SU1617475A1 - Spatial magnetic core for three-phase transformer - Google Patents

Abstract

The invention relates to electrical engineering, in particular to transformer construction. The aim of the invention is to reduce losses by improving the magnetic properties, which is achieved by performing stepped rods by winding separate C-shaped twisted parts 1, 2, 3 of different widths and laying them symmetrically relative to the vertical plane with decreasing core width from the center to the periphery. 3 il.

Description

1

The invention relates to electrical equipment, in particular to transformer construction. The purpose of the invention is to reduce losses by improving the magnetic properties.

FIG. Figure 1 shows a rod (transformer with 2K --- 6, fig. 2, sections of vertical and horizontal sections of rods; fig. 3, the spatial magnetic conductor of the three phase transformer, horizontal projection.

The spatial magnetic circuit of a three-phase transformer is constructed as follows.

Rectangular mandrels having the same height but different widths are wound from electrical tape steel of the same width 0-shaped cores with different winding widths. Each of the obtained cores is cut along the longitudinal axis of symmetry at an angle of 60 ° to the lateral surface into C-halves 1-E (FIG. 1 3). From the resulting set of halves, magnetic cores are formed. Each rod contains K 3 cores (2K - 6 halves). In this case, the halves with the largest winding width 1, 4 and 7 (Fig. 3), obtained from the same 0-shaped cores, are applied side-wise to each other to form a wedge with cut planes with an angle of 120 °, and the halves with smaller winding widths, the corresponding pairs of which are obtained from the respective cores, are applied laterally to the previous ones symmetrically relative to the vertical plane with decreasing width from the center to the periphery, while their cut planes coincide with the wedge generators.

In this case, in any cross section of the vertical section of the rod, the step figure 10 is formed, inscribed with a circle.

Since the heights of the vertical sections of each of the elements forming the rod are the same, in the cross section of the horizontal sections of the rods there are formed figures in the form of stepped trapezoids 11 and 12 (Fig 2), the large bases of which are oriented towards each other.

Three crankshaft are joined at the vertices, a total of three-phase transformer three-phase conductor assembly (FIG. 3).

Spatial magnetic core

A three phase transformer works as follows.

The variable magnetic flux created by the transformer primary winding

the passage through the horizontal sections of the magnetic circuit tends to close along the shortest path and extends mainly along the lower layers of these sections,

In the proposed design of the magnetic core, the cross section of the inner layers of the horizontal sections of the rods is larger than the cross section of the outer, and this leads to a better use of electrical steel, to an improvement in its magnetic properties due to a uniform distribution of the flux lines in this section, and in general to a reduction in steel losses on these sections of the magnetic circuit, and, consequently, to the effective use of thin-sheet electrical steels (including amorphous, manufactured in the form of narrow strips).

Thus, the design of the spatial magnetic circuit of a three-phase transformer has a positive effect, which consists in reducing the losses in the steel of the horizontal sections of the rods.

Claims (1)

Invention Formula Spatial magnetic three-phase transformer containing 0-shaped cores, wound from a tape of the same width, cut at an angle of 60 ° to the side surface on C-shaped halves, having the same height of vertical sections, folded by side portions to form rods, characterized in that, in order to reduce losses by improving the magnetic properties, each rod is made of K 2 cores of different widths of winding, of which two halves are located symmetrically relative to the vertical plane with decreasing width of the core from the center to the periphery. FIG. 2