromagnetic shielding device for one end of a set of cables (10, 30), the cable set comprising at least two shielded cables (11, 12), each shielded cable comprising, on a shielded section, a conductor internal (111, 121) and a shielding sheath (112, 122) enveloping the internal conductor, the shielded cables being devoid of shielding sheath on an end section, the electromagnetic shielding device comprising: a shielding recovery ring (31, 31A) through which the internal conductors are able to pass, a set of shielding recovery conductors (321, 322), each shielding recovery conductor being capable of electrically connecting the sheath of shield (112, 122) of one of the shielded cables to the shield recovery ring (31, 31A), and a connection element (41, 41A) electrically connecting all of the shield recovery conductors (321, 322) in the vicinity of a junction between the shielded section and the end section, so as to form an electromagnetic shielding between the connection element and the shielding take-up ring. 2. An electromagnetic shielding device according to claim 1, in which the shielding recovery conductors (321, 322) extend between the connection element (41, 41A) and the shielding recovery ring (31, 31A). by being arranged at the periphery of the internal conductors (111,121) of the shielded cables (11,12). 3. Electromagnetic shielding device according to one of claims 1 and 2, wherein the shielding recovery conductors are distributed uniformly around the periphery of the internal conductors of the shielded cables. 4. Electromagnetic shielding device according to one of the preceding claims, in which at least one of the shielding recovery conductors (321, 322) is wound around the internal conductors (III, 121) of the shielded cables. 5. An electromagnetic shielding device according to one of the preceding claims, wherein the shielding recovery conductors (321, 322) each comprise a braid of electrically conductive material. 6. Electromagnetic shielding device according to one of the preceding claims, in which one end of each shielding recovery conductor (321, 322) is mounted in abutment on an external surface (313, 313A) of the shielding recovery ring. (31, 31A). 7. An electromagnetic shielding device according to claim 1, further comprising, for each shielding recovery conductor (321, 322), a self-welding sleeve (331, 332), each self-welding sleeve being able to wrapping the shielding sheath (112, 122) of one of the shielded cables in the vicinity of the junction between the shielded section and the end section, and being connected to the shielding conductor (321, 322). 8. Electromagnetic shielding device according to one of the preceding claims, in which the connection element (41, 41A) comprises at least one of the following elements: a crimp ring, an electric wire, a cable tie, a strip of electrically conductive material. 9. An electromagnetic shielding device according to one of the preceding claims, in which the connection element (41, 41A) is disposed on the end section. 10. An electromagnetic shielding device according to claim 9, in which the connection element (41, 41A) encloses the shielding recovery conductors (321, 322). 11. Electrical connector for one end of a set of cables (10, 30), the cable set comprising at least two screened cables (11, 12), each screened cable comprising, on a screened section, an internal conductor ( 111, 121) and a shielding sheath (112, 122) enveloping the internal conductor, the shielded cables being devoid of shielding sheath on an end section, the electrical connector (40, 60) comprising a connection piece (21, 21A ) to which the internal conductors of the shielded cables can be connected, and an electromagnetic shielding device according to one of the preceding claims. 12. An electrical connector according to claim 11, comprising a body, the shielding recovery ring (31, 31A) forming a part of a body of the electrical connector. 13. electrical connection assembly comprising a set (10, 30) of cables and an electrical connector (40, 60) according to one of claims 11 and 12, the cable assembly comprising at least two shielded cables (11, 12 ), each screened cable comprising, on a screened section, an internal conductor (111,121) and a screened sheath (112, 122) enveloping the internal conductor, the screened cables being devoid of screened sheath on an end section. 14. An electrical connection assembly according to claim 13, in which the cable assembly further comprises at least one unshielded cable (13, 14), each unshielded cable being disposed inside a volume delimited by l 'set of shield recovery conductors (321, 322).