EP0298878A1 - Toroidal transformer with an integrated self-induction device - Google Patents

Abstract

The transformer comprises a closed annular main magnetic circuit (20), on which an internal electrical winding (26) is wound. A magnetic core (42), in the form of an open annular sector, is held at the periphery of the internal winding by peripheral bars (35). The assembly is covered by the external electrical winding (48). The magnetic core (42) determines the value of the transformer self-inductance.

Description

The present invention relates to electrical transformers intended for the transmission of electrical energy, and more particularly to transformers in which at least one of the windings has an integrated self-inductance.

Transformers with integrated self-inductance are generally formed around a conventional magnetic circuit with two or three parallel columns connected by two end crosspieces, the primary and secondary windings being wound around the central column. The integrated self-inductance is achieved by providing an open auxiliary magnetic circuit, surrounded by only one of the primary or secondary electrical windings. This secondary magnetic circuit, not saturable under the usual conditions of use, allows for example to limit the short-circuit current of the transformer.

These conventional magnetic circuit transformers have the disadvantage of being relatively bulky and heavy; the configuration of the magnetic circuit causes harmful electromagnetic radiation in the vicinity of the transformer, radiation further increased very significantly when incorporating a secondary magnetic core to achieve self-inductance.

Electric transformers are also known, generally called toroidal transformers, the magnetic core of which has a closed annular shape. The primary and secondary windings of such a transformer are generally wound on top of each other. We know that such a transformer is, at equal power, less bulky and lighter than a conventional magnetic circuit transformer with two or three columns.

Such a toroidal transformer is however more difficult to produce, and in particular more difficult to wind, since the magnetic circuit is already closed during the winding and the electric winding wire must pass as many times through the central chimney of the magnetic circuit as '' there are turns to form the winding.

Attempts have been made to produce toroidal transformers with integrated self-inductance, by separating the primary and secondary windings from one another, that is to say by winding a first winding on a first circular sector of the magnetic circuit, and winding the other winding on a second circular sector of the magnetic circuit different from the first sector. Such a solution does not prove to be usable industrially, because it makes the electrical windings even more difficult to wind on the toroid, and the winding cannot be easily automated. Such an arrangement also leads to increasing the volumes, the copper sections constituting the windings, and the heating of the transformer; the self-inductance thus obtained is difficult to control quantitatively, when it is desired to design a transformer having new characteristics. It is further noted that this structure leads to a significant increase in the electromagnetic radiation in the vicinity of the transformer.

The object of the present invention is in particular to avoid the drawbacks of known transformers, by proposing a new toroidal transformer structure with integrated self-inductance which is particularly simple and easy to wind, to assemble.

According to another object of the invention, this new structure makes it possible to design a transformer with integrated self-inductance around which the electromagnetic radiation is relatively much weaker.

According to another object of the invention, the structure makes it possible to adjust and control at will the value of the integrated self-inductance, by a simple mechanical displacement of certain parts of the structure; it is thus much easier to design and produce transformers with new electrical characteristics, and the characteristics can be obtained precisely.

According to another object of the invention, the new structure is relatively inexpensive, because the magnetic circuit is composed of elements whose shapes are simple and easy to produce, and whose assembly is particularly rapid and requires only a little workforce. The structure is also particularly well suited to allow very extensive automation of the assembly.

Another important problem which the present invention aims to solve is the thermal heating appearing in transformers with a toric circuit. At equal power, this temperature rise is relatively greater than in transformers with a conventional magnetic circuit with three columns, because in these conventional transformers, the heat exchange surfaces are much more important. In the case of a toroidal transformer, the internal electrical winding is totally trapped by the layers of electrical insulation and by the external electrical winding, so that the heat exchanges are considerably slowed down.

The invention therefore provides particularly advantageous embodiments, in which the electrical insulation means have a shape and a structure allowing thermal transfer from the interior electrical winding to the outside, and notably increasing the natural cooling of the windings. . Consequently, such a structure makes it possible to reduce the cross section of the conductors, hence a significant gain on the weight of copper, a very expensive material.

