EP0010461B1 - Anti-microphonic coaxial cable to function at a high temperature - Google Patents

Description

The invention relates generally to coaxial cables which are used in electronics techniques for transmitting electrical signals of very low intensity and applies more particularly to those of these cables which operate in medium hostile and high temperature.

Such a coaxial cable known per se, is shown in FIG. 1 and consists of two electrodes, namely a central core 1 and an outer braid 3 separated by a dielectric medium 2 surrounding the central core. The central core 1 is generally made of sometimes tinned red copper, the dielectric 2 is made of a material with high resistivity such as Teflon and the external conductive braid 3 is generally made of sometimes silvery red copper.

It is also known that such a cable has what is called the microphonic effect when it is subjected even very weakly to the stresses generated by a vibratory regime. In fact, in this case, the relative slippages which exist between the three elements mentioned above, cause friction which generates electrical charges the larger the dielectric is more perfect. These charges create an electric field which by induction creates currents which are superimposed on the electrical signals which the cable is precisely responsible for conveying and disturbs in a sometimes unacceptable way the safe reception of the signal to be transported. To combat this phenomenon, it has been envisaged to place between the dielectric 2 and the braid 3, an envelope made of plastic material loaded with carbon which, being therefore semiconductor, limits the level of the electric charges generated and allows the flow of these Ci in the braid 3 with which it is in contact. This antimicrophonic protection in itself known, however, has the disadvantage that it does not overcome the electric charges induced by the friction phenomena developing between the core 1 and the dielectric 2; on the other hand, when it comes to making a coaxial cable operating in a hostile environment having vibrations and in particular at a high temperature of the order of several hundred degrees Celsius as is the case for the transmission of measurements coming from a nuclear reactor core, it is then impossible to use such an intermediate plastic envelope and the problem of microphonic protection of the cable is then completely called into question.

In general, moreover, to withstand temperatures of several hundred degrees centigrade, the coaxial cables undergo a transformation essentially concerning their dielectric, which then consists of a number of high density ceramic beads, generally in pure alumina, strung on the core of the cable and covered by an outer stainless steel braid. Fig. 1 shows such a coaxial cable for high temperature of a type known per se.

In this fig.1, there is shown a coaxial cable comprising a central core 1 of stainless steel or copper covered with stainless steel on which beads 2, made of pure alumina, constituting the dielectric are strung. As seen in fig. 1, the pearls 2 preferably have the shape of a portion of a cylinder limited by respectively convex and concave end surfaces so as to be able to fit perfectly into each other. The second electrode of this cable consists of an outer braid 3, also made of stainless steel and which may comprise several layers.

Until now, such cables which by their constitution can withstand high temperatures, have not been able to be fitted with antimicrophonic devices.

• a) les câbles en question sont à diélectrique à air, et les corps d'espacement prévus de place en place ne sont là que pour servir d'entretoise, maintenant l'âme du câble au centre de la tresse ; or, à haute température, et sous rayonnement l'air s'ionise, ce qui perturbe le fonctionnement du câble de façon inacceptable.
• b) les surfaces en présence et susceptibles de frotter l'une sur l'autre ne sont métallisées que partiellement et, notamment, de façon discontinue entre l'âme et les différents corps d'espacement. Il en résulte que de telles structures ne permettent absolument pas de supprimer les nuisances dues à l'effet microphonique, en particulier lors des torsions du câbles qui peuvent engendrer des frottements entre des portions de surfaces isolantes non revêtues et l'une des électrodes métalliques.

It has already been envisaged, for coaxial cables operating under relatively high voltage or frequency and using air as a dielectric, to avoid the phenomena of electrical discharge by sparks by partially coating the surfaces of the spacing bodies threaded on the core of the cable. in contact with the braid of a layer of noble metal. This is the case for example of the coaxial cables which are the subject of the patents DE-C-702 951 and GB-A-397 081. The solutions described in these patents are however inapplicable to obtain the antimicrophonic effect under the physical conditions mentioned. above, for the following two reasons:

• a) the cables in question are air dielectric, and the spacers provided from place to place are only there to serve as a spacer, keeping the cable core in the center of the braid; however, at high temperature, and under radiation the air ionizes, which disturbs the functioning of the cable in an unacceptable way.
• b) the surfaces present and likely to rub one on the other are only partially metallized and, in particular, discontinuously between the core and the different spacing bodies. As a result, such structures absolutely do not make it possible to eliminate the nuisances due to the microphonic effect, in particular during twisting of the cables which can cause friction between portions of uncoated insulating surfaces and one of the metal electrodes.

