RU2187876C1 - Split-phase two/four/six/ten pole changing winding - Google Patents

Abstract

FIELD: electrical engineering; single-phase variable-speed motors. SUBSTANCE: proposed winding provides for developing four-pole motors with 24, 36, and 48 stator slots. Winding is built up of two parts each having 2q coils, diameter pitch being for pole pair number P₂ = 2 and pole pair ratio P₁:P₂ = 1:2 and P₃>P₂. Novelty is that all coils are assembled in six concentric coil groups, coil number per group being dependent on numerical series 1K, 1K, 1K, 1K, 1K, 1K, where K is positive integer number K = Z₁/12, and Z₁ is number of stator slots; starting and finishing leads of coil groups are brought out; at P₁ = 1 parallel-interconnected coil groups numbered 1, 4, 5 according to above-given series are connected in parallel with parallelinterconnected coil groups 2, 3, 6 through capacitor; at P₂ = 2 coil groups 2, 3, 6 are interconnected in parallel, coil groups 1, 4, 5 are interconnected in parallel and series-connected to coil groups 2, 3, 6; capacitor is connected in parallel with coil groups 1, 4, 5; at P₄ = 5 coil groups 1, 5, 3 are interconnected in series, coil groups 6, 4, 2 are interconnected in series and connected in parallel with coil groups 1, 5, 3; capacitor is connected in parallel with coil group 4; at P₃ = 3 coil groups 1, 3, 4 are interconnected in series, coil groups 2, 6, 3 are interconnected in series and parallel-connected to coil groups 1, 3, 4; capacitor is parallel-connected to coil groups 2, 6. EFFECT: enhanced speed control range, reduced number of leads being changed over thereby facilitating pole changing process. 9 dwg

Description

 The invention relates to electrical engineering and can be used to create single-phase multi-speed electric motors.

 Known two-layer winding at 12/6/2 poles, containing 24 uniformly distributed along the perimeter of the stator, equal-coil coils of the same pitch with numbers from 1 to 24, divided into 18 coil groups, with conclusions from the beginning 1, 2, 3, 6, 13, 18 coil groups, with leads from the ends 4, 7, 16, 17 of the coil groups, while the coil groups with numbers 13, 1, 7, 4, 10, 16, as well as 3 s 9, 5 s 11, 15 are sequentially included from 18, the coil groups with numbers 2, 12, 14, 6, 8, 18, as well as 3 s 5, 11 s 15, 17 s 9, are sequentially included in the opposite direction [1].

 The disadvantages of this winding are lower winding coefficients at 6 and 2 poles, a complex scheme of in-phase connections, an imbalance in the magnitude of currents in parallel branches at 6 and 2 poles, a more complex technology for laying coil groups in the stator core and a lower degree of use of the size of the base motor; the absence of a speed control step in the range from 1000 1 / min to 3000 1 / min.

A single-layer two-phase winding with a variable number of pole pairs P ₁ , P ₂ , P ₃ , and P ₁ : P ₂ = 1: 2, and P ₃ > P ₂ , made on the number of stator slots Z ₁ = 24, consisting of two parts, in each part of 6 coils with a diametrical pitch with the number of pairs of poles Р ₂ , containing q / a = 3 branches in each phase, both branches are connected in series with three taps, the pole P _{2 is} formed by the consonant inclusion of coils of the first and second parts winding, the pole P ₁ - turning their counter, and the polarity P ₃ is defined by the relation P ₃ = P ₂ q / a, the first phase cat swarm is formed by odd winding branches, and the second phase - the even; in this case, the next branch is included counter to the previous one [2].

 The disadvantages of this winding are a large number of switched outputs, equal to 18, and the absence of a step for controlling the frequency of rotation of the electric motor in the range from 500 1 / min to 1500 1 / min.

 The present invention solves the problem of increasing the number of steps for regulating the frequency of rotation of the electric motor, reducing the number of switched outputs, which simplifies the switching of the winding when switching the numbers of pairs of poles.

