FR2821480A1 - MULTI-STRANDED MUTUALLY INSULATED CONDUCTOR CABLE WITH CERTAIN NON-ISOLATED INDIVIDUALLY STRANDS AND INDUCING COIL FOR HIGH CURRENTS INCLUDING AT LEAST ONE SUCH CABLE - Google Patents

Abstract

The multistrand conducting cable (9,9') is formed by a determined number (N) of conducting strands (10) all of which have substantially the same cross-section and each of which is electrically insulated from the neighbouring strands. Said conducting strands consist of a first series (N1) made up of several individual strands which are electrically insulated (1) and a second series (N2) of bare strands (2). The cable is made up of a stack of at least two successive coaxial layers of conducting strands (10) having a circular cross-section, said layers being disposed around a central conducting strand (3, 4) and forming a structure such that the difference in the number of strands between two consecutive layers is equal to six. Such a cable is used in the production of high-current inductance coils.

Description

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Mutually insulated multi-strand conductor cable with certain strands not individually insulated, and inductance coil for high currents incorporating at least one such cable
The invention relates to a conductor cable with multiple strands for use in inductors with high currents, the strands preferably being made of the same metal as aluminum. Such a cable is formed of a determined number of conductive strands, all substantially of the same section and each electrically isolated from the strands which are contiguous to it. It is known that the use of mutually insulated multiple-strand conductor cables makes it possible to limit the losses due to the variable magnetic field in high power inductors. A cable generally consists of a bundle of strands surrounded by an insulating sheath. The multi-strand structure allows the bundles to be twisted and then wound into cylindrical windings. It also makes it possible to make the bundles relatively malleable insofar as the circular shape of the section of an original cable can be modified by rolling.

Patent EP 0092018 discloses laminated bundles in rectangular shapes of different dimensions, all made up of the same number of conductive strands each covered with an insulator so as to be electrically isolated from the strands which are contiguous to it. Such a cable embodiment is however not optimal in terms of cost, and the Applicant has sought to reduce the cost price of the cables by intervening in the overall cost of insulating the conductive strands. The Applicant has thus designed different cables based on the same concept of mutual insulation of the conductive strands used, making it possible to globally reduce the amount of product necessary for this insulation.

 To this end, the subject of the invention is a conductor cable with multiple strands for use in inductors with high currents, formed of a determined number of conductive strands all substantially of the same section and each electrically isolated from the strands which it are contiguous, characterized in that the conductive strands consist of a first series consisting of individually electrically insulated strands and in a second series consisting of bare strands.

In one embodiment of a cable according to the invention, the cable consists of a stack of at least two successive coaxial layers of conductive strands of circular sections, said layers being arranged around a central conductive strand and forming a structure such that two consecutive layers have a difference in number of strands equal to six.

In a first embodiment, the cable comprises two coaxial layers arranged around a bare central strand. The first layer consists of strands all individually insulated, the second layer consists of alternating

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 individually insulated strands and bare strands. In a second embodiment, the cable comprises three coaxial layers arranged around an insulated central strand. The first layer consists of alternating individually insulated strands and bare strands, the second layer consists of strands all individually insulated, and the third layer consists of nine individually insulated strands and nine bare strands arranged alternately.

In one embodiment of a cable according to the invention, the cable has a section of approximately rectangular shape, said shape being obtained by compression of an initial cable of circular section in two perpendicular radial directions.

The invention advantageously applies to an inductor for high currents as described in patent EP 0092018, which makes it possible to significantly reduce the cost of manufacturing such a coil. Such an inductor comprises individual coaxial coils, each formed by the winding of a compressed cable from an initial cable according to the invention.

In an embodiment of an inductor using cables according to the invention, the conductive strands of an individual coil have a section which is different from that of the strands of another coil and which is up to 20 % lower than that of the strands of the original cables. In another embodiment, each conductive strand of an individual coil has a section which varies over part of the length of the strand.

Examples of embodiment of cables and inductors according to the invention are described below in relation to the following figures.

Figure 1 is a schematic sectional view of an embodiment of a cable with nineteen strands, according to the invention.

FIG. 1a is a schematic representation of the two-layer structure and of the properties of symmetry of the nineteen-strand cable shown in FIG. 1.

Figure 2 is a schematic sectional view of an embodiment of a cable with thirty seven strands, according to the invention.

FIG. 2a is a schematic representation of the three-layer structure and of the properties of symmetry of the thirty-seven-strand cable shown in FIG. 2.

FIG. 3 is a schematic sectional representation of a cable obtained by rolling an initial cable as shown in FIG. 2.

Figure 4 is a schematic representation in longitudinal half section of an inductor for high currents, using cables according to the invention laminated into rectangular shapes.