The present invention specifically relates to an antimicrophonic coaxial cable which can operate in a hostile environment and in particular at high temperature, without having the drawbacks of the prior art.

It is essentially characterized in that all the contact surfaces between the beads and the core, between the beads and the outer braid and between the consecutive beads are provided with a conductive metallic coating, said coating ment being in particular continuous on the core of the cable.

In this way, in fact, the slippages or friction which can occur when such a cable undergoes vibrations or alternative mechanical stresses, practically no longer generate the appearance of charges of the electrostatic type or of the piezoelectric type, since the relative slips which occur between the two metal parts and no longer between a metal part and a dielectric and that the core is somehow protected by a continuous metal envelope.

In embodiments of the invention, the coaxial cable also includes a certain number of metallic intermediate pieces threaded on the core and placed between each of the consecutive beads, which gives it a certain complementary flexibility.

According to the present invention, the metallic coating of the friction surfaces can be produced in two different ways.

In a first embodiment, the metallic coating of said surfaces is produced by means of a deposit made on the parts of the surface thereof which are in contact with the core, the braid and / or the intermediate pieces, said deposit possibly being constituted for example by an alloy of molybdenum and manganese obtained from a pulverulent solution in an appropriate solvent which is left to dry and which is fixed by a treatment at a high temperature oven to make the combination of the alloy with the alumina surfaces of the pearls.

According to a second embodiment of the present invention, the metallic coating of the friction surfaces consists of rings and metal sleeves which are crimped directly around the pearls or which are forced into their central orifice. In this case, an advantageous variant of the invention consists in using said metal sleeves threaded into the central orifice of each pearl to constitute at the same time the intermediate pieces making the desired spacing between two consecutive pearls.

• la figure 2 représente un exemple de réalisation du premier mode de mise en oeuvre de l'invention selon lequel les perles de diélectrique sont recouvertes partiellement d'une couche métallique ;
• la figure 3 représente un exemple de réalisation du deuxième mode de mise en oeuvre de l'invention dans lequel les perles de matériaux diélectriques sont serties de bagues et de fourreaux métalliques ;
• la figure 4 représente le détail d'une bague d'acier inoxydable ;
• la figure 5 représente le détail d'un fourreau d'acier inoxydable utilisé dans le dispositif de la fig. 3 ;
• la figure 6 représente une variante intéressante de l'invention dans laquelle manquent les pièces intercalaires.

In any case, the invention will be better understood by referring to the application examples described below, and given by way of nonlimiting examples with reference to FIGS. 2 to 6 attached on which:

• FIG. 2 represents an exemplary embodiment of the first embodiment of the invention according to which the dielectric beads are partially covered with a metallic layer;
• FIG. 3 represents an exemplary embodiment of the second embodiment of the invention in which the beads of dielectric materials are set with rings and metal sleeves;
• Figure 4 shows the detail of a stainless steel ring;
• 5 shows the detail of a stainless steel sheath used in the device of FIG. 3;
• Figure 6 shows an interesting variant of the invention in which the intermediate pieces are missing.

In the embodiment shown in FIG. 2 there are also the main constituent elements of a coaxial cable according to the invention and the corresponding elements which bear the same reference numbers as in the previous example.

In this example, however, the intermediate pieces 4 are constituted by small cylinders 4 of stainless steel pierced along their axis with an orifice allowing the passage of the steel core 1 and are thus threaded onto said core 1 alternately with the pearls 2. In this embodiment, only the external lateral 6 and internal 7 edges as well as the wall portions 9 of the pearls 2 must be metallized. For more flexibility in assembly, the edges 10 of the intermediate cylinders 4 as well as the outer edges 11 of the beads 2 have a rounded or hemispherical shape, since the presence of sharp angles would deteriorate the metallic coating deposited on the dielectric 2. The different previous conditions mean that neither the intermediate pieces 4, nor the outer ringed tube 3 come into contact with the ceramic constituting the pearls 2. In this embodiment it may sometimes be desirable to divide the intermediate elements 4 into two parts to give more flexibility to the entire cable.

