SU1628098A1 - Sectional magnet - Google Patents

Abstract

The invention relates to electrical engineering and can be used in the manufacture of magnetic coupling elements. The aim of the invention is to simplify the manufacturing technology of oval-shaped disk magnets. The goal is achieved by the fact that the magnet consists of two small radius sectors and two truncated large radius sectors arranged in alternating sequences, the central angles of the sectors being 90 °, the radii are connected to the oval semi-axis by the ratio given in the claims. 3 il.

Description

The invention relates to electrical engineering and can be used in the manufacture of magnetic coupling elements.

The purpose of the invention is to simplify the manufacturing technology of oval shaped disk magnets.

FIG. 1 shows the magnetic elements from which a disk magnet with an oval cross section is assembled; in fig. 2 - oval, allowing to establish the ratio of the geometric dimensions of individual elements; Fig. 3 shows the experimental dependence of the radii of the sectors (constituent elements) on the required ovality.

A composite disk magnet with a given ovality consists of two sectors 1 of smaller radius and two truncated sectors of 2 larger radius. The spatial arrangement of the magnetic elements of the composite magnet is shown in FIG. 1 g Some ratios of the geometric dimensions of the elements of a composite magnet can be determined using FIG. 2

The semi-axes of the oval q and b are associated with par, the sector dius with the following expressions:

/

but

OA AO

R-r

4 t 004 G + -JJ-

where A04 OO g; 0.0 R;

R-r

OO4 - (-004) cos 45 -; b 0В - BO, - 00, -

T

ABOUT

to

00

00

where BO, - R;

00

00 „

R-r

ZG

From FIG. 2 that the height h of the truncated sector is equal to the minor axis, i.e. h b.

The ratio of the geometric dimensions of the elements of a composite magnet, namely the sector radii, to the semi-axes of the oval section was experimentally revealed.

Ten oval layouts made of sectors with different ratios of radii r / R were made. On these mock-ups, both the radii of the sectors and the semi-axes of the ovals composed of these sectors were measured with a caliper.

The results of measurements in relative units are presented in the table.

The results presented in the table, processed using the method of least squares and the expression obtained:

1,087

-4F

028

1,088

(one)

which is graphically represented in FIG. 3

Using the expression (1) or the graph in Fig 3, it is possible for any ratio 25 a / b (ovality) to find the required radii of sectors, from which it is possible to make an oval with a given ovality.

Two types of composite magnets are manufactured from StaCO- and barium ferrite. For this purpose, two disks with CiliO and φ 20 mm and thickness of 4 mm each were taken from SinC05, and disks φ 60 and φ30 mm, thickness 6 mm from barium ferrite.

Each disk was cut with a diamond tool into four equal parts - into four sectors with central angles equal to 90.

Sectors in each pair of magnets with large radii

worked to get truncated sectors with heights for SmCOj .: h

 25FT 14.4 mm, for ferrite

2

bari h 30 30-15

I

19.4 mm.

Composite magnets were assembled from the obtained sectors by gluing. Composite magnets were magnetized axially, ferrite composite magnet - axially four-pole.

The proposed composite magnet is most effective in the manufacture of single specimens or small series of magnets, since this results in a significant economic effect due to the savings on the manufacture of complex precision tools (molds).

Claims (1)

Invention Formula A composite magnet containing a set of magnetic elements, which is based on the fact that, in order to simplify the manufacturing technology of oval-shaped disk magnets, it consists of two sectors of small radius and two truncated sectors of large radius arranged in an alternating sequence, while the central the angles of the sectors are equal to 90s, the radii are connected with the semi axis of the oval by r / r with 1,087- - 1, 028 1,088 where g is the smaller radius; R is a large radius; R-r and “g is the semi-major axis of the oval; -J2 R-g .- - the small axis of the oval, .a honeycomb of the truncated sector is equal to b. r / R 0.1 0.2 0.3 0.4 0.5 0.5 0.6 0.7 0.8 0.9 1.0. a / b 2,025 1,763 1,574 1,432 1,320 1,231 1,157 1,096 1,045 1.0 Editor M. Kelemei about oh, oh, oh, b qb w fig.z Compiled by A. Lukin Tehred A. Kravchuk Proofreader M. Demchik