SU1686616A1 - Stator of single-phase induction motor - Google Patents

Abstract

The invention relates to electrical engineering and allows to improve the performance of an asynchronous motor. The main and auxiliary (starting) windings of the stator of a single-phase asynchronous electric motor are made of concentric coils. The number of turns thereof decreases towards the inner coil. This allows the amplitudes of higher harmonics to be significantly attenuated. Laying of the winding is carried out without step lifting mechanized alternately pulling into the slots of the core of the main and auxiliary stator windings. 2 h. the item of f-ly, 4 ill.

Description

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The invention relates to the field of electrical engineering and can be used in the design and manufacture of asynchronous electric motors.

The aim of the invention is to improve the performance of an asynchronous motor.

FIG. Figure 1 shows the frontal distribution pattern of a single-double-layer bipolar stator winding located in the eighteen slots of the core; in fig. 2 is a flow chart for laying a winding through three transitions; in fig. 3 is an end diagram of the distribution in the grooves of the core of a single-layer quadripolar stator winding located in the thirty-six groove X of the core; in fig. 4 is a flow chart for laying a winding through two transitions.

The winding of FIG. 1 is located in the slots 1 to 18, the winding of FIG. 3 - in the slots from 1 to 36.

The main winding of each pair of stator poles of a single-phase asynchronous electric motor is made of two semi-groups of concentric coils with an extended pole-phase zone. The outer concentric coils A of each semigroup completely fill the groove of the core. A part of the inner concentric coils and semigroups fill the grooves of the core incompletely, with a decrease in the number of turns to the innermost coil of the semigroup. The auxiliary starting winding of the stator of a single-phase asynchronous electric motor consists of coils B and B, the turns of which fill the rest of the core groove

Internal concentric coils of the main winding belonging to different coil semigroups of one pair of poles, and incompletely filling the grooves of the core, can be placed in different layers relative to the bottom of the slot. In this case, the concentric coils assist oo o

ABOUT

The individual windings are placed (Figs. 1 and 2) with one side in the layer facing the bottom of the groove, and the other side placed in the layer facing the slot wedge.

Reducing the number of turns of the inner coils of each semigroup of the main winding towards the innermost coil can be performed according to the cosine-like distribution of conductors along the core grooves.

Laying the winding is carried out without lifting step as follows. In the grooves of the stator core, the main and auxiliary windings are alternately mechanically pulled in, followed by wedging of its active sides in the slots of the core.

The design features of this winding with different number of turns of concentric coils with extended pole-phase zones allow to obtain in the air gap of a single-phase asynchronous electric motor an MDS curve close to sinusoidal. This makes it possible to significantly attenuate the amplitudes of higher harmonics and improve performance.

Claims (3)

1. The stator of a single-phase asynchronous electric motor, containing a core with grooves in which the active sides of the stator winding coils fixed by slot grooves, located on  //// Top bottom Slot numbers (LH) Third transition L Second transition I First transition each pair of poles, including concentric coils of the main winding and concentric coils of the auxiliary (start) winding, characterized in that, in order to improve the performance characteristics of an induction motor, the main winding of each pair of poles is made of two semi-groups of concentric coils, the outer coils of each of which the groove is completely filled, and a part of the inner coils of the semigroup does not fully fill the grooves of the core with a decrease in the number of turns to the inner coil of the semigroup, the auxiliary winding consists of coils, the coils 5 of which fill the remaining part of the groove of the core. 2. A stator according to claim 1, characterized in that the inner coils of the main winding belonging to different coil semigroups of one pair of poles and the core not fully filling the slots are placed in different layers relative to the bottom of the groove, while the coils of the auxiliary winding are placed with one active side in layer facing the bottom of the groove and the other active 5 side placed in a layer facing the mortise wedge. 3. The stator according to claim 1, characterized in that it reduces the number of turns of the inner coils of each semi-group of the main winding towards the innermost coil 30 is made according to the cosine law of the distribution of conductors along the core slots. Sh 0 1 i R Sh to S four