SU815778A1 - Transformer - Google Patents

Description

The invention relates to electrical engineering and can be used in high voltage transformers in all fields of their application.

A voltage transformer is known in which the high-voltage winding is made of toroidal coils that are placed on the insulating cylinder and are insulated from one another by insulating rings, i.e., the primary winding, one-piece from several turns of wire, passes through the windows of the toroidal coils inside the said insulating cylinder and returns through insulating cylinder outside of toroidal coils. An annular magnetic circuit in toroidal coils is completely isolated from the high-voltage winding [1].

The disadvantage of this transformer is the low dielectric strength of the insulation of high-voltage toroidal coils, due to the fact that the lack of electrical contact of the annular magnetic circuit and the high-voltage winding leads to different potentials of the magnetic circuit and the winding and to the effect on the insulation around the magnetic circuit of the doubled voltage of the high-voltage winding.

Also known is a high voltage transformer containing a secondary winding made in the form of isolated ₅ multilayer toroidal coils, in which an annular magnetic circuit is connected by contact with one turn of the inner layer of the toroidal coil, toroidal coils are placed in insulating cells on a centering insulating cylinder, 10 and the primary winding is made in the form of metal rods. The lower terminal of the secondary winding is grounded. The output from the outer layer of the winding of all toroidal coils acts as a high-voltage output [2].

The disadvantages of the known device 'is that the lowest voltage toroidal coil must be isolated from the grounded parts of the transformer at its own operating voltage, and 2Q external insulation of the highest voltage toroidal coil must be provided with respect to the primary winding at the full rated voltage of the high voltage winding of the transformer.

The purpose of the invention is improved reliability and reduced size.

This goal is achieved: I, in that the inner layer of the winding of the lower toroidal coil is connected to the inner layer of the subsequent coil, the tap of the outer layer of which is connected to the tap of the outer layer of the upper coil, and the second terminal of the high-voltage winding is connected to the inner layer of the middle coil, the outer layer of which is connected to the removal of the inner layer of the coil located above it.

In FIG. 1 shows an electrical diagram of a transformer; in FIG. 2 - transformer, general view with cuts.

The transformer contains a low-voltage winding 1 with connecting contacts 2 and 3, a high-voltage winding 4 in the form of several toroidal coils 5, which are equipped with an annular magnetic circuit, 6 and a multilayer winding 7. The low-voltage winding 1 passes through the centers of the windows of the toroidal coils 5. The high-voltage winding 4 is equipped with an insulated high-voltage pin 8 and pin 9 to a grounded neutral. An annular magnetic circuit 6 is connected by a contact 10 to one turn of the first inner layer of the multilayer winding 7 of the toroidal coil. The outer layer of the winding 7 of one toroidal coil And is equipped with a long high-voltage cable outlet 12, held along the higher potential toroidal coils 5 and connected to the outlet 13 from the outer layer of the winding 7 of the most distant toroidal coil 5. Jumper 14 connecting the lowest potential toroidal coil 5 and toroid 11 is made with reinforced electrical insulation. The remaining toroidal coils 5 are interconnected so that the tap 13 of the outer layer of the winding 7 of the toroidal coil 5 is connected to a less potential toroidal coil, and the tap 15 from the ring magnetic core 6 from the inside of the multilayer winding 7 is connected to a higher potential toroidal coil. The outlet 15 from the inside of the multilayer winding 7 is electrically insulated for the full operating voltage of the toroidal coil 5. The external insulation of the toroidal coil 11 is made reinforced by the use of a more electrically durable dielectric, taking into account the action of a higher voltage on it compared to the external insulation of the toroidal coils 5, high-voltage cable outlet 12 is made taking into account the action on it of the total voltage of two toroidal coils 5.

The transformer operates as follows.

The primary primary voltage is supplied to the transformer through the connecting contacts 2 and 3 of the low-voltage winding 1. The primary current induces secondary voltage in the windings 7 of the toroidal coils 5, which is transmitted to the load network via the high-voltage output 8. The output 9 of the grounded neutral of the load network closes the current circuit of the high-voltage winding 4. The external insulation of the toroidal coil 1Ί is exposed to increased voltages from the side of the highest voltage winding 4; it is exposed to the voltage of four toroidal coils attaches, i.e., reduced compared to the own voltage of the high-voltage winding 4.