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A first example of a cable according to the invention is shown in cross section in FIG. 1. This cable comprises nineteen conductive strands 10 of the same circular sections, which consist of a first series NI of twelve strands 1 individually electrically insulated and in a second N2 series made up of seven bare strands 2. A strand 1 is individually electrically insulated, for example by a varnish or an enamel applied to its surface, and a conductive strand 2 is described as bare, the metal surface of which is not covered with any insulating. As shown in Figure la, the cable structure forms a radial stack of two coaxial layers 5, 6 of strands, these layers being arranged around a central conductive strand 3 naked. It can be noted that all the conductive strands 1 or 2 of the same first or second series NI or N2 are arranged in an axial symmetry with respect to the central strand 3 which constitutes the longitudinal axis of the cable. The first layer 5 and the second layer 6 consist respectively of six strands and twelve strands. The second layer 6 consists of an alternation of individually insulated strands 1 and bare strands 2, and surrounds the first layer 5 which consists only of individually insulated strands 1. This structure allows the cable to be able to be deformed within certain limits by adequate compression consisting of rolling in two orthogonal directions, without risking contacting two bare strands which would alter the mutual insulation of the strands. From an economic standpoint, in comparison with conventional cables with nineteen strands all individually insulated, the cable produced according to the invention obviously allows the quantity of enamel or varnish used to be substantially reduced.

The multi-strand cables preferably used in the invention have a structure in successive coaxial layers such that two consecutive layers have a difference in number of strands equal to six. The number of strands constituting such cables is therefore easily calculated as a function of the number of layers. A two-layer cable as described above has 1 + 6 + 12 or 19 strands.

 A second example of a cable according to the invention is shown in cross section in Figure 2. As shown in Figure 2a, this cable 9 consists of three successive coaxial layers 5, 6, and 7 of conductive strands 10 of the same circular sections . These layers are arranged around an individually insulated central conductor strand 4, unlike the first example where the central strand is bare. The number of strands of the cable is calculated as the sum 1 + 6 + 12 + 18, or 37 strands. As in the first example, the last layer consists of an alternation of individually insulated strands 1 and bare strands 2, and surrounds the penultimate layer which consists only of

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 individually insulated strands 1. This embodiment of a 37-strand cable allows it to be compressed within certain limits without altering the mutual insulation of the strands.

It can be noted that any bare conductive strand 2 at the level of the last layer 7 of the cable is symmetrical with an insulated conductive strand 1, according to an axial symmetry with respect to the central strand 4.

 FIG. 3 represents a cross section of a cable 9 ′ obtained by the moderate rolling of an initial cable 9 with three circular coaxial layers as shown in FIG. 2. It is known from patent EP 0092018 that cables with multiple strands all individually insulated, of circular section, can be compressed within certain limits by rolling so as to give them at least approximately a rectangular section. The initial cable 9 according to the invention, shown in FIG. 2, likewise has a circular section which can be compressed until an approximately rectangular shape 8 is obtained which has a width e and a height h. The w / h ratio is within a certain range depending on the type of strands used in an initial cable 9 and the type of insulation used for the strands, so as to maintain sufficient insulation between the strands after compression by rolling the initial cable. The lower and upper limits of the range are not fixed on the date of the request for a given type of initial cable and insulation, because they depend on the results of validation tests of the insulation of a 9 'laminated cable. . The Applicant has been able to verify that among the various known isolation techniques such as varnishing, enameling or even oxidation, applicable to the conductive strands of a cable according to the invention, there is an enameling technique with a type enamel which perfectly withstands the stresses produced by rolling in a range of the w / o ratio between 0.7 and 1.5. It is not however excluded that this range could be widened further, for example between 0.5 and 2, following additional validation tests. Likewise, new insulation processes or products even more resistant to mechanical stress could be developed to further increase the acceptable limits of deformation of an initial cable.

 Figure 4 shows in longitudinal half-section an inductor for high currents using multiple strand conductive cables laminated in rectangular shapes, as described in patent EP 0092018, but where the cables used are cables 9 'with certain strands not individually insulated, according to the invention. The inductor here comprises three individual coils 11 each produced by winding a cable 9 'in turns isolated from each other. Conventionally, the coils 11 are arranged one inside the other in a coaxial manner

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 around the axis A of symmetry of the inductor, to provide between them cylindrical air volumes 12 necessary for the electrical insulation and for their cooling. They have between them numbers of turns which decrease with their diameter while retaining approximately the same axial winding height H. As described above, the cables 9 'are made up of conductive strands 1 and 2 which are electrically isolated from each other, and are compressed into shapes 8 of different dimensions in the direction of the axis A of the coil. A magnification of the section of a cable 9 is shown on the right of the figure. The central individual coil of the cable 9 is represented in the drawing with an el / hl ratio approximately equal to 2, which in practice constitutes a limit value of the w / h ratio which is not yet validated at the date of the request. .

Because the number of turns of an individual coil decreases with the diameter of the winding, the shape 8 of the section of each cable 9 ′ has a w / o ratio which generally also decreases with this diameter.