Another object of the invention is to reduce the average length of the turns constituting the electrical windings of the transformer, without harming the electrical insulation or the section of the magnetic circuit.

The invention also allows the winding of toroidal transformers with a flat wire of large section. Due to the rectangular cross-section of the magnetic circuit, the turns are arranged radially. They are therefore contiguous in the bore of the torus and spread over the outer periphery, by difference in the developed lengths of the outside and inside diameters of the torus. After having wound a first layer of contiguous turns in the bore of the torus, the next layer tends to be superimposed on the previous one in the bore, but to be inserted between the turns of the first layer on the external periphery. In an intermediate zone, the external turns come to bear on the internal turns at a point on their edge, so that the contact taking place on a very small surface constitutes a support zone at very high pressure liable to damage the electrical isolation. The invention provides means for avoiding this effect of concentration of the tensile force on two point supports at each turn.

Another object of the invention is to ensure correct maintenance of the auxiliary magnetic circuit carrying out the integrated self-inductance, so as to avoid sheet metal vibrations generating harmful noises.

Another important object of the invention is to reduce considerably the number of parts necessary to ensure the electrical insulation of the windings. This results in a reduction in the cost of raw materials, and above all a reduction in the cost of the labor required for assembly.

To achieve these and other objects, the toroidal transformer according to the present invention comprises a closed annular main magnetic circuit, means for electrically isolating the external surface of the magnetic circuit, an internal electrical winding wound on the circuit insulation. main magnetic, an intermediate electrical insulation surrounding the interior electrical winding, and an exterior electrical winding wound around the intermediate electrical insulation. The transformer according to the invention further comprises at least one magnetic core, comprising at least one open annular sector bounded by an air gap and arranged parallel to the annular main magnetic circuit between the interior electrical winding and the exterior electrical winding. The magnetic core determines, by its structure and its position, the value of the self-inductance of the external electric winding.

According to an advantageous embodiment, the magnetic core comprises at least one annular sector disposed around the periphery of the interior winding. As an alternative or in addition, the magnetic core comprises at least one annular sector disposed in the central chimney of the interior winding.

According to a particular embodiment, the core comprises two successive annular sectors arranged around the periphery of the interior winding. This facilitates the insertion of the magnetic core and the adjustment of the inductance by positioning the successive annular sectors.

In a first embodiment, the electrical insulation means comprise an upper ring and a lower ring, made of an insulating and rigid material, the external contours of which are connected to each other by axial bars forming a support for the peripheral magnetic core. The peripheral magnetic core advantageously consists of a stack of curved sheets around the periphery defined by the axial bars and on which it is held by insulating peripheral wrapping. This structure considerably facilitates the mounting of the transformer, that is to say the assembly of its constituents, and the adjustment of the self-inductance can be ensured by sliding the sheets in the housing defined between the axial bars and the peripheral wrapping.

The upper and lower rings advantageously comprise a circular internal contour with a diameter less than the internal diameter of the annular main magnetic circuit; the crowns thus form a support on which the external winding can be wound. The rings thus ensure a separation of the two windings, increase the heat exchange surface, participate in the electrical insulation, and define a rigid support allowing the automation of the winding of the external winding.

In a preferred embodiment, adapted to a shape of a toric magnetic circuit with a substantially rectangular section, the electrical isolation means comprise an upper toric cap, electrically insulating, and a lower toric cap, electrically insulating; each toric cap is limited by a circular external contour of diameter only a little greater than the external diameter of the ring formed by the internal electrical winding, and being limited by a circular internal contour of diameter only a little less than the internal diameter of l ring formed by the internal electrical winding; the respective contours of the upper cap and the lower cap opposite one another are separated by a space promoting the transfer of heat energy. This embodiment significantly increases the transfer of heat energy from the interior winding to the outside, and provides a significant gain in space in the central bore of the circuit.

The outer faces of the cap edges advantageously have a rounded cross section. This arrangement significantly reduces the length of copper necessary for the realization of the electrical winding, and improves the regularity of winding.

