DE954622C - Combined current and voltage converter - Google Patents

Description

Combined current and voltage converter The invention relates to a combined current and voltage transformer, in which -the current transformer and the voltage transformer in a common, preferably made of insulating material, expediently oil-filled Vessel are housed and where the Stromwanffler, its on earth potential lying, preferably ring-shaped iron core that is at near-earth potential Secondary winding and insulated accordingly for the full operating voltage the primary winding is arranged above the voltage converter. The invention consists in that the voltage converter has a jacket core with a in the direction of the core leg running cavity in the center leg carrying the windings and that this cavity for the passage of the ends of the current transformer secondary winding to the secondary terminals located on the floor (or foundation) of the converter vessel serves. It is particularly useful if the current transformer toroidal core carrying the secondary winding in a manner known per se with a voltage sufficient for half the operating voltage Insulation layer is surrounded and on top. facing away from the voltage converter Half of the ring-shaped primary winding, which is also isolated for half the operating voltage carries that furthermore the insulation layer surrounding the secondary wound current transformer core on the side facing the voltage converter, one for half the operating voltage dimensioned, insulating tube in which the ends of the secondary current transformer winding through the cavity of the voltage transformer core carrying approximately half the operating voltage are led.

The invention provides significant advantages over the known combined converters achieved. With these is namely, both for the Voltage converter as well as for the. Current transformer uses a so-called cascade connection; d. H. the iron cores of both converters carry half the operating voltage and are galvanic connected to each other and the iron core of the voltage transformer carries on two opposite one another Thighs. the high-voltage winding, divided into two coils, the iron core of the current transformer on one of the opposite legs, which are driven by thrust windings primary and secondary winding coupled to one another. The core planes are perpendicular to each other, and the voltage transformer is in the one encompassed by the current transformer core Space, or the current transformer is located in the space enclosed by the voltage transformer core. The fact that a current transformer is used in the invention, which no cascade damage and therefore no thrust windings are required, the space requirement of the combined. Converter lower. Another advantage of the invention is that for the combined current and voltage transformers have the same current transformer design can be used as they are with simple normal current transformers. is common. Further it is possible to use the current transformer with several cores (so-called measuring and relay cores) to equip what with cascade converters and, accordingly, with the previously known combined Converting to difficulties. comes across and therefore did not happen. Because of that, B at the combined. Converter according to the invention of the current transformer above the Voltage converter is arranged, are those in the known combined converters. long yoke parts in the current or voltage transformer avoided., which over long distances electrostatic short circuits between. Represent high voltage and earth and one, require greater height of the insulating vessel containing the transducer. Execution of the voltage converter in the manner of a jacket transformer enables the combined Converter according to the invention of a particularly compact design, so that the vessel only about as high as the known only one voltage converter for the same. Vessels containing operating voltage and also practically hardly larger in diameter than this will. Also the arrangement and fastening of the primary connection lines of the current transformer in the invention is much cheaper than in the. known combined converters.

It was already known, transformers or transducers to be provided with a jacket-like core, the center leg of which carries the windings has a cavity extending in the direction of the leg axis. With these well-known Transformers and instrument transformers, however, this cavity is only one. through the core construction conditional, necessary evil, which is expedient by a more skilful arrangement of the core is eliminated, as is the treatment of these transformers Show publications. In the subject matter of the invention, however, this cavity is Intentionally provided in the middle leg of the sheath core and serves as above is explained, a special purpose, namely to pass the ends of the Secondary winding of a combined with the voltage transformer. Current transformer.

