SE517703C2 - A transformer and its use - Google Patents

Description

: upon illa; 10 15 20 25 30 35 517 703 The suction transformers used today contain a core of iron. around which the primary and secondary windings are wound. Due to its high permeability, the iron core allows a high magnetic flux at low excitation current. However, there are a number of disadvantages to a core of iron. Iron has a non-linear excitation curve, which means that disturbing harmonics are generated when series-connected several suction transformers. An iron core can saturate, which means that the suction transformer stops working at high currents, for example when the overhead contact line is short-circuited to the rails, directly or indirectly via the locomotive. The non-linear magnetization curve of the iron further means that there is an upper limit for usable magnetic flux. This means that the core of a suction transformer, which only uses the linear part of the manetisation curve, becomes unnecessarily large. The large iron core means that the suction transformers become large and heavy. Usually a suction transformer weighs between 2 and 4 tons. Due to its size and high weight, the suction transformer must be placed on specially designed posts or placed built into cabinets on the ground and connected to the overhead contact line via a high-voltage cable. It would be desirable to be able to hang the suction transformers on some of the posts that currently support the overhead line. In this way, no extra poles, cabinets that stand on the ground or any extra high-voltage cable are needed. PCT / EP99 / 02782 discloses a suction transformer which, instead of having separate primary and secondary windings, has a flexible cable wound around the iron core. The flexible cable comprises an inner and an outer conductor which are coaxially arranged and separated by an insulating layer. One of these conductors forms the primary winding and the other forms the secondary winding in the transformer. Such a suction transformer has a very low impedance and a transformation ratio which is almost exactly one, which means that the leakage flows from the transformer become negligible, but it has the above-mentioned disadvantages due to the iron core. 1: a 15 - 15 15 25 25 35 35 517 705 3 DISCLOSURE OF THE INVENTION The object of the present invention is to provide a transformer which does not have the above-mentioned disadvantages. In particular, a small, lightweight transformer is sought which is possible to hang on an existing catenary pole and which does not saturate.

This object is achieved with the initially stated device which is characterized in that the transformer comprises a core of a non-magnetisable material and a capacitor connected to some winding in the transformer. Since it is the iron core that makes the largest contribution to the weight of the transformer, a transformer with a core of a non-magnetizable material, such as air or glass fiber, will weigh considerably less than an iron core. A non-magnetizable core can be made small in size. Additional advantages of a transformer according to the invention are that it is cheap to manufacture, it has a linear excitation curve and never saturates.

A transformer without an iron core according to the invention is provided by means of coaxially arranged primary and secondary windings wound around a core of non-magnetisable material and a capacitor connected to some winding in the transformer. If a traditional transformer with separately arranged primary and secondary windings is provided with a core of a non-magnetizable material, it will draw a very high magnetizing current due to the fact that it must build up a strong magnetic field in a large volume. When a grain transformer is loaded, the magnetic flux will disappear between the primary and secondary windings and reduce the connection between them. Due to the fact that the transformer according to the invention has coaxially arranged windings, most of the magnetic field is forced to stop between the inner and the outer winding.

To prevent the excitation current from becoming too high and overloading the mains, a capacitor is connected to someone in. |. »Isla 10 15 20 25 30 35 517 703 of the windings. The capacitance of the capacitor and the excitation inductance of the transformer together form a pivot circuit, where the excitation current will remain and thus not affect the network. A transformer according to the invention will outwardly behave like a traditional transformer, but it does not have the disadvantages of the traditional transformer due to the non-linear magnetization curve of the iron. Preferably, the inner conductor is a high voltage conductor and the outer conductor a low voltage conductor, since less insulation is then required on the outer conductor.

According to a preferred embodiment of the invention, the flexible cable is wound so that it forms a toroidal coil. With such an arrangement, the magnetic leakage currents from the windings are reduced by keeping the magnetic field inside the toroid.

According to an embodiment of the invention, the capacitor is connected to either the primary winding or the secondary winding. This is a simple and inexpensive way to connect the capacitor. In some applications, it is particularly advantageous to connect the capacitor to the secondary winding so that the resistance of the current path in connection with the capacitor can be used as a discharge resistor in connection with relatively large short-circuit currents.

