FR2735606A1 - Coaxial cable for ultrasound and medical usage - Google Patents

Abstract

Coaxial cable (10) comprises: (a) an inner electrical conductor (11); (b) intermediate insulating dielectric material (13) surrounding the inner electrical conductor and comprising longitudinal grooves (15) sepd. by longitudinal flanges (14) in such a way as to define cavities, the dia. of the circle formed by joining the ends of the flanges in a transverse section of the cable, is \-5 mm; (c) an outer electrical conductor (16) surrounding the insulating material; and (d) an outer protective layer (18) of insulating material surrounding the outer electrical conductor. The outer electrical conductor (16) is in direct contact with the flange (14) of the intermediate insulator (13) to give a polygonal transverse cross-section.

Description

COAXIAL CABLE
The present invention relates to a coaxial cable, particularly intended for use in the field of ultrasound and in the medical field.

 It will be recalled that a coaxial cable consists, in a well-known manner, of an interior electrical conductor surrounded by an intermediate insulator made of a dielectric material, itself surrounded by an exterior electrical conductor coaxial with the interior conductor, then by a sheath. external mechanical protection made of insulating material. The cables concerned by the present invention are those having a diameter on insulator not exceeding 5 mm.

 Several solutions are currently known in the field of coaxial cables in order to produce the intermediate insulator. To obtain high impedances, typically greater than 50 Ω, it is known that the material constituting the insulator must have a dielectric constant as close as possible to 1, the dielectric constant of air. For this reason, it is known to use to make the insulation of so-called aerated or cellular materials, such as aerated Polytetrafluoroethylene (PTFE) or cellular polyethylene for example. These materials are very schematically in the form of foams, that is to say that they contain numerous gas bubbles, this decreasing their dielectric constant compared to the case where they are massive, that is to say without gas bubbles.

 In general, for conventional coaxial cables, a tube of such material is extruded around the inner conductor to produce the intermediate insulation. However, the more the dimensions of the cable decrease, the more disadvantages this extrusion has.

In particular, it is difficult to produce for cellular or aerated products, and the gas bubbles, which are produced during extrusion, are distributed heterogeneously in the insulation, concentrating on the surface of the internal conductor, so the cable impedance is irregular. In addition, this reduces the adhesion of the insulation to the inner conductor.

 It is therefore preferred to use, instead of an extruded tube of aerated or cellular material, a ribbon of such a material, which leads to much better electrical performance. However, this poses problems in stripping the cable for possible connections, problems all the more delicate as the diameter of the cable is small. In addition, taping is expensive and difficult to perform.

 Another possible solution, which also makes it possible to further increase the quantity of gas in the insulator, consists in using insulators made of a solid dielectric material but comprising longitudinal grooves separated from each other by ribs also longitudinal so as to define alveoli. We then say that the insulation is honeycombed. These grooves and ribs are either straight or helical around the longitudinal axis of the cable.

Such intermediate insulators are described for example in the documents
EP-AO 373 120 or GB-2 160 147.

 It is accepted and well known that, for the coaxial cable to have satisfactory electrical performance, the external electrical conductor must be perfectly coaxial with the interior electrical conductor and perfectly cylindrical. For this, in the cables described in the two previous documents, a cylindrical tube is extruded around the honeycomb insulation, and the external electrical conductor is deposited around this tube.

 This poses several problems when it is desired to produce a coaxial cable of small dimensions. Indeed, this additional tube increases the dimensions of the cable (its thickness must be at least 0.5 mm, which corresponds to an increase in cable diameter of 1 mm, or 20% of the diameter on maximum desired insulation).

 Furthermore, this tube, which at the same time serves as mechanical protection of the cable against crushing, is made of a solid material, which results in a reduction in the impedance of the cable.

 The present invention therefore proposes to produce a coaxial cable of reduced dimensions whose insulator is compact, easy to produce, makes it possible to obtain satisfactory electrical performance in particular in terms of impedance, and does not interfere with the stripping of the cable.

 The present invention provides for this purpose a coaxial cable comprising: - an interior electrical conductor, - an intermediate insulator made of a dielectric material, surrounding said interior electrical conductor and comprising a plurality of longitudinal grooves separated from each other by also longitudinal ribs of so as to define cells, the diameter of the circle circumscribed to the polygon obtained by joining in a cross section of said cable, the ends of said ribs, being less than or equal to 5 mm, - an external electrical conductor surrounding said insulator, - an external sheath of protection made of an insulating material, surrounding said external electrical conductor, characterized in that said external electrical conductor is disposed directly in contact with the ribs of said insulator so that its cross section is polygonal.

