KR20190074137A - motor - Google Patents

Abstract

The present invention relates to a motor and, more specifically, to a Vernier motor capable of effectively preventing separation of a permanent magnet. According to an embodiment of the present invention, the motor comprises: a rotor including multiple magnets arranged in a circumferential direction; a stator core including a core, a tooth part extended from the core to face the rotor, and two or more teeth (flux modulation pole (FMP)) formed on the tooth part and having an air gap with the rotor, and formed by punching a magnetic steel sheet; and a coil wound around a slot between tooth parts. Moreover, a stator magnet is arranged between the teeth, and a ratio (α/β) of the radial length of the stator magnet (stator pitch, α) with respect to the radial length of the teeth (FMP pitch, β) is 1.2 to 2.1. According to an embodiment of the present invention, provided is a three-phase motor for operating a drum of a washing machine.

Description

Motor {motor}

The present invention relates to a motor, and more particularly to a vernier motor.

The motor is a device for rotating the rotor by electromagnetic interaction between the stator and the rotor to transmit the rotational force to the outside. Here, the rotating force of the rotor drives the load through the rotating shaft.

The stator generally comprises a stator core and a coil wound around the stator core. Accordingly, an electromagnetic force is generated as current flows through the coil.

The rotor is rotated by the electromagnetic force. To improve the performance of the motor, a rotor is provided with a permanent magnet (magnet) mounted thereon. In such a motor, the rotor rotates due to the interaction between the electromagnetic force generated by the stator and the magnetic force of the magnet of the rotor.

1 shows a conventional motor. Such a motor may be a motor for driving a drum as a motor of a washing machine.

The motor 1 includes a rotor 10 and a stator 20. For example, the rotor 10 may be rotatably disposed outside the stator 20 in the radial direction. A gap G may be formed between the rotor 10 and the stator 20 in the radial direction. The rotor 10 can rotate without contacting the stator 20 through the gap G. [ The rotor 10 may be directly connected to a shaft for rotating the drum so that the rotor and the drum are rotated together. This type is generally referred to as direct drvie (DD) mode.

The rotor 10 may include a rotor core 11 and a magnet 14. The rotor core may be formed of a magnetic material, and the magnet 14 may be mounted on the radially inward side surface of the rotor core 11. The magnet 14 may be provided as a permanent magnet so as to have respective magnetic poles. The magnet 12 magnetized in the S-pole and the magnet 13 magnetized in the N-pole can be alternately mounted along the circumferential direction. Therefore, the number of such magnets 14 becomes equal to the number of magnetic poles of the rotor.

The stator 20 may include a stator core 21, a tooth portion 22 projecting radially from the stator core, and a tooth 23 provided at a radial end of the tooth portion 23. The stator core 21, the teeth 22, and the teeth 23 may be formed of the same magnetic material, or may be formed of a conductive steel sheet.

A slot (24) is formed between the tooth portion (22) and the tooth portion (22), and a wire is wound on the slot to form a coil.

For example, the radial distance between the teeth 23 and the magnet 14 may be referred to as a gap G. [

A conventional motor, such as the motor shown in Fig. 1, has a rotor number of poles of 40, a tooth number of 24, a number of stator poles of 8, and a stator slot number of 24. That is, the number of teeth and the number of slots can be made equal.

Fig. 2 shows another conventional type of motor. The basic form is the same as in Fig. Therefore, redundant description is omitted for the same matters.

The stator 20 shown in Fig. 2 shows an example in which one tooth portion 22 has two teeth 23. Therefore, the number of teeth corresponding to twice the number of tooth portions can be formed. A tooth gap 25 may be formed between the tooth 23 and the tooth 23 formed on one tooth 22. The tooth gap 25 may be formed to be equal to the circumferential width of the teeth 23.

A conventional motor, such as the motor shown in FIG. 2, has a rotor number of poles of 40, a tooth number of 24, a number of stator poles of 8, and a stator slot number of 12. That is, the number of teeth and the number of slots are the same, and the number of flux modulation poles (FMP) can be twice the number of teeth.

Likewise, the motor shown in Fig. 2 can be applied to a motor for driving a drum of a washing machine, and it can be seen that the same rotor can be used, only the structure of the stator is different.

The conventional motor shown in FIGS. 1 and 2, in particular, the washing machine motor is driven by the electromagnetic force generated in the permanent magnet and the stator provided in the rotor. The magnitude of the current and voltage that can be provided through the coil of the stator can not but be limited. Therefore, the magnitude of the electromagnetic force or the output of the motor that can be provided through the stator can not be limited.

To solve this problem, a vernier motor having a permanent magnet in the rotor may be provided. An example of a vernier motor is disclosed in Japanese Patent Application (Publication No. JP2013-005563, hereinafter referred to as "prior invention").

There is a problem that the permanent magnet provided on the stator is attached and detached due to the attraction force generated between the permanent magnet provided on the rotor and the permanent magnet provided on the stator. In order to solve such a problem, the prior art discloses forming a holder of a non-magnetic body for inserting a permanent magnet between a tooth and a tooth of a stator. That is, the permanent magnet is fixed to the stator by molding the permanent magnet in the holder of the non-magnetic body.

Specifically, in the prior art, a stator core and a permanent magnet, which are magnetic materials, are insert-molded, and then a nonmagnetic material, which is a resin material, surrounds the stator core and the permanent magnets.

Therefore, in the prior art, the material cost and the machining cost of the motor are inevitably increased. This is because a complicated structure for forming the holder is inevitably added and the material cost is increased. Further, after molding, additional processing is required, and the production cost is inevitably increased.

Particularly, since the stator is manufactured by molding, the dispersion of the error during manufacturing is inevitably increased and the reliability is lowered. Further, since the space occupied by the permanent magnet holder is additionally generated, the size of the entire stator is inevitably increased.

On the other hand, the conventional drum driving motor of the washing machine has a problem that the structure is complicated and the manufacturing is not easy since the number of slots is large. Therefore, there is a need to provide a motor that is simpler and easier to manufacture while satisfying the equivalent performance or higher.

It is an object of the present invention to solve the problems of the conventional motor, particularly the vernier motor.

It is an object of the present invention to provide a motor that can suppress a simple structure, an increase in material cost, and an increase in motor size.

According to an embodiment of the present invention, there is provided a motor that can easily and stably mount a permanent magnet on a stator.

According to an embodiment of the present invention, a permanent magnet can be directly inserted into a stator core, which is a magnetic body, but a permanent magnet can be prevented from being detached very effectively structurally.

According to an embodiment of the present invention, there is provided a motor capable of effectively preventing radial displacement of a permanent magnet inserted into a stator.

