FR2958790A1 - US INTERCONNECT MEMBER FOR A TRANSFORMER COIL, COIL HAVING SUCH AN ORGAN, ACTIVE PART, AND TRANSFORMER COMPRISING SUCH AN ACTIVE PART. - Google Patents

Abstract

This intermediate member (20) for isolating two windings belonging to a coil comprises a generally annular plate (21) and a plurality of spacers (31-36) arranged on at least one of the faces of the plate (21) so as to define channels for the flow of a dielectric fluid. The plate (21) and the spacers (31-36) are made of polyaramid. So-called main spacers (31-34) define at least one main channel (51-53), the or each main channel (51-53) having multiple directional changes and extending in a main direction (Y23-Y24) which joins two opposite edges (23, 24) of the plate (21). The spacers (31-36) are main monobloc and extend over a length (L31, L32, L33, L34) greater than or equal to 40% of the length (L21) of the plate (21), the lengths being measured in parallel to the main direction (Y23-Y24).

Description

BACKGROUND OF THE INVENTION The present invention relates to an intermediate member for isolating two windings of spiral conductors belonging to a traction transformer coil. Moreover, the present invention relates to a traction transformer coil comprising at least one such intermediate member. In addition, the present invention relates to an active part of a traction transformer comprising at least one such coil. On the other hand, the present invention relates to a traction transformer comprising such an active part. The present invention can be used in the field of traction transformers, which equip electric vehicles such as a train, a tram or a metro.

A traction transformer coil generally comprises a winding sequence of spiral conductors, sometimes called "slabs", and several spacers, sometimes referred to as "screen washers". The windings and the intermediate members are superposed alternately and coaxially. Each intermediate member generally has the function of cooling, supporting and electrically isolating two windings which are superimposed on it. An intermediate member of the prior art generally comprises a plate and several spacers arranged on the faces of this plate. The plate and the spacers may be made of poly-aramid, a material which exhibits appropriate mechanical behavior, electrical resistivity and resistance to thermal stresses. Such an intermediate member comprises a plurality of small spacers spaced from each other so as to define passages for the flow of the dielectric fluid. The manufacture of such an intermediate member is long and difficult, so expensive, because each of the many spacers must be positioned at a specific location to help fulfill the functions of support and cooling. The present invention aims in particular to overcome these disadvantages, by providing a simplified intermediate manufacturing member and optimized operation for cooling, mechanical support and electrical insulation. For this purpose, the invention relates to an intermediate member for isolating two windings of spiral conductors belonging to a traction transformer coil, the intermediate member comprising at least one plate and several spacers, said at least one plate having a generally annular shape, the spacers being arranged at least on one of the faces of the plate so as to define channels for the flow of a dielectric fluid, the plate and the spacers being made totally or partially of poly-aramid, preferably Nomex (registered trademark). This intermediate member is characterized in that said main struts define at least one main channel, the or each main channel having multiple changes of direction and extending in a main direction which joins two opposite edges of the plate, and in that that the main spacers are monobloc and extend over a length greater than or equal to 40% of the length of the plate, the lengths being measured parallel to the main direction. In other words, the main spacers are long compared to the dimensions of the plate, which limits the number of spacers needed to perform the functions of support, cooling and insulation. An intermediate member according to the invention is therefore simpler and less expensive to manufacture. According to other advantageous but optional features of the invention, taken separately or in any technically permissible combination: the main struts extend over a length greater than or equal to 70% of the length of the plate; the main spacers are secured to the plate by means of ultrasonic welds made in the polyaramid; spacers have rectilinear sections in the region of the opposite edges of the plate; the area occupied by the spacers arranged on one face of the plate is less than or equal to 50%, preferably less than or equal to 40%, more preferably less than or equal to 35% of the area of said face of the plate; - spacers are arranged so as to seal the dielectric fluid edges of the plate which extend parallel to the main direction; - The intermediate member comprises a plurality of main channels - the main struts defining the or each main channel have a form of periodic function; the form of periodic function is selected from the group consisting of zigzags, saw teeth, sinusoids and crenellations; and the plate comprises a polarizer, such as a notch, an orifice or a projection, for discriminating the two faces of the plate during the assembly of the intermediate member in the transformer coil.

