SU510765A1 - Three phase conductors - Google Patents

Description

(54) THREE-PHASE CURRENT

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their location is due to design considerations. The secondary windings are interconnected in series and counter-and in series with adjustable resistance 9.

The cross section of the magnetic circuit must be designed for magnetic flux corresponding to the current flowing in the corresponding jumper.

Magnetic cores with secondary winding .1i can be placed on the jumper of any of the ends of the conductor, as well as on the jumpers of both ends.

All load-bearing structures 10, the generator housing and the transformer housing are grounded using ground busbars.

Earthing of the shields is carried out either directly at each end of the section of the conductor, for which the extreme supports of the shielding casing of the middle phase are made without insulating gaskets, or using tires connecting the shielding casing of the middle phase to the grounded housing of the generator or transformer.

The conductor may be divided into two or more sections.

In this case, the shielding covers of the sections, electrically continuous at each of the sections, are separated by insulating spacers. The shielding housings of the middle phase are either grounded at the ends of each section or connected to the generator and transformer housings.

The pipelines of different sections of the conductor may differ in the dimensions of the sections and the number of turns of the secondary windings.

When the conductor is in operation, currents circulate in the shielding housings, the individual components of which are coupled by magnetic fluxes of mutual induction with currents in the conductor busbars. One component of the current in each shield is determined by the current flowing in the same phase, and the other by the currents flowing in the other two phases. Only current components, determined by the current of the same phase, flow through the jumpers. The components defined by the currents of the two other phases circulate within each shield enclosure.

With an increase in the value of the component currents in the shields, caused by currents in the tires of the same phases, the external magnetic flux of the conductor and the values of the components determined by the currents in other phases decrease. The largest values of the external magnetic flux and the component currents in the shielding enclosures determined by the currents in the two other phases correspond to the absence in the current of the shielding enclosures of the component determined by the current of the same phase, i.e. the absence of a connection between the shielding enclosures.

The smallest values of the external magnetic flux and the component currents in the shielding enclosures determined by the currents in the other two phases correspond to the highest value in the current of the shielding enclosures of the component determined by the current in the same phase, i.e. the connection of the shielding enclosures using the lowest possible resistances . The smallest energy losses in shielding housings are obtained with optimal complex resistances of the shielding housings connections, i.e. with some combination of the values of the component currents in the shielding housings.

At a certain value of the complex resistance of the connections of the shielding housings, which is optimal, the best working conditions of the conductor are achieved, assessed by the most advantageous combination

energy losses in the conductor, in metal bodies that are in the magnetic field of the conductor, and in the connection of the screens of the conductors. The optimum values of the indicated resistances are achieved either by an appropriate choice of the dimensions of the magnetic cores or by adjusting the current in the secondary windings, and the number of turns in the secondary windings may be different.

Claims (1)

Invention Formula Three-phase conductors containing busbars, shieldings installed on the busbar of each phase, jumpers electrically connecting the shieldings to each other, and installed at one end of the section of the conductor Magnetic cores with primary and secondary windings, different In order to reduce losses in the shielding enclosures, the magnetic cores are made closed, with their primary windings being jumpers, and the secondary windings are connected in opposite directions. w / five . five