 In the cable according to the invention ,. a cellular insulator is used without using a tube, so that the section of the external conductor is polygonal, and that there is consequently not a constant distance between the two conductors of the cables.

 Quite surprisingly, it has been found that such a structure makes it possible to obtain, with a diameter on insulator comparable with that of a cable with ventilated or cellular insulated tape, a substantially identical impedance.

 In addition, the impedance has the desired regularity characteristics.

 While it has generally been accepted so far that a coaxial cable can only work if the inner and outer conductors are coaxial and both are cylindrical, it is the merit of the present invention to have discovered that, for a diameter on insulator limited to approximately 5 mm, the electrical performance is substantially identical whether the external conductor is cylindrical or not.

 Having noted this, the use of the tube recommended in the prior art is no longer necessary, which makes it possible both to save space and to improve the electrical performance in terms of impedance.

 It was also verified that, given the small dimensions of the cable according to the invention, the shape of the insulator alone ensures good resistance of the cable to mechanical deformation during crushing of the cable, so that the mechanical protection function of the tube of the prior art is fulfilled by the insulator in the cable according to the invention.

 Other characteristics and advantages of the present invention will appear in the following description of several embodiments of the present invention, given by way of illustration and in no way limitative.

 In the following figures: - Figure 1 is a cross section of a cable according to a first embodiment of the present invention, - Figure 2 is a cross section of a cable according to a second embodiment of the present invention , - Figure 3 is a cross section of a cable according to a third embodiment of the present invention, - Figure 4 is a cross section of a cable according to a fourth embodiment of the present invention, - Figure 5 is a cross section of a cable according to a fifth embodiment of the present invention.

 In all these figures, the common elements have a reference number bearing the same unit digit, and a tens digit corresponding to the number of the associated figure.

 We see in cross section in Figure 1 a cable 10 according to the invention which comprises, arranged coaxially from the inside to the outside: - an internal electrical conductor 11 consisting of a strand of 7 strands 12 of silver copper wires of 0.03 mm in diameter each, the inner conductor 11 thus having a diameter of 0.09 mm, - an intermediate insulation 13 extruded, made of Ethylene and Propylene Fluoride (FEP) comprising 6 longitudinal ribs 14 delimiting 6 grooves also longitudinal 15, thus forming 6 longitudinal cells, the diameter of the circumscribed circle passing through the ends of the ribs 14 in the cross section shown being 0.33 mm, - an external electric conductor 16 hexagonal formed by a helical winding with contiguous turns of wires 17 of silver-plated copper each having a diameter of 0.03 mm, the diameter of the circle circumscribed to the outer conductor 16 in the cross section shown etan t thus 0.39 mm, - an outer mechanical protection sheath 18 in extruded FEP, of diameter equal to 0.5 mm.

 The ends 14A of the ribs 14 closest to the inner conductor 11 are connected to each other so as to immediately define around this conductor a tubular portion 19. The length of each rib 14 in the cross section shown, between its end 14A and its other end 14B, is 0.12 mm in the example shown.

 In FIG. 2, the insulator 23 comprises three ribs 24 delimiting three grooves 25.

 In FIG. 3, the insulator 33 comprises 4 ribs 34 delimiting 4 grooves 35.

 In FIG. 4, the insulator 43 comprises 8 ribs 44 delimiting 8 grooves 45.

 In FIG. 5, the insulator 53 comprises 12 ribs 54 delimiting 12 grooves 55.

 According to an advantageous embodiment, as shown in the figures, the ends 14B, 24B, 34B, 44B or 54B of the respective ribs 14, 24, 34, 44 or 54 closest respectively to the external conductors 16, 26, 36 , 43 or 56 are truncated so as to offer sufficient mechanical support for the respective associated external conductors. It has been found that this also makes it possible to improve the constancy of the impedance of the cable in space.

 According to the invention, the number of ribs of the insulation 13, 23, 33, 43 or 53 can vary between 3 and 24 depending on the applications, and in particular according to the diameter of the cable. The choice of suitable number of ribs will be made to ensure a compromise between the mechanical strength of the coaxial cable, which requires a high number of ribs, and the electrical performance of the cable, which require a low number of ribs, because the more the number of ribs increases, the more massive material there is in the insulation, and therefore the less the dielectric constant of the latter is close to 1, which prevents impedances greater than 50 Q for the small dimensions of the cables according to the invention.

 The best results are obtained by choosing a number of ribs between 6 and 12.