According to an embodiment of the present invention, there is provided a motor capable of effectively preventing a permanent magnet inserted perpendicularly to a stator from deviating in a vertical direction through an insulator coupled to an upper portion and a lower portion of the stator core, respectively.

It is an object of the present invention to provide a motor that maximizes performance by optimizing the ratio between the pitch of the magnet mounted on the teeth of the stator core and the tooth pitch.

According to an embodiment of the present invention, when a plurality of teeth are formed in one tooth portion, a motor is provided that optimizes the ratio between the width of the tooth portion and the width of the passage portion branched from the tooth portion to the tooth to provide maximum performance I want to.

According to one embodiment of the present invention, there is provided a washing machine drum driving motor which is easy to manufacture and has excellent performance.

According to an aspect of the present invention, there is provided a rotor comprising: a rotor having a plurality of magnets along a circumferential direction; The rotor according to claim 1, wherein the core comprises a core, a tooth portion extending from the core to face the rotor, and at least two flux modulating poles (FMP) formed on the tooth portion and having an air gap with the rotor, A stator core; And a coil wound around a slot between the tooth portion and the tooth portion, wherein a stator magnet is provided between the tooth and the tooth, and the stator magnet is disposed on the circumferential length (FMP pitch, The ratio (? /?) Of the circumferential length (stator pitch,?) Of the rotor (1) to the rotor (2) is 1.2 to 2.1.

Preferably, the stator core is formed with a magnet mounting portion integrally formed with the stator core so as to be embedded in the radial direction between the teeth and the teeth.

The magnet mounting portion is preferably formed integrally with the stator core by punching the stator core.

Three teeth may be formed per tooth portion, and two stator magnets may be provided.

[Beta] of the three teeth are equal to each other, and [alpha] of the two stator magnets is preferably equal to each other.

The motor has a tendency that counter electromotive force and efficiency increase as the ratio (? /?) Increases at 1.0, and the torque ripple has a tendency to increase after decreasing.

Wherein the motor has an efficiency of 105% or more and a torque ripple of 100% or more and a torque ripple of 100% in a case where the ratio (? /?) Is 1.0 to 1.2 95% or less.

The stator core may include a passage portion extending in the circumferential direction of the tooth portion and connected to the teeth.

The width Wt of the tooth portion in the longitudinal direction is preferably larger than the width Wm in the longitudinal direction of the passage portion.

The ratio (Wt / Wm) of the width (Wt) to the width (Wm) is preferably 2.63 to 3.38.

The efficiency of the motor is preferably 85% or more within the range of the ratio (Wt / Wm) of 2.63 to 3.38.

The passage portion may extend in the circumferential direction beyond the magnet mounting portion and then be connected to the teeth.

The passage portion may extend in an oblique shape having an angle larger than 90 degrees with the tooth portion and may be connected to the teeth.

In order to increase the width between the circumferential end of the magnet mounting portion and the passage portion, the corner portion of the magnet mounting portion may be formed to have an inclined surface.

And the inclined surface is formed to be parallel to the passage portion.

The corner of the stator magnet mounted on the magnet mounting portion preferably has a chamfer surface corresponding to the inclined surface.

The magnet mounting portion includes a radial surface extending in the radial direction and a circumferential surface extending in the radial direction at both ends of the circumferential surface, and the inclined surface may be formed only between the circumferential surface and any one radial surface.

And the inclined surface is formed only at an edge part of the opposite end of the circumferential surface which is further away from the tooth part in the circumferential direction.

The angle between the radial surface and the inclined surface is preferably 59 degrees.

According to an aspect of the present invention, there is provided a rotor comprising: a rotor having a plurality of magnets along a circumferential direction; The rotor according to claim 1, wherein the core comprises a core, a tooth portion extending from the core to face the rotor, and at least two flux modulating poles (FMP) formed on the tooth portion and having an air gap with the rotor, A stator core; And a coil wound around the slot between the tooth portion and the tooth portion, wherein a stator magnet is provided between the tooth and the tooth, the stator core extends in the circumferential direction on both sides of the tooth portion, Wherein a width Wt of the tooth portion in the longitudinal direction is greater than a width Wm in the longitudinal direction of the passage portion and a ratio Wt / Wt of the width Wt to the width Wm, Wm) is in the range of 2.63 to 3.38.

According to an aspect of the present invention, there is provided a rotor comprising: a rotor having a plurality of magnets along a circumferential direction; The rotor according to claim 1, wherein the core comprises a core, a tooth portion extending from the core to face the rotor, and at least two flux modulating poles (FMP) formed on the tooth portion and having an air gap with the rotor, A stator core; And a coil wound around a slot between the tooth portion and the tooth portion,

A magnet mounting portion formed integrally with the stator core so as to be embedded in the radial direction between the teeth and the teeth and having an opening toward the air gap and having oblique projections formed at both ends of the opening in the circumferential direction to narrow the width of the opening, ; And a magnet mounted on the magnet mounting portion.

The motor may be a three-phase motor for driving a drum of a washing machine.

The magnet mounting portion is preferably formed by punching the stator core.

The magnet mounting portion includes a circumferential surface spaced radially from the opening, a radial surface extending from both ends of the circumferential surface toward the opening, and a space defined between the tapered projection and the radial end of the tapered projection Lt; / RTI > The magnet mounting portion is a space extending vertically and is a space in which the magnet is vertically inserted and mounted.

The circumferential width of the opening is preferably smaller than the circumferential width of the circumferential surface.

Wherein the inclined projection has an inclined surface extending in a direction in which a circumferential width of the opening is narrowed at a radial end of the radial surface; And a circumferential surface extending in the circumferential direction of the tooth and connected to an end of the inclined surface.

The angle between the radial surface and the inclined surface is preferably smaller than 180 degrees.

Preferably, the angle between the inclined surface and the circumferential surface is less than 90 degrees, and the radial width between the inclined surface and the circumferential surface is smaller in the circumferential direction.

And the length of the inclined surface is larger than the length of the inclined projection in the circumferential direction and the length of the inclined projection in the radial direction.

The length of the inclined projection in the circumferential direction and the length of the inclined projection in the radial direction are preferably equal to each other.

The circumferential length and radial length of the oblique projection are preferably 0.4 mm or more and 1.2 mm or less.

The magnet mounted on the magnet mounting portion is formed to be smaller than the size of the magnet mounting portion to be inserted into the magnet mounting portion in the vertical direction. And the magnet mounted on the magnet mounting part is formed to be fitted to the magnet mounting part.

Wherein the magnet mounted on the magnet mounting portion includes: a reference surface corresponding to the circumferential surface; A side surface corresponding to the radial surface; A chamfer surface corresponding to the inclined surface; And an opposed surface forming the air gap. And the opposed surface is exposed to the outside of the air gap through the opening.