Furthermore, the subject of the present invention is a traction transformer coil comprising a succession of spiral conductor windings and several intermediate members as described above, two successive windings being isolated by at least one intermediate member, the windings and the intermediate members being superimposed alternately and coaxially. In addition, the subject of the present invention is an active part of a traction transformer comprising at least one low voltage coil and at least one high voltage coil superimposed coaxially, the active part being characterized in that at least one of the low coils voltage and high voltage is as explained above. In addition, the subject of the present invention is a traction transformer, in which the magnetic circuit surrounds the coils, the transformer comprising an active part as explained above. The present invention will be well understood and its advantages will also emerge in the light of the description which follows, given solely by way of nonlimiting example and with reference to the appended drawings, in which: FIG. 1 is a sectional view of FIG. a portion of a transformer coil according to the present invention; Figure 2 is a front view, along the arrows I l in Figure 1, an intermediate member according to the present invention; in Figure 2, the sectional plane of Figure 1 is identified by the line 1-1; and FIG. 3 is an enlarged view of detail III in FIG. 2. An active transformer part according to the invention comprises at least one high-voltage coil and one low-voltage coil, at least one of which conforms to to the invention. Figure 1 illustrates a portion of a coil 1 of the high voltage type. In the present application, the terms "low voltage" and "high voltage" are relative to the scale of the voltages present in a traction transformer according to the invention. For example, for a traction transformer whose power output is about 1000 kVA, the low voltage can typically be between 500 V and 2000 V, while the high voltage can typically be between 15 kV and 30 kV. The coil 1 comprises a stack or a succession of windings 10 unrepresented conductors and spirally wound. The coil 1 also comprises several intermediate members 20 according to the invention. The intermediate members 20 are designated as "spacers" because two successive windings 10 are isolated by at least one intermediate member 20, in this case by a single intermediate member 20 in the example of FIG. the coil 1, in a direction of superposition X1-X'1, are formed by separating members 2 and 3. The windings 10 and the intermediate members 20 are superimposed alternately and coaxially, the superimposition axis being merged or parallel to the superimposition direction X1-X'1. In the present application, the term "coaxial" refers to a global axis of symmetry of the intermediate members 20 and the windings 10. In the example of Figures 1 and 2, this global axis of symmetry coincides with the superposition direction X1 -X'1.

An intermediate member 20 according to the invention comprises a plate 21 and spacers which are designated in their entirety by the reference 30 in Figure 1. These spacers are sometimes also called "shims". FIG. 2 shows an intermediate member 20 comprising a plate 21 and a set of spacers 30, some of which are designated in FIGS. 2 and 3 by the references 31, 32, 33, 34, 35 and 36. The spacers of the assembly 30 which are visible in Figure 2 are disposed on one of the faces 211 of the plate 21. As shown in Figure 1, another set of spacers, symmetrical to the assembly 30 relative to the plate 21, is arranged on the other face 212 of the plate 21. The profile of the windings 10 superimposed on the intermediate member 20 are shown in phantom in Figures 2 and 3. The spacers 31 to 36 are arranged on the plate 21 so as to define channels, in particular main channels 51, 52 and 53 visible in Figure 2, for the flow of a dielectric fluid. This dielectric fluid may be for example a synthetic ester such as Midel (registered trademark). The dielectric fluid makes it possible to cool the coil 1 by evacuating the heat produced in the windings 10 when the transformer is in operation. The dielectric fluid also contributes to electrically isolating two successive windings. The plate 21 and the spacers of the assembly 30, the spacers 31 to 36 are made entirely of poly-aramid and more particularly Nomex (registered trademark). The mechanical behavior, the electrical resistivity and the resistance to thermal stresses of this poly-aramid allow the intermediate member 20 to fulfill its functions of mechanical support and electrical insulation of the windings 10. The mechanical support function consists in particular in minimizing the arrow produced between two spacers during a mechanical stress occurring for example during a short circuit.

The unrepresented conductors forming the windings 10 are wound in flat spirals generally around the superposition direction X1-X'1. These conductors may for example consist of stranded son covered with a poly-aramid sheath, for example Nomex (trademark). This sheath can be made by covering the conductors. The plate 21 has a generally annular shape. The central region of the plate 21 has an opening 22 in the form of a rectangle which is intended for the passage of a magnetic core not shown. The outer periphery of the plate 21 is generally in the shape of a rectangle, the corners of which are chamfered. The outer periphery of the plate 21 thus has more precisely the shape of an octagon. Among the spacers of the assembly 30, there are said main spacers 31, 32, 33 and 34 and so-called secondary spacers 35 and 36. The main spacers 31 to 34 define three main channels 51, 52 and 53. Each main channel 51, 52 or 53 has multiple changes of direction and extends in a main direction Y23-Y24 which joins two opposite edges 23 and 24 of the plate 21. In the example of Figure 2, the main direction Y23-Y24 is parallel to the largest dimension of the plate 21, that is to say the long side of the rectangle formed by the opening 22. In other words, the main direction Y23-Y24 is parallel to the long length of the rectangle defining the opening 22 or the rectangle in which is inscribed the outer periphery of the plate 21. In addition the main direction Y23-Y24 is perpendicular to the superposition direction X1-X'1. More specifically, the main spacers 31 and 33 define the main channel 51, the main spacers 31 and 32 define between them the main channel 52 and the main spacers 32 and 34 define between them the main channel 53.

