JPH09322442A - Electric motor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To eliminate any additional insulation material and reduce cogging torque. SOLUTION: At an opening part 4b in a slot 4, an opening part 4d on winding 6 side has a size wider than an opening part 4c on permanent magnet 11 side. Namely, the width dimension A of the opening part 4c on permanent magnet 11 side is set smaller and the width dimension B of the opening part 4d on winding 6 side is set larger than the width dimension A. The opening width dimension C of an insulator 5 is set smaller than the width dimension B of the opening part 4d on winding 6 side.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a motor suitable for being driven by a high voltage.

[0002]

As is well known, in a motor, a fixed structure having a stator core having a slot and a winding provided through an insulator provided in the slot is provided. Some include a child and a rotor having a permanent magnet. In such a motor, in particular, a motor driven at a high voltage, it is necessary to secure a certain insulation distance between the non-insulating surface of the stator core and the winding.

From the viewpoint of motor characteristics, it is also important to increase the slot space factor as much as possible and improve motor efficiency. The most difficult insulation distance is between the stator core opening and the winding. Is.

Therefore, conventionally, there is known a structure in which an insulating wedge is inserted and arranged in the slot opening. But,
In this case, an insulating wedge is additionally required, and an inserting and fixing work is required. In addition to this, there is also a configuration in which the slot opening is widened and the entire surface of the opening is covered with an insulator to the end. However, in this device, the slot opening is widened, so that the cogging torque is increased, and the vibration noise and rotation irregularity of the motor are increased.

The present invention has been made in view of the above circumstances, and an object thereof is to provide a motor that does not require another insulating material, does not require insertion work thereof, and can reduce cogging torque. It is in.

[0006]

The present invention comprises a stator core having a plurality of teeth and a winding provided through an insulator provided in a slot formed by adjacent teeth. A stator having a fixed magnet and a rotor having a permanent magnet, the opening width dimension of the slot opening on the winding side is larger than the opening width dimension of the slot opening on the permanent magnet side. It is characterized in that the opening width dimension of the opening of the insulator is set smaller than the opening width dimension of the slot opening on the winding side.

According to such a structure, when the permanent magnet side is viewed from the winding in the slot, the opening width of the insulator is narrow,
Next, since the opening width on the winding side in the slot is wide and the opening width on the permanent magnet side in the slot is narrow, the distance from the winding to the exposed core portion via the opening end of the insulator ( The so-called creepage distance) becomes longer, and the insulation property can be improved. Moreover, in this case, another insulating material is not required, and therefore the insertion work can be eliminated, and the slot opening width dimension on the permanent magnet side is not increased.
It can contribute to the reduction of cogging torque.

Another aspect of the present invention is a stator having a stator core having a plurality of teeth and a winding provided through an insulator provided in a slot formed by adjacent teeth. And a rotor having a permanent magnet, wherein an opening width dimension of the slot opening on the winding side is larger than an opening width dimension of the slot opening on the permanent magnet side. It is characterized in that the width is set to be twice as large as the plate thickness of the insulator or more than the width of the opening on the side, and the insulator is extended and attached to the inner surface of the opening on the winding side.

In this structure, since the insulator is extended to the vicinity of the permanent magnet side in the slot opening, it is possible to improve the insulating property, and another insulating material is not necessary. The insertion work can be eliminated, and the slot opening width on the permanent magnet side is not increased, so that the cogging torque can be reduced. Further, since the opening where the extended portion of the insulator is located is formed wider than twice the plate thickness of the insulator, the insulator does not project into the slot opening, and There is no danger of disturbing the winding.

[0010]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a first embodiment of the present invention will be described with reference to FIGS. First, FIG.
1, the sleeve 1 provided at a stationary portion (not shown)
The stator 2 is attached to the. In this stator 2, the stator core 3 has a plurality of teeth 3a,
A slot 4 is formed by the adjacent teeth 3a. A winding 6 is formed in the winding housing portion 4a (see FIG. 1) of the slot 4 via an insulator 5 made of, for example, PBT resin (polybutylene terephthalate resin).