Fig.3 shows an embodiment of the second embodiment of the invention in which the metallic coating of the pearls 2 is constituted with respect to the external surface by a stainless steel ring 12 mounted hot or by any other known means on the dielectric and shown in more detail in FIG. 4; the metallic coating of the central orifices as well as the spacers 4 are produced using sheaths 13, one of which is more particularly shown in FIG. 5, the sleeves 13 being made of a stainless steel cylinder force-fitted at very low temperature (in liquid nitrogen for example) inside the central orifices 5 of the alumina beads 2. The sleeves 13 are made of stainless steel and fitted after fitting the rings 12; they are drilled right through along their axis with an orifice 14 intended for the passage of the stainless steel core 1 of the coaxial cable (fig. 5).

In the embodiment of FIG. 3, the external electrode 3 is also constituted by a ringed tube made of stainless steel and each alumina pearl 2 is a disc pierced along its axis with a hole whose diameter is equal to the outside diameter steel sleeves 13.

Fig. 6 finally shows a very interesting variant of the invention in which we manage to further improve the electrical qualities of the cable while eliminating the intermediate parts. This is achieved by giving the dielectric 2 the form of spherical balls or (ellipsoid ) alumina which are metallized on all their surface portions in contact with the core 1 or the braid 2 in stainless steel as well as the neighboring pearls. In Fig. 6, four pearls 2a to 2d are shown, the first two 2a and 2b on the left side of the drawing are seen in section and the last two 2c and 2d on the right side, are seen from the front in elevation . In this fig. 6 the metallized parts are shown in reinforced lines. This configuration, which is easier to manufacture because it requires only one component, offers, in addition to its antimicrophonic qualities, the advantage of eliminating any capacitive effect which occurs in the other variants between the metallized external faces of the intermediate pieces and the metal sheath.

By way of example, a coaxial cable according to the invention was the subject of a comparative test with a cable of known type as shown in FIG. 1 in which the alumina beads had no protection particular metal on their surface part in connection with the core and the external braid. The cable sample was placed in a shielded enclosure and rigidly fixed at two points. A mechanical device gave the cable an alternating movement with an amplitude of 4 mm, the period of which was 2 seconds. The measurements, carried out on two cable samples, one according to the prior art, the other according to the invention, made it possible to note an amplitude of the piezoelectric signal which was 3.4 · 10- ¹² amps in the first case and only 2.4 10 ^-14 amperes for a coaxial cable of the antimicrophonic type produced according to the invention and conforming to the embodiment of FIG. 3.

Claims (6)

1. Noise-suppressed coaxial, cable, of the known type comprising between the core (1) and the external sheath (3) an insulation of high-density ceramic beads (2) threaded on the cable core, characterized in that all contact surfaces between the beads and the core, between the beads and the external sheath, and between adjacent beads, are provided with a conductive metallic lining, said lining being in particular continuous on the cable core.

2. Coaxial cable according to Claim 1, characterized in that the metallic lining on said surfaces comprises an alloy of molybdenum and manganese.

3. Coaxial cable according to Claim 1, characterized in that the conductive metallic lining comprises metallic external sleeves (12) and internal sleeves (13) fitted on said beads (2).

4. Coaxial cable according to either one of Claims 1 and 2, characterized in that the beads (2a, 2b, 2c, 2d) are pure alumina balls threaded together by the core (1) and metallized on their surface portions in contact with the core (1), the external sheath (3) and the adjacent beads.

5. Coaxial cable according to any one of Claims 1 to 3, characterized in that it comprises a plurality of metallic spacer members (4) threaded on the core (1) and provided between each adjacent pair of beads (2).

6. Coaxial cable according to Claim 3, characterized in that said metallic internal sleeves are tightly threaded in the central bore (5) of each bead (2) and simultaneously act as spacer members.

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