The angle between the side surface of the magnet and the chamfer surface is preferably greater than 90 degrees and smaller than the angle between the radial surface of the magnet mounting portion and the inclined surface.

The reference surface and the opposite surface of the magnet may be curved. Thus, the magnet is formed to have a "C" shape so that magnetic flux concentration in the radial direction can be effectively performed.

It is preferable that three teeth are formed per tooth portion, and the magnet mounting portion is formed between the teeth and two teeth are formed per tooth portion.

The circumferential width (pitch) of the tooth is preferably smaller than the circumferential width (pitch) of the magnet mounting portion.

It is preferable that the circumferential widths of the three teeth are equal to each other and the circumferential widths of the two magnet mounting portions are equal to each other.

And an insulator made of an insulating material and coupled to the upper surface and the lower surface of the stator core, respectively, and the coil is coupled after the insulator is coupled to surround the tooth portion.

The insulator may include a top cover portion that covers the top and bottom surfaces of the magnet mounting portion and supports the top and bottom surfaces of the magnet mounted vertically to the magnet mounting portion.

The motor according to the present embodiment can exhibit performance equal to or higher than that of the conventional motor, and the structure can also be simply formed.

The features in the above-described embodiments may be implemented in combination unless they are contradictory or exclusive in other embodiments.

According to one embodiment of the present invention, it is possible to provide a motor that can suppress a simple structure, an additional material cost rise suppression, and an increase in motor size.

According to the embodiment of the present invention, it is possible to provide a motor which can easily and stably mount the permanent magnet on the stator.

According to an embodiment of the present invention, it is possible to provide a motor capable of directly inserting a permanent magnet into a stator core, which is a magnetic body, while preventing the permanent magnet from being detached very effectively structurally.

According to an embodiment of the present invention, it is possible to provide a motor that can effectively prevent radial displacement of a permanent magnet inserted into a stator.

According to an embodiment of the present invention, it is possible to provide a motor that can effectively prevent the permanent magnets inserted perpendicularly to the stator from deviating in the vertical direction through the insulators respectively coupled to the upper and lower portions of the stator core.

According to one embodiment of the present invention, it is possible to provide a motor that provides maximum performance by optimizing the ratio between the pitch of the magnet mounted between the teeth of the stator core and the tooth pitch.

According to an embodiment of the present invention, when a plurality of teeth are formed in one tooth portion, a motor is provided that optimizes the ratio between the width of the tooth portion and the width of the passage portion branched from the tooth portion to the tooth to provide maximum performance can do.

According to an embodiment of the present invention, it is possible to provide a washing machine drum driving motor which is easy to manufacture and has excellent performance.

1 shows an example of a conventional motor,
Fig. 2 shows an example of another conventional motor,
Figure 3 illustrates a portion of a motor according to one embodiment of the present invention,
Fig. 4 shows an enlarged view of a part of the motor shown in Fig. 3,
5 is an enlarged view of the motor shown in Fig. 3, omitting the stator magnet,
Fig. 6 shows a change in back electromotive force with respect to the slope length L1 of the slanting projection shown in Fig. 5,
Fig. 7 is a graph showing the relationship between the slope length L1 of the slanting projection shown in Fig. 5, the circumferential length L2 of the slanting projection and the radial length L3 of the slanting projection, and the change in the counter electromotive force with respect to these changes Respectively,
8 shows an example of a motor according to an embodiment of the present invention,
9 shows the tooth pitch β, the magnet pitch α and the width Wt of the tooth portion and the width Wm of the passage portion of the stator in the motor according to the embodiment of the present invention,
FIG. 10 shows a change in the counter electromotive force and the change in the permanent magnet material ratio with respect to the? /? Ratio change in FIG. 9,
FIG. 11 shows a change in the counter electromotive force, a torque ripple, and an efficiency change with respect to the change in the ratio alpha / beta in FIG. 9,
FIG. 12 shows an efficiency change state with respect to the Wt / Wm ratio change in FIG. 9,
FIG. 13 shows a variation of the Wt / Wm ratio with respect to the variation of the Wt / Wm ratio and the variation of the tooth width Wt of FIG. 9,
14 shows a state of the magnetic flux saturation by the passage portion and an embodiment of the passage portion and the magnet mounting portion for preventing magnetic flux saturation,
15 shows a state of magnetic flux saturation by the passage portion and another embodiment of the passage portion and the magnet mounting portion for preventing magnetic flux saturation,
Fig. 16 shows the relationship between the passage portion of another embodiment shown in Fig. 15 and the inclined surface of the magnet mounting portion,
17 shows the relationship between the number of slots of the stator, the end-turn length of the coil, and the torque,
18 shows the relationship between the number of slots of the stator, the end-turn length of the coils and the efficiency,
19 shows the relationship between the number of slots of the stator, the core loss, and the terminal voltage.

Hereinafter, a vernier motor according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

The motor structure in the attached drawings shows a horizontal cross-sectional view for convenience of explanation.

First, a basic structure of a vernier motor according to an embodiment of the present invention will be described with reference to FIG. In FIG. 3, for convenience, only one of the three motors divided in the circumferential direction is shown as the motor 100.

The motor 100 may include a stator 200 and a rotor 110. The stator is configured to be fixed to an object, and the rotor may be configured to rotate with respect to a fixed stator. As shown in the figure, the rotor 110 may be rotated radially outward relative to the stator 200, and such a motor may be referred to as an outer rotor type motor.

The stator 200 may include a core 210, a teeth 220 and a tooth 230. The core 210, the teeth 220 and the teeth 230 may be referred to as a stator core. That is, the stator core may include the core 210, the teeth 220, and the teeth 230. A slot 240 may be formed between the tooth portion 220 and the tooth portion 220.

A plurality of teeth 230 may be provided on one tooth portion 220. For example, two teeth may be formed on one tooth portion 220. However, as will be described later, the number of teeth to be formed per tooth portion can be varied, and FIG. 3 shows an example in which three teeth 230 are formed in one tooth portion 220.

The teeth 230 may be provided to form a gap G with the rotor. That is, a configuration in which the stator 200 forms a gap G by forming a distal end in the radial direction may be referred to as a tooth 230. The teeth 230 may be a passage through which the magnetic flux moves with respect to the rotor through the gap G. [ Therefore, it can be called a flux modulation pole (FMP).

The core 210 may be formed in an annular shape, and the center may be formed in an empty shape. That is, the core as a whole can be formed in a donut shape. The core 210 forms the center of the stator in the outer rotor type motor, and therefore, the tooth portion 220 may extend in the radial direction of the core 210.