On the other hand, a rotating shaft 8 is inserted into and supported by the sleeve 1 via a bearing 7, and an outer rotor type rotor 9 is attached to the rotating shaft 8. This rotor 9
Is formed by attaching a permanent magnet 11 to the rotor yoke 10.
The permanent magnet 11 faces the outer peripheral surface of the stator core 3.

FIG. 1 shows a part of this motor. An opening 4b is formed in the slot 4, and in this opening 4b, with respect to the opening 4c on the permanent magnet 11 side, The opening 4d on the winding 6 side is wider by one step, that is, the width dimension A of the opening 4c on the permanent magnet 11 side is set smaller, and the opening from the opening 4c to the winding 6 side is set. 4d width dimension B (opening 4
The width dimension of the narrow portion of d) is set larger than the width dimension A. The width A is preferably narrow in view of the magnetic circuit characteristics, and is set, for example, to such a degree that the conducting wire of the winding wire 6 can pass when winding the winding, for example, about three times the thickness of the conducting wire.

The insulator 5 is inserted so as to cover the inner surface of the winding accommodating portion 4a of the slot 4, and the opening 4b side is open. The width dimension C of the opening 5a of the insulator 5 is set to be smaller than the width dimension B of the opening 4d on the winding 6 side. In this case, the width dimension is set equal to the width dimension A of the opening 4c.

According to this embodiment, the slot 4
When the permanent magnet 11 side is seen from the winding 6 in the inside, the width of the opening 5a of the insulator 5 is narrow, the width of the opening 4d of the opening 4b of the slot 4 on the winding 6 side is wide, and 4c of the opening 4b on the permanent magnet 11 side
Since the width of the coil is narrower, the distance from the winding 6 to the exposed portion of the stator core 3 through the end of the opening 5a of the insulator 5 (so-called creepage distance) becomes longer, improving the insulation. It can be planned. In addition, in this case, another insulating material is not required, and therefore the insertion work can be eliminated, and the width dimension A of the opening 4c on the permanent magnet 11 side is not increased, which can contribute to the reduction of the cogging torque. .

Particularly in this embodiment, the opening 5a of the insulator 5 is formed.
The width C of the slot opening 4b is set to be equal to the width A of the opening 4c of the slot opening 4b on the permanent magnet 11 side. Does not interfere with the winding.

Next, FIG. 3 shows a second embodiment of the present invention. This embodiment differs from the first embodiment in the following points. That is, the inner surface of the opening 4d on the winding 6 side of the opening 4b of the slot 4 is connected to the opening 5a of the insulator 5.
It is formed in a circular arc concave shape centered on the end. According to this embodiment, similarly to the first embodiment, the winding 6 to the insulator 5 are connected.
The distance to the exposed portion of the stator core 3 (so-called creepage distance) via the end of the opening 5a of the stator core 3 becomes longer, so that the insulation property can be improved and the cross-sectional area of the stator core 3 (magnetic path area ) Can be increased, which can further contribute to the reduction of cogging torque.

FIG. 4 shows a third embodiment of the present invention, which is different from the first embodiment in the following points. That is, in the opening 4b of the slot 4, the width dimension B of the opening 4d on the winding 6 side is made wider than the width dimension A of the opening 4c on the permanent magnet 11 side by at least twice the plate thickness of the insulator 21. The insulator 5 is extended and mounted on the inner surface of the opening 4d. In this case, the width dimension B of the opening 4d is a constant width dimension.

In such a structure, the insulator 21
However, since the opening 4b of the slot 4 is extended to the vicinity of the permanent magnet 11 side, it is possible to improve the insulating property, and another insulating material is not necessary, so that the insertion work is also unnecessary. In addition, since the width dimension A of the opening 4c on the permanent magnet 11 side is not increased, the cogging torque can be reduced. Further, since the opening 4d in which the extended portion of the insulator 21 is located is formed wider than twice the plate thickness of the insulator 21, the insulator 21 projects into the opening 4b of the slot 4. There is no danger of disturbing the winding of the winding wire. In each of the above-described embodiments, only the outer rotor type motor has been described, but the invention can be applied to the inner rotor type motor.

