阅读说明：本技术 定子和马达 (Stator and motor ) 是由 内势英明 右田贵之 北垣宏 伊藤辰也 大北晃弘 于 2018-06-25 设计创作，主要内容包括：定子具有定子铁芯、绝缘件以及多根线圈线。绝缘件具有位于铁芯背部的正上方并沿着周向延伸的外壁部。在外壁部设置有从上端向下侧延伸的第1缺口部。在外壁部的外侧面上设置有向径向外侧突出的第1凸部。第1缺口部的朝向上侧的底面位于比第1凸部的下表面靠上侧的位置。一对线圈线的搭接线在外壁部的径向外侧沿着外壁部的外侧面以上下排列的方式沿周向延伸。设上下排列的一对搭接线中的一方为上侧搭接线,设通过上侧搭接线的下侧的另一方为下侧搭接线。上侧搭接线穿过第1缺口部而被引出到外壁部的径向外侧。下侧搭接线通过第1凸部的正下方。(The stator has a stator core, an insulator, and a plurality of coil wires. The insulator has an outer wall portion located immediately above the core back portion and extending in the circumferential direction. The outer wall portion is provided with a 1 st notch portion extending downward from the upper end. A1 st convex part protruding outward in the radial direction is provided on the outer side surface of the outer wall part. The bottom surface of the 1 st notch facing upward is located above the lower surface of the 1 st projection. The crossover wires of the pair of coil wires extend in the circumferential direction along the outer surface of the outer wall portion in a vertically aligned manner on the radially outer side of the outer wall portion. One of a pair of vertically arranged overlapping wires is defined as an upper overlapping wire, and the other of the pair of vertically arranged overlapping wires passing through the lower side of the upper overlapping wire is defined as a lower overlapping wire. The upper crossover passes through the 1 st notch part and is drawn out to the radial outside of the outer wall part. The lower overlapping line passes through the position right below the 1 st convex part.)

1. A stator, having:

a stator core having an annular core back portion centered on a central axis extending in a vertical direction and a plurality of teeth extending radially inward from the core back portion;

an insulator mounted to the stator core; and

a plurality of coil wires wound around the teeth with the insulating material interposed therebetween,

the plurality of coil wires each have:

a plurality of coils wound around the teeth so as to be wound in concentrated form; and

a crossover wire connecting the plurality of coils to each other,

the insulating member has:

a base portion surrounding an outer peripheral surface of the tooth; and

an outer wall portion located immediately above the core back portion and extending in a circumferential direction,

the outer wall part is provided with a 1 st notch part extending from the upper end to the lower side,

a 1 st convex part protruding to the radial outside is arranged on the outer side surface of the outer wall part,

the bottom surface of the 1 st notch facing upward is located above the lower surface of the 1 st projection,

the crossover wires of the pair of coil wires extend in the circumferential direction along the outer surface of the outer wall portion in a vertically aligned manner on the radially outer side of the outer wall portion,

one of a pair of the overlapping wires arranged vertically is an upper overlapping wire, the other of the pair of the overlapping wires passing through the lower side of the upper overlapping wire is a lower overlapping wire,

the upper crossover is drawn out to the radial outside of the outer wall portion through the 1 st notch portion,

the lower overlapping line passes through the position right below the 1 st convex part.

2. The stator according to claim 1,

a 2 nd convex part protruding to the radial outside is arranged on the outer side surface of the outer wall part,

the lower surface of the 2 nd projection is located above the bottom surface of the 1 st notch,

the upper crossover line passes directly below the 2 nd protrusion.

3. The stator according to claim 1 or 2,

the outer wall part is provided with a 2 nd notch part extending from the upper end to the lower side,

the bottom surface of the 2 nd notch facing upward is located below the lower surface of the 1 st projection,

the lower crossover wire is drawn out to the radial outside of the outer wall portion through the 2 nd notched portion.

4. The stator according to claim 2,

the 2 nd convex portion has a width in the circumferential direction larger than that of the 1 st convex portion.

5. The stator according to any one of claims 1 to 4,

the 1 st projection is disposed adjacent to the 1 st notch in the circumferential direction.

6. A motor, comprising:

the stator of any one of claims 1 to 5; and

and a rotor that is opposed to the stator with a gap therebetween in a radial direction and rotates around the center axis.

Technical Field

The invention relates to a stator and a motor.

Background

Generally, a coil of a motor is configured by winding a coil wire around teeth of a stator core. When 1 coil wire is wound around a plurality of teeth, a crossover wire connecting the coils is wound on the upper side of the coil. In order to prevent the crossover of the coil wire wound first in the winding step from obstructing the path of the coil wire wound later, the crossover is wound radially outward of the coil. For example, patent document 1 discloses the following configuration: a protrusion is provided on the radially outer side of the coil so that the crossover wire is along the protrusion.

Disclosure of Invention

Problems to be solved by the invention

When a plurality of crossover wires are wound in the circumferential direction on the radially outer side of the coil, there is a possibility that the crossover wires may contact each other. Further, when the crossover wires are inserted into the slots to suppress interference between the crossover wires, there is a problem in that the assembly process becomes complicated and the manufacturing cost of the stator increases.

In view of the above circumstances, an object of the present invention is to provide a stator and a motor that can suppress contact between overlapping wires without complicating an assembly process.

Means for solving the problems

A stator according to one embodiment of the present invention includes: a stator core having an annular core back portion centered on a central axis extending in a vertical direction and a plurality of teeth extending radially inward from the core back portion; an insulator mounted to the stator core; and a plurality of coil wires wound around the teeth with the insulating material interposed therebetween. The plurality of coil wires each have: a plurality of coils wound around the teeth so as to be wound in concentrated form; and a crossover wire connecting the plurality of coils to each other. The insulating member has: a base portion surrounding an outer peripheral surface of the tooth; and an outer wall portion located directly above the core back portion and extending in a circumferential direction. The outer wall portion is provided with a 1 st notch portion extending downward from an upper end. A1 st convex portion protruding outward in the radial direction is provided on the outer side surface of the outer wall portion. The bottom surface of the 1 st cutout facing upward is located above the lower surface of the 1 st projection. The crossover wires of the pair of coil wires extend in the circumferential direction along the outer surface of the outer wall portion in a vertically aligned manner on the radially outer side of the outer wall portion. One of a pair of the overlapping wires arranged vertically is an upper overlapping wire, and the other of the pair of the overlapping wires passing through the lower side of the upper overlapping wire is a lower overlapping wire. The upper crossover is drawn out to the radial outside of the outer wall portion through the 1 st notch portion. The lower overlapping line passes through the position right below the 1 st convex part.