As shown in FIG. 3, the core 210 may have a plurality of teeth 220 protruding radially outward along the circumferential direction. That is, the tooth portion 200 protrudes outward in the radial direction, so that the stator of the outer rotor type motor can be formed. For convenience, a structure including both the core 210, the teeth 220, and the teeth 230 described above may be referred to as a stator core.

The stator core 205 and the plurality of tooth portions 220 may be integrally formed. That is, it can be formed to have a single body. Similarly, the teeth 230 formed on the tooth portion 220 may be integrally formed on the tooth portion 220. Of course, the plurality of cores 210 may be connected to each other along the circumferential direction to form a core 210 having an annular shape. This can be referred to as a split type core 210. That is, a plurality of core pieces may be connected to each other in the circumferential direction to form an annular stator core.

Of course, one or a plurality of tooth portions 220 may be formed integrally with each of the pieces of the stator core.

Such a stator core or a stator core piece may be formed by tapping a steel sheet. That is, it is possible to form a stator core or a stator core piece by tapping a steel sheet having a small thickness. This punching process can be carried out very precisely and the dimensional error is very small. Therefore, no separate machining is required after punching.

After each steel sheet is punched out, the stator core can be formed by stacking. This stacking can determine the height of the stator core or the thickness of the stator core. Of course, such lamination can be performed after making the stator core into a strip shape. That is, the stator core of a single body can be formed by winding the stator core in a spiral form and laminating it.

In any case, the overall shape, detailed structure and dimensions of the stator core 205 can be precisely formed through the punching process.

The stator 200 is provided with a coil 240. Specifically, the coil 240 is formed by winding the tooth portion 220. A slot 240 is formed between the tooth portion 220 and the neighboring tooth portion 220 along the circumferential direction. The number of the teeth 220 and the number of the slots 240 becomes equal. Therefore, a number of coils 240 equal to the number of teeth or the number of slots are formed. The slot 240 may be a space through which the coil 240 is wound.

The coils 240 may be formed to form three phases, and U, V, and W phases may alternately be provided along the circumferential direction. The number of the teeth 220 may be formed to have a multiple of 3 in the case of a three-phase motor because one coil 240 per one tooth portion 220 is wound to form each phase.

According to the present embodiment, the magnet 260 can be directly mounted on the stator core 205. [ For this purpose, the stator core 205 may be provided with a magnet mounting portion 250.

The magnet mounting portion 250 may be formed as a part of the stator core 205. That is, when the stator core 205 is formed as a rudder, the magnet mounting portion 250 may be formed at the same time. In other words, the magnet mounting portion 250 may be formed on the stator core 205 itself other than the stator core 205. Therefore, a separate material, a separate process, or a separate space for forming the magnet mounting portion 250 is not required. That is, the magnet mounting portion 250 may be formed as a part of the stator core 205.

As shown in FIG. 3, three teeth 230 may be formed on one tooth portion 220. The teeth 230 may extend in the circumferential direction from the radial end of the tooth portion 220 to form two teeth 230 at both ends and a tooth 230 at the center. The teeth may be positioned to face the rotor.

The magnet mounting portion 250 may be formed between the teeth 230 and the teeth 230 adjacent to each other in one tooth portion 220. Accordingly, when three teeth 230 are formed on one tooth portion 220, two magnet mounting portions 250 can be formed.

The magnet mounting portion 250 may be formed to be embedded in the radial direction between the teeth 230 and the teeth 230. Specifically, the magnet mounting portion 250 may be formed in a shape in which a space between the teeth 230 and the teeth 230 is removed. Therefore, when the stator core 205 is punched, the magnet mounting portion 250 can be formed at the same time. In other words, the magnet mounting portion 250 may be formed as a part of the stator core 205 of the magnetic body.

The rotor 110 may include a rotor core 111 and a magnet 114. The magnet may be alternately provided with an S pole magnet magnet 112 and an N pole magnet magnet 113 alternately. A plurality of magnets 114 may be provided along the circumferential direction of the rotor core 111, and the magnetizing directions are alternated.

Specifically, the magnet 114 may include an actual magnet 112 and a virtual magnet 113. The actual magnet 112 may be a magnet made of a magnetic material and the virtual magnet 113 may mean a space between the actual magnet 112 and the actual magnet 112 or a nonmagnetic material filled in the space.

As shown in Fig. 4, the actual magnet 112 can be magnetized so that magnetic flux flows radially inward. The radially inner side of the actual magnet 112 may be magnetized to the N pole and the radially outer side to the S pole. These actual magnets 112 are arranged at predetermined intervals along the circumferential direction of the rotor. Therefore, the magnetizing direction of the virtual magnet 113 is opposite to the actual magnet 112. [

It is preferable that the circumferential width of the actual magnet 112 is larger than the circumferential width of the virtual magnet 113. Therefore, it becomes possible to manufacture a high-efficiency motor using the magnetic flux generated in the actual magnet 112.

As shown in FIG. 4, the magnetization direction of the magnet 260 provided on the stator may be the same as the magnetization direction of the actual magnet 112. Therefore, attraction is generated between the magnet (112) of the rotor and the magnet (260) of the stator. That is, a pulling force to pull each other in the radial direction is generated.

Assuming that the rotor magnet 112 is firmly fixed to the rotor core 112, the magnet 260 of the stator is subjected to a force radially deviating from the rotor core. Therefore, a fixing structure for preventing the magnet 260 of the stator from radially deviating is required.

However, as in the prior art, forming a fixing structure separately from the stator core causes many problems.

According to the present embodiment, the magnet mounting portion 250 can be formed to mount and fix the magnet 260 on the stator core 205 itself.

The magnet mounting part 250 may be provided to insert the magnet 260 after the stator core 205 is formed. That is, the magnet 260 may be inserted in the vertical direction in the stator core 205 and the inserted magnet 260 may not be detached in the radially outward direction.

The magnet mounting portion 250 is formed between the teeth 230 and the teeth 230. Therefore, the magnet mounting portion 250 has the opening 253 in the radial direction. The opening 253 may be said that the magnet mounting portion 250 is opened toward the gap G. [ Therefore, the magnet 260 inserted vertically into the magnet mounting part 250 may be radially deviated through the opening 253.

In order to prevent the detachment of the magnet 260, a slant projection 255 is preferably formed on the magnet mounting portion. Specifically, the slanting protrusion may be formed at both ends of the opening 253, and may be a protrusion formed so as to narrow the width of the opening 253 in the circumferential direction. Therefore, the slanting protrusion may be formed symmetrically with respect to the circumferential center of the opening.

In other words, two oblique protrusions 255 are formed in one magnet mounting portion 250. The relationship between the teeth arranged in the circumferential direction, the magnet mounting portion, and the teeth is described in a linear state. In this case, since the magnet mounting portion is formed between the two teeth, the oblique protrusions protrude rightward in the left tooth 230, In the teeth 230, the inclined projections project leftward. Therefore, the width of the opening portion is narrowed by the projecting length of the slanting projection. Therefore, the magnet 250 inserted into the magnet mounting part 250 and filling the magnet mounting part 250 can be prevented from being radially deviated by the narrowed opening part.

