WO2009133584A1 - Optimized transformer, in particular for carrying ou dielectric tests - Google Patents

Abstract

An optimized transformer (1), in particular for carrying out dielectric tests, comprising a containment case (2) which is placed on a support structure, a magnetic core (3) placed inside the containment case (2), a primary winding (4), coupled with the magnetic core (3) and a secondary winding (6), magnetically coupled with the primary winding (4) through the magnetic core (3). At least one between the primary winding (4) and the secondary winding (6) comprises a plurality of layers (8) facing one another, defining linear directions (Y) substantially parallel each other, each layer (8) including a plurality of elementary coils independent one from another, electrically connected each other.

Description

OPTIMIZED TRANSFORMER, IN PARTICULAR FOR CARRYING OUT DIELECTRIC TESTS

The present invention relates to an optimized single-phase transformer, particularly for carrying out dielectric tests.

It is known that in electrotechnics a special type of single-phase transformers is used to perform dielectric tests on an electrical apparatus, such as a transformer, for example in order to test the degree of insulation of the windings in respect to the other parts of the apparatus itself. As known, a transformer is a static machine operating in alternating current suitable to convert the parameters of output voltage and electric current with reference to those input ones while keeping a high efficiency.

The single-phase transformer includes two or more inductor circuits, called primary windings and secondary winding, mutually coupled each other through a common magnetic flux, which varies over time, supplied by a high permeability magnetic circuit, called ferromagnetic core.

The primary winding and the secondary winding are also called in jargon high voltage winding and low voltage winding respectively. A first winding, usually the primary one, receives power at a given value of voltage and frequency from an electrical energy source, such as for example the electric network, while the second winding, usually the secondary one, provides power to a user load at the same frequency value and at a voltage value usually different from that one which supplies the first winding.

Constructively, the ferromagnetic core is composed of a series of shaped laminations, packed together, and, generally, presents a so- called "columns" or "shell" type shape.

The stretches of the ferromagnetic core on which the primary and secondary windings are wound are called columns and are connected together by transverse portions called core clamps.

The section of these columns can be rectangular, square or joggled, in relation to the operating voltages and the chosen power of the transformer. The solution with columns having steps section is the most expensive but allows a better use of the space available within the windings and a better anchoring of the latter.

The junction between the columns and the core clamps is a magnetic gap whose thickness must be reduced in order to minimize the reluctance of the magnetic circuit.

The windings, made of even enamelled copper or aluminium, consist of coils formed by several turns and coaxially mounted on one or more columns of the ferromagnetic core in accordance with a concentric or alternate lay-out.

In the concentric lay-out, the coils forming the primary winding and the coils forming the secondary winding have different diameters; in the alternate lay-out, the coils forming the primary winding and the coils forming the secondary winding have the same diameter and are mounted one intercalated the other.

The primary winding and the secondary winding are properly insulated each other, in the case of the concentric lay-out for example by a high dielectric strength material tubular cylinder, such as prestressed paper-based material, or by a screen composed of a series of cylinders made of carton overlapped each other.

The transformer also provides appropriate channels between the windings for the passage of a refrigerant fluid, for example mineral oil or air in natural or forced ventilation, in order to dispose the power dissipated both in the ferromagnetic core, due to hysteresis and parasitic currents, and in the windings due to Joule effect.

Moreover, the transformer comprises a containment case, made of metallic or insulating material and inside which the abovementioned members are positioned, as well as an expansion reservoir of the refrigerant fluid.

In a transformer for dielectric tests a predetermined voltage at industrial frequencies for a given time interval is applied, with the purpose of testing the level of insulation of the windings towards the other parts of a certain electrical apparatus, usually another transformer. At the light of this, a specific classification of the transformers for carrying out dielectric tests has been made ready in the field: there are, in fact, transformers with insulation class up to 130 kV, up to 170 kV, up to 400 kV and so forth.

During dielectric tests, the transformer supplies an electric current only to feed its own capacities and those ones of the test apparatus, i.e. included between fractions of amperes and 1/2 amperes.

The present invention relates to transformers, in particular for carrying out dielectric tests, provided with the so-called "cigar" winding, made of several layers facing one another, the height of which decreases progressively, according to a prefixed rule, starting from the column on which the winding is wound towards the outside, in direction orthogonal to the column itself.

This constructive shape, as already said, allows a better use of the space available inside the windings, favouring also the limitation of the overall sizes of the containment case of the transformer.

According to the known technique, the cigar winding is of the single stage type, dealing with a single coil winding which distributes and develops without interruption between the various layers which composed it.