A motor according to one embodiment of the present invention includes: the above-described stator; and a rotor that is opposed to the stator with a gap therebetween in a radial direction and rotates around the center axis.

Effects of the invention

According to one embodiment of the present invention, it is possible to provide a stator and a motor in which contact between overlapping wires can be suppressed without complicating an assembly process.

Drawings

Fig. 1 is a sectional view of a motor according to an embodiment.

Fig. 2 is a cross-sectional view of an embodiment of a stator.

Fig. 3 is a perspective view of a stator according to an embodiment.

Fig. 4 is an enlarged view of a part of fig. 3.

Fig. 5 is a top view of an embodiment of a stator.

Fig. 6 is a diagram showing a winding process of the U-phase coil.

Fig. 7 is a diagram showing a winding process of the V-phase coil.

Fig. 8 is a diagram illustrating a winding process of the W-phase coil.

Fig. 9 is a perspective view showing a hook portion according to an embodiment.

Fig. 10 is a perspective view showing a hook portion in modification 1.

Fig. 11 is a perspective view showing a hook portion in modification 2.

Detailed Description

Hereinafter, a motor according to an embodiment of the present invention will be described with reference to the drawings. In the following drawings, in order to make the structures easier to understand, the actual structures may be different from the structures in scale, number, and the like.

An X-Y-Z coordinate system is shown in the figures as appropriate. In the present specification, the Z-axis direction is a vertical direction in which the positive side is an upper side and the negative side is a lower side. The central axis J appropriately shown in each drawing is an imaginary line parallel to the Z-axis direction and extending in the up-down direction. In the following description, the axial direction of the center axis J, i.e., the direction parallel to the vertical direction, is simply referred to as the "axial direction", the radial direction about the center axis J is simply referred to as the "radial direction", and the circumferential direction about the center axis J is simply referred to as the "circumferential direction". In each figure, the circumferential direction is indicated by an arrow θ as appropriate.

The positive side in the Z-axis direction in the axial direction is referred to as "upper side", and the negative side in the Z-axis direction in the axial direction is referred to as "lower side". The side that advances clockwise in the circumferential direction when viewed from the upper side toward the lower side, i.e., the side that advances in the direction of arrow θ, is referred to as the "circumferential side". One side of the circumferential direction that advances counterclockwise when viewed from the upper side toward the lower side, i.e., one side that advances in the direction opposite to the direction of arrow θ, is referred to as "the other circumferential side".

The terms "vertical direction", "upper side" and "lower side" are only names for describing the arrangement relationship of the respective parts, and the actual arrangement relationship may be an arrangement relationship other than the arrangement relationship indicated by the names.

< Motor >

Fig. 1 is a sectional view of a motor 1 of the present embodiment. The motor 1 of the present embodiment is a three-phase ac motor. The motor 1 of the present embodiment is an inner rotor type motor. The application of the motor 1 of the present embodiment is not particularly limited. The motor 1 is mounted on, for example, an electric pump and an electric power steering apparatus.

The motor 1 includes a rotor 2, a stator 3, a bearing holder 4, a housing 5, and a pair of bearings 6. The rotor 2 rotates relative to the stator 3 about a central axis J extending in the vertical direction.

The housing 5 has a cylindrical shape with a bottom. The housing 5 internally houses the rotor 2, the stator 3, the bearing holder 4, and the pair of bearings 6. The bearing holder 4 is located on the upper side of the stator 3. The bearing holder 4 is supported by the inner peripheral surface of the housing 5. The pair of bearings 6 are arranged at intervals in the axial direction. The pair of bearings 6 supports the shaft 2a of the rotor 2. One of the pair of bearings 6 is supported by the bearing holder 4, and the other is supported by the housing 5.

< rotor >

The rotor 2 rotates about the central axis J. The rotor 2 and the stator 3 are opposed to each other with a gap in the radial direction. The rotor 2 has a shaft 2a, a rotor core 2b, and at least one magnet 2c, and the shaft 2a has a central axis J.

The shaft 2a extends along the central axis J. In the example of the present embodiment, the shaft 2a has a cylindrical shape extending in the axial direction. The shaft 2a is supported by a plurality of bearings 6 to be rotatable about the central axis J. The shaft 2a is not limited to the above-described cylindrical shape, and may be, for example, a cylindrical shape.

The rotor core 2b is formed by laminating a plurality of electromagnetic steel plates in the axial direction. The rotor core 2b is provided with a center hole 2h penetrating in the axial direction. The central hole 2h is located at the center of the rotor core 2b as viewed in the axial direction. The shaft 2a passes through the central hole 2 h. The shaft 2a is directly or indirectly fixed to the rotor core 2 b.

The magnet 2c is fixed to the outer peripheral surface of the rotor core 2 b. The magnet 2c is radially opposed to the teeth 12 of the stator 3. The magnet 2c of the present embodiment is a ring-shaped magnet. N poles and S poles are alternately arranged in the circumferential direction in the magnet 2 c. The rotor 2 may have a plurality of magnets arranged in the circumferential direction. In this case, the magnets having N poles on the outer side in the radial direction and the magnets having S poles on the outer side in the radial direction are alternately arranged in the circumferential direction.

The rotor 2 of the present embodiment is a rotor of an SPM (surface permanent Magnet) type in which magnets 2c are disposed on the outer peripheral surface of a rotor core 2 b. However, the rotor 2 may be an IPM (Interior Permanent Magnet) type rotor in which magnets are embedded in the rotor core. The rotor core 2b and the magnet 2c may be housed inside a cylindrical rotor cover.

< stator >

The stator 3 is substantially annular about the center axis J. The stator 3 includes a stator core 10, an insulator 20, and a plurality of coil wires 40. The coil wire 40 constitutes a coil 50.

< stator core >

The stator core 10 surrounds the rotor 2 at a radially outer side of the rotor 2. The stator core 10 is formed by laminating a plurality of electromagnetic steel plates in the axial direction, for example. Therefore, the stator core 10 extends in the axial direction with the same cross section. The stator core 10 of the present embodiment is an integrated stator core that is not divided in the circumferential direction.

Fig. 2 is a sectional view of the stator 3. As shown in fig. 2, the stator core 10 has a core back 11, a plurality of teeth 12, and a plurality of umbrella portions 13.

