RU2751533C1 - Method for winding phase stator windings of multi-pole electric machine - Google Patents

Abstract

FIELD: electrical engineering.SUBSTANCE: invention relates to the field of electrical engineering in terms of electrical machines. The method for winding the phase windings of the stator of a multi-pole electric machine is that the wire of the phase multi-pole winding is laid in the grooves between the teeth of the stator magnetic circuit, alternately on the left and right, bending each tooth of the stator magnetic circuit sequentially, first in the forward direction, then in the opposite direction, thus forming around each tooth the stator magnetic circuit is a coil consisting of two halves. The outputs of the beginning and end of the phase winding cross each other on the tooth of the stator magnetic circuit.EFFECT: invention increases the efficiency of the electric machine.1 cl, 1 dwg

Description

The invention relates to the field of electrical engineering in terms of electrical machines.

, при этом статор выполнен с N<m зубами со симметричными и асимметричными шляпками, разделенными пазами, намотка обмотки статора выполнена пофазно для групп зубов, расположенных симметрично по окружности статора на угловом расстоянии

друг от друга, при этом в одну группу для намотки одной фазы входят зубы с симметричными и асимметричными шляпками, а угловое расстояние между краями шляпок, обращенными в сторону группы зубов, предназначенной для намотки другой фазы, равно угловому расстоянию между полюсными делениями числа магнитных полюсов ротора, равного числу последовательно расположенных зубов одной группы, относящейся к одной фазе.Known is a synchronous electric motor-generator (RF patent No. RU 181979 U1 dated 2017.12.29 by Alexander Stepanovich Andrenko), containing a stator with a three-phase winding and a rotor made in the form of a multi-pole magnet with magnetic poles uniformly spaced around the circumference of m alternating m, with a pitch of pole division equal

, while the stator is made with N <m teeth with symmetrical and asymmetric caps, separated by slots, the stator winding is wound in phases for groups of teeth located symmetrically around the stator circumference at an angular distance

from each other, while teeth with symmetrical and asymmetric caps are included in one group for winding one phase, and the angular distance between the edges of the caps facing the group of teeth intended for winding another phase is equal to the angular distance between the pole divisions of the number of magnetic poles of the rotor equal to the number of consecutively located teeth of one group belonging to one phase.

Multi-pole stator winding is made on a group of teeth with alternating winding directions.

The model has the following drawback - the winding performed on a group of stator teeth with alternating winding directions, due to the connecting sections between the teeth, will have an incomplete number of turns on each tooth and, as a result, will have a deviation of the magnetic flux from the tooth axis, which leads to a decrease in the magnetic voltage on stator poles and the appearance of a lateral magnetic gradient on the active surface of the teeth, which creates an axial force on the motor shaft, loading the bearings and leading to their increased wear, reducing the efficiency of the electric machine as a whole. In this case, the fewer turns the stator winding contains, the higher the described losses will be and the lower the efficiency of the electric machine.

Technical challengeis the need to create such winding method, which will allow to withstand a whole number of turns, since the transitions of the winding wire from tooth to tooth of the magnetic circuit of an electric machine are also live parts and create their own fluxes of magnetic induction, which cause a deviation of the toothed flux of magnetic induction from the axis of the tooth, which leads to a decrease in the magnetic voltage and a decrease the efficiency of the electric machine.

The technical result consists in increasing the efficiency of the electric machine.

The claimed method is illustrated by a drawing: FIG. 1 is a winding diagram.

The method of winding the phase windings of the stator of a multi-pole electric machine is that an insulated winding wire made of a conductive material is laid in the grooves between the teeth of the stator magnetic circuit of an electric machine, alternately bending around each tooth from the left and right, first in one, then in the opposite direction, thus forming a complete turn around each tooth of the stator magnetic circuit, consisting of two halves. The terminals of the beginning and end of the winding are crossed with each other on the stator tooth to get a full turn. Thus, a winding is formed in which all interdental joints are formed by symmetrical semi-turn winding elements and the magnetic flux of the teeth of the magnetic circuit does not have lateral deviations, while creating the maximum magnetic voltage on the active surfaces of the teeth.

The proposed method eliminates all possible deviations of the tooth flux of magnetic induction from the axis of the stator tooth and increases the efficiency of electrical machines in which the stator winding has a small number of turns. This is especially true for low-voltage electrical machines and high-power electrical machines, which have a multi-pole winding with a small number of turns.

For example, consider a "single-turn" winding, where one turn of the phase winding is made on each tooth of the stator magnetic circuit. The winding diagram is shown in Fig. 1, where number 1 shows the teeth of the magnetic circuit of an electric machine, number 2 shows the winding wire. The beginning and end of the winding of the phase winding are designated respectively by the letters H and K. The conclusions of the winding H and K must intersect on the tooth of the stator magnetic circuit, as shown in the figure. Thus, a winding is obtained that does not distort the flux of magnetic induction emanating from the teeth of the magnetic circuit of the stator of an electric machine.

Practical implementation of the method

In the described way, several flagship models of bicycle motor-wheels from various leading manufacturers were rewound. The number of turns and the connection diagram of the windings were left the same as in the original. The rest of the wheel motor elements were left unchanged. Tests after rewinding in all cases showed an increase in the efficiency of motors by 5-7%. In the generation mode, the rewound motor-wheels showed an increase in the generated voltage by 5-7%.

Claims (2)

1. The method of winding the phase windings of the stator of a multi-pole electric machine, which consists in the fact that the wire of the phase multi-pole winding is laid in the grooves between the teeth of the stator magnetic circuit, alternately on the left and right of each tooth of the stator magnetic circuit sequentially, first in the forward direction, then in the opposite direction, thus forming around each tooth of the stator magnetic circuit, a coil consisting of two halves. 2. The method of winding the phase windings of the stator of a multi-pole electric machine according to claim 1, characterized in that the terminals of the beginning and end of the phase winding intersect with each other on the tooth of the stator magnetic circuit.

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