The magnet mounting portion 250 includes a circumferential surface 251 spaced radially from the opening 253 and a radial surface 251 extending from both ends of the circumferential surface 251 toward the opening 253 252). The magnet mounting portion 250 may be defined as a space defined between the circumferential surface 251, the radial surface 252, and the radial ends of the oblique protrusions 255 and the oblique protrusions 255. That is, this space is a space having a depressed cross section between the teeth and the teeth, and the magnet 260 can be mounted in this space.

The circumferential surface 251 may be formed in a curved shape having a single radius of curvature. The distal end of the slant projection 255 and the distal end of the slant projection 255 can form a curved opening 253 having a single radius of curvature. Therefore, the magnet mounting portion 250 has a "C" shape, so that the magnet 260 mounted on the magnet mounting portion 250 can also have a "C" shape. Therefore, it is preferable that the circumferential width of the opening 253 is smaller than the circumferential width of the circumferential surface 251 so that the magnet mounted on the magnet mounting portion 250 is not radially detached.

As described above, the magnet mounting portion 250 and the slanting protrusions 255 thereof may be referred to as a portion of the stator core 205. The inclined projection 250 may be a protrusion protruding in the circumferential direction of the tooth 230 and may be formed at the time of punching.

Punching is a process of forming a desired shape by stamping a steel sheet with a press. Therefore, a structure having a thin thickness may be damaged when punched or easily damaged after punching. Therefore, it is preferable that the protrusion protruded to narrow the circumferential width of the opening 253 is a triangular protrusion. That is, it is preferable that the projections are formed in such a shape that the width becomes narrower toward the projecting direction. With this shape, protrusions of a desired shape can be formed at the time of punching, and the damage of the protrusions can be effectively prevented.

Specifically, the protrusion 255 may include a circumferential surface 257 and an inclined surface 256. Due to the inclined surfaces 256, these protrusions may be referred to as oblique protrusions 255. The circumferential surface 257 is a surface extending in the circumferential direction at the radial end of the tooth and the inclined surface 256 extends from the radial surface end of the tooth or the magnet mounting portion toward the distal end of the circumferential surface 257 . Therefore, it is preferable that the angle (Y) between the radial surface (the side of the tooth) of the magnet mounting portion and the inclined surface is smaller than 180 degrees.

The circumferential surface 257 and the inclined surface 256 intersect with each other, and such an intersection point may be referred to as the end of the inclined projection. Therefore, the angle Z between the circumferential surface 257 and the inclined surface 256 is preferably smaller than 90 degrees. Therefore, the inclined projection 255 has a shape that protrudes in the circumferential direction of the right triangle due to the inclined surface 256 and the circumferential surface 257, and the radial width becomes narrower toward the protruding direction or the circumferential direction. Since the thickness at the projecting start point of the oblique projection 255 is largest, it is easy to strike and the damage can be minimized during punching.

As described above, the magnet 260 mounted on the magnet mounting portion 250 is inserted and fixed to the magnet mounting portion 250. Therefore, it is preferable that the magnet 260 is formed in the magnet mounting part 250 and smaller than the size of the magnet mounting part 250.

Therefore, the magnet 260 corresponds to the reference surface 261 corresponding to the circumferential surface 251 of the magnet mounting portion, the side surface 262 corresponding to the radial surface 252 of the magnet mounting portion, the inclined surface 256 And an opposed surface 264 forming the air gap G. The air gap G, The radius of curvature of the opposing surface may be formed to coincide with the radius of curvature of the stator core 205. [ Similarly, the reference plane 261 of the magnet may be formed as a curved surface having a single radius of curvature.

The chamfered surface 263 of the magnet 260 may be a chamfered edge portion. Therefore, the angle X between the side surface 262 of the magnet 260 and the chamfered surface 263 is important. It is preferable that the angle X is smaller than the angle Y. [ This is because the tolerance g between the magnet 260 and the magnet mounting portion 250 can be minimized when the angle X is smaller than the angle Y. [ That is, the magnet 260 and the magnet mounting portion 250 can be formed with a certain tolerance, and the magnet 260 can be mounted on the magnet mounting portion 250. Since the tolerance g can be managed, it is possible to effectively prevent the inserted magnet 260 from being shaken by the magnet mounting portion 250.

On the other hand, in the magnet mounting part 250, the slanting protrusion 255 prevents the magnet 260 from coming off, and substantially reduces the volume of the magnet mounting part 250. This means that the volume of the magnet 260 mounted on the magnet mounting part 250 is reduced. That is, the volume of the magnet 260 is reduced by the volume corresponding to the chamfer surface 263 of the magnet. In addition, magnetic flux leakage may occur in the circumferential direction due to the inclined projections 255.

Therefore, in the absence of such slanting protrusion 255, the electromagnetic performance can be maximized. When there is no oblique projection 255, when the counter electromotive force representing the performance of the motor is 100%, it is necessary to limit the size of the oblique projection 255. [ If the size of the slant projection 255 is increased, the detachment of the magnet 260 can be more firmly prevented, but the performance of the motor deteriorates.

On the other hand, there is a limit in reducing the size of the slanting protrusion 255. [ This is because the inclined projection 255 must be formed integrally with the stator core 205 by punching.

With reference to Figs. 5 to 7, the optimal numerical values for the size of the warp projections 255 will be described in detail.

5, the slanting projection 255 is formed such that the length L1 of the slanting surface 256 is smaller than the radial length L2 of the slanting projection 255 and the inclination angle of the slanting surface 255, Is preferably larger than the circumferential length L3 of the projection 255. [

Specifically, the radial length L2 of the slant projection 255 and the circumferential length L3 of the slant projection 255 may be the same. Therefore, the slanting protrusion 255 may have an isosceles triangle shape in which the length of the inclined surface is long.

It is noted that the length L1 of the inclined plane 256 is determined by the radial length L2 of the inclined projection 255 and the circumferential length L3 of the inclined projection 255. [ If there is no oblique projection 255, it can be seen that L1, L2, and L3 are all zero.

As shown in FIG. 6, as the slope length L1 of the slanting protrusion increases, the size of the slanting protrusion 255 increases, so that the counter electromotive force decreases. The decrease in the counter electromotive force means a decrease in performance of the motor.

Particularly, there is a limit in reducing the circumferential length L3 and the radial length L2 of the slanting protrusion 255. [ In other words, a minimum length must be ensured in order to facilitate the pulling and to prevent damage to the slanted projections.