The core back 11 has a substantially annular shape centered on the central axis J. The outer peripheral surface of the core back 11 is fixed to the inner peripheral surface of the case 5.

The teeth 12 extend radially inward from the core back 11. In the present embodiment, 6 teeth 12 are provided in the stator core 10. The teeth 12 extend radially with substantially the same cross-section. The plurality of teeth 12 are arranged at equal intervals in the circumferential direction. A coil wire 40 is wound around the teeth 12 with the insulator 20 interposed therebetween. Therefore, the coil wire 40 passes between each other through a pair of teeth 12 adjacent in the circumferential direction.

The umbrella portion 13 is located at the radially inner front end of the tooth 12. The umbrella portion 13 is wider than the teeth 12 in the circumferential direction. That is, the dimension of the umbrella portion 13 in the circumferential direction is larger than the dimension of the teeth 12 in the circumferential direction. The radially inward surface of the umbrella-shaped portion 13 is formed in an arc shape centered on the central axis J when viewed in the axial direction. The surface of the umbrella-shaped portion 13 facing the inside in the radial direction is radially opposed to the magnet 2c of the rotor 2.

< insulating Member >

As shown in fig. 1, the insulator 20 is mounted to the stator core 10. The insulating member 20 is made of an insulating material (e.g., an insulating resin). The insulator 20 is sandwiched between the stator core 10 and the coil wire 40, and ensures insulation of the stator core 10 from the coil wire 40.

The insulator 20 has an upper part 20A and a lower part 20B. The upper member 20A and the lower member 20B are each one member. The upper member 20A and the lower member 20B each have a substantially annular shape centered on the central axis J. The upper member 20A is mounted from the upper side with respect to the stator core 10. The lower member 20B is mounted from the lower side with respect to the stator core 10. The upper member 20A surrounds the upper end surface of the core back 11 and the upper regions of both circumferential end surfaces of the teeth 12. The lower member 20B surrounds the lower end surface of the core back 11 and the lower regions of the circumferential end surfaces of the teeth 12. The insulator 20 surrounds the outer peripheral surface of the teeth 12 by being attached from above and below with respect to the stator core 10 by the upper member 20A and the lower member 20B.

The upper member 20A and the lower member 20B may be the same shape as each other or different shapes from each other. The upper member 20A and the lower member 20B may be formed of one member. That is, the insulator may be a cylindrical member.

The insulator 20 has a base portion 21, an inner wall portion 23, and an outer wall portion 24.

The base 21 surrounds the outer peripheral surface of the tooth 12. The same number of bases 21 as the teeth 12 are provided. In the present embodiment, 6 base portions 21 are provided in the insulator 20. In the present embodiment, the base 21 surrounds the entire outer peripheral surface of the tooth 12. However, the base portion 21 may expose a part of the outer peripheral surface of the tooth 12 as long as insulation between the tooth 12 and the coil wire 40 can be secured.

The inner wall portion 23 is provided in plurality in the insulator 20. Each inner wall portion 23 overlaps the umbrella portion 13 as viewed in the axial direction. The inner wall portion 23 extends in the circumferential direction. Inner wall portions 23 are provided in the upper member 20A and the lower member 20B, respectively. The upper member 20A and the lower member 20B are provided with inner wall portions 23 in the same number as the teeth 12, respectively. The inner wall 23 of the upper member 20A is located directly above the umbrella-shaped portion 13 and contacts the upper end surface of the umbrella-shaped portion 13. The inner wall 23 of the lower member 20B is located directly below the umbrella-shaped portion 13 and contacts the lower end surface of the umbrella-shaped portion 13. The inner wall portion 23 restricts the coil wire 40 wound around the teeth 12 from moving radially inward.

The outer wall portion 24 has an annular shape centered on the central axis J. Outer wall portions 24 are provided in the upper member 20A and the lower member 20B, respectively. The outer wall portion 24 of the upper member 20A is positioned directly above the core back 11 and contacts the upper end surface of the core back 11. The outer wall portion 24 of the lower member 20B is located directly below the core back 11 and contacts the lower end surface of the core back 11. That is, the pair of outer wall portions 24 overlap the core back portion 11 as viewed in the axial direction.

The outer wall portion 24 extends in the circumferential direction. The outer wall portion 24 and the inner wall portion 23 radially face each other. The outer wall 24 restricts the coil wire 40 wound around the teeth 12 from moving radially outward.

Fig. 3 is a perspective view of the stator 3. Fig. 3 is a diagram showing a state of the stator 3 immediately after the winding step. After the winding step, a step of raising the lead wire 41 in the axial direction is performed.

As shown in fig. 3, the outer wall portion 24 of the upper member 20A is provided with a plurality of lead-wire cutout portions (cutout portions) 24a, a plurality of crossover cutout portions (cutout portions) 24b, a plurality of 1 st convex portions (convex portions) 24c, and a plurality of 2 nd convex portions (convex portions) 24 d.

The lead wire cutout 24a is open to the upper side and extends downward from the upper end surface of the outer wall portion 24. The lead wire cutout 24a penetrates in the radial direction. The outer wall portion 24 of the present embodiment is provided with 5 lead-wire cutouts 24 a. The 5 lead-wire cutouts 24a are located radially outward of the coil 50.

In the winding step of the coil wire 40, the lead wire 41 extending from the coil 50 passes through the lead wire cutout 24 a. The lead wire 41 is drawn out radially outward from the coil 50 by passing through the lead wire cutout 24 a. Thus, the lead wires 41 do not protrude upward from the coil 50, and do not obstruct the path of the coil wire 40 in the winding step. After the winding process is completed, the leader line 41 that has passed through the leader line notch 24a is raised upward.

In the present embodiment, the lead-wire cutout 24a is not provided radially outward of the last wound coil 50 of the 6 coils 50. Since the lead wire 41 extending from the coil 50 wound last is drawn at the end of the winding process, the path of the other coil wire 40 is not obstructed. Therefore, the lead wire 41 of the coil 50 wound last does not need to pass through the lead wire cutout portion 24a, and therefore the lead wire cutout portion 24a is not provided.

The lap-line notch 24b is open to the upper side and extends downward from the upper end surface of the outer wall 24. The lap-line notch 24b penetrates in the radial direction. The crossover wire 42 of the coil wire 40 passes through the crossover notch 24 b. That is, the crossover wire 42 is routed from the radially inner side to the radially outer side of the outer wall portion 24 via the crossover notch portion 24 b.