In an economical embodiment of the inductor, the cables 9 'forming the individual coils 11 are all made from identical initial cables 9. The conductive strands 10 of a cable 9 'are then all of substantially the same section for a given coil 11. Although the simplest embodiment consists in using cables 9 ′ with the same conduction sections for all the individual coils 11, the Applicant has designed another embodiment in which the coils 11 have relatively conduction sections between them different. This result may seem surprising given the fact that in this economical embodiment, the coils 11 are all formed from identical initial cables 9. It is explained by the fact that the applicant has been able to note by appropriate tests that an initial cable 9 can be stretched longitudinally during the compression operation by rolling, up to a certain limit of elongation of the strands, without deterioration of the insulation used which covers the first series of strands. Thus, the cable 9 ′ obtained has a conduction section which can be up to approximately 20% less than that of the initial cable. There are therefore two options for economically producing an inductor according to the invention: a first where all the individual coils 11 have the same conduction section, and a second where at least two individual coils 11 have sections between them of relatively different conduction. This second option can have interesting technical advantages, with in particular the possibility of producing a central coil 11 with a conduction section different from those of the coils which surround it, in order to limit the heating in the center of the inductor where the cooling is less effective than at the periphery. Of course, other arrangements can be

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être réalisée de façon moins économique à partir de câbles initiaux 9 dont au moins deux possèdent des sections de conduction relativement différentes. Il faut alors disposer d'au moins deux types de câbles à brins multiples pour entamer la fabrication de la bobine d'inductance. produced, for example where all the coils 11 are of the same section except the peripheral coil 11, which may have a higher current density because it is better cooled than the internal coils by its position. It is obvious that the inductance coil produced in this second option can also

be made less economically from initial cables 9, at least two of which have relatively different conduction sections. It is then necessary to have at least two types of cables with multiple strands to start manufacturing the inductor.

The second option described above can also be declined in different embodiments in which the longitudinal stretching of a cable 9 during rolling is not carried out uniformly over the length of cable used for an individual coil 11. Thus, the strands 1 and 2 of a cable 9 'of a coil 11 can each have sections which vary over part of their length. In particular, the section of a strand may be provided larger towards the end of the cable in the lower part of the inductor than over the remaining part of the length of the strand, since the lower part of a cable is better cooled as the rest of the cable. Thus, from identical initial cables 9, there are several different embodiments of an inductor according to the invention.

Claims (13)

 CLAIMS 1 / Conductive cable with multiple strands for use in high current inductors, formed by a determined number (N) of conductive strands (10) all substantially of the same section and each electrically isolated from the strands contiguous to it , characterized in that said conductive strands consist of a first series (NI) consisting of individually electrically insulated strands (1) and in a second series (N2) consisting of bare strands (2). 2 / conductive cable according to claim 1, wherein the cable consists of a stack of at least two successive coaxial layers of conductive strands (10) of circular sections, said layers being arranged around a central conductive strand (3 , 4) and forming a structure such that two consecutive layers have a difference in number of strands equal to six. 3 / conductor cable according to claim 2, in which the last layer consists of alternating individually insulated strands (1) and bare strands (2), and in which this last layer surrounds a penultimate layer consisting of strands all individually isolated (1). 4 / conductive cable according to claim 3, wherein the cable comprises two coaxial layers (5,6) arranged around a bare central strand (3). 5 / conductive cable according to claim 3, wherein the cable comprises three coaxial layers (5,6,7) arranged around an insulated central strand (4). 6 / conductor cable according to one of claims 1 to 5, wherein the cable (9 ') has a section of shape (8) approximately rectangular, said shape being obtained by compression of an initial cable (9) of circular section in two perpendicular radial directions. 7 / conductor cable (9,9 ') according to one of claims 4 and 6, wherein all the conductive strands (1,2) of the same first or second series (Ni, N2) are arranged in an axial symmetry relative to the central strand (3). 8 / conductive cable (9,9 ') according to one of claims 5 and 6, wherein any bare conductive strand (2) at the last layer (7) is symmetrical with an insulated conductive strand (1) according to an axial symmetry with respect to the central strand (4). 9 / Inductance coil for high currents, comprising at least two individual coils (11) each produced by winding an insulated conductive cable, said coils (11) being arranged one inside the other coaxially around the axis (A) of symmetry of the inductor coil to provide air volumes between them (12) and having between them decreasing numbers of turns <Desc / Clms Page number 8>  with their diameter while retaining approximately the same axial winding height (H), said conductive cables being made up of multiple strands electrically insulated from each other and being compressed into shapes (8) of different dimensions in the direction of the axis ( A) of the coil, characterized in that at least one individual coil (11) is formed from a conductive cable (9 ') which has a certain number of bare strands (2), the other strands (1) being electrically isolated. 10 / Inductor according to claim 9, wherein the cables (9 ') forming the individual coils (11) are all made from identical initial cables (9) of the same circular section, the conductive strands (10) d 'A single individual coil (11) all being substantially of the same section. 11 / Inductance coil according to claim 10, wherein the conductive strands (10) of an individual coil (11) have a section which is different from that of the strands of another coil (11) and which is up to 20% lower than that of the strands of said initial cables (9). 12 / Inductor according to claim 11, wherein each conductive strand (10) of an individual coil (11) has a section which varies over part of the length of the strand. 13 / Inductance coil according to one of claims 9 to 12, wherein at least one individual coil (11) is formed by the winding of a cable according to claim 6.