Such a constructive choice primarily determines the production of huge coils windings, which complicate the fitting operations. This is extremely evident when considering that, especially for transformers intended for dielectric tests, the field market requires for them insulation class of 400/500 kV at industrial frequencies which, therefore, makes them rather bulky.

Secondly, any problem or damage which occurs in the winding, for example due to short circuits, partial discharges, overvoltages, voltage drops or whatever, inevitably causes the need to replace the entire winding, with the obvious disadvantages which this implies in terms of intervention times and costs to be sustained.

The present invention intends to overcome the drawbacks of the prior art just cited.

More in detail, main purpose of the invention is to provide an optimized transformer, in particular for carrying out dielectric tests, in which at least one between the high and low voltage windings is composed of coils of axial sizes smaller than the known transformers, the electric power being equal.

Within such a purpose, it is task of the invention to simplify with respect to the known art the fitting of a transformer at least in relation to the windings.

It is a second purpose of the present invention to limit with respect to the current state of the art the negative effects resulting from a damage on any point of at least one of the coil windings of a single-phase transformer. Within such second purpose, it is task of the invention to make easier, quicker and less expensive even under the economic point of view the operations of maintenance, repair and replacement which must be performed on the windings of a transformer. It is a last but not least purpose of the present invention to make available an optimized transformer, in particular for carrying out dielectric tests, which can be manufactured through the current technologies, without rise in time and costs for the manufacturer and which is able to meet the requirements of the market at competitive prices. The aforesaid purposes are achieved by an optimized transformer, in particular for carrying out dielectric tests, as the attached claim 1 , to which they refer for the sake of brevity.

Other characteristics of detail of the optimized transformer of the invention are reported in the subsequent dependent claims. Advantageously, at least one of the windings, preferably the primary, of the optimized transformer of the invention is of the type defined as "cigar" and is made of a plurality of elementary coils, independent and physically distinct each other.

In the transformer of the invention, the electrical connection between each of the coils determines as a whole a winding of proportions equal to those ones of equivalent windings of the known type in which a single continuous winding extends along the entire path defined by the various layers.

This allows the arrangement of coils windings having sizes smaller than those ones of the windings of the known transformers.

Still advantageously, the possible failure suffered by a coil belonging to the winding involves replacement intervention of only that particular coil and not of the entire winding, as it happens instead in the known art. As far as both operator's times of intervention and costs to be incurred for such interventions are concerned, obvious and considerable benefits are, thus, achieved.

Equally advantageously, the transformer of the invention is ease to assemble by any specialists skilled in these works in electrotechnics.

The aforesaid purposes and advantages will result at a greater extent with the following description of a preferred embodiment of the invention, given as an indicative but not limitative way, with reference to the appended drawings in which: figure 1 is a view in longitudinal section of the optimized transformer of the invention; - figure 2 is the cross section view of the transformer of figure 1 ; figure 3 is an enlargement of a portion of the transformer of figure 1 ; figure 4 is an enlarged detail of figure 3; - figure 5 is an enlarged detail of figure 4.

The optimized single-phase transformer according to the invention, used especially for carrying out dielectric tests, is shown in section in figures 1 and 2, where it is globally indicated with 1.

It is observed that the optimized transformer 1 comprises: - a containment case 2 which is placed on a support structure S, for example the floor of an industrial plant; a magnetic core, as a whole numbered with 3, positioned inside the containment case 2; a primary winding, overall indicated with 4, associated with the magnetic core 3 and suitable in this case to be electrically connected, at the outlet 5 present in the containment case 2, with a user load, not shown and consisting for example of an electrical apparatus to be tested; a secondary winding, as a whole reported with 6, magnetically coupled with the primary winding 4 through the aforesaid magnetic core 3 and, in this case, suitable to be electrically connected, at the terminal connectors 7, with electrical energy supply means, namely an electricity generator, not shown.

According to the invention, the primary winding 4 comprises a plurality of layers 8 facing each other, defining linear directions Y substantially parallel each other, each of which includes a plurality of elementary coils independent one from another, electrically connected each other.

The containment case 2 is of the type in itself known in the field here concerned, made for example of metallic material.

Even the magnetic core 3 presents shape and composition of the type in itself known in the electrotechnical industry field: in particular, the magnetic core is of the so-called column type and is formed by a plurality of mutually packed laminations with low loss figure.