The outer contour of each of the caps may advantageously comprise an annular groove facing the annular groove of the other cap; the magnetic core, comprising a stack of curved sheets, is held by the caps, the edges of the magnetic core being pinched respectively in the upper cap groove and in the lower cap groove. Optionally, the caps provide themselves maintaining the electrostatic screens of the transformer.

• - la figure 1 représente une vue générale de côté d'un transformateur selon la présente invention ;
• - la figure 2 représente une vue de dessus du transformateur de la figure 1 ;
• - la figure 3 est une vue de dessus en coupe selon le plan A-A de la figure 1 dans un premier mode de réalisation ;
• - la figure 4 est une demi-vue de côté en coupe selon le plan B-B et à plus grande échelle de la figure 3;
• - la figure 5 illustre les inconvénients d'une bobinage de fil de gros diamètre sur un circuit à section rectangulaire ;
• - la figure 6 illustre l'advantage de bobinage d'un fil de gros diamètre sur un circuit dont les coins sont arrondis ;
• - la figure 7 illustre les inconvénients de bobinage d'un conducteur électrique plat à section rectangulaire sur un circuit magnétique torique ;
• - la figure 8 illustre, à grande échelle, l'imbrication des spires selon la présente invention ;
• - la figure 9 est une vue en bout d'axe des enroulements électriques de transformateur torique à conducteur électrique plat de section importan­te ;
• - la figure 10 est une vue de dessus en coupe selon le plan A-A de la figure 1, dans un second mode de réalisation ; et
• - la figure 11 est une demi-vue de côté en coupe selon le plan C-C et à plus grande échelle de la figure 10.

Other objects, characteristics and advantages of the present invention will emerge from the following description of particular embodiments, given in relation to the attached figures, among which:

• - Figure 1 shows a general side view of a transformer according to the present invention;
• - Figure 2 shows a top view of the transformer of Figure 1;
• - Figure 3 is a top view in section along the plane AA of Figure 1 in a first embodiment;
• - Figure 4 is a half side view in section along the plane BB and on a larger scale in Figure 3;
• - Figure 5 illustrates the drawbacks of a winding of large diameter wire on a rectangular section circuit;
• - Figure 6 illustrates the advantage of winding a large diameter wire on a circuit whose corners are rounded;
• - Figure 7 illustrates the disadvantages of winding a flat electrical conductor with rectangular section on a toroidal magnetic circuit;
• - Figure 8 illustrates, on a large scale, the nesting of the turns according to the present invention;
• - Figure 9 is an end-of-axis view of the electrical windings of toroidal transformer with flat electrical conductor of large section;
• - Figure 10 is a top view in section along the plane AA of Figure 1, in a second embodiment; and
• FIG. 11 is a half side view in section along the plane CC and on a larger scale of FIG. 10.

The transformer according to the present invention, shown in Figures 1 and 2, has a generally annular exterior shape. The body 1 of the transformer is a ring of axis II and of substantially rectangular section. The body is integral with a fixing and transport assembly 2 comprising a first end element 3 and a second end element 4 applied respectively to the first flank 5 of the body 1 and to the second flank 6 of the body 1. The end elements 3 and 4 are connected by a central column 7 of link, surmounted by a carrying loop 8.

In the embodiment shown in FIG. 2, the end elements, such as the first element 3, comprise three divergent branches in a star. Thus, the first end element 3 comprises the branches 9, 10 and 11. The branches meet in the center, in the axis II of the transformer, and are integral with the central connecting column 7. The central connecting column 7 crosses the central chimney 12 of the body 1. A support plate 13, integral with the first end element 3, supports the electrical connection terminals of the transformer. The divergent branches have their internal faces shaped to match the shape of the first flank 5 or of the second flank 6 of the body 1, in the vicinity of the central chimney 12 of the body 1, thus ensuring a lateral connection between the body 1 and the assembly of fixing and transport 2.

Figures 3 and 4 illustrate the internal constitution of the transformer body 1 according to a first embodiment of the invention. For clarity of the drawings, the sheets of the magnetic circuit have been partially represented; the same applies to the conductors constituting the transformer windings, conductors which are shown in cross section in FIG. 3 and in longitudinal section in FIG. 4.

