Arrangement of interleaved windings for power transformers

Abstract

Arrangement of interleaved secondary windings for power transformers that reduces the thickness of secondary windings and allows to build transformers with an odd number of layers.

Claims

1. An interleaved windings arrangement for power residential transformers, wherein the interleaved windings arrangement comprises two low voltage secondary windings (BT1 and BT2), the low voltage secondary windings (BT1 and BT2) comprise conductors, the conductors are interleaved adjacent to each other, and the conductors of the low voltage secondary windings (BT1 and BT2) are connected to three secondary terminals, wherein the three secondary terminals comprise a first secondary terminal (X1), a second secondary terminal (X2), and a third secondary terminal (X3), in such a way that when current flows through the second secondary terminal (X2), the current flowing through the low voltage secondary windings (BT1 and BT2) flows in opposite directions to each other, and magnetic fields generated around the conductors have opposite directions, so that a voltage induced in a high voltage winding is decreased.

2. The interleaved winding arrangement according to claim 1, wherein the conductors of the low voltage secondary windings (BT1 and BT2) are connected to the first secondary terminal (X1), the second secondary terminal (X2), and the third secondary terminal (X3) in a series or in a parallel arrangement.

Description

DESCRIPTION OF THE FIGURES OF THE INVENTION

(1) FIG. 1 shows the configuration of the secondary windings (BT1 and BT2) for interlacing connection.

(2) FIG. 2 shows the interleaved connection of the secondary windings of the present invention where: a) serial connection, b) parallel connection.

(3) FIG. 3 shows the surge current path and magnetic fields in the secondary windings with the interleaved arrangement of the present invention.

(4) FIG. 4 shows the connection of the transformers evaluated in a monophase system.

(5) FIG. 5 shows the connection of the transformers evaluated in a delta-star three phase system.

(6) FIG. 6 shows an electrical diagram of scaled surge current test.

(7) FIG. 7 shows the voltage curves supplied in the low voltage winding by terminal X2 (400 V) and the induced voltage measured in terminal number 3 (at 40% of the total turns) of the high voltage winding (26.0 V) of transformer C.

(8) FIG. 8 shows the comparative graph of induced voltages in the scaled surge current test.

DETAILED DESCRIPTION OF THE INVENTION

(9) The present invention provides a novel arrangement of secondary windings, based on simultaneously winding the conductors of the two sections of low voltage winding (BT1 and BT2). To do this, two conductors are wound adjacently until the total of the turns is achieved along all the required layers, ensuring that they always remain isolated from each other and that at the ends they are connected in such a way that they constitute the two necessary windings in the secondary. FIG. 2 shows the arrangement of the windings of the present invention and how they are connected to the secondary terminals (X1, X2 and X3).

(10) Said interlaced arrangement allows current flows that are contrasted with each other in the sections of the low voltage winding, which in turn forces the magnetic fields generated around the conductors, also have opposite turns and there is a decrease in their effect by inducing a voltage in the high-voltage winding of lesser magnitude than in an apparatus without interlacing.

(11) With the arrangement of the present invention, local and immediately opposite magnetic fields are produced which are canceled even more effectively than in the currently available winding configurations (FIG. 3). By establishing the aforementioned configuration, the need to have a multiple of four in the number of layers and number of turns in the secondary windings is eliminated, the requirement of the interlaced connection in said windings is eliminated, the balancing of the dispersion reactances is preserved, the magnitude of circulating currents between the windings is decreased and, a low magnitude of the voltage induced by surge currents due to the cancellation of magnetic fluxes between adjacent conductors is guaranteed.

(12) To demonstrate the behavior of the winding arrangement of the present invention, it was compared with respect to a conventional arrangement. The transformers considered for the comparative analysis corresponded to two monophase residential type transformers, prepared to operate at full load 10 kVA capacity, with a single winding on the side of the primary one (high voltage) configured to be connected in a monophase system with 19920 V phase voltage as seen in FIG. 4. This type of transformers can also be used in a three-phase system by connecting them in a grounded star configuration allowing a 34,500 V, line voltage as seen in FIG. 5. Because the terminal H2 of the primary winding, in all cases is connected to ground, this type of transformers only consists of a single nozzle for terminal H1. The side of the secondary one consisted of two winding sections each to supply 120 V, so they can be connected in series for 240 V supply or in parallel for 120 V supply at full load. This part of the transformer consisted of three nozzles X1, X2 and X3. The live parts were prepared with tip output at a certain percentage of the total number of layers of the high voltage winding. The detail of the layer in which each tip of test comes out is mentioned in table 3.1.

(13) TABLE-US-00001 TABLE 3.1 Location of the tip output in the high voltage winding. C I Transformer (interlaced winding) (interleaved winding) Terminal % of total AT Layer % of total AT Layer 1 17% 11% 2 29% 23% 3 40% 34% 4 51% 46% 5 63% 57% 6 74% 69% 7 86% 80% % of Total Layers AT 100%  100% 

(14) The prototypes described above were assembled in cylindrical tanks “post type” with a nozzle on the high voltage side.

(15) To validate the performance of the interleaved windings of the secondary one with respect to the voltage induced in the primary one due to the lightning surge current, a comparison was made between the two proposed prototypes. The test was named “Escalated Surge Current Test”. The connection thereof is shown in FIG. 6.