 This problem is solved by distributing all winding coils into 6 concentric coil groups with leads from the beginning and ends of coil groups, changing the number of coils in coil groups, changing the distribution of the number of coils in coil groups around the stator perimeter.

The invention is illustrated by drawings.
FIG. 1 - a detailed diagram of a two-phase pole-switchable winding at 2/4/6/10 poles;
figure 2 - connection diagram of the coil groups at two poles;
FIG. 3 - scan of the stator of an electric motor with slot numbers and current directions in them at two poles;
figure 4 - connection diagram of the coil groups at four poles;
FIG. 5 - scan of the stator of an electric motor with slot numbers and current directions in them at four poles;
6 is a diagram of the connection of the coil groups at ten poles;
FIG. 7 - scan of the stator of an electric motor with slot numbers and current directions in them at ten poles;
Fig - connection diagram of the coil groups at six poles;
FIG. 9 - scan of the stator of an electric motor with slot numbers and current directions in them at six poles.

In FIG. 1 shows a winding diagram for an engine with 24 stator slots. The winding is made single-layer, consisting of two parts, with a diametrical pitch with the number of pole pairs P ₂ = 2, contains 6 concentric coil groups with numbers from 1 to 6 and switchable leads with numbers from 7 to 23.

 The number of coils in each coil group is determined in accordance with the number series 1K, 1K, 1K, 1K, 1K, 1K.

Here K - a positive integer equal to K = Z _1/12;
Z ₁ - the number of grooves of the stator.

Each part of the winding consists of 2q coils;
here q - a positive number equal to q = Z _1/8.

 The winding can be performed in electric motors with the number of stator slots multiple of 12, for example, 24, 36, 48, etc. The switched leads connected to the external coil in each coil group are taken as the beginning of the coil group, and connected to the internal coil as the end of the coil group.

 The winding contains six coil groups with numbers from 1 to 6 and conclusions with numbers from 7 to 23.

Figure 2 shows the connection diagram of the coil groups when you turn on the winding by the number of pairs of poles P ₁ = 1.

 At the same time, the beginnings of 1, 2, 6 coil groups and the ends of 3, 4, 5 coil groups are combined at one point; at one point the end of 1 coil group and the beginning of 4 and 5 coil groups are combined; at one point the beginning of 3 coil groups and the ends of 2 and 6 coil groups are combined; the capacitor is connected to the combined terminals 1, 4, 5 of the coil groups and the combined terminals 2, 3, 6 of the coil groups; coil groups 1, 4, 5 are connected in parallel; coil groups 2, 3, 6 are connected in parallel and through a capacitor are connected in parallel with coil groups 1, 4, 5.

 If the voltage is applied to the conclusions 8, 11, 13, 16, 18, 22 combined at one point and the conclusions 7, 17, 21 combined at one point, then we obtain the directions of the currents in the grooves corresponding to 2 poles of the magnetic field.

 In FIG. 3 shows a scan of the motor stator with slot numbers and current directions in them at 2 poles. The “+” sign indicates the positive direction of the current, and the “-” sign indicates the negative direction at the given time.

Figure 4 shows the connection diagram of the coil groups when you turn on the winding by the number of pairs of poles P ₂ = 2.

 Moreover, the beginning of 2 coil groups and the ends of 3 and 6 coil groups are combined at one point; at one point the beginning of 1, 3, 4, 5, 6 coil groups and the end of 2 coil groups are combined; at one point the ends of 1, 4, 5 coil groups are combined; coil groups 2, 3, 6 are connected in parallel; coil groups 1, 4, 5 are connected in parallel and connected in series with 2, 3, 6 coil groups; the capacitor is connected in parallel with the coil groups 1, 4, 5.

 If the voltage is applied to the conclusions 11, 13, 23 combined at one point and the conclusions 7, 16, 18 combined at one point, then we obtain the directions of the currents in the grooves corresponding to the 4 poles of the magnetic field.

 In FIG. 5 shows a scan of a motor stator with slot numbers and current directions in them at 4 poles.

Figure 6 shows the connection diagram of the coil groups when the winding is turned on by the number of pole pairs P ₄ = 5.