Therefore, it is not preferable to make the length of L2 or L3 smaller than 0.4 mm as shown in Fig. Of course, in the case of less than 0.4 mm, the back electromotive force may approach 100% of the standard, but various problems such as difficulty of the kick, damage of the warping protrusion 255 after the punch, and deviation of the magnet 260 may occur. Therefore, the length of L2 or L3 is preferably 0.4 mm or more. So that the inclined projection is not damaged even if stress is concentrated on the radial length portion of the inclined projection.

On the other hand, as the length of L2 or L3 increases, the size of the slanted projections 255 becomes large, and the counter electromotive force becomes small. As described above, since the length L1 of the inclined surface is determined by L2 and L3, it can be seen that the back electromotive force is small as shown in FIGS. 6 and 7 as L1 becomes larger.

Therefore, in order to minimize the decrease in the electromagnetic performance, it is necessary to limit the size of the slanting protrusion so as to have 95% of the reference electromotive force. That is, it is preferable to limit the size of the slanted projections to 1.2 mm or less based on L2 to L3.

As a result, it is preferable that L2 or L3 of the oblique projection is determined between 0.4 mm and 1.2 mm. The range of L1 can also be determined through the range of L2 and L3. When L2 and L3 are the same and the angle between L2 and L3 is a right angle, L1 can be determined to be larger than L2 and L3 by using a trigonometric function. L 1 in FIG. 7 is shown as a value in the case where the lengths of L 2 and L 3 are equal to each other and are straight-line.

The magnet mounting portion 250 or the slanting protrusion 255 may be formed for the radial deviation of the magnet 260.

Since the magnet 260 is vertically inserted into the magnet mounting portion 250, there is a possibility that the inserted magnet 260 is vertically detached due to an impact. In order to prevent such a vertical deviation of the magnet 260, an insulator 270 may be provided in an embodiment of the present invention.

8, the insulator 270 may be configured to cover the upper portion and the lower portion of the stator core 205 to insulate the stator core 205 from the coils 240. As shown in Fig. Accordingly, the structure of the insulator 270 may be a general structure in a motor for driving a drum of a washing machine.

The insulator 270 may be provided with an upper insulator covering the upper portion of the stator core 205 and a lower insulator covering the lower portion, and they may be coupled to each other to cover the stator core 205.

Specifically, the insulator 270 may include a core cover 271 covering the core and a tooth cover 273 covering the tooth portion. The coil 240 is wound around the teeth cover 273.

In this embodiment, the tooth cover 274 may include a tooth cover 274 that extends further in the radial direction at the tooth cover 273 to cover the tooth. The tooth cover 274 may be formed to cover not only the tooth but also the magnet mounting portion 260. A coupling portion 272 for coupling the stator to the tub of the washing machine may be formed radially inward of the core cover 271. All of these configurations can be formed integrally by injection molding.

Thus, the upper insulator covers the upper portion of the magnet mounting portion, and the lower insulator covers the lower portion of the magnet mounting portion. For example, the magnet may be inserted into the magnet mount after the lower insulator and the stator core are coupled. The upper insulator can then be coupled to the stator core and the lower insulator. By such a structure and assembling procedure, the magnet can be prevented from vertically separating from the magnet mounting portion.

A reinforcing rib 275 may be formed on the tooth cover 274 of the insulator 270 according to the present embodiment. That is, a reinforcing rib 275 extending in the circumferential direction at the radial end portion of the tooth cover 274 may be formed. Therefore, even if a force is applied to the teeth cover 274 by the magnet in the vertical direction, the teeth cover 274 can stably support the magnet by the reinforcing ribs 275.

Through the above-described embodiments, it is possible to mount the magnet very easily by integrally forming the magnet mounting portion in a form embedded in the stator core. In addition, it is possible to prevent the magnet from deviating in the radial direction through the inclined projection of the magnet mounting portion. Further, the structure of the insulator can be changed to effectively prevent the magnet from deviating in the vertical direction from the magnet incoming portion.

In addition, it is possible to provide a highly efficient and robust motor through the shape and size range of the slanted projections.

Hereinafter, a structure of a stator core capable of increasing the output density of the motor by increasing the counter electromotive force will be described in detail.

First, it was found that the counter electromotive force varies according to the change of the ratio (? /?) Of the circumferential length (FMP pitch,?) Of the tooth and the circumferential length (stator pitch,?) Of the stator magnet.

The change in the counter electromotive force, the torque ripple and the efficiency according to the increase / decrease in the ratio of? /? based on the case where the? /? ratio is 1 is shown in FIG. 10 and FIG.

As a result of varying the α / β ratio around 1, it was found that the back electromotive force and the efficiency are basically increased as the α / β ratio becomes larger than 1. The torque ripple performance also shows an increasing tendency. That is, it is preferable that the stator pitch is larger than the FMP pitch.

It is understood that the ratio of α / β which makes the efficiency performance equal to or more than 105% based on 100% of α / β ratio at 1 is 1.2 or more. It can be seen that the torque ripple performance is still improved in this rate increasing process.

As the ratio increases further, the efficiency tends to increase further, indicating that the torque ripple performance improves and sharply decreases. That is, when the? /? Ratio exceeds 2.1, it is found that the torque ripple performance is lower than that when? /? Ratio is 1.

Considering the relation between the α / β ratio, the counter electromotive force performance, the efficiency and the torque ripple, the optimum α / β ratio is 1.2 to 2.1.

Particularly, in the stator core 205 shown in Fig. 9, three teeth 230 are formed at the radial end of one tooth portion 220. As shown in Fig. That is, a stator core having three teeth and two stator magnets per one tooth portion is shown.

Therefore, in the stator core 205 having such a structure, it is preferable that the? /? Ratio is determined to be between 1.2 and 2.1.

Further, in order to achieve symmetry, β of the three teeth are equal to each other, and α of the two stator magnets is preferably equal to each other. It is preferable that both the teeth and the magnet mounting portion are formed symmetrically with respect to the centering tooth.

The characteristics of the magnet mounting portion 250, the stator core, and the rotor in this embodiment will be the same as in the above-described embodiment.

9, since a plurality of teeth 230 are formed in one tooth portion 220, the width of the magnetic flux path toward the tooth 230 is greater than the width of the magnetic flux path in the tooth portion 220. Therefore, Can not help but be small. Because it is branched into a plurality of teeth 230 in one tooth portion 220. This branch path may be referred to as a passage portion 225.

The passage portion 225 may be a portion of the stator core 205 and may extend to both sides of the tooth portion 220 to be connected to both teeth.

The relationship between the width Wt of the tooth portion 220 and the width Wm of the passageway portion when the three teeth 230 are formed on one tooth portion 220 as in the present embodiment, Can greatly affect the efficiency of the system.