According to a preferred embodiment of the invention, the transformer comprises a third winding where the capacitor is connected to the third winding. Preferably, the number of turns in the third winding is between one and ten. In order to be able to provide a sufficiently high excitation current, the capacitor must have a large capacitance. Developments in the field of capacitors have led to cheap low-voltage capacitors with high capacitance values. If the transformer is used in an application with high voltage levels across the primary and secondary windings and the capacitor is connected across one of these windings, then a capacitor is needed that can withstand high voltages and also some form of voltage protection is needed. Such high voltage capacitors are both large and expensive. By instead providing "urine all" the transformer with a third winding with a few turns and connecting the capacitor to this, the voltage level is reduced to an order of magnitude which is well suited for the aforementioned low voltage capacitors with high capacitance. The number of revolutions on the third winding determines the voltage level across the capacitor. By selecting a certain number of revolutions, an optimal voltage level can be obtained for the capacitor.

According to a further embodiment of the invention, the third winding is designed as a mechanical structure which holds the transformer together. Advantageously, the third winding comprises a first turn in the form of an annular structure, around which the flexible cable is wound, and a second turn in the form of an annular structure arranged to at least partially surround the wound flexible cable. The primary winding and the secondary winding are thus arranged between the first and the second turn in the third winding. In this way, the third winding forms a simple but robust structure that holds the capacitor together.

According to an embodiment of the invention, said capacitor is dimensioned so that it compensates for reactive voltage losses. In some applications, it is desirable to compensate for reactive losses. It is known to compensate for inductances with capacitances. By selecting the value of the capacitor capacitance so that it compensates for the reactive loss, the capacitor is used for two different purposes. The capacitor is partly used to compensate for reactive losses and partly to provide part of the transformer's excitation current.

DESCRIPTION OF THE DRAWINGS The present invention will now be explained by means of various embodiments described by way of example and with reference to the accompanying drawings.

Figure 1 shows a cross section through a coaxial cable used in a transformer according to the invention. Figure 2 shows a schematic perspective view of a first embodiment of a transformer according to the invention. Figure 3 shows a circuit diagram of the transformer in Figure 2.

Figure 4 shows a transformer according to a second embodiment of the invention. Figure 5 shows a cross section through the transformer in figure 4..

Figure 6 shows a circuit diagram of the transformer in Figures 3 and 4.

DESCRIPTION OF EMBODIMENTS Figure 1 shows a flexible cable 1 comprising an inner conductor 2 formed of wires. for example of copper, which is enclosed by a first semiconducting layer 3. A first insulating layer 4 of, for example, plastic or rubber surrounds the first semiconducting layer 3, which in turn is surrounded by a second semiconducting layer 5, an outer conductor 6 formed by a further number of wires. and a second insulating layer 7. The outer and inner conductors are thus arranged coaxially. Figure 2 shows a transformer 10 according to a first embodiment of the invention. Figure 3 shows a circuit diagram of the transformer 10. The transformer 10 comprises a coaxial cable 1, of the type shown in Figure 1, which is wound so as to form a toroidal coil 11. The coaxial cable 1 is wound around a core 12 of a non-core meshable material, such as fiberglass or other plastic. The main task of the core 12 is to provide a support for the lndnlngen and a bracket for a possible suspension device.

Alternatively, the core 12 may consist of air only. The inner conductor 2 in the cable 1 forms the primary winding 13 of the transformer and connections to it can be made via bushings and connection means 14.

The outer conductor 6 in the cable 1 forms the secondary winding 15 of the transformer and connections to it can be made via connection runs: be "flow" means 15 15 connected to the outer conductor ends, where the second insulating layer is missing. The inner conductor 2 constitutes a high voltage conductor and the outer conductor 6 constitutes a low voltage conductor.

Furthermore, the transformer 10 comprises a capacitor 18 arranged over the secondary winding 15 via the connecting means 16. Alternatively, the capacitor 18 can be arranged over the primary winding 13 via the connecting means 14. The capacitor is arranged so as to provide at least a part of the excitation current needed to drive the transformer. The size of the capacitor depends on the voltage range in which it is to be applied. If the voltage is high, a low capacitance is sufficient and if the voltage is low, a high capacitance is needed. In an application where the transformer is used for voltage supply of a railway and where the secondary winding is connected to the return conductor, the voltage across the secondary winding and across the capacitor is in the order of a few hundred volts. In such an application, the capacitor must be designed for this higher voltage. To protect the capacitor, it can include an overvoltage protection, for example a varistor or a valve diverter.

