KR100322265B1 - Coil Winding Method For Stator Of a Single Phase Induction Motor - Google Patents

Abstract

Disclosed is a stator winding method of a single phase induction motor. As disclosed, the stator winding method of the present invention is a stator winding method of a single-phase induction motor for winding a main winding, a speed control winding and an auxiliary winding in 36 slots of a stator core. The auxiliary winding is made of a process of winding alternately according to a predetermined rule so that no empty slot is generated in eight poles in 36 slots of the stator core; Harmonic noise and motor input due to empty slots can be reduced, and starting torque is increased to have the effect that the performance and efficiency of the motor as a whole can be improved.

Description

Coil Winding Method For Stator Of a Single Phase Induction Motor

The present invention relates to a single-phase induction motor, and more particularly, a stator winding method of a single-phase induction motor for changing the winding method of the stator of the motor to increase the driving torque and improve the motor efficiency by reducing the input of the motor. It is about.

In general, the single-phase induction motor is composed of a stator and a rotor that is rotated by the generation of a magnetic field by the electric force with the stator. The stator has a main winding (MAIN Coil) and a sub winding (SUB Coil) at an electric angle Each is wound with a 90 ° polar axis.

That is, the stator of the single-phase induction motor has an electric pole 90 ° electrically ahead of the main winding when the AC power from the outside is applied to the main winding and the auxiliary winding wound in the multiple slots. The force that the auxiliary winding preferentially rotates is acted on. At this time, in the auxiliary winding, the high-speed rotation is achieved because the current phase is ahead of the main winding by a capacitor connected in series.

1 is a diagram showing 36 slot shapes of a stator core of a single phase induction motor.

As shown in FIG. 1, the disk-shaped stator 100 constituting the single-phase induction motor has 36 slots 102 formed along its inner circumferential surface, and the 36 slots 102 have main slots for driving a motor. The winding, auxiliary winding and speed control winding are wound to eight poles.

2 is a diagram schematically showing the order in which the winding is wound in 36 slots of the stator core according to the conventional winding method.

As shown in FIG. 2, in the case of winding 8 windings in 36 slots of the stator core, the main winding M1 and the speed control windings C1 and C2 drawn from the first slot occupy four slots. To form a winding group to be wound, wound into eight winding groups occupying a total of 32 slots and finally drawn out from the 33rd slot. In addition, the auxiliary winding (S1) is drawn in from the third slot and is wound across every five slots or four slots to be drawn out from the 35th slot.

However, according to the winding method of the stator core in such a conventional single-phase induction motor, the main winding M1 and the speed control windings C1 and C2 have eight windings occupying four slots for 36 slots of the stator core. Since it is formed as a group, only 32 slots are used, and 4 slots, that is, 5th, 14th, 23rd, and 32nd slots, are left as empty slots, and even the auxiliary winding S1 can use such empty slots. You will not be wound up.

Accordingly, in a single-phase induction motor, such four empty slots act as a major factor that causes the functional harm, such as harmonic noise of the slot, input rise of the motor, and lowering of starting torque, and such a malfunction state is driven by the motor. There is a problem that the efficiency can be reduced.

Accordingly, the present invention has been made to solve the above problems, and provides a stator winding method of a single-phase induction motor for winding a winding without generating empty slots for 36 slots of the stator core.

1 shows 36 slot shapes of a stator core of a single phase induction motor,

2 is a diagram schematically showing the order of winding the winding in 36 slots of the stator core according to the conventional winding method,

3 is a diagram schematically showing the order in which the main winding and the speed control winding are wound in 36 slots of the stator core according to a preferred embodiment of the present invention;

4 is a diagram schematically showing a sequence in which sub windings are wound in 36 slots of a stator core according to a preferred embodiment of the present invention;

FIG. 5 is a view showing a sequence in which the main winding and the speed control winding of FIG. 3 and the sub winding of FIG. 4 are integrally wound in 36 slots of the stator core;

6 is a view showing an example in which a motor drive circuit formed by the main winding, the sub winding and the speed control winding of the present invention is connected to the stator;

7 is a view showing the configuration of a motor drive circuit applied to the winding method of the present invention.