In the embodiment shown in these figures, the transformer comprises a main magnetic circuit 20 in the form of a closed circular ring, of rectangular section. The magnetic circuit consists, in known manner, of a circular sheet winding.

The magnetic circuit 20 is electrically isolated over its entire surface. The electrical insulation can advantageously be ensured by an internal strip 21 covering the wall of the internal chimney of the magnetic circuit, an external strip 22 covering the peripheral wall of the magnetic circuit, an upper flange 23 covering the upper flank of the magnetic circuit and a flange lower 24 covering the lower side of the magnetic circuit. The insulation can be completed by a wrapping 25, the wrapping simultaneously ensuring the maintenance of the flanges 23 and 24 and the strips 21 and 22 on the magnetic circuit, to define a manipulable sub-assembly capable of receiving a winding by mechanical means. ques automatic.

The sub-assembly thus formed receives, by winding in a known manner, a first electrical winding called internal winding 26, consisting of a suitable number of turns of electric wire wound around the magnetic circuit 20.

A flat upper crown 27 is applied against the upper flank 28 of the internal electrical winding 26, and a flat lower crown 29 is applied against the lower flank 30 of the internal electrical winding 26. The crowns 27 and 29 are made in one electrically insulating material having sufficient rigidity to support and maintain the external electrical winding without excessive deformation. Preferably, the upper 27 and lower 29 rings have identical external contours 31 and 32, and internal contours 33 and 34 which are also identical, the crowns being both centered on the axis I-I of the transformer. The upper 27 and lower 29 rings are connected, in the vicinity of their external contours 31 and 32, by axial bars 35, and, in the vicinity of their internal contours 33 and 34, by axial columns 36. In the embodiment shown , the transformer comprises four axial columns such as column 36, regularly distributed around the periphery of the central chimney of the internal electrical winding 26. According to one embodiment, the columns 36 can be in abutment against the internal wall of the winding interior electric 26; according to another embodiment, an electrostatic screen 37 can be interposed between the columns 36 and the interior wall of the interior electrical winding 26, as shown in FIG. 4. The interior contours 33 and 34 have a circular shape of smaller diameter to the inside diameter of the ring formed by the inside electric winding 26, so as to define two surfaces against which the conductors forming the outside electric winding 38 come to bear and curve.

Similarly, the outer contours 31 and 32 of the crowns 27 and 29 have a circular shape with a diameter greater than the outer diameter of the ring formed by the inner electrical winding 26. Thus, the contours 31 and 32 form a bearing surface for the electrical conductors of the external electrical winding 38. The rings form a support on which the external electrical winding 38 is wound, and participate in the electrical isolation of the windings from one another.

The upper 27 and lower 29 rings are made of an electrically insulating and mechanically rigid material. The columns 36 have a circular section, and their ends are inserted into axial holes 39 of corresponding section of the crowns. The bars 35 have a rectangular section, and their ends engage in radial notches 40 of corresponding section of the crowns. The bars have an external notch 41, of length substantially equal to half the height of the magnetic circuit 20, and of sufficient depth to receive the magnetic core 42. In the embodiment shown, the transformer comprises twelve axial bars such as the strip 35, regularly distributed around the periphery of the ring formed by the internal electrical winding 26. According to one embodiment, the strips can be pressed against the internal electrical winding. According to the embodiment shown, an electrostatic screen 49 is interposed between the bars 35 and the internal electrical winding 26.

The magnetic core 42 consists of a stack of magnetic sheets, of rectangular shape, bent and applied radially from the outside in the notches 41 of the bars 35. The notches 41 therefore have a length slightly greater than the height of the magnetic core . After application, the sheets of the magnetic core 42 are held in position pressed into the notches by a peripheral tape 43 for isolating and holding the magnetic core.