Figures 4 and 5 show a transformer 20 according to a second embodiment of the invention. Figure 6 shows a circuit diagram of the transformer 20. The transformer 20 comprises a coaxial cable 1, of the type shown in Figure 1, which is wound so as to form a toroidal coil 21. The inner conductor 2 in the cable 1 forms the primary winding 22 of the transformer and the outer conductor 6 in the cable 1 forms the secondary winding 24 of the transformer 24. The transformer 20 differs from that shown in Figures 2 and 3 in that it comprises a third winding 26 and that a capacitor 28 is arranged over the third winding 26. .

The third winding 26 comprises two turns arranged in the form of a first 30 and a second 32 hollow ring which are substantially toroidal in shape. The rings 30 and 32 are mainly made of metal, for example in aluminum. In order to avoid a short circuit in the first pine ring 30, it is provided with a gap 34 preferably filled with an electrically insulating material such as, for example, glass fiber or rubber. The gap 34 is arranged so that it runs concentrically around the entire ring. In the same way, the second ring 32 is provided with a gap 35 filled with an electrically insulating material. The first and second rings are arranged concentrically in such a way that the first ring 30 encloses the second ring 32. The toroidal coil 21 is arranged between the two rings 30. 32. The first ring 32 forms a casing around the toroidal pole 21 which is wound around the second ring 32. Thus, the turns in the third winding form a mechanical structure that assembles the transformer. The rings 30 and 32 are connected to each other via a conductor 36. The space 38 inside the second ring 32 forms a core of air.

The capacitor 28 is connected to the second ring 30 via. not shown, connections arranged on each side of the gap 34. Thanks to the fact that the third winding 26 contains only a few turns, it is sufficient to use a capacitor intended for low voltage.

Transformers 10 and 20 are well suited for use in connection with voltage supply to a railway and in particular for voltage supply to a railway which has a separate return conductor for the current. In such an application where the supply takes place with alternating voltage, it is also of interest to be able to compensate for reactive losses that occur in the lines. The value of the capacitance is then chosen taking into account that it must also compensate for all or part of the voltage drop due to inductance in the line. Capacitor is dimensioned so that its capacitance C is the sum of the capacitance needed to supply the magnetizing current Cmagn and the capacitance needed to compensate for at least some of the reactive losses Ciwmp in the circuit according to the formula C = cmagn + Ccomp- The invention is not limited to the embodiments shown but can be varied and modified within the scope of the appended claims. For example, the third winding may also consist of only one revolution or more than two revolutions. Preferably, the winding contains less than tic turns.

Claims (12)

øonun: urine 10 15 20 25 30 35 517 703 10 PÅTENTKRAV Transformer (10, 30) wound with a flexible cable (1) comprising an inner (2) and an outer (6) conductor, which are arranged coaxially and are separated by an insulating layer (4), one of which of said conductor forms a primary winding (13, 22) and the other forms a secondary winding (15, 24), the transformer comprising a core (12, 38) of a non-magnetizable material and a capacitor (18, 28) connected to any winding in the transformer. A transformer according to claim 1, wherein the flexible cable (1) is wound so as to form a toroidal coil (11, 21). Transformer according to claim 1 or 2, that it comprises a third winding (26) and that the capacitor (28) is connected to the third winding. A transformer according to claim 3, that the third winding (26) is formed as a mechanical structure (32) which holds the transformer together. A transformer according to claim 3 or 4, that the number of turns in the third winding is between one and ten. A transformer according to any one of claims 3, 4 or 5, wherein the third winding (26) comprises a first turn in the form of an annular structure (32), around which the flexible cable is wound. A transformer according to claim 6, wherein the third winding comprises a second turn in the form of an annular structure (30) arranged to at least partially surround the wound flexible cable. »Arna uupnu 10 15 517 703 11 Transformer according to claim 1 or 2, that the capacitor (18) is connected to one of the primary winding (13) or the secondary winding (15). Transformer according to any one of claims 1-8. 53131 that the inner conductor (2) constitutes a high voltage conductor and the outer conductor (6) constitutes a low voltage conductor. Transformer according to any one of the preceding claims, that said capacitor (18, 28) is dimensioned so that it compensates for reactive voltage losses. A transformer according to any one of the preceding claims, Käg; that it is a suction transformer adapted for use in connection with voltage supply to railways. Use of a transformer according to any one of claims 1-10 for voltage supply to a railway.