Thus, the spacers, in particular the spacers 31 to 36, contribute to filling the cooling function of the coil 1, since they define channels, in particular the main channels 51, 52 and 53, for the flow of the dielectric fluid intended to evacuate the heat generated in the windings 10. In addition, the spacers 31 to 36 contribute to the support function by transmitting to the plate 20 the forces exerted by the windings 10 subjected to a magnetic field. In addition, the spacers, the dielectric fluid and the dimensions of the plate 21 can electrically isolate two successive windings 10. To achieve the multiple directional changes of each main channel 51, 52 or 53, the main spacers 31-34 preferably each have a form of periodic function. More specifically, the edges of the spacers 31 to 34 have periodic function forms. Thus, the main spacers 31 and 32 have zigzag shapes and the spacers 33 and 34 have crenellated shapes. The periodic function form may be selected from the group consisting of zigzags, saw teeth, sinusoids, and crenellations. These forms of periodic functions make it possible to define main channels 51, 52 and 53 which have multiple changes of direction along the main direction Y23-Y24 and over most of their respective lengths. In the region of the edges 23 and 24, the spacers 31 to 36 have rectilinear sections. These rectilinear sections allow to collect and evacuate the dielectric fluid without generating excessive loss of loads. Furthermore, each main spacer 31 to 34 is integral and extends over a respective length L31, L32, L33 or L34 which is greater than or equal to 40%, preferably greater than or equal to 70%, of the length L21 of the plate 21, the lengths being measured parallel to the main direction Y23-Y24.

The length L21 may for example be about 1000 mm. The maximum width of the plate 21, measured perpendicularly to the main direction Y23-Y24, may be for example about 1000 mm. In the example of FIGS. 2 and 3, the lengths L31, L32, L33 and L34 are respectively about 786 mm, 976 mm, 571 mm and 476 mm, ie respectively 79%, 98%, 57% and 48% of the length L21.

The production of the main spacers 31 to 34 integrally simplifies their attachment to the plate 21. In fact, the spacers 31 to 36 can be secured to the plate 21 by means of ultrasonic welds made in the polyaramid. Insofar as the spacers of the assembly 30, in particular the main spacers 31 to 36, are accurately positioned, their one-piece construction reduces their assembly time to the plate 21, thus the cost of an intermediate member 20. In the present application, the term "monoblock" refers to a piece formed in one piece according to at least one of its dimensions. For example, a main spacer is in one piece along its length, that is to say in the main direction Y23-Y24. The area occupied by all the spacers disposed on the face 211 of the plate 21 is less than or equal to 50%, preferably less than or equal to 40%, more preferably less than or equal to 35% of the total surface area of this face 211. As shown in Figure 2, the area called "occupied" by the spacers on the face 211 is shown in white. Conversely, the unoccupied or "free" surface of the face 211 is shown in gray in FIGS. 2 and 3. The unoccupied or "free" surface of the face 211 is dedicated to the circulation of the dielectric fluid. In the example of Figures 2 and 3, the ratio between the "occupied" area and the total area of a face of the plate 21 is about 30%. Such a ratio makes it possible to find an optimal compromise between the functions of mechanical support and cooling that fills the intermediate member 20. The struts 33 and 34 are arranged on the plate 21 so as to seal the dielectric fluid edges 25 and 26 of the plate 21 which extend parallel to the main direction Y23-Y24. Thus, the dielectric fluid flows from the edge 24 to the edge 23 without leakage by the edges 25 and 26, which guarantees a relatively uniform cooling of the plate 21. Similarly, in order to minimize the deflection that presents a winding 10 between two successive spacers, the maximum distance separating two spacers 31, 32 successive, measured parallel or perpendicular to the main direction Y23-Y24, is less than or equal to 70 mm, preferably less than or equal to 50 mm.

As shown in Figure 2, this maximum distance separating two successive spacers may be a distance L31.32 measured parallel to the main direction Y23-Y24, or a distance H31.32 measured perpendicularly to the main direction Y23-Y24. Furthermore, the outer periphery of the plate 21 has a notch 27 that performs the keying function. Such a polarizer makes it possible to reduce the manufacturing costs of an intermediate member, since an operator can quickly discriminate the two faces 211 and 212 of the plate 21 during the assembly of the intermediate member 20 between two windings 10 and in the coil 1 of the transformer according to the invention. Such a polarizer thus reduces the risk of errors during assembly.