The 1 st projection 24c and the 2 nd projection 24d are provided on the radially outward facing outer surface 24p of the outer wall portion 24. The 1 st projection 24c and the 2 nd projection 24d project radially outward from the outer surface 24p of the outer wall portion 24. The 1 st and 2 nd convex portions 24c and 24d are located on the upper side of the coil wire 40 wound along the outer side surface 24p on the radially outer side of the outer wall portion 24. The 1 st and 2 nd convex portions 24c and 24d restrict the coil wire 40 from moving upward, and suppress the coil wire 40 from moving upward on the outer wall portion 24.

As shown in fig. 3, a plurality of crossover wires 42 of the coil wire 40 are wound around the outer surface 24p of the outer wall portion 24. The plurality of crossover wires 42 extend along the outer side surface 24p radially outward of the outer wall portion 24. A pair of the plurality of crossover wires 42 extends along the outer surface 24p of the outer wall portion outside the outer wall portion in the radial direction so as to be aligned in the vertical direction. The pair of crossover wires 42 are drawn out radially outward of the outer wall portion 24 through the crossover notch portions 24b, respectively.

Here, one of the pair of overlapping wires 42 extending in the vertical direction on the upper side is an upper overlapping wire 42A, and the other one on the lower side is a lower overlapping wire 42B. That is, the lower crossover 42B is located below the upper crossover 42A. The crossover notch 24B through which the upper crossover wire 42A passes is defined as an upper notch (1 st notch) 24bA, and the crossover notch 24B through which the lower crossover wire 42B passes is defined as a lower notch (2 nd notch) 24 bB. In the following description, the 1 st notch portion is referred to as an upper notch portion, and the 2 nd notch portion is referred to as a lower notch portion.

Fig. 4 is a partially enlarged view of the stator 3. As shown in fig. 4, each of the upper cutout portion 24bA and the lower cutout portion 24bB has a bottom surface 24bA facing upward. Bottom surface 24bA of lower cutout 24bB is located lower than bottom surface 24bA of upper cutout 24 bA.

The 1 st projection 24c has a lower surface 24ca facing downward. Similarly, the 2 nd projection 24d has a lower surface 24da facing downward. Lower surface 24da of 2 nd convex portion 24d is located above lower surface 24ca of 1 st convex portion 24 c.

Bottom surfaces 24bA of upper cutout portion 24bA and lower cutout portion 24bB and lower surfaces 24ca and 24da of 1 st projection portion 24c and 2 nd projection portion 24d are arranged at positions different from each other in the vertical direction. These vertical positions are, in order from the upper side toward the lower side, lower surface 24da of 2 nd convex portion 24d, bottom surface 24bA of upper cutout portion 24bA, lower surface 24ca of 1 st convex portion 24c, and bottom surface 24bA of lower cutout portion 24 bB.

Lower surface 24da of 2 nd projecting portion 24d is located above bottom surface 24bA of upper cutout portion 24 bA. The distance in the vertical direction between lower surface 24da of 2 nd projection 24d and bottom surface 24bA of upper cutout 24bA is slightly larger than the wire diameter of coil wire 40.

The upper crossover wire 42A is drawn out to the radial outside of the outer wall portion 24 through the upper cutout portion 24 bA. The upper crossover wire 42A is wound in the circumferential direction along the outer surface 24p of the outer wall 24. The upper crossover wire 42A passes directly below the 2 nd projection 24 d. That is, the upper crossover line 42A and the 2 nd convex portion 24d overlap each other when viewed in the vertical direction. The upper crossover wire 42A may be in contact with the lower surface 24da of the 2 nd projection 24 d. The upper crossover wire 42A extends in the circumferential direction between the lower surface 24da of the 2 nd convex portion 24d and the bottom surface 24bA of the upper cutout portion 24 bA. According to the present embodiment, the upper crossover 42A is disposed so as to be sandwiched between the 2 nd convex portion 24d and the bottom surface 24bA of the upper cutout portion 24bA, whereby the winding of the upper crossover 42A can be stabilized.

Bottom surface 24ba of lower cutout 24bB is located below lower surface 24ca of 1 st projection 24 c. The distance in the vertical direction between bottom surface 24ba of lower cutout 24bB and lower surface 24ca of 1 st projection 24c is slightly larger than the wire diameter of coil wire 40.

The lower crossover wire 42B is drawn out to the radial outside of the outer wall portion 24 through the lower cutout portion 24 bB. The lower crossover wire 42B is wound in the circumferential direction along the outer surface 24p of the outer wall portion 24. The lower overlapping wire 42B passes directly below the 1 st projection 24 c. That is, the lower overlapping wire 42B and the 1 st convex portion 24c overlap each other when viewed in the vertical direction. The lower crossover wire 42B may be in contact with the lower surface 24ca of the 1 st projection 24 c. The lower crossover wire 42B extends in the circumferential direction between the lower surface 24ca of the 1 st convex portion 24c and the bottom surface 24ba of the lower cutout portion 24bB in the up-down direction. According to the present embodiment, the lower crossover 42B is disposed so as to be sandwiched between the 1 st convex portion 24c and the bottom surface 24ba of the lower cutout portion 24bB, whereby the lower crossover 42B can be stably routed.

In the present embodiment, the width in the circumferential direction of the 2 nd convex portion 24d is larger than the width in the circumferential direction of the 1 st convex portion 24 c. In the winding step, the upper crossover wire 42A is hooked on the 2 nd projection 24 d. The upper crossover wire 42A passes near the upper end of the outer wall portion 24. According to the present embodiment, the upper crossover 42A is gripped by a sufficient length in the circumferential direction by providing the 2 nd projection 24d to be long in the circumferential direction, and the upper crossover 42A can be effectively prevented from coming off from the outer wall portion 24 to the inside. On the other hand, in the winding step, the lower overlapping wire 42B is hooked on the 1 st projection 24 c. By reducing the length of the 1 st projection 24c in the circumferential direction, the lower overlapping wire 42B can be easily hooked on the 1 st projection 24 c.