12 and 13 show the relationship between the Wt / Wm ratio and the motor efficiency. And, since Wt must be larger than Wm (assuming that the main passage is larger than the branch passage), it is preferable to determine Wm first and then vary Wt.

As shown, it can be seen that the efficiency is maintained at 85% within a certain range by changing the Wt / Wm ratio. That is, the efficiency is maintained at about 85% within the range of the Wt / Wm ratio of 2.63 to 3.38, so that it does not change. However, it can be seen that the efficiency drops sharply before and after this range.

Therefore, it is preferable that the Wt / Wm ratio is determined within a period in which the efficiency satisfies 85%. In order to satisfy this Wt / Wm ratio, Wt may be determined within a range of 21 mm to 27 mm.

The characteristics of the magnet mounting portion 250, the stator core, and the rotor in this embodiment will be the same as in the above-described embodiment.

Therefore, the width Wt of the passage portion in the present embodiment can be influenced by the magnet mounting portion.

For example, when the passage portion is formed obliquely, the gap between the passage portion and the magnet mounting portion can be narrowed. In the left-hand side of FIG. 14, when the passage portion extends in an oblique line, the width between the passage portion and the corner portion of the magnet mounting portion becomes narrow, and magnetic flux saturation occurs at this portion.

In order to prevent this, as shown in the right side of Fig. 14, the passage portion preferably extends in the circumferential direction. Particularly, it is preferable that the passage portion extends further in the circumferential direction than the magnet mounting portion and is connected to the teeth. Therefore, it can be seen that the magnetic flux saturation at the corner portion of the magnet mounting portion is remarkably reduced.

On the other hand, extending the passage portion in the circumferential direction increases the length of the magnetic flux path. That is, it can be said that the magnetic flux moving in the radial direction is circumferentially bypassed.

Therefore, it is preferable that the passage portion extends in the oblique direction on the premise that flux saturation is prevented. That is, it is preferable that the passage portion between the teeth in the tooth portion extends in an oblique shape. That is, the angle between the tooth portion and the passage portion is preferably larger than approximately 90 degrees. It can be said that the extension of the passage portion in the circumferential direction is smaller than approximately 90 degrees.

However, in this case, as shown in the left-hand side of FIGS. 14 and 15, magnetic flux saturation occurs at the corner of the magnet mounting portion. This flux saturation is closely related to the decrease of Wm.

Therefore, it is preferable that the corner portion of the magnet mounting portion, which determines the width of the passage portion between the passage portion and the passage portion, is formed as an inclined surface without changing the shape of the passage portion. An example of this is shown in the right side of Fig.

That is, the width of the passage portion can be increased by forming the inclined surface 258 of the magnet mounting portion to be substantially parallel to the passage portion. Of course, a chamfer surface may be formed in the stator magnet 260 to correspond to the inclined surface 258. Such a chamfered surface is different from the chamfered surface for preventing magnet deviation in the above-described embodiment, and it is preferable that the width is also larger.

The magnet mounting portion may include a circumferential surface 251 and radial surfaces 252 and 252a on both sides. An inclined surface 258 may be formed at an edge portion between the radial surface 252a and the circumferential surface 251 at a position spaced apart from the center of the circumferential direction of the tooth portion 220. [ Due to this inclined surface, the length of the radial surface 252a is less than the length of the other radial surface 252.

The angle? Between the radial surface 252a and the inclined surface 258 is preferably about 59 degrees. The inclined surface 258 is preferably formed in parallel with the passage portion.

Meanwhile, the motor described in the above embodiments may be a motor for driving a drum of a washing machine. For example, the rotor may be a motor that rotates radially outward relative to the stator.

The stator, for example, the engaging portion 272 of the insulator shown in Fig. 8, can be fixed to the rear wall of the tub. A shaft connected to the center of the drum through the rear wall of the tub may be connected to the center of the rotor through the center of the stator. Thus, as the rotor rotates relative to the stator fixed to the tub, the drum can rotate.

In the case of the drum washing machine (front loader), there is a limitation in increasing the front-rear length of the motor (i.e., the height of the motor) due to the limit of the size of the cabinet. Similarly, in the case of the top loader, there is a limitation in raising the height of the motor due to the limitation of the upper and lower dimensions of the cabinet.

The motor for driving the drum of the washing machine is a three-phase motor. In recent years, the motor is being controlled very precisely by using an inverter.

Since the motor for driving the drum of the washing machine must perform various strokes such as washing, rinsing and dehydration, it is necessary to satisfy the reference torque performance and efficiency.

Particularly, as described above, the increase in the height of the motor is very limited because it causes an increase in the size of the cabinet. It is the end-turn length of the coil that determines the height of the motor.

The coil is wound on the tooth portion of the stator, and the end-turn length increases as the number of turns becomes larger or the diameter of the coil becomes thicker. The end-turn means a portion of the coil protruding from the top and bottom of the tooth portion, so the sum of the thickness of the stator core and the length of the top-bottom end-turn can be referred to as the height of the stator.

On the assumption that the number of turns of the stator, that is, the number of turns of the entire coil, is constant, the length of the end-turn can not be reduced as the number of slots of the stator core increases. If the number of slots is large, the number of turns per slot is reduced, and therefore, the length of the end-turn is inevitably reduced.

It is possible to determine the optimal number of slots through the relationship between the number of such slots and the requirements of the motor-driving three-phase motor of the washing machine.

Since the motor is a three-phase motor, the number of slots should be selected to be a multiple of three so that the coil of three phases can be wound. Basically, the number of slots and the number of teeth should be 6 or more.

Fig. 17 shows the relationship between the number of slots and the torque performance. If the number of slots is 6, the end-turn height becomes larger than the requirement, causing a problem of increasing the size of the motor. Also, the torque performance did not satisfy the requirements.

However, when the number of slots is 9, it is found that both the end-turn condition and the torque condition are satisfied. Of course, as the number of slots increases, the end-turn length tends to decrease.

Based on the torque conditions, the number of slots was found to be satisfactory at 9, 12, 15, 18 and 21. As the number of slots increased from 9 to 18, the torque performance gradually improved and then decreased rapidly at 21, but the torque condition was satisfied at 21. However, it can be seen that the torque performance is superior to the number of slots 21 in the number of slots 9.

18 shows the correlation between the number of slots and the efficiency. The efficiency decreased gradually as the number of slots increased. Although the efficiency condition is satisfied in the approximate slot number 21, it can be seen that the slot number is satisfied at 9, 12, 15 and 18 when the efficiency condition is strengthened to 80% or more. Therefore, it is preferable that the number of slots is 9, 12, 15, and 21 through the efficiency condition and the end-turn length condition.