According to a variant not shown, the polarizer can be formed by a projection or by an orifice. An intermediate member 20 serves to cool the windings 10, to mechanically support and electrically isolate them from each other. The production of the components of a poly-aramid interlayer 20, preferably of Nomex (registered trademark), makes it possible to withstand higher temperatures than traditional materials such as cardboard. According to a variant not shown, the intermediate member according to the invention comprises a single main channel. The main spacers defining the main channels of an intermediate member according to the invention are long compared to the dimensions of the plate, which limits the number of spacers necessary to perform the functions of mechanical support, cooling and electrical insulation . An intermediate member according to the invention is therefore simpler and less expensive to manufacture. An active part according to the invention may be incorporated in a traction transformer, in particular a "battleship" type transformer in which the magnetic circuit surrounds the two coils. A coil and an active part according to the invention, which incorporate intermediate members in accordance with the invention, are not only inexpensive but also reliable, since the functions of mechanical support, cooling and electrical insulation are effectively fulfilled by the intermediate members according to the invention.

Claims (1)

1. intermediate member (20) for isolating two windings (10) of spiral conductors belonging to a coil (1) traction transformer, the intermediate member (20) comprising at least one plate (21) and several spacers ( 31-36), said at least one plate (21) having a generally annular shape, the spacers (31-36) being arranged at least on one of the faces (211, 212) of the plate (21) so as to defining channels for the flow of a dielectric fluid, the plate (21) and the spacers (31-36) being wholly or partially made of poly-aramid, preferably Nomex (registered trademark), this intermediate member (20) ) being characterized in that said main spacers (31-34) define at least one main channel (51-53), the or each main channel (51-53) having multiple directional changes and extending in one direction (Y23-Y24) which joins two opposite edges (23 , 24) of the plate (21), and in that the main spacers (31-34) are in one piece and extend over a length (L31, L32, L33, L34) greater than or equal to 40% of the length ( L21) of the plate (21), the lengths being measured parallel to the main direction (Y23-Y24). 2. Intermediate member (20) according to claim 1, characterized in that the main spacers (31-34) extend over a length (L31, L32, L33, L34) greater than or equal to 70% of the length ( L21) of the plate (21). 3. Intermediate member (20) according to claim 1 or 2, characterized in that the main spacers (31-34) are secured to the plate (21) by means of ultrasonic welds made in the poly-aramid. 4. Intermediate member (20) according to one of the preceding claims, characterized in that spacers (31-36) have straight sections in the region of the opposite edges (23, 24) of the plate (21). 30 5. Intermediate body (20) according to one of the preceding claims, characterized in that the area occupied by the spacers (31-36) disposed on one face (211) of the plate (21) is less than or equal to 50 %, preferably less than or equal to 40%, more preferably less than or equal to 35% of the area of said face (211) of the plate (21). 35 6. Intermediate member (20) according to one of the preceding claims, characterized in that spacers (33, 34) are arranged so as to seal the dielectric fluid edges (25, 26) of the plate (21). which extend parallel to the main direction (Y23-Y24). 7. Intermediate member (20) according to one of the preceding claims, characterized in that it comprises a plurality of main channels (51-53). 8. Intermediate member (20) according to one of the preceding claims, 10 characterized in that the main spacers (31-36) defining the or each main channel (51-53) have a form of periodic function. 9. An intermediate member (20) according to claim 8, characterized in that the periodic function form is selected from the group consisting of zigzags, sawtooths, sinusoids and crenellations. 10. Intermediate member (20) according to one of the preceding claims, characterized in that the plate (21) comprises a polarizer (27), such as a notch, an orifice or a projection, to discriminate the two faces ( 211, 212) of the plate (21) during assembly of the spacer member (20) in the transformer coil (1). 11. Traction transformer coil (1) comprising a succession of spiral conductor windings (10) and a plurality of spacers (20) according to one of the preceding claims, wherein two successive windings (10) are isolated by means of minus an intermediate member (20), the windings (10) and the intermediate members (20) being superposed alternately and coaxially (X1-X'1). 12. Active tensile transformer part comprising at least one low voltage coil and at least one coaxially superimposed high voltage coil (1), the active part being characterized in that at least one of the coils (1) is low voltage and high voltage is according to claim 11. 13.- Traction transformer, wherein the magnetic circuit surrounds the coils (1), the transformer comprising an active portion according to claim 12. 35