In the present embodiment, the upper crossover 42A passes through the upper cutout 24bA, and therefore is not easily moved to a position below the bottom surface 24bA of the upper cutout 24 bA. Further, since the lower crossover wire 42B passes directly below the 1 st convex portion 24c, it is not easily moved to a position above the lower surface 24ca of the 1 st convex portion 24 c. In the present embodiment, bottom surface 24bA of upper cutout portion 24bA is located above lower surface 24ca of 1 st convex portion 24 c. Therefore, according to the present embodiment, the upper crossover 42A and the lower crossover 42B can be suppressed from contacting each other.

In the present embodiment, the 1 st projection 24c is disposed adjacent to the upper cutout 24bA in the circumferential direction. That is, the 1 st projection 24c is disposed in the vicinity of the upper cutout 24 bA. Therefore, the 1 st projection 24c suppresses the upper movement of the lower crossover 42B, and the upper cutout 24bA suppresses the lower movement of the upper crossover 42A. According to the present embodiment, the 1 st projection 24c and the upper cutout 24bA are disposed adjacent to each other in the circumferential direction, and the upper crossover 42A and the lower crossover 42B can be effectively prevented from being loosened and coming into contact with each other.

< coil wire >

Next, the coil wire 40 will be described in more detail. Fig. 5 is a plan view schematically showing the stator 3.

The coil wire 40 is wound around the teeth 12 via the insulator 20 to form a coil 50. The coil 50 is wound around the teeth 12 so as to be wound in concentrated form. The stator 3 of the present embodiment is provided with 3 coil wires 40.

In the following description, when 3 coil lines 40 are to be distinguished from each other, they are referred to as a U-phase coil line (1 st coil line) 40U, V phase coil line (2 nd coil line) 40V and a W-phase coil line (3 rd coil line) 40W, respectively.

The 3 coil wires 40 each have: a plurality of (2 in the present embodiment) coils 50; a crossover wire 42 connecting the plurality of coils 50 to each other; and a pair of lead wires 41 which are located at the ends of the coil wire 40 and extend from the coil 50. One of the pair of lead wires 41 is located at the end of the coil wire 40 at which the winding is started, and the other is located at the end of the coil wire 40 at which the winding is completed. In the following description, when the pair of lead wires 41 are to be separated from each other, one of the lead wires at the end of the start of winding is referred to as a start lead wire 41A, and the other lead wire at the end of winding is referred to as an end lead wire 41B. In the present embodiment, the starting lead wire 41A and the ending lead wire 41B extend from the radially outer end portions of the coil 50.

The 6 coils 50 provided in the stator 3 are classified into 2U-phase coils 50U, 2V-phase coils 50V, and 2W-phase coils 50W.

In fig. 5, a tooth 12 located in the + Y direction (direction of 12 points) with respect to the central axis J is assumed to be the 1 st tooth 12A. Further, the teeth 12 are 2 nd to 6 th teeth 12B to 12F from the 1 st tooth 12A toward one side in the circumferential direction.

The 2U-phase coils 50U are formed by winding U-phase coil wires 40U around teeth 12 different from each other. The 2U-phase coils 50U are configured by winding U-phase coil wires 40U around the 1 st tooth 12A and the 4 th tooth 12D, respectively. The 2U-phase coils 50U are connected to each other at the crossover 42. Further, lead wires 41 are drawn from the 2U-phase coils 50U, respectively.

The 2V-phase coils 50V are formed by winding the V-phase coil wires 40V around different teeth 12. The 2V-phase coils 50V are formed by winding V-phase coil wires 40V around the 2 nd tooth 12B and the 5 th tooth 12E, respectively. The 2V-phase coils 50V are connected to each other at a crossover 42. Further, lead wires 41 are drawn from the 2V-phase coils 50V, respectively.

The 2W-phase coils 50W are formed by winding W-phase coil wires 40W around teeth 12 different from each other. The 2W-phase coils 50W are formed by winding W-phase coil wires 40W around the 3 rd tooth 12C and the 6 th tooth 12F, respectively. The 2W-phase coils 50W are connected to each other at a crossover 42. Further, lead wires 41 are drawn from the 2W-phase coils 50W, respectively.

Fig. 6 to 8 are views showing winding processes of the U-phase coil wire 40U, V phase coil wire 40V and the W-phase coil wire 40W, respectively. Fig. 6 to 8 are schematic views of the 1 st to 6 th teeth 12A to 12F, respectively, as viewed from the central axis J side (i.e., from the radially inner side).

The 3 coil wires 40 are wound around the teeth 12 in the order of the U-phase coil wire 40U, V and the phase coil wire 40V, W and the phase coil wire 40W. All the coil wires 40 are wound counterclockwise when viewed from the center axis J side with respect to the teeth 12.

As shown in fig. 5, the crossover wires 42 of all the coil wires 40 (U-phase coil wire 40U, V-phase coil wire 40V and W-phase coil wire 40W) have lead-out portions 42c, lead-in portions 42d, and outer passage portions 42 a. The crossover wire 42 of the V-phase coil wire 40V and the W-phase coil wire 40W has an inner passage portion 42b linearly extending radially inward of the outer wall portion 24. That is, the crossover wire 42 of the U-phase coil wire 40U does not have the inner passage portion 42 b.

The lead portion 42c is led out from the coil 50 wound around the tooth 12. The lead portion 42c is drawn radially outward from the coil 50, passes through the jumper notch 24b, and is drawn radially outward of the outer wall portion 24. The lead portion 42c is connected to the other end portion of the outer passage portion 42a in the circumferential direction.

The outer passage portion 42a extends in the circumferential direction. The outer passage portion 42a extends along the outer side surface 24p of the outer wall portion 24 radially outward of the outer wall portion 24. Further, the U-phase coil wire 40U has 1 outer passage portion 42 a. On the other hand, the V-phase coil wire 40V and the W-phase coil wire 40W have 2 outer passage portions 42 a. In the V-phase coil wire 40V and the W-phase coil wire 40W, the inner passage portions 42b are provided between the 2 outer passage portions 42 a.

Both ends of the inner passage portion 42b are connected to the outer passage portion 42a, respectively. The inner passage portion 42b is inserted through the corresponding jumper notch portion 24b at both ends. Thereby, the inner passage portion 42b passes radially inward of the outer wall portion 24. The inner passage portion 42b extends linearly between the pair of overlapping-wire cutout portions 24 b.

The lead-in portion 42d is connected to the circumferential one-side end portion of the outer passage portion 42 a. The lead-in portion 42d is led from the radially outer side to the radially inner side of the outer wall portion 24 through the crossover notch portion 24b, so as to be connected to the coil 50.