The magnetic core 3 presents in longitudinal section a rectangular profile, including two opposite columns 31 , 32, on the second of which the windings 4 and 6 are arranged, the columns being reciprocally connected by two yokes 33, 34 which are compressed by core clamps 9, 10 made of metallic material, one of which connected with the containment case 2 through anchorage means, as a whole reported with 11 and the other one supported by a reference plane 12. Furthermore, figures 1 and 2 show some of the other traditional member organs of a transformer, in particular for carrying out dielectric tests, also provided in the optimized transformer 1 of the invention, such as the high voltage insulators 13, connected with the primary winding 4, and the low voltage insulators 14, connected with the secondary winding 6.

In figure 2 the expansion reservoir 15 is also shown containing hot oil used as refrigerant fluid and insulator responsible for the disposal of heat generated inside the containment case 2 of the transformer 1.

As mentioned, in the case at issue and preferably, the primary winding 4 comprises the aforesaid layers, in this case in number of four, one facing the other.

Indeed, the secondary, or low voltage, winding 6 comprises two conductive plates coupled from symmetrically opposite parties to the column 32 of the magnetic core 3. In further embodiments of the transformer of the invention, not illustrated in the attached drawings, the number of layers present in the primary winding will be different from that one indicated above, the same depending on the design choices and the voltage values to be achieved.

There could be also other embodiments of the invention, not shown, in which only the secondary winding includes the layers or both the primary winding and the secondary winding comprise such layers.

The windings 4 and 6 are magnetically coupled with the column

32 of the magnetic core 3, with the primary winding 4 which surrounds the secondary winding 6 through the interposition of an insulating screen 16 and, consequently, the column 32 of the magnetic core 3 with which it is coaxial.

In particular, the linear directions Y defined by the various layers 8 of the primary winding 4 are parallel not only among them but also to the columns 31 and 32 of the magnetic core 3.

In the drawings appended to the present description, the various coils which form the primary winding 4 are respectively indicated with:

• A, if belonging to the first layer, that one closest to the magnetic core 3;

• B, if belonging to the second layer;

• C, if belonging to the third layer; • D, if belonging to the fourth layer, that one farthest from the magnetic core 3.

The coils are reciprocally connected in series and arranged one consecutively the other along the tortuous path defined by the layers 8 of the primary winding 4. The aforesaid coils include the same number of turns, each of them producing, preferably but not necessarily, a voltage of 20 kV.

The optimized transformer 1 also includes a plurality of spacer gates 17 which separate one from the other the coils in each of the layers 8, as figure 3 better highlights. The height of each of the layers 8 decreases in gradual and prearranged way, on the basis of the constructive choices, starting from the column 32 of the magnetic core 3 and according to a longitudinal direction X orthogonal to the linear directions Y defined by the layers 8.

The terminal coil of a layer 8 is electrically connected with the terminal coil of the immediately subsequent layer 8 by means of an intermediate line 18 which splits the voltage up in order to avoid peaks thereof.

The intermediate line 18 is faced to the ends of each of the layers 8 in order to interpose itself between any layer 8 and the reciprocally opposite core clamps 9, 10 placed inside the containment case 2.

In this case, through an intermediate line 18 the last coil of the first layer 8 is connected with the first coil B of the second adjacent layer 8, the last coil B of the second layer 8 is connected with the first coil C of the third layer 8 and the last coil C of the third layer 8 is connected with the first coil D of the fourth layer 8.

The intermediate line 18 has a substantially semi-elliptical shape profile 18' which includes a flat surface 18a facing the coils of two layers 8 adjacent and consecutive each other, as it can be seen for example in figure 4 for the coils indicated with C and the coils indicated with D. The intermediate line 18 is also covered with a laminar paper

19, clearly visible in figure 5, suitable to make equipotential the outer surface 18b of the intermediate line 18.

The optimized transformer 1 also comprises: a low voltage terminal 20, well visible in figures 3 and 5, suitable to split the voltage up, facing the first coil A of the longest length layer 8 closest to the column 32 of the magnetic core 3; a full voltage terminal 21 , well visible in figures 3 and 4, suitable to split the voltage up, facing the last coil D of the shortest length layer 8 farthest from the column 32 of the magnetic core 3. The low voltage terminal 20 and the full voltage terminal 21 are interposed between one of the layers 8 and one of the core clamps 9, 10. Even the low voltage terminal 20 and the full voltage terminal

21 are covered with a laminar paper in order to make them equipotential.

By virtue of these design features, in the case at issue, for example, the gradual reduction of the height of the layers 8 along the longitudinal direction X allows to achieve voltage V values divided as follows along the primary winding 4, starting from a value V = 0 V on the low voltage terminal 20:

• V = 160 kV at the first intermediate line 18 between the first and the second layer 8;

• V = 300 kV at the second intermediate line 18 between the second and the third layer 8;

• V = 420 kV at the third intermediate line 18 between the third and the fourth layer 8; • V = 500 kV at the full voltage terminal 21.