In connection with the removal of high voltage from the depth of the upper toroidal coils and the output of high voltage from the middle toroidal coil of the high-voltage winding, the high-voltage electric field changes more uniformly along the high-voltage winding, its longitudinal insulation decreases, as a result, the reliability of electrical insulation increases and, when other conditions being equal, the dimensions and weight of the transformer are reduced, since it is possible to reduce or eliminate the height of the supporting insulation transformer.

Claims (2)

(54) Transformer The purpose of the invention is to increase reliability and reduce dimensions. The goal is achieved by the fact that the inner winding layer of the lower toroidal coil is connected to the inner layer of the subsequent coil, the outer layer of which is connected to the outer layer of the upper coil of the outer layer, and the second output of the high voltage winding is connected to the inner layer of the middle coil, the outer layer of which is connected to the outlet of inner layer located above the coil. FIG. 1 shows an electrical circuit of a transformer; in fig. 2 - transformer, general view with cuts. The transformer contains a low-voltage winding 1 with connecting contacts 2 and 3, a high-voltage winding 4 in the form of several toroidal coils 5, which are equipped with an annular magnetic circuit, 6 and a multilayer winding 7. The low voltage winding 1 passes through the centers of the windows of the toroidal coils 5. The high-voltage winding 4 is equipped with insulated high-voltage terminal 8 and terminal 9 to a grounded neutral. The annular magnetic circuit 6 is connected by contact 10 with one turn of the first inner layer of the multilayer winding 7 of the toroidal coil. The outer layer of the winding 7 of one toroidal coil 11 is equipped with a long high-voltage cable outlet 12, conducted along the higher potential toroidal coils 5 and connected to the outlet 13 from the outer layer of the winding 7 of the most distant toroidal coil 5. Reamer 14, connecting the lowest potential toroidal coil 5 and toroidal coil 11, is made with enhanced electrical insulation. The remaining toroidal coils 5 are interconnected so that the outlet 13 of the outer layer of the winding 7 of the toroidal coil 5 is connected to a less potential toroidal coil, and the outlet 15 from the annular magnetic circuit 6 is connected to a higher potential toroidal coil from the inside of the multilayer winding 7. The outlet 15 from the inside of the multilayer winding 7 is electrically insulated to the full operating voltage of the toroidal coil 5. The external insulation of the toroidal coil 11 is reinforced by applying a more electrically strong dielectric considering the effect of a higher voltage compared to the external insulation of toroidal coils 5, the high-voltage cable tap 12 is made with regard to the effect on it of the total voltage of two toroidal coils 5. The transformer operates as follows. Through the connecting contacts 2 and 3 of the low-voltage winding 1, the primary voltage is supplied to the transformer. The primary current induces a secondary voltage in the windings 7 of the toroidal coils 5, which is transmitted to the network by the high-voltage output of terminal 8. The high-voltage output of the grounded neutral of the network closes the high-voltage winding circuit 4. The external insulation of the toroidal coil L is under the influence of high voltages from the side of the high-voltage winding 4 itself is subjected to the stress of four toroidal coils, i.e., reduced in comparison with the intrinsic voltage of the high voltage winding 4. In connection with the removal of high QQ voltage from the depth of the upper toroidal coils and the output of high voltage from the middle toroidal coil of the high voltage winding, the high-voltage electrical voltage changes more uniformly field along the high-voltage winding, decreases its strength in the longitudinal insulation, as a result, the reliability of electrical insulation increases and, under other conditions being equal, the dimensions and mass t ansformatora, since it is possible to reduce or eliminate the height of the support insulator transformer tion. The invention includes a transformer containing a high voltage winding with leads, the lower of which is grounded, made in the form of isolated toroidal multilayer coils located on ring cores and forming a cylindrical column, inside which a low voltage loop-like primary winding is fixed in an insulating cylinder, and the inner layer of each coil is fixed galvanically connected to the core, characterized in that, in order to increase reliability and reduce the size, the inner winding layer of the bottom oidalnoy coil is connected to the inner layer subsequent coil retraction of the outer layer of which is connected with a tap of the upper outer layer of the coil, and a second terminal connected to the high voltage winding secondary coil inner layer, the outer layer of which is connected to the tap of the inner layer situated above it katuschki. Sources of information taken into account in the examination 1. England patent No. 782299, cl. 38, 21 T, 1956. 2. USSR author's certificate number 674109, cl. H 01 F 31/00, 1977.