According to the invention, the magnetic core 42 has an open profile in the form of an annular sector, substantially parallel to the main magnetic circuit 20 and limited by an air gap. In the embodiment shown in FIG. 3, the magnetic core 42 consists of a first annular sector 44 and a second successive annular sector 45 arranged around the periphery of the internal electrical winding 26. The ends of the two sectors successive annulars 44 and 45 are separated on one side by a first air gap 46 of small thickness, and are separated on the other side by a second air gap 47 much larger. The air gap 47, represented on the Figure 3, occupies a little over a quarter of the circumference. We understand that we can slide the magnetic sheets forming the first sector 44 and / or the second sector 45, at the periphery of the bars 35, to adjust the value of the self-inductance of the transformer.

The bars 35 and the columns 36 are secured to the upper 27 and lower 29 rings, for example by gluing or force fitting, so that the assembly constitutes a sub-assembly of a single piece capable of being wound by means automatic mechanicals to receive the external electric winding. Thus, the exterior electrical winding 48 forms the exterior layer of the transformer body. In the embodiment shown, the outside winding 48 covers the magnetic core, the inside winding and part of the area of the second air gap 47.

In other embodiments, an external electrical winding 48 can be provided which covers the entire magnetic circuit and the internal winding.

The magnetic core 42, in the embodiment shown in FIG. 4, has a height equal to approximately half the height of the magnetic circuit 20, and is placed halfway up the main magnetic circuit 20.

It is understood that, according to the invention, the magnetic core 42 is disposed between the interior electrical winding 26 and the exterior electrical winding 48. This magnetic core 42 determines the value of the self-inductance presented by the exterior electrical winding 48. One can in particular use the transformer according to the invention by choosing the internal winding as secondary winding, and the external winding 48 as primary winding, so that the transformer is then a transformer whose primary has self-inductance .

In FIG. 3, the references 481 and 482 designate the outputs of the external electrical winding 48. This winding is formed by four strands wound in parallel. The references 261 and 262 designate the ends of the internal electrical winding 26, and the reference 263 designates the midpoint thereof. This winding is formed by three strands wound in parallel. Reference 370 designates the outputs of grounding conductors of screens 37 and 49.

It is conceivable, without departing from the scope of this invention, different arrangements of the magnetic core 42. Thus, according to a second embodiment, the magnetic core can be shaped into an annular sector disposed in the central chimney of the inner winding 26.

According to a third embodiment, the magnetic core can be shaped into an annular sector disposed on one of the sides 28 or 29 of the inner winding 26.

One can also design a magnetic core 42 in several parts, some parts being arranged on the sides 28 or 30, certain other elements being arranged on the periphery or inside the chimney.

Figures 9 to 11 illustrate the internal constitution of the transformer body 1 according to a second embodiment of the invention.

The main magnetic circuit 20 of this embodiment is the same as that of the embodiment of Figures 3 and 4, namely a closed circular ring, of rectangular section, consisting of a circular sheet winding.

The magnetic circuit 20 is electrically isolated over its entire surface. According to this embodiment, the means for electrically isolating the magnetic circuit comprise an upper toroidal insulating cap of the magnetic circuit 50, a lower insulating cap of the magnetic circuit 51, each covering the respective upper face and lower face of the magnetic circuit 20 and part of the outer and inner lateral faces of the magnetic circuit, the caps 50 and 51 being connected by an outer cylindrical electrical insulator 52 and an inner cylindrical electrical insulator 53. The upper 50 and lower 51 caps for magnetic circuit isolation have, on their external faces, a rounded outer edge 54, and a rounded inner edge 55.

The advantage of the rounded edges 54 and 55 is explained in relation to FIGS. 5 and 6: when the electrical conductor is wound on the toroidal magnetic circuit, and more particularly when the electrical conductor has a relatively large section, it does not it is not possible to bend the conductor at a right angle when passing each edge. Thus, in FIG. 5, when the magnetic circuit has sharp edges, the electrical conductor, wound around the magnetic circuit 20 in the direction of the arrow 156, forms corners rounded, the beginning of each curve starting at the corner of the magnetic circuit, the end of each curve ending away from the magnetic circuit, thus defining at each corner a clearance such as clearance 157. With a conductor whose thickness is approximately 2 mm, such a clearance may exceed 3 mm. As a result, the electrical winding occupies a much larger section than the section of the magnetic circuit, and this section is offset from the section of the magnetic circuit, as shown in Figure 5. In addition to the loss caused by the increase resulting in volume, winding difficulties ensue, and the winding generally lacks regularity.