[0019]

As apparent from the above description, the present invention has the following effects. According to the invention of claim 1, the opening width dimension of the slot opening on the winding side is set to be larger than the opening width dimension of the slot opening on the permanent magnet side, and the slot opening portion on the winding side. Since the opening width dimension of the opening of the insulator is set smaller than the opening width dimension of, the distance (so-called creepage distance) from the winding to the exposed core portion via the end of the opening of the insulator is It can be made longer, the insulation property can be improved, and another insulating material is not required. Therefore, the insertion work is also unnecessary, and the slot opening width on the permanent magnet side is not increased, so cogging is not required. It can contribute to the reduction of torque.

According to the second aspect of the present invention, the opening width dimension of the opening portion of the insulator is set to be substantially equal to the opening width dimension of the slot opening portion on the permanent magnet side. When the winding is wound, this insulator does not interfere with the winding. According to the third aspect of the present invention, the inner surface of the opening on the winding side of the slot opening is formed in a circular arc concave shape centered on the end of the opening of the insulator, so that the insulation can be improved. In addition, the cross-sectional area of the stator core can be increased, which can further contribute to the reduction of cogging torque.

According to the invention of claim 4, the opening width dimension of the slot opening on the winding side is insulated from the opening width dimension of the slot opening on the permanent magnet side from the opening width dimension on the permanent magnet side. It was set to be more than twice as thick as the thickness of the child, and the insulator was extended to the inner surface of the opening on the winding side. The creepage distance to the exposed core can be increased to improve the insulation,
Moreover, since another insulating material is not required, the insertion work thereof is not required, and the slot opening width dimension on the permanent magnet side is not increased, which can contribute to the reduction of the cogging torque. There is no risk that it will interfere with the winding.

[Brief description of drawings]

FIG. 1 is a cross-sectional plan view of an essential part showing a first embodiment of the present invention.

FIG. 2 is a longitudinal sectional side view.

FIG. 3 is a cross-sectional plan view of essential parts showing a second embodiment of the present invention.

FIG. 4 is a cross-sectional plan view of an essential part showing a third embodiment of the present invention.

[Explanation of symbols]

2 is a stator, 3 is a stator core, 3a is teeth, 4 is a slot, 4a is a winding housing, 4b is an opening, 5 is an insulator, 6 is a winding, 8 is a rotating shaft, 9 is a rotor. , 11 are permanent magnets, and 21 is an insulator.

Claims (4)

[Claims] 1. A stator composed of a stator core having a plurality of teeth and a winding provided through an insulator provided in a slot formed by adjacent teeth, and a permanent magnet. And a rotor having, wherein the opening width dimension of the slot opening on the winding side is set to be larger than the opening width dimension of the slot opening on the permanent magnet side. A motor in which the opening width dimension of the opening of the insulator is set smaller than the opening width dimension on the winding side. 2. The motor according to claim 1, wherein the opening width dimension of the opening of the insulator is set to be substantially equal to the opening width dimension of the slot opening on the permanent magnet side. 3. The motor according to claim 1, wherein an inner surface of the opening on the winding side of the slot opening is formed in a circular arc concave shape centered on an end of the opening of the insulator. 4. A stator having a stator core having a plurality of teeth and a winding provided through an insulator provided in a slot formed by adjacent teeth, and a permanent magnet. A rotor having an opening width dimension of the slot opening on the winding side of the slot opening section with respect to an opening width dimension of the slot opening on the permanent magnet side. A motor characterized in that the width is set to be at least twice as large as the plate thickness of the insulator, and the insulator is extended and mounted to the inner surface of the opening on the winding side.