(U phase coil wire)

As shown in fig. 6, the U-phase coil wire 40U is first wound around the 1 st tooth 12A and then wound around the 4 th tooth 12D. Thus, the U-phase coil wire 40U constitutes a pair of U-phase coils 50U. A starting lead wire 41A extends from the U-phase coil 50U wound around the 1 st tooth 12A. Further, a terminal lead wire 41B extends from the U-phase coil 50U wound around the 4 th tooth 12D. As shown in fig. 5, the starting lead wire 41A and the ending lead wire 41B of the U-phase coil wire 40U are drawn out to the radial outside through the lead wire cutout portions 24 a.

As shown in fig. 5, a pair of U-phase coils 50U are connected to each other via a crossover wire 42. A lead portion 42c of the crossover wire 42 extends from the U-phase coil 50U wound around the 1 st tooth 12A. The lead-out portion 42c is led out to the radial outside of the outer wall portion 24 through the jumper notch portion 24b located on the radial outside of the 1 st tooth 12A, and is connected to the outer passage portion 42A.

The crossover wire 42 of the U-phase coil wire 40U extends in the outer passage portion 42a to one circumferential side along the outer side surface 24p of the outer wall portion 24 located radially outward of the 2 nd tooth 12B and the 3 rd tooth 12C. The crossover 42 of the U-phase coil wire 40U is drawn into the radial inside of the outer wall portion 24 at the drawn-in portion 42D through the crossover notch portion 24b located on the radial outside of the 4 th tooth 12D. The crossover wire 42 of the U-phase coil wire 40U is wound around the 4 th tooth 12D at the end of the lead-in portion 42D, and is connected to the U-phase coil 50U.

(V phase coil wire)

As shown in fig. 7, the V-phase coil wire 40V is first wound around the 5 th tooth 12E, and then wound around the 2 nd tooth 12B. Thus, the V-phase coil wire 40V constitutes a pair of V-phase coils 50V. A starting lead wire 41A extends from the V-phase coil 50V wound around the 5 th tooth 12E. Further, a terminal lead wire 41B extends from the V-phase coil 50V wound around the 2 nd tooth 12B. As shown in fig. 5, the starting lead wire 41A and the ending lead wire 41B of the V-phase coil wire 40V are drawn out to the radial outside through the lead wire cutout portions 24 a.

As shown in fig. 5, a pair of V-phase coils 50V are connected to each other via a crossover wire 42. The lead portion 42c of the crossover wire 42 extends from the V-phase coil 50V wound around the 5 th tooth 12E. The lead-out portion 42c is led out to the radially outer side of the outer wall portion 24 through the crossover notch portion 24b located radially outward of the 5 th tooth 12E, and is connected to the outer passage portion 42 a.

The crossover wire 42 of the V-phase coil wire 40V extends in the circumferential direction to one side along the outer side surface 24p of the outer wall portion 24 located radially outward of the 6 th tooth 12F at the outer passage portion 42a, and is connected to the inner passage portion 42 b. The inner passage portion 42b is introduced radially inward of the outer wall portion 24 through the gap portion 24b for a crossover located between the 6 th tooth 12F and the 1 st tooth 12A in the circumferential direction.

The inner passage portion 42b drawn radially inward of the outer wall portion 24 linearly passes directly above the 1 st tooth 12A. The inner passing portion 42b of the V-phase coil wire 40V passes directly above the U-phase coil 50U wound around the 1 st tooth 12A. That is, when viewed in the axial direction, a part of the inner passage portion 42b of the V-phase coil wire 40V overlaps the wound coil 50 (U-phase coil 50U in the present embodiment). The inner passage portion 42b is located radially inward of the start lead wire 41A extending from the U-phase coil 50U wound around the 1 st tooth 12A.

The inner passage portion 42B that has passed directly above the 1 st tooth 12A is drawn radially outward of the outer wall portion 24 through the overlapping-wire cutout portion 24B located circumferentially between the 1 st tooth 12A and the 2 nd tooth 12B. The inner passage portion 42b drawn out to the radially outer side of the outer wall portion 24 is connected to the outer passage portion 42 a. The outer passage portion 42a extends to one side in the circumferential direction along the outer side surface 24p of the outer wall portion 24 so as to be connected to the introduction portion 42 d. The lead-in portion 42d of the V-phase coil wire 40V is led into the radial inside of the outer wall portion 24 through the crossover notch portion 24B located radially outside of the 2 nd tooth 12B. The crossover wire 42 of the V-phase coil wire 40V is wound around the 2 nd tooth 12B at the end of the lead-in portion 42d, and is connected to the V-phase coil 50V.

(W phase coil wire)

As shown in fig. 8, the W-phase coil wire 40W is first wound around the 3 rd tooth 12C and then wound around the 6 th tooth 12F. Thus, the W-phase coil wire 40W constitutes a pair of W-phase coils 50W. A starting lead wire 41A extends from the W-phase coil 50W wound around the 3 rd tooth 12C. Further, a terminal lead wire 41B extends from the W-phase coil 50W wound around the 6 th tooth 12F. As shown in fig. 5, the starting lead wire 41A of the W-phase coil wire 40W is drawn out to the radial outside through the lead wire cutout portion 24 a. The end lead wire 41B of the W-phase coil wire W extends upward.

As shown in fig. 5, a pair of W-phase coils 50W are connected to each other via a crossover wire 42. The lead portion 42C of the crossover wire 42 extends from the W-phase coil 50W wound around the 3 rd tooth 12C. The lead-out portion 42C is drawn out to the radial outside of the outer wall portion 24 through the crossover notch portion 24b located on the radial outside of the 3 rd tooth 12C, and is connected to the outer passage portion 42 a.

The crossover wire 42 of the W-phase coil wire 40W extends along the outer surface 24p of the outer wall 24 toward one circumferential side at the outer passage 42a, and is connected to the inner passage 42 b. The inner passage portion 42b is introduced radially inward of the outer wall portion 24 through the gap portion 24b for a crossover located between the 3 rd tooth 12C and the 4 th tooth 12D in the circumferential direction.