Explanation of symbols on the main parts of the drawings

100: stator core, 102: slot,

106: winding winding, M2: main winding,

S2: auxiliary winding, C3, C4: speed control winding.

According to the present invention for achieving the above object, in the stator winding method of a single-phase induction motor for winding the main winding, the speed control winding and the auxiliary winding in 36 slots of the stator core, the main winding and the speed control winding A stator winding method of a single-phase induction motor is provided, in which an auxiliary winding is wound alternately according to a predetermined rule so that an empty slot is not formed in eight poles in 36 slots of the stator core.

Preferably, the main winding and the speed control winding are drawn from the fifth slot of the stator core and are eighth-12th-9th-10th-13th-14th-17th-21st-18th-19th -22nd-23rd-26th-30th-27th-28th-31st-32th-35th-3rd-36th-1st-4th-36th slots It is made to be withdrawn.

More preferably, the auxiliary winding is drawn from the eighth slot of the stator core so that 10th-7th-11th-15th-12th-16th-19th-23rd-21st-24th-20th -26th-28th-25th-29th-33rd-30th-34th-1st-5th-3rd-6th-2nd slots do.

According to the present invention configured as described above, the main winding, the speed control winding and the auxiliary winding of the 36 slots formed in the stator core of the single-phase induction motor alternately according to a certain rule to eight poles without any empty slots being generated. By being able to be wound, harmonic noise and motor input by the empty slots can be reduced, and starting torque can be raised to improve the performance and efficiency of the motor as a whole.

Hereinafter, the present invention configured as described above will be described in detail with reference to the accompanying drawings.

That is, FIG. 3 is a diagram schematically showing the order in which the main winding and the speed control winding are wound in 36 slots of the stator core according to the preferred embodiment of the present invention, and FIG. 4 is a stator core according to the preferred embodiment of the present invention. FIG. 5 is a diagram schematically illustrating an order in which sub windings are wound in 36 slots of FIG. 5, and FIG. 5 illustrates an order in which the main winding and the speed control winding of FIG. 3 and the sub windings of FIG. 4 are integrally wound in 36 slots of the stator core. The figure shown.

First, as shown in Figure 3, according to the stator winding method of the present invention, the main winding (M2) and the speed control winding (C3, C4) to the fifth slot-eighth slot, eighth slot-12th slot Subsequently, it is wound in the forward / backward direction from the twelfth slot to the ninth, tenth slot, the thirteenth and the fourteenth slots, and then the winding process of the slot from the fourteenth slot is repeated.

That is, the main winding M2 and the speed control windings C3 and C4 are wound up to the 14th slot-17th slot, 17th slot-21st slot, and 18 times in the forward / rear direction from the 21st slot. The windings are sequentially wound for the 19th slot, the 22nd, and the 23rd slots, and the windings passed through the 23rd slot are continued to the 26th slot, and then the 26th slot to the 30th slot, and from that 30th slot. It is sequentially wound to the 27th, 28th, 31st, and 32nd slots in the forward / backward direction, and continues from the 32nd slot to the 35th slot.

Next, the main winding M2 and the speed control windings C3 and C4 leading to the 32nd slot-35th slot are wound up to the 35th slot-3rd slot, and then the forward / backward direction from the 3rd slot. 36 times, it is wound up sequentially in the 1st slot and the 4th slot.

After the winding process is performed, the main winding M2 and the speed control windings C3 and C4 wound up to the 36th slot are drawn out.

In addition, as shown in Figure 4, according to the winding method of the present invention, the auxiliary winding (S2) is drawn from the eighth slot of the 36 slots of the stator core to the eighth-tenth-seventh-eleventh slot It is wound up and the auxiliary winding S2 from the eleventh slot extends to the fifteenth-twelveth-sixteenth-nineteenth slots. The auxiliary winding S2 wound in the 19th slot is connected to the 26th slot through the 23rd-21st-24th-20th slots. The auxiliary winding S2 wound to the 26th slot performs the same winding process as the above winding process for subsequent slots.