In FIGS. 1 and 2, an exemplary embodiment for a combined converter according to the invention is shown schematically in two different longitudinal sections that do not match in scale, while FIG. 3 shows a cross section through the voltage converter part. On the annular, z. B. from tape wound core ii of the current transformer is the secondary winding 12 and applied to it an insulation 13 sufficient for half the operating voltage. On the upper half of the ring sits the primary winding 15 of the current transformer, which is also provided with an insulation 14 for half the operating voltage, that is to say the one after. Type of so-called cross ring converter is carried out. The iron core ii is at earth potential. The ends of the primary winding 15 are. at. the schematically indicated primary connection terminals K, L out. The insulation layer 13 surrounding the secondary wound toroidal core settles. down in an insulating tube 16 dimensioned for half the operating voltage, in which the ends of the secondary winding 12 pass through the voltage transformer core to those located on the floor or foundation of the transformer. Secondary terminals k, L are guided .. The voltage transformer core, designed in the manner of a jacket core, consists of four surrounding the windings, symmetrically distributed over the circumference of the coil. frame-shaped partial cores 17, 18, 19 and 2o, the inner legs of which are encased by the coils and are dimensioned and arranged in such a way that the. for the insulating tube 16 required cavity of iron remains free. One can. If necessary, provide only two partial cores 17 and 19 or 18 and 20 or even more than four partial cores, which are evenly distributed over the circumference of the coil 24. The ends of the innermost winding layer of each coil half are connected to each other and to the core core 17 to 2o and a disk 25 made of conductive material separating the two halves of the coil, so that the iron core of the voltage converter is at half the high voltage potential. The end of the outermost winding layer of the upper coil half 23 is connected to the high-voltage connection terminal U. Which is connected to the one primary connection terminal K of the current transformer. The corresponding winding end of the lower coil half a4 is led to the terminal X, which is at ground potential. The secondary winding 26 of the voltage converter, the ends of which are connected to the secondary connection terminals u, x, is applied to the outermost winding layer of the coil half 24. The coil half 23 and the coil half 24 carrying the secondary winding are isolated from the outer legs and yokes of the partial cores and from one another accordingly for half the operating voltage. No special insulation is required from the inner legs, since the ends of the innermost winding layers are conductively connected to the iron core. The insulating tube 16 can be used as a support for the active parts of the current transformer, if necessary, if you z. B. provides a flange 27, at the same time serve to carry the voltage converter. A corresponding fastening of the insulating tube 16 on the floor or foundation of the combined transducer must be ensured. The vessel accommodating the combined transducer, which is only indicated in Fig. 2 for the sake of simplicity. then consists of an insulating jacket 28 (e.g. porcelain or hard paper) and a metal lid, which is not shown, and which is at high voltage, as well as the floor or foundation, which is also not shown, but which is already mentioned and which is at earth potential. The vessel is preferably filled with oil or else. with someone else. Filled with isolating agent.

In deviation from the embodiment shown in Figs the iron core of the voltage transformer can also be connected to earth potential. In In this case, the insulating tube 16 can be omitted because the secondary connecting lines of the current transformer have earth potential or near-earth potential or through a metal Tube can be replaced if it is used as a support. for the current transformer and, if applicable should also be used for the voltage converter. But then you have to cut the coil half 23 of the voltage converter opposite the outer legs. and yokes of the partial cores as well as with respect to the other coil half 24 accordingly for the full: operating voltage and insulate against the inner legs of the partial cores for half the operating voltage. The lower bobbin half 24 must face the inner legs and yokes. the Part cores are isolated for half the operating voltage. Opposite the outer thighs With the secondary winding applied to it, it does not need any special. Isolation, because its outer winding end, like the partial cores, is at earth potential. The partial cores of the voltage converter can. in this arrangement with their lower Yokes rest on the floor or foundation or be arranged close above it.

The high-voltage winding of the voltage converter can also be made from disks. or department coils with appropriate insulation can be set up. If, how already mentioned, the iron core of the voltage transformer is placed on earth potential, can, man, his high-voltage winding .also in the form of a single layer wound Run coil; the end of the innermost winding layer is then connected to earth potential out, so that a special insulation against the inner thighs of the iron core is not required. Opposite the outer legs and the yokes, the high-voltage coil must appropriately insulated for the full operating voltage. Be thrust windings naturally not required in this arrangement.