The inner passage portion 42b drawn radially inward of the outer wall portion 24 linearly passes directly above the 4 th tooth 12D and the 5 th tooth 12E. Inner passage portion 42b of W-phase coil wire 40W passes directly above U-phase coil 50U wound around 4 th tooth 12D and V-phase coil 50V wound around 5 th tooth 12E. That is, when viewed in the axial direction, a part of the inner passage portion 42b of the W-phase coil wire 40W overlaps the already-wound coil 50 (in the present embodiment, the U-phase coil 50U and the V-phase coil 50V). The inner passage portion 42B is located radially inward of the terminal lead wire 41B extending from the U-phase coil 50U wound around the 4 th tooth 12D. The inner passage portion 42b is located radially inward of the starting lead wire 41A extending from the V-phase coil 50V wound around the 5 th tooth 12E.

The inner passage portion 42b that has passed directly above the 4 th tooth 12D and the 5 th tooth 12E is drawn radially outward of the outer wall portion 24 through the overlapping-wire cutout portion 24b located circumferentially between the 5 th tooth 12E and the 6 th tooth 12F. The inner passage portion 42b drawn out to the radially outer side of the outer wall portion 24 is connected to the outer passage portion 42 a. The outer passage portion 42a extends to one side in the circumferential direction along the outer side surface 24p of the outer wall portion 24 so as to be connected to the introduction portion 42 d. The lead-in portion 42d of the W-phase coil wire 40W is led into the radial inner side of the outer wall portion 24 through the crossover notch portion 24b located on the radial outer side of the 6 th tooth 12F. The crossover wire 42 of the W-phase coil wire 40W is wound around the 6 th tooth 12F at the end of the lead-in portion 42d, and is connected to the W-phase coil 50W.

< production method >

Next, a method of manufacturing the stator 3 will be explained. The method for manufacturing the stator 3 mainly includes a step of attaching the insulator 20 to the stator core 10 and a winding step. The winding step is a step of winding the plurality of coil wires 40 around the plurality of teeth 12 via the crossover wires 42 to form the coil 50.

The winding step is performed in the order of the U-phase coil wire 40U, V phase coil wire 40V, W phase coil wire 40W. In the winding step, the starting lead wire 41A and the ending lead wire 41B are drawn radially outward through the overlapping-wire cutout 24B of the outer wall portion 24.

After the winding process of the 3 coil wires 40 is completed, a process of raising the lead wires 41 (the starting point lead wire 41A and the end point lead wire 41B) of the coil wires 40 of the respective phases upward is performed. Through this step, the lead wire 41 is extended in the axial direction. The lead wire 41 extending upward from the coil 50 is connected to the power supply device via a conductive member such as a bus bar.

The outer passage portion 42a is formed by extending the crossover wire 42 of the coil wire 40 in the circumferential direction along the outer surface 24p of the outer wall portion 24 so as not to interfere with the path of the winding machine when winding another coil 50 to be sequentially wound.

Here, attention is paid to the winding process of the U-phase coil wire 40U and the W-phase coil wire 40W. In the manufacturing method of the present embodiment, after the U-phase coil wire 40U is wound, the V-phase coil wire 40V is wound. That is, the U-phase coil wire 40U is a coil wire wound first (1 st coil wire), and the W-phase coil wire 40W is a coil wire wound later (2 nd coil wire).

In the winding step of the U-phase coil wire 40U, the winding machine (or winding worker) causes the crossover wire 42 of the U-phase coil wire 40U to extend along the outer surface 24p of the outer wall 24 on the radially outer side of the outer wall 24. Thus, the outer passage portion 42a is provided in the crossover 42 of the U-phase coil wire 40U.

In the winding step of the V-phase coil wire 40V, the winder linearly extends the crossover wire 42 of the V-phase coil wire 40V along the outer surface 24p of the outer wall 24 on the radially outer side of the outer wall 24, and linearly extends the crossover wire 42 of the V-phase coil wire 40V on the radially inner side of the outer wall 24 in a region overlapping the lead-out wire 41 of the U-phase coil wire 40U in the radial direction. Thus, the crossover wire 42 of the V-phase coil wire 40V is provided with the outer passage portion 42a and the inner passage portion 42 b. The inner passage portion 42b of the V-phase coil wire 40V passes radially inward of the lead wire 41 of another coil wire 40 (U-phase coil wire 40U in the present embodiment).

In the conventional structure, the crossover of the coil wire does not include the inner passage portion 42b of the present embodiment. The crossover wire of the conventional structure passes through the outside of the outer wall portion over substantially the entire length thereof and directly above the lead wire of the coil wire that has been wound first. Therefore, when the lead wire is raised after the winding process, the lead wire comes into contact with the crossover of another coil wire. Therefore, there is a possibility that insulation between the coil wires of the other phases may become insufficient. Further, the following problems arise: the raised lead wires are expanded radially outward, thereby enlarging the radial dimension of the stator.

According to the present embodiment, the crossover wire 42 of the V-phase coil wire 40V that is wound later passes radially inward of the outer wall portion 24 in the region that overlaps the lead wire 41 of the U-phase coil wire 40U that is wound earlier in the radial direction. Therefore, even if the lead wire 41 of the U-phase coil wire 40U is raised after the winding step, the lead wire 41 of the U-phase coil wire 40U does not interfere with the crossover wire 42 of the V-phase coil wire 40V. This ensures insulation between the U-phase coil wire 40U and the V-phase coil wire 40V. Further, the rising lead wires 41 can be prevented from spreading radially outward, and the radial dimension of the stator 3 can be prevented from expanding.

Here, the relationship between the coil wire 40 wound first and the coil wire 40 wound later is described with attention being paid to the U-phase coil wire 40U and the V-phase coil wire 40V. However, the same applies to the relationship with the coil wires wound first (U-phase coil wire 40U and V-phase coil wire 40V) when the W-phase coil wire 40W is focused as the coil wire 40 to be wound later.

In the winding step, the coil wire 40 is wound around the teeth 12 and then drawn out to the outside in the radial direction of the outer wall portion 24. That is, in the winding step, the coil wire 40 is not directly drawn out as the inner passage portion 42b after being wound around the teeth 12. In the winding step, the coil wire 40 is once drawn out to the outside in the radial direction of the outer wall portion 24 after constituting the inner passage portion 42b, and is wound around the teeth 12. That is, in the winding step, the coil wire 40 is not wound directly around the teeth 12 from the inner passage portion 42 b. Therefore, according to the present embodiment, the inner passage portion 42b is connected to the outer passage portion 42a at both ends.