On the contrary, by providing rounded edges such as edges 54 and 55, the electrical conductor follows the shape of the edge perfectly on each pass, and is thus correctly applied to the insulation, each of its branches being parallel to the corresponding side of the magnetic circuit. One might think that the fact of providing rounded edges 54 and 55 would tend to increase the apparent section of the assembly formed by the magnetic circuit and its external insulator. In reality, and surprisingly, it is found that this arrangement tends, on the contrary, to reduce the length of the conductor turn surrounding the magnetic circuit, and this results in a saving of copper forming this conductor.

A partial wrapping can join the insulators 50, 51, 52 and 53 around the magnetic circuit. The sub-assembly thus formed then receives, by winding, in a known manner, the first internal electrical winding 26. In the embodiment shown, the internal winding 26 consists of a suitable number of turns of flat electrical conductor with section rectangular. There is shown a three-layer winding, a first layer 260 formed of radial turns which are contiguous in the central chimney 12 of the circuit, and which are spaced from one another on the lateral external peripheral face of the circuit; this first layer 260 is covered by a second layer 261, shown partially in Figure 9, formed of radial turns also contiguous in the central chimney 12, itself surmounted by a third layer 262 of the same structure, which covers it.

An upper toric cap 56 is fitted against the side upper 28 of the inner electric winding 26, and a lower toric cap 57 is fitted against the lower flank 30 of the inner electric winding 26. The upper 56 and lower toric caps 57 are made of an electrically insulating material having a certain flexibility . Preferably, the upper 56 and lower 57 caps are identical. They respectively have circular external contours 58 and 59 with a diameter only slightly greater than the external diameter of the ring formed by the internal electrical winding 26. The caps 56 and 57 are limited by an internal contour, respectively 60 and 61, circular of diameter only a little less than the inside diameter of the ring formed by the inside electric winding 26. The outside contours 58 and 59 of the two caps 56 and 57 are separated from each other by a space 62 promoting transfer of heat energy from the inside winding 26 to the outside. Likewise, the contours 60 and 61 are separated from each other by a space 63 favoring the passage of heat energy from the interior winding 26 towards the central chimney 12.

The upper 56 and lower 57 caps are shaped to be applied with little play on the inner winding 26. After their installation, they can be held in position by any means, for example by a few turns of ribbon divided in two or three zones on the periphery of the circuit.

Each cap 56 or 57 comprises an inner rim 64 partially covering the inner cylindrical face of the inner electrical winding 26, and an outer rim 65 partially covering the outer lateral cylindrical face of the inner electrical winding 26. These edges ensure the fitting caps 56 and 57 on the inside winding, and their thickness defines the thickness of the air gap separating the inside electric winding 26 from the outside electric winding or the magnetic shunt.

It can be seen in FIG. 11 that the external contours 58 and 59 of the two caps 56 and 57 have a particular shape: thus, the external contour 58 of the cap 56 comprises an annular groove 66, and the external contour 59 of the cap 57 comprises an annular groove 67, the grooves 66 and 67 facing each other as shown in the figure.

The magnetic core 42, consisting of a stack of curved magnetic sheets, of rectangular shape, has an upper edge 68 engaged in the groove 66 and a lower edge 69 engaged in the groove 67. When winding the outer winding, over the caps 56 and 57, the walls of the grooves 66 and 67 tend to tighten and pinch the edges of the magnetic core 42. This results in a very tight hold of the sheets, avoiding noise and vibration, and facilitating their mounting . Despite the tightening, it remains possible to slide one of the sheets forming the magnetic core 42, for subsequent adjustment of the transformer. In this embodiment, the magnetic core 42 has an open profile, in the form of an annular sector with a single air gap 47.

The external electrical winding 48, formed of radial turns, covers the assembly thus formed. The caps 56 and 57 form the support of the external electrical winding 48.