Advantageously, the transformer 1 comprises a pressing ring

22 placed close to the low voltage terminal 20 and interposed between the latter and the core clamps 9.

Such pressing ring 22 also performs the function of laterally protecting the primary winding 4 at the first layer 8.

According to the preferred embodiment here described of the invention, the optimized transformer 1 includes a plurality of piles 23 of pressing rings 24, interposed between each of the core clamps 9, 10 and the primary winding 4 and positioned close to the intermediate line 18 and the full voltage terminal 21.

The height of these piles 23 increases gradually with the decreasing of the height of the layers 8 of the primary winding 4 along the longitudinal direction X and, therefore, with the increase of the lateral distance between the primary winding 4 and the core clamps 9, 10.

Since with the decreasing of the height of the shortest layer 8 along the longitudinal direction X also corresponds an increase of the voltage in the primary winding 4, the height of the pile 23 is directly proportional to the voltage which is found in the primary winding 4 passing from the first layer 8, close to the magnetic core 3, to the fourth layer 8, that one farthest from the magnetic core 3.

In detail, the pressing rings 24 of a same pile 23 present variable thickness, provided that the pressing rings 24 of most reduced thickness are positioned in the vicinity of the intermediate lines 18 and the full voltage terminal 21, as it can be better noticed from figures 3-5.

The optimized transformer 1 also comprises a plurality of insulating elements 25 suitable to limit the electric field inside the containment case 2, placed side-by-side each other between each of the layers 8 and between the shortest length layer 8 and the containment case

2.

Each of the insulating elements 25 includes a laminar cylinder made of cardboard, paper or other similar and suitable cellulose-based material, sized so as to endure the mechanical and electrical stresses to which the optimized transformer 1 is subjected.

In preferred but not binding way, the optimized transformer 1 comprises shielding means, overall indicated with 26, interposed among some of the insulating elements 25 and among some of the pressing rings 24 at the intermediate lines 18 and the full voltage terminal 21.

The shielding means 26 increases the protection of the primary winding 4 from possible electrical discharges, voltage drops, overvoltages and so on since they create among the insulating elements 25 channels which compel such anomalous effects to make a forced and tortuous path which causes dissipation thereof, virtually preventing that they reach the primary winding 4.

As figure 5 better shows, the shielding means 26 comprise, preferably but not necessarily, a plurality of laminar rings 27 and a plurality of laminar caps 28, each opposite and facing the laminar rings 27.

In particular, a stretch of the laminar rings 27 and the laminar caps 28 is interposed among the most reduced thickness pressing rings 24, located at the intermediate lines 18 and the full voltage terminal 21.

Each of the laminar rings 27 and each of the laminar caps 28 have, preferably, a substantially L-shaped profile.

Moreover, both the laminar rings 27 and the laminar caps 28 are made of cardboard, paper or other material however derived from cellulose.

The functioning of the single-phase optimized transformer 1 is substantially equivalent to that one of the common transformers nowadays available on the market, to which they refer for the sake of explanatory convenience. The peculiar features of the optimized transformer 1 are expressed, indeed, in the constructive composition of the winding, especially the high voltage or primary one numbered with 4, which, compared to the known art, allows to limit the harmful effects resulting from an electrical pulse, an overvoltage, a short circuit or similar events on any point of the winding itself.

In such an occurrence, in the transformer of the invention it will be necessary to arrange only for the replacement of the coil hit by the discharge or impulse, with the consequent obvious advantages.

On the basis of what explained, it is understood, therefore, as the optimized transformer of the invention, in particular for carrying out dielectric tests, reaches the purposes and achieves the advantages previously mentioned.

In implementation phase, changes could be made to the optimized transformer, in particular for carrying out dielectric tests of the invention consisting, for example, in more than one single magnetic core inside the containment case.

Moreover, the number of layers can vary on the basis of the constructive choices and the electrical power to be developed, that number could be different from that one previously described and illustrated in the appended drawings.

It is, finally, clear that many other variations may be made to the optimized transformer in question, without for this reason going out of the novelty principles inherent the inventive idea here expressed, as it is clear that, in the practical implementation of the invention, materials, shapes and sizes of the illustrated details may be any, depending on the needs, and replaced with others technically equivalent.