 In addition, it is important to have symmetry in each cross section of a cable according to the invention, that is to say that, in the same section of the cable, the section of each of the ribs is the image. from that adjacent to it (for example the one preceding it) in an axis rotation of the longitudinal axis X of the cable, and of an angle less than or equal to 120.

 By way of comparison, a cable according to the invention having a diameter on insulator of 0.33 mm has an impedance of 78 Q at 1 MHz, while a coaxial cable of the prior art with ventilated insulating tape (this is the type of cable of the prior art which allows optimal electrical performance to be obtained at small dimensions) having a diameter on insulator of 0.32 mm has an impedance of 80 n at the same frequency. It can therefore be seen that with the invention, the electrical performance is comparable while the external conductor is not cylindrical.

 Compared with cables of the prior art with taped insulation, the cable according to the invention has the advantage of allowing easy stripping and of being easy to carry out by extrusion, which makes it possible to obtain a lower production cost. .

 Of course, the invention is not limited to the embodiments which have just been described.

 In particular, the material constituting the intermediate insulator can be chosen from all the materials known in the field of coaxial cables for producing such insulators. It will preferably be massive in order to ensure better mechanical strength of the cable.

This material can be for example FEP, Perfluoroalkoxy (PFA),
PTFE, a polyolefin such as polyethylene, polypropylene or polymethylpentene.

 Likewise, the material constituting the interior and exterior conductors as well as that constituting the exterior protective sheath can be chosen from all the materials known in the field of coaxial cables to fulfill identical functions.

 The external conductor can consist in any known manner, and for example of a braid of wires instead of a winding. However, according to the invention, it will always have a polygonal and not circular section.

 The intermediate insulation is not necessarily extruded, but can be obtained by any suitable method known to those skilled in the art.

 Finally, any means can be replaced by equivalent means without going beyond the ambit of the present invention.

Claims (1)

1 / Coaxial cable (10,20,30,40,50) comprising: - an internal electrical conductor (11,21,31,41,51), - an intermediate insulator (13,23,33,43,53) in a dielectric material, surrounding said inner electrical conductor and comprising a plurality of longitudinal grooves (15,25,35,45,55) separated from each other by ribs (14,24,34,44,54) also longitudinally to define cells, the diameter of the circle circumscribed to the polygon obtained by joining in a cross section of said cable, the ends of said ribs (14,24,34,44,54), being less than or equal to 5 mm, - an electrical conductor outer (16,26,36,46,56) surrounding said insulator (13,23,33,43,53), - an outer protective sheath (18,28,38,48,58) made of an insulating material, surrounding said external electrical conductor, characterized in that said external electrical conductor (16,26,36,46,56) is disposed directly in contact with the ribs (14, 24,34,44,54) of said insulator (13,23,33,43,53) so that its cross section is polygonal.  21 Cable according to claim 1 characterized in that the number of said ribs (14,24,34,44,54) is between 3 and 24, and preferably between 6 and 12.  3 / Cable according to one of claims 1 or 2 characterized in that, in the same cross section of said cable, the cross section of each of said ribs (14,24,34,44,54) is the image of that which it is adjacent to it in an axis rotation with the longitudinal axis (X) of the cable and an angle less than or equal to 1200.  4 / cable according to one of claims 1 to 3 characterized in that the ends (14B, 24B, 34B, 44B, 54B) of said ribs (14,24,34,44,54) furthest from said inner conductor (11 , 21,31,41,51) are truncated so that they provide stable support for said external conductor (16,26,36,46,56).  5 / cable according to one of claims 1 to 4, characterized in that said insulator (13,23,33,43,53) is extruded.  6 / cable according to one of claims 1 to 5, characterized in that the ribs (14,24,34,44,54) and the grooves (15,25,35,45,55) of the insulation (13 , 23,33,43,53) are helical around the longitudinal axis (X) of the cable. Propylene, Perfluoroalkoxy, PTFE, and polyolefins such as polyethylene, polypropylene and polymethylpentene.  7 / Cable according to one of claims 1 to 6, characterized in that said insulator (13,23,33,43,53) consists of a material chosen from Ethylene Fluoride and  8 / cable according to one of claims 1 to 7, characterized in that said inner electrical conductor (11,21,31,41,51) is a strand of metal son (12,22,32,42,52).  9 / Cable according to one of claims 1 to 8, characterized in that said outer conductor (16,26,36,46,56) consists of a helical assembly of metal wires (17,27,37,47 , 57) or metallic ribbons or a braid of metallic threads.  10 / Cable according to one of claims 1 to 9, characterized in that said outer sheath (18,28,38,48,58) is made of FEP.