The external faces of the contours 58, 59, 60 and 61 of the caps 56 and 57 advantageously have a rounded cross section, as shown in FIG. 11. Thanks to this rounded section, the mean external winding turn 48 has a reduced length, and the winding is more regular. The outer face of the caps 56 and 57 also has a special feature which makes it possible to solve the problems linked to the winding of a flat electrical conductor of large section on a toric core. The problem encountered is illustrated in FIGS. 7 and 8. By the fact that the turns of a first layer 70 are contiguous in the zone 71 facing the central chimney 12 of the circuit, the same turns are discarded in the outer zone 72. When an upper layer of turns is wound over the lower layer 70, for example when the conductor 73 is positioned, this conductor overlaps two conductors of the lower layer 70 in the vicinity of the zone 71, but tends to be inserted between two conductors of the lower layer 70 in the vicinity of the external zone 72. The transition from the overlap to the insertion takes place in an intermediate zone, in which the conductor 73 is folded and comes to bear at two lateral points 74 and 75 on each of the conductors of the lower layer 70. These punctual lateral supports are, the seat of significant pressure, producing damage to the conductive insulators.

To avoid this drawback, the caps 56 and 57 comprise, on their outer flat faces, shims 75, regularly distributed in a circle in an intermediate zone between the inner contour and the outer contour of the caps. The spacers 75 have a height substantially equal to the thickness of the flat conductor, and are separated from each other by a space 76 of width greater than the width of the flat conductor forming the winding. Thus, to form the outer winding 48, a first winding layer 77 is formed by conductor turns each engaged between two successive shims. A second winding layer 78 is constituted by turns of conductor each passing over the upper face of a block, as shown in FIG. 9. Thus, as seen in FIG. 8, the block 75 avoids point contact lateral between the conductors of the lower layer 70 and the conductor 73 of the upper layer.

The caps 56 and 57 ensure the mechanical retention of the magnetic core 42. As shown in FIG. 9, the caps 56 and 57 can also ensure the maintenance of the electrostatic screens 37 and 49, arranged between the primary winding and the secondary winding of the transformer.

The annular grooves 66 and 67 ensuring the maintenance of the magnetic core 42 can be interrupted on a part of their periphery, allowing the manipulation of the sheets of the magnetic circuit 42 for their displacement by peripheral sliding. The sheets are accessible in the area of the air gap 47, an area which is not entirely covered by the external electrical circuit 48. In reality, the external electrical circuit 48 covers the entire toroid, except for a part of the air gap 47.

One can take advantage of the presence of caps 56 and 57 to provide, in their upper or lower surfaces, chimneys for the passage of conductors to maintain and ensure the passage of the ends of the inner windings.

In the embodiment shown in Figures 9 to 11, only the caps 56 and 57 are provided with shims 75. Surprisingly, it has been observed that the presence of these shims 75 considerably improves the regularity of arrangement of the turns of the outer winding 48. This results in a significant improvement in the reproducibility of the electrical characteristics of the transformer thus obtained, so that it becomes almost useless to adjust these electrical characteristics, after assembly by manipulation of the sheets of the magnetic core 42.

One can also consider using caps comprising shims 75 either between the primary winding and the secondary winding of the transformer, but between successive layers of winding, thus providing the same advantages. Wedges 75 could also be used on the magnetic circuit caps 50 and 51. The shims 75 can also advantageously be used with electrical conductors of round section.

The caps 56 and 57 between electrical windings can advantageously be pierced with lights distributed over their surfaces. Such lights, not shown in the figures, promote heat exchange from the inside winding to the outside.

The present invention is not limited to the embodiments which have been explicitly described, but it includes the various variants and generalizations thereof contained in the field of claims below.

