SU811423A1 - Synchronous generator - Google Patents

Description

FIG. 1 shows a portion of the cross section of the generator; in fig. 2 is a groove cross section and flow pattern.

i the operator contains a stator 1 with grooves 2, in which jumpers 6 are made of ferromagnetic material. The rotor is made of permanent magnets 4. In grooves 2, separated by bridges 3, there are conductors about stator 1 wiring. adjacent pole division - increases in such a way that the difference between the ampere turns in the two adjacent parts of the groove 2 on both sides of the jumpers 3 creates a note in the jumper sufficient to saturate it.

The placement of the conductors 5 in the stator 1 winding along the height of the base 2 allows the generator voltage to be controlled without a special biasing winding on the back of the stator or on the jumpers.

The operation of the generator is as follows.

When the permanent magnets 4 rotate, an emf is induced in the stator 1 winding. EMF is proportional to the winding flux linkage. Since jumpers 3 are made in the slots 2, a part of the flow of the magpites 4 closes along the jumpers 3 and will be connected to the part of the winding conductors 5. As the generator load increases, the voltage drop in the winding conductors 5 will increase and the dissipation current of stator 1 will increase, which will close around the base 2 and its parts via jumpers 3 (Fig. 2). This flow will dissolve the jumpers in the selected generator operation mode, which the selection of jumper section 3 will also comply with, it will be saturated with the sum of the fluxes of magnet 4 and dissipated stator winding 1. The flow of dispersion in jumper 3 will take place only if the magnetizing force of the conductors of one part of the groove 2 is different from the magnetizing force of the other part of the groove 2 on both sides of the jumper 3.

Due to the saturation of jumper 3 and a significant decrease in its magnetic permeability, the flux of magnet 4, which closes along the stator 1 strut, increases and will be coupled with a large number of stator winding conductors 5, which will increase the voltage of the generator. The direction of flow in the bridges 3 on different pole divisions should be different, therefore the sides of the sections lying, for example, in one slot in its lower part, in another slot belonging to the other pole division (adjacent), should be located in the upper part because the current in

they have opposite directions. The two sections should be laid in the same way, i.e., on one pole division, a section with a smaller number of conductors 5 should be laid above the previous section in the adjacent part of the groove 2, on the other pole division the other side of this section should be laid down on the previous section. Thus, the sections are laid in series with a decreasing or increasing number of conductors 5 in the adjacent parts of the groove 2 along its height. In this case, on all pole divisions, the direction of the scattered flow of the winding and the working flow of magnetite 4 will be ensured and the effect of magnetizing the jumpers 3 will be obtained. wedges from magnetodielectric, or other methods, for example using a composite stator.

An additional winding on the jumpers can be used to control the voltage frequency of the generator. To select the required voltage control mode (range), you can change the number of conductors 5 on either side of the jumper 3, the material of the jumper 3, its cross-section and the width of the groove 2. The proposed generator allows you to refuse

from the bias windings on the jumpers 3, since the magnetisation is provided by the stator winding itself.

Claims (2)

1. Balagurov V. А. Electric machines with permanent magnets, M., “Energie, 1964, p. 345-348. 2. USSR author's certificate No. 603060, cl. H 02 K 21/12, 1977. / H FIG. 2 /