That to lead through. The insulating tube 1.6 serving the secondary winding ends of the current transformer through the voltage transformer core can also be designed as a condenser bushing with conductive inserts, which is particularly advantageous for higher operating voltages. It is also possible to combine the current transformer with a cascade voltage transformer according to the invention which has several cores. An example of these two possible designs is shown schematically in Figure 4. In the insulating jacket 28 is again the current transformer with the iron core ii, the secondary winding 12, the insulation 13 and the correspondingly insulated primary winding 15. 29 denotes a capacitor bushing provided with conductive inserts, which have the two iron cores 30, 31. Cascade voltage converter enforced. The arrangement of each of the two. Iron cores corresponds to that shown in Figs. I to 3. The high-voltage winding of the voltage converter consists of the four coils 32, 33, 34 and 35 connected in series. The iron core 30 is at the same potential as the connection line between the two coils 32, 33, while the core 31 is connected to the connection between the two coils 34.35 The thrust windings are denoted by 36, 37 and 38, 39, respectively, and the two coupling coils are denoted by 40 and 41. With regard to the required insulation, what has been said about Figs The voltage converter is arranged and insulated on the high-voltage coil 35 of the lower iron core 31 in the same way as the secondary winding 26 in the examples shown in Fig. 1 and 3. As Fig at which it penetrates the iron core 30 of the voltage transformer, corresponding to the higher potential which this iron core has compared to the secondary winding which is at earth potential sending the current transformer has a larger one. Diameter and correspondingly more conductive deposits. on than at the point at which the Konden.satordurchführung 29 the iron core. 31 des. Current transformer interspersed. The conductive insert located approximately in the middle of the thicker part of the capacitor bushing is used with the iron core for better voltage control. 31 conductively connected, as is also indicated schematically in Fig. 4. If the cascade voltage converter has more than two iron cores, the capacitor bushing will be further graded in its diameter accordingly.

Claims (6)

PATENT CLAIMS: i. Combined current and voltage transformer, in which the current transformer and the voltage transformer are accommodated in a common container, preferably made of insulating material, suitably filled with oil, and in which the current transformer, its preferably ring-shaped iron core, which is at ground potential, the secondary winding which is at ground potential and above, accordingly the primary winding is insulated for the full operating voltage, is arranged above the voltage converter, characterized in that the voltage converter has a jacket core with a cavity extending in the direction of the core legs in which the windings are supported. Central leg and that this cavity to pass through: lead. the ends of the current transformer secondary winding to the secondary terminals located on the floor (or foundation) of the transformer vessel. 2. Combined current and voltage converter according to claim i, characterized in that ß the current transformer ring core carrying the secondary winding in a known manner with a sufficient for half the operating voltage. Insulation layer is surrounded and on the upper half facing away from the voltage converter carries the ring-shaped primary winding, which is also insulated for half the operating voltage, that also carries the. secondary-wound current transformer core on the insulation layer facing the voltage transformer. Page continues in an insulating tube dimensioned for half the operating voltage, in which the ends of the secondary winding of the current transformer are passed through the cavity of the voltage transformer core carrying approximately half the operating voltage. 3. Combined current and voltage transformer according to claim 2, characterized in that the connection ends of the current transformer secondary winding surrounding insulating tube as a support for the current transformer, possibly also. as Support for the voltage converter is used. 4. Combined current and voltage converter according to claim 2 or 3, characterized in that that which surrounds the connection ends of the secondary winding of the current transformer Insulating tube is designed as a condenser bushing with conductive inserts. 5. Combined current and voltage converter according to claim i or one of the following Claims, characterized in that the voltage converter is a cascade voltage converter is designed with several iron cores. 6. Combined current and voltage converter according to claim 5, characterized in that the insulating tube surrounding the connection ends of the StromwandlersekundärwickIung, designed as a capacitor bushing according to the different. Differences in potential of the individual iron cores of the cascade voltage converter with respect to the connection ends of the secondary winding of the current converter are graded in its diameter in a manner known per se. Considered publications: German patent specifications No. 723 131, 349 356, 533273, Swiss patent specifications No. 226 858, 252 62 1 , 2o2 629, 15 0 970; British patents No. 331 810, .a.24 753: Austrian patents. No. 119 859, 1.21383, 118549; Textbook: M. Wa 1 ter, current and voltage converter, 1944, p. Ii i.