Claims (15)

1 - Toroidal transformer, comprising:
- a closed annular main magnetic circuit (20),
- means for isolating (21, 22, 23, 24, 25) from the magnetic circuit,
- an internal electrical winding (26) wound on the means for isolating the magnetic circuit,
- intermediate electrical isolation means (27, 29, 35, 36, 43) surrounding the interior electrical winding,
- an external electrical winding (48) wound around the intermediate electrical insulation,
characterized in that it comprises an open magnetic core (42) comprising at least one annular sector bounded by an air gap and arranged parallel to the annular main magnetic circuit (20) between the interior electrical winding (26) and the exterior electrical winding (48). 2 - Transformer according to claim 1, characterized in that the magnetic core (42) comprises at least one annular sector (44) arranged along the periphery of the internal electrical winding (26). 3 - Transformer according to one of claims 1 or 2, characterized in that the magnetic core (42) comprises at least one annular sector disposed in the central chimney of the internal electrical winding (26). 4 - Transformer according to any one of claims 1 to 3, characterized in that the magnetic core (42) comprises at least one annular sector disposed on a side (28, 30) of the inner winding (26). 5 - Transformer according to any one of claims 1 to 4, characterized in that the external electrical winding (48) covers the magnetic core (42), the internal electrical winding (26) and part of the area of the 'air gap (47). 6. - Transformer according to any one of claims 1 to 5, characterized in that it comprises an upper ring (27) rigid and electrically insulating and a lower ring (29) rigid and insulating, the outer contours (31, 32) are connected to each other by axial bars (35) forming a support for the magnetic core (42). 7 - Transformer according to claim 6, characterized in that that the axial bars (35) comprise an external notch (41) whose length is slightly greater than the height of the magnetic core (42), to receive the core and ensure its axial positioning, the magnetic core (42) comprising a stack of sheets bent around the periphery defined by the axial bars (35) and on which they are held by an insulating peripheral wrapping (43). 8 - Transformer according to one of claims 6 or 7, characterized in that the upper (27) and lower (29) rings have an inner contour (33, 34) of circular diameter less than the inner diameter of the ring formed by l internal electric winding (26), and have an external contour (31, 32) of diameter greater than the external diameter of the ring formed by the internal electric winding (26), so that the rings form a support on which is wound outside winding (48). 9 - Transformer according to any one of claims 1 to 5, characterized in that:
- it comprises an electrically insulating upper toric cap (56) and an electrically insulating lower toric cap (57),
- each toric cap (56, 57) being limited by a circular external contour (58, 59) of diameter only slightly greater than the external diameter of the ring formed by the internal electrical winding (26), and being limited by a circular internal contour (60, 61) of diameter only a little less than the internal diameter of the ring formed by the internal electrical winding (26),
- The respective contours of the upper cap (56) and the lower cap (57) facing each other being separated by a space (62, 63) promoting the transfer of heat energy. 10 - Transformer according to claim 9, characterized in that each cap (56, 57) comprises an inner rim (64) and / or outer (65) partially covering the corresponding lateral cylindrical face of the inner electrical winding (26). 11 - Transformer according to one of claims 9 or 10, characterized in that the outer faces of the contours (58, 59, 60, 61) of the cap have a rounded cross section. 12 - Transformer according to any one of claims 9 to 11, characterized in that:
the caps (56, 57) comprise, on their external planar faces, shims (75) regularly distributed in a circle in an intermediate zone between the outer contour (58) and the inner contour (60), the shims (75) having a height substantially equal to the thickness of the conductor forming the winding, the wedges being separated from each other by a space (76) of width greater than the width of the conductor,
- A first winding layer (77) consists of conductor turns each engaged between two successive shims, a second winding layer (78) consists of conductor turns each passing over the upper face of a shim . 13 - Transformer according to any one of claims 9 to 12, characterized in that:
the outer contour (58, 59) of each of the caps (56, 57) comprises an annular groove (66, 67) facing the annular groove of the other cap,
- The magnetic core (42) comprises a stack of curved sheets whose edges (68, 69) are pinched respectively in the upper cap groove (66) and in the lower cap groove (67), so that the magnetic core (42) is held by the caps. 14 - Transformer according to claim 13, characterized in that the annular grooves (66, 67) are open over a portion of their periphery, allowing the manipulation of the sheets of the magnetic core (42) by peripheral sliding. 15 - Transformer according to any one of claims 9 to 14, characterized in that the caps hold, by their outline, electrostatic screens (37, 49) between inner winding (26) and outer winding (48).

Images