Claims

1. Optimized transformer (1), in particular for carrying out dielectric tests, comprising: a containment case (2) suitable to be placed on a support structure; at least one magnetic core (3) located within said containment case (2); a primary winding (4), coupled with said magnetic core (3); - a secondary winding (6), magnetically coupled with said primary winding (4) through said magnetic core (3), characterized in that at least one between said primary winding

(4) and said secondary winding (6) comprises two or more layers (8) facing each other, defining linear directions (Y) substantially parallel each other, each of said layers (8) including a plurality of elementary coils independent one from another, electrically connected each other.

2. Transformer (1) as claim 1) characterized in that said primary winding (4) includes two or more layers (8) facing each other.

3. Transformer as claim 1) characterized in that said secondary winding comprises two or more layers facing each other.

4. Transformer as claim 1) characterized in that said primary winding and said secondary winding comprise each two or more layers facing each other.

5. Transformer (1) as any of the previous claims characterized in that said magnetic core (3) is of the columns type, and said windings (4,

6) are magnetically coupled with one of said columns (31 , 32), with said primary winding (4) which surrounds said secondary winding (6) through the interposition of an insulating screen (16) and is coaxial to said column (32) of said magnetic core (3). 6. Transformer (1) as any of the previous claims characterized in that said coils include the same number of turns, each of them being suitable to produce a voltage of 20 kV.

7. Transformer (1) as any of the previous claims characterized in that said coils are reciprocally connected in series and arranged one consecutively the other.

8. Transformer (1) as any of the previous claims characterized in that it includes a plurality of spacer gates (17) which separate one from the other said coils in each of said layers (8).

9. Transformer (1) as claim 5) characterized in that the height of each of said layers (8) decreases in gradual and prearranged way starting from said column (32) of said magnetic core (3) and according to a longitudinal direction (X) orthogonal to said linear directions (Y) defined by said layers (8).

10. Transformer (1) as claim 9) characterized in that the terminal coil of a layer (8) is electrically connected with the terminal coil of the subsequent layer (8) through an intermediate line (18), suitable to split the voltage up, facing the ends of each of said layers (8) to interpose itself between each of said layers (8) and a pair of core clamps (9, 10) opposed each other, arranged inside said containment case (2).

11. Transformer (1) as claim 10) characterized in that said intermediate line (18) is covered with a laminar paper (19) suitable to make equipotential the outer surface (18b) of said intermediate line (18).

12. Transformer (1) as claim 10) characterized in that said intermediate line (18) has a substantially semi-elliptical shape profile (18') which comprises a flat surface (18a) facing said coils of two of said layers (8) one contiguous to the other.

13. Transformer (1) as claim 10) characterized in that it comprises: a low voltage terminal (20), suitable to split the voltage up, facing the first coil of the longest length layer (8) closest to said column (32) of said magnetic core (3); - a full voltage terminal (21), suitable to split the voltage up, facing the last coil of the shortest length layer (8) farthest from said column (32) of said magnetic core (3), said low (20) and full (21) voltage terminals being interposed between said layer (8) and one of said core clamps (9, 10).

14. Transformer (1) as claim 13) characterized in that it comprises at least one pressing ring (22) placed close to said low voltage terminal (20) and interposed between said low voltage terminal (20) and one of said core clamps (9, 10).

15. Transformer (1) as claim 13) characterized in that it comprises a plurality of piles (23) of pressing rings (24) interposed between each of said core clamps (9, 10) and said primary winding (4) and positioned close to each of said intermediate lines (18) and said full voltage terminal (21).

16. Transformer (1) as claim 15) characterized in that the height of said pile (23) gradually increases with the decreasing of said height of said layers (8) of said primary winding (4).

17. Transformer (1) as claim 15) characterized in that it includes one or more insulating elements (25) suitable to limit the electric field inside said containment case (2), placed side-by-side each other between each of said layers (8) and between said shortest length layer (8) and said containment case (2).

18. Transformer (1) as claim 17) characterized in that each of said insulating elements (25) comprises a laminar cylinder made of paper, cardboard or other similar cellulose-based material.

19. Transformer (1) as claim 17) characterized in that it comprises shielding means (26), interposed between two or more of said insulating elements (25) and between two or more of said pressing rings (24) at said intermediate lines (18) and said full voltage terminal (21), suitable to increase the protection of said primary winding (4) against overvoltages, electrical discharges, voltage drops or whatever.

20. Transformer (1) as claim 19) characterized in that said shielding means (26) include one or more laminar rings (27) and one or more laminar caps (28), facing and opposite to said laminar rings (27).

21. Transformer (1) as claim 20) characterized in that each of said laminar rings (27) and each of said laminar caps (28) have a substantially L-shaped profile.

22. Transformer (1) as claim 20) characterized in that each of said laminar rings (27) and each of said laminar caps (28) are made of paper, cardboard or other material derived from cellulose.