(16) This test consisted of supplying a wave of 400 V impulse voltage of 1.2×50 μs in the secondary winding through terminal X2, in such a way that it produces a current that penetrates through said terminal and then returns to ground through terminals X1 and X3. At the output of each of these terminals, a 500-ohm linear resistance and a voltage meter were connected in series, seeking to obtain the current value in the secondary one. Both prototypes were prepared with a surplus in the high voltage conductor (AT) at a certain number of layers, so that they served as “terminals” for the intermediate measurement of the requested voltage.

(17) The test equipment used for this case was a Haefely® Model RSG 482 Recurrent Generator with a maximum load voltage of 500 V. The impulse test was carried out individually; that is, an impulse was shot and the voltage of one intermediate high-voltage tip was measured at the same time until the values of the seven tips were obtained, ensuring that the impulses did not show a variation greater than 3% between shot and shot. The voltages obtained were normalized and plotted against the tip tested to compare the behavior obtained for the two prototypes.

(18) As mentioned above, the impulse test is carried out individually at different locations of the high voltage winding. FIG. 7 shows the voltage curves supplied in the low voltage winding by terminal X2 (400 V) and the voltage induced in terminal number 3 in layer 14 of the high voltage winding (26.0 V) of the prototype (C). Tables 4.1 and 4.2 show the voltages referred to ground obtained for the interlaced prototype (C) and for the interleaved prototype (I) respectively, while in FIG. 8 it is shown as a graph, the comparative in induced voltages of both prototypes.

(19) TABLE-US-00002 TABLE 4.1 Test results in interlaced prototype (C). AT winding Ground induced voltage Terminal percentage in AT winding 1 17% 26.4 V 2 29% 26.4 V 3 40% 26.4 V 4 51% 26.4 V 5 63% 26.4 V 6 74% 26.4 V 7 86% 26.4 V

(20) TABLE-US-00003 TABLE 4.2 Test results in interleaved prototype (I). AT winding Ground induced voltage Terminal percentage in AT winding 1 11% 19.0 V 2 23% 18.4 V 3 34% 18.8 V 4 46% 19.0 V 5 57% 18.0 V 6 69% 18.8 V 7 80% 19.0 V

(21) The current observed in each of the output terminals of the secondary winding (X1 and X3) is 0.6 amperes, so there is a current of 1.2 total amps fed by terminal X2.

(22) In graph of FIG. 8, it can be seen that the interleaved winding shows a better performance in the task of canceling the magnetic fields generated in the two sections of the secondary winding, allowing to induce a smaller amount of voltage in the primary winding and fulfilling the function of protecting it when the phenomenon of surge current occurs.

(23) On the other hand, the following performance tests were also carried out on each of the prototypes.

(24) Power losses with the transformer under load

(25) To carry out this test, the input and output parameters of the two transformers evaluated were first obtained. Table 4.3 shows in summary the comparison of the behavior of power losses with load in both prototypes with the serial and parallel connections in their secondary windings.

(26) TABLE-US-00004 TABLE 4.3 Comparison of the behavior in tests of power losses with load. Prototype C Prototype I (interlaced) (interleaved) BT connection Series Parallel Difference Series Parallel Difference I.sup.2R losses (pu) 1.000 1.002 0.002 1.011 1.017 0.006 Indeterminate losses (pu) 1.000 1.964 0.964 0.957 1.942 0.985 Load losses (pu) (Watts) 1.000 1.016 0.016 1.010 1.031 0.031

(27) In the summary presented in Table 4.3, it is observed that with the interleaved configuration of the windings, the effect of the losses with load when changing from serial to parallel connection is more sensitive to electromagnetic phenomena than seen in interlaced windings; However, the result obtained does not represent a risk condition that discredits the functionality of the interleaved connection of the windings, since the variations seen with this configuration are within the range of historical variation observed for this type of transformers.

(28) Impedance Voltage

(29) In order to obtain the percentage of impedance in each of the connections, the percentage values of resistance and reactance of the set of windings for each connection thereof (series and parallel) were calculated. Table 4.4 summarizes the comparison of the behavior in impedance percentage tests in both prototypes with the serial and parallel connections in their secondary windings.

(30) TABLE-US-00005 TABLE 4.4 Comparison of the behavior in impedance percentage tests. Prototype C Prototype I (interlaced) (interleaved) BT connection Series Parallel Difference Series Parallel Difference Resistance (%) 0.93 0.93 0.00 0.94 0.95 0.01 Resistance (%) 1.26 1.33 0.07 1.08 1.15 0.07 Impedance (%) 1.57 1.63 0.06 1.43 1.49 0.06

(31) In the summary presented in Table 4.4, it is observed that with the interleaved configuration of the windings, the effect of the impedance percentage when switching from serial to parallel connection is more sensitive than that seen in interlaced windings; however, the result obtained does not represent a risk condition that discredits the functionality of the interleaved connection of the windings, since the variations seen with this configuration are within the range of regulation variation that should not be greater than 7.5% for this type of transformers.

(32) The results shown above make it possible to ensure that the arrangement of interleaved windings of the present invention effectively cancels the voltage induced in the primary winding, without increasing the risk of failure due to the effects of the surge current; likewise, they make it clear that the arrangement object of the present, has a better performance in the task of canceling the magnetic fields generated in the two sections of the secondary winding than the conventional arrangements currently available.

(33) The present invention has been described according to a preferred embodiment; however, it will be apparent to a technician with average knowledge in the field, that modifications may be made to the invention, without departing from its spirit and scope.