19 shows the correlation between iron loss, terminal voltage and slot number. As the number of slots increases, terminal voltage and core loss tends to increase. In particular, it was found that the core loss and terminal voltage tend to rise sharply in the interval in which the number of slots increases from 18 to 21. Therefore, it was found that both the iron loss and the terminal voltage conditions were satisfied in the case of slots 9, 12, 15 and 18.

As a result, it was found that the number of slots of the stator in the three-phase motor for driving the drum of the washing machine was determined to be one of 9, 12, 15 and 18. That is, considering the end-turn condition, the torque condition, the efficiency condition, the iron loss condition, and the terminal voltage condition, the number of slots within this range is optimal, and the number of slots out of this range is significantly different from each condition.

As shown in Fig. 1, the number of slots of a stator in a three-phase motor for driving a washing machine drum is generally more than 24. Therefore, since there are many places where a coil should be formed, coil formation is not easy. And, the winding machine also has to be complicated due to an increase in the number of coil spots.

However, in the case of the three-phase motor for driving a drum of the washing machine according to the present embodiment, one of 9, 12, 15 and 18 having a slot number less than 24 can be selected and applied. Therefore, the manufacture of the stator becomes very easy. Further, since a rotor of the same type can be used, it is not necessary to specially manufacture the rotor again.

The reduction in the number of slots also simplifies the structure of the insulator described above.

Further, in the case of the three-phase motor for driving a drum of the washing machine according to the present embodiment, it is possible to provide a motor with higher efficiency by mounting a magnet to the stator as well as an electromagnetic force by a coil in a stator of the same size as the conventional one. Particularly, since the size of the tooth portion is larger than that of the conventional tooth portion due to the reduction in the number of slots, the magnet mounting portion can be integrally formed in a part of the tooth portion, and the magnet can be easily mounted.

In a conventional three-phase motor for a washing machine, since the number of slots is large, the size of the teeth at the distal end of the tooth portion and the tooth portion is relatively small. Therefore, there is no space for mounting the magnet by being recessed in the teeth, and when the magnet is mounted through the injection structure separately from the stator core, the size of the stator becomes large.

Assuming that the stator core shown in FIG. 1 and the stator core shown in FIG. 3 have the same size (the diameter of the stator core), the difference in size of the stator core according to the present embodiment can be intuitively recognized, It can be seen that the magnet can be mounted by recessing a part of the radial end portion of the stator core.

In the present embodiment, it can be seen that the radial width of the teeth is significantly larger than the tooth radial width in the conventional washing machine motor. Therefore, it can be seen that the magnet can be supported effectively by covering the magnet mounting portion through the insulator.

100: motor 110: rotor
111: rotor core 112: rotor magnet
200: stator 205: stator core
210: core 220:
230: Tees 240: Coils
250: magnet mounting portion 260: stator magnet

Claims (20)

A rotor having a plurality of magnets along a circumferential direction;
The rotor according to claim 1, wherein the core comprises a core, a tooth portion extending from the core to face the rotor, and at least two flux modulating poles (FMP) formed on the tooth portion and having an air gap with the rotor, A stator core; And
And a coil wound around a slot between the tooth portion and the tooth portion,
A stator magnet is provided between the teeth and the teeth,
Wherein a ratio (? /?) Of the circumferential length (stator pitch,?) Of the stator magnet to the circumferential length (FMP pitch,?) Of the teeth is 1.2 to 2.1. The method according to claim 1,
Wherein the stator core is formed with a magnet mounting portion integrally formed with the stator core so as to be embedded in the radial direction between the teeth and the teeth. 3. The method of claim 2,
Wherein the magnet mounting portion is integrally formed with the stator core by punching the stator core. The method of claim 3,
Wherein three teeth are formed and one of the stator magnets is provided per tooth portion. 5. The method of claim 4,
And? Of the three teeth are equal to each other, and? Of the two stator magnets are equal to each other. 6. The method of claim 5,
The motor includes:
The back electromotive force and efficiency tend to increase as the ratio [alpha] / [beta] increases at 1.0, and the torque ripple has a tendency to increase after decreasing. The method according to claim 6,
The motor includes:
The efficiency is 105% or more and the torque ripple is 95% or less in comparison with the efficiency 100% and the torque ripple 100% in the case where the ratio (? /?) Is 1.2 to 2.1 Features a motor. 5. The method of claim 4,
Wherein the stator core includes a passage portion extending in both circumferential directions in the tooth portion and connected to the teeth. 9. The method of claim 8,
And the width Wt of the tooth portion in the longitudinal direction is greater than the width Wm in the longitudinal direction of the passage portion. 10. The method of claim 9,
And a ratio (Wt / Wm) of the width (Wt) to the width (Wm) is 2.63 to 3.38. 11. The method of claim 10,
Wherein the efficiency of the motor is at least 85% within a range of the ratio Wt / Wm of 2.63 to 3.38. 9. The method of claim 8,
Wherein the passage portion extends in the circumferential direction beyond the magnet mounting portion and is connected to the teeth. 9. The method of claim 8,
Wherein the passage portion extends in an oblique shape with an angle greater than 90 degrees with the tooth portion and is connected to the teeth. 14. The method of claim 13,
Wherein a corner portion of the magnet mounting portion is formed to have an inclined surface in order to increase the width between the circumferential end of the magnet mounting portion and the passage portion. 15. The method of claim 14,
And the inclined surface is formed to be parallel to the passage portion. 15. The method of claim 14,
And a corner of the stator magnet mounted on the magnet mounting portion has a chamfer surface corresponding to the inclined surface. 17. The method of claim 16,
The magnet mounting portion
And a radial surface extending radially at opposite ends of the circumferential surface,
Wherein the inclined surface is formed only between the circumferential surface and any one of the radial surfaces. 18. The method of claim 17,
Wherein the inclined surface is formed only at an edge portion of the opposite end of the circumferential surface which is further away from the tooth portion in the circumferential direction. 19. The method of claim 18,
And an angle between the radial surface and the inclined surface is 59 degrees. A rotor having a plurality of magnets along a circumferential direction;
The rotor according to claim 1, wherein the core comprises a core, a tooth portion extending from the core to face the rotor, and at least two flux modulating poles (FMP) formed on the tooth portion and having an air gap with the rotor, A stator core; And
And a coil wound around a slot between the tooth portion and the tooth portion,
A stator magnet is provided between the teeth and the teeth,
Wherein the stator core includes a passage portion extending in both circumferential directions in the tooth portion and connected to the teeth,
The width Wt of the tooth portion in the longitudinal direction is larger than the width Wm in the longitudinal direction of the passage portion,
And a ratio (Wt / Wm) of the width (Wt) to the width (Wm) is 2.63 to 3.38.

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