That is, the auxiliary winding S2 wound in the 26th slot is connected to the 28th-25th-29th slot, and wound from the 29th slot to the 33rd-30th-34th-1st slot, The first slot is wound up to the fifth, third, sixth, and second slots.

In addition, the auxiliary winding S2 wound up to the second slot is drawn out.

Meanwhile, the main winding M2 and the speed control windings C3 and C4 wound by the winding process as shown in FIG. 3 and the auxiliary winding S2 wound by the winding process as shown in FIG. 4 are integrated. The wound state is as shown in FIG. 5.

That is, as shown in Figure 5, the main winding (M2) and the speed control windings (C3, C4) and the auxiliary winding (S2) in the 36 slots 102 of the stator core 100 by empty slots In this state, it is possible to wind up to 8 poles.

6 is a view showing an example in which the motor driving circuit formed by the main winding, the sub winding and the speed control winding of the present invention is connected to the stator, and FIG. 7 shows the configuration of the motor driving circuit applied to the winding method of the present invention. The figure shown.

As shown in FIG. 6, an eight-pole winding group formed by the main winding M2, the speed control windings C3 and C4, and the auxiliary winding S2 is provided in 36 slots of the stator core 100. 106 is formed, the eight-pole winding group 106 has the incoming line (S) and the outgoing line (L) of the main winding (M2) and the speed control windings (C3, C4) In addition to passing, the starting and exiting of the auxiliary winding S2 is also passed.

As shown in FIG. 7, in the motor driving circuit including the main winding M2, the speed control windings C3 and C4, and the auxiliary winding S2, the inlet S of the main winding M2 is a commercial AC. Connected to one end of the power source AC, the capacitor CAP and the auxiliary winding S2 are connected in series with the rotor R centered between the inlet S and the outgoing L of the main winding M2. Is connected.

In addition, the start line L of the main winding M2 and the start line L of the auxiliary winding S2 are connected to one end of a temperature protector T / P, and the temperature switch T / P While the speed control windings C3 and C4 are connected in series from the other end, the speed control windings C3 and C4 are connected in series, while the speed control windings C3 and the speed control windings C4 have their respective speeds between the inlet line S and the start line L. It is connected to the other end of the commercial AC power supply via the switch SW.

On the other hand, the speed switching switch (SW) changes the state of the closed circuit formed through the speed control windings (C3, C4) by switching switching, so that the speed switching of the motor is made.

According to the present invention made as described above, the winding method of the winding for the 36 slots provided in the stator core of the single-phase induction motor can be wound to 8 poles so as not to generate a ball slot, the ball slot is not generated As a result, the harmonic noise and the motor input due to the empty slot can be reduced, and the starting torque is increased to improve the performance and efficiency of the motor as a whole.

The present invention is not limited to the above-described specific preferred embodiments, and various modifications can be made by any person having ordinary skill in the art without departing from the gist of the present invention claimed in the claims. Of course, such changes are intended to fall within the scope of the claims set forth.

Claims (3)

In the stator winding method of a single-phase induction motor for winding the main winding, the speed control winding and the auxiliary winding in 36 slots of the stator core, The stator of the single-phase induction motor, characterized in that the main winding and the speed control winding, and the auxiliary winding is wound alternately according to a predetermined rule so that no hole slots are generated in eight poles in 36 slots of the stator core. Winding method. According to claim 1, wherein the main winding and the speed control winding is drawn from the fifth slot of the stator core 8th-12th-9th-10th-13th-14th-17th-21st-18th -19th-22nd-23rd-26th-30th-27th-28th-31st-32nd-35th-3rd-36th-1st-4th-36th slots Stator winding method of a single-phase induction motor characterized in that it is made to be drawn out. According to claim 1, wherein the auxiliary winding is drawn from the eighth slot of the stator core 10th-7th-11th-15th-12th-16th-19th-23rd-21st-24th- 20th-26th-28th-25th-29th-33rd-30th-34th-1st-5th-3rd-6th-2nd slots Stator winding method of a single-phase induction motor characterized in that.