 In this case, the ends 1 and 6 of the coil groups are combined at one point; the ends of 2 and 3 coil groups are combined at one point; the beginning of 1 coil group is connected to the end of 5 coil groups, the beginning of 5 - with the beginning of 3; beginning 6 - with beginning 4, end 4 - with beginning 2; coil groups 1, 5, 3 are connected in series; coil groups 6, 4, 2 are connected in series and connected in parallel with coil groups 1, 5, 3; the capacitor is connected in parallel with the coil group 4.

 If the voltage is applied to the conclusions 7, 23 combined at one point and the conclusions 9, 13 united at one point, then we obtain the directions of the currents in the grooves corresponding to 10 poles of the magnetic field.

 7 shows a scan of the stator of the motor with the numbers of the grooves and the directions of the current in them at 10 poles.

On Fig shows a diagram of the connection of the coil groups when you turn on the winding on the number of pairs of poles P ₃ = 3.

 At the same time, the beginnings of 1 and 2 reel groups are combined at one point; at one point the beginnings of 4 and 5 reel groups are combined; the end 1 of the coil group is connected to the beginning of the 3 coil group, the end 3 to the end 4, the end 2 to the end 6, the beginning 6 to the end 5; coil groups 1, 3, 4 are connected in series; coil groups 2, 6, 5 are connected in series and connected in parallel with coil groups 1, 3, 4; the capacitor is connected in parallel with the coil groups 2, 6.

 If the voltage is applied to conclusions 8, 11, combined at one point and conclusions 17, 21, combined at one point, then we will obtain the directions of the currents in the grooves corresponding to 6 poles of the magnetic field.

 In Fig.9 shows a scan of the stator of the motor with the numbers of the grooves and the directions of the current in them at 6 poles.

The magnitude of the winding coefficients at the step of the winding y = 6 (Z ₁ = 24) are for 2, 4, 6 and 10 poles, respectively, K _ob2 = 0.71; K _ob4 = 0.95; K _ob6 = 0.65; To _{about 10} = 0.70.

 Due to the accepted number of coils in the coil groups, the distribution of the number of coils in the coil groups, the distribution of the grooves in which the switched leads are located, the number of steps for controlling the speed of the electric motor increases, the number of switched leads decreases.

Sources of information
1. Voitech A. A. Multi-speed single-phase capacitor motors. - Kiev: Naukova Dumka, 1964, p. 136-137.

 2. RU patent 2096891, H 02 K 17/06, 1997.

Claims (1)

Two-phase pole-switched winding at 2/4/6/10 poles, consisting of two parts, each part of the winding consists of 2q coils with a diametrical pitch with the number of pole pairs P ₂ = 2, with the ratio of the numbers of pole pairs P ₁ : P ₂ = 1: 2 and P ₃ > P ₂ , characterized in that all the coils are distributed in 6 concentric coil groups with the number of coils in each coil group, determined in accordance with the number series 1K, 1K, 1K, 1K, 1K, 1K, where K is a whole positive integer equal to K = Z _1/12, a Z ₁ - the number of the motor stator slots, with the conclusions from the beginnings and the ends of the coil g SCP, when P ₁ = 1 in parallel includes coil groups with numbers determined according to the above beside, 1, 4, 5, parallel to include coil groups 2, 3, 6, connected in parallel across the capacitor the coil groups 1, 4, 5, at P ₂ = 2, coil groups 2, 3, 6 are connected in parallel, coil groups 1, 4, 5 are connected in parallel and connected in series with 2, 3, 6 coil groups, the capacitor is connected in parallel with coil groups 1, 4 and 5, with P ₄ = 5 coil groups 1, 5, 3 are connected in series, coil groups 6, 4, 2 are included They are connected in series and connected in parallel with coil groups 1, 5, 3, the capacitor is connected in parallel with coil group 4, with P ₃ = 3, coil groups 1, 3, 4 are connected in series, coil groups 2, 6, 5 are connected in series and connected in parallel with coil groups 1, 3, 4, the capacitor is connected in parallel to the coil groups 2, 6.

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