Therefore, when the coil wire 40 is wound around the teeth 12, the inner passage portion 42b does not obstruct the path of the winding machine. The inner passage portion 42b is wound around the outer wall portion 24 at both ends thereof. Therefore, the inner passage portion 42b can be extended in the direction perpendicular to the vertical direction. As a result, the inner passage portion 42b can be prevented from contacting the coil 50 located directly below the inner passage portion 42b, and the performance of the stator 3 can be stabilized.

According to the present embodiment, the crossover wires 42 of the V-phase coil wire 40V and the W-phase coil wire 40W each have an inner passage 42 b. Since the inner passage portion 42b extends linearly, the crossover wire 42 can be shortened as compared with a case where it passes through the outer side of the outer wall portion 24 in the radial direction. As a result, the weight of the stator 3 and the cost of the coil wire 40 can be reduced.

(hook part)

Fig. 9 is a perspective view of a part of the crossover 42 of the V-phase coil wire 40V. Note that, although the structure of the crossover wire 42 of the V-phase coil wire 40V is described here, the W-phase coil wire 40W having the inner passage portion 42b similarly to the V-phase coil wire 40V can also have a similar structure.

The outer wall portion 24 is provided with a hook portion 25. As described above, the crossover wire 42 of the V-phase coil wire 40V has the inner passage portion 42b connected to the outer passage portion 42a at both ends. The inner passage portion 42b is routed radially inward of the outer wall portion 24 at a boundary portion with the outer passage portion 42 a. The crossover wire 42 is hooked to the hook portion 25 at the boundary between the outer passage portion 42a and the inner passage portion 42 b.

In the winding step, tension is applied to the crossover wire 42 so that the crossover wire 42 does not slacken. The crossover wire 42 is hooked to the hook portion 25 at the boundary between the outer passage portion 42a and the inner passage portion 42b, and thus the outer passage portion 42a is prevented from moving radially inward of the outer wall portion 24 and can be made to follow the radially outward of the outer wall portion 24.

The outer wall portion 24 has an upper end surface 24s facing upward. The upper end surface 24s is provided with a 1 st region 26a and a 2 nd region 26b which are different in height from each other, and a step 27 which connects the 1 st region 26a and the 2 nd region 26 b. The 1 st region 26a is higher than the 2 nd region 26 b. In the present embodiment, the step portion 27 constitutes the hook portion 25. That is, the crossover wire 42 is drawn around the radially inner side of the outer wall portion 24 as the inner passage portion 42b by the outer passage portion 42a extending in the circumferential direction and hooked on the step portion 27.

According to the present embodiment, the outer wall portion 24 is provided with the 1 st region 26a and the 2 nd region 26b having different heights, and the step portion 27 between the 1 st region 26a and the 2 nd region 26b constitutes the hook portion 25. Therefore, the crossover wire 42 can be hooked on the hooking portion 25 without greatly moving the nozzle of the winder in the vertical direction, and the time of the winding process can be shortened. Further, since the 2 nd area 26b is lower than the 1 st area 26a, the nozzle of the winding machine can be suppressed from contacting the outer wall portion 24 in the 2 nd area 26 b.

(modification of hook portion 1)

Next, a hook 125 according to modification 1 that can be employed in the present embodiment will be described with reference to fig. 10. The same reference numerals are given to the same constituent elements as those of the above-described embodiment, and the description thereof will be omitted.

As in the above-described embodiment, the crossover wire 42 is hooked to the hooking portion 125 of the present modification at the boundary between the outer passage portion 42a and the inner passage portion 42 b. The hook portion 125 of the present modification is provided on the upper end surface 24s of the outer wall portion 24. In the present modification, the hook portion 125 is a 1 st projection 127 projecting upward from the upper end surface 24s of the outer wall portion 24. That is, the 1 st protrusion 127 constitutes the hook portion 125.

The crossover wire 42 is routed to the radially inner side of the outer wall portion 24 as an inner passage portion 42b by extending in the circumferential direction at the outer passage portion 42a and hooking to the 1 st projection 127. The crossover wire 42 extends in the circumferential direction at the outer passage portion 42a and is hooked to the 1 st projection 127 so as to be routed to the radially inner side of the outer wall portion 24 as an inner passage portion 42 b.

(modification of hook-and-hold portion 2)

Next, a hook 225 according to modification 2 that can be employed in the present embodiment will be described with reference to fig. 11. The same reference numerals are given to the same constituent elements as those of the above-described embodiment, and the description thereof will be omitted.

As in the above-described embodiment, the crossover wire 42 is hooked to the hooking portion 225 of the present modification at the boundary between the outer passage portion 42a and the inner passage portion 42 b. The hook portion 225 of the present modification is provided on the outer surface 24p of the outer wall portion 24. In the present modification, the hooking portion 225 is a 2 nd protrusion 227 that protrudes radially outward from the outer side surface 24p of the outer wall portion 24. That is, the 2 nd protrusion 227 constitutes the hook portion 125.

The crossover wire 42 is routed to the radially inner side of the outer wall portion 24 as the inner passage portion 42b by extending in the circumferential direction at the outer passage portion 42a and hooking to the 2 nd projection 227. The crossover wire 42 extends in the circumferential direction at the outer passage portion 42a and is hooked to the 2 nd projection 227 so as to be routed to the radially inner side of the outer wall portion 24 as the inner passage portion 42 b.

While the embodiment of the present invention and the modification thereof have been described above, the configurations of the embodiment and the modification, and the combination thereof, are merely examples, and addition, omission, replacement, and other modifications of the configurations can be made within the scope not departing from the gist of the present invention. The present invention is not limited to the embodiments.

For example, the stator 3 of the above embodiment has 6 coils 50. However, the number of coils 50 of the stator 3 is not limited to the present embodiment. In the above embodiment, 2 coils 50 are constituted by 1 coil wire 40. However, 3 or more coils may be formed from 1 coil wire 40.

Description of the reference symbols

1: a motor; 2: a rotor; 3: a stator; 10: a stator core; 11: the back of the iron core; 12: teeth; 20: an insulating member; 21: a base; 24: an outer wall portion; 24 a: a notch portion (notch portion) for a lead wire; 24 b: a notch (notch) for a lap joint line; 24 c: the 1 st projection (convex); 24 d: the 2 nd convex part (convex part); 24 p: an outer side surface; 24 s: an upper end surface; 25. 125, 225: a hook portion; 26 a: region 1; 26 b: a 2 nd region; 27: a step portion; 40: a coil wire; 40U: a U-phase coil wire (1 st coil wire); 40V: a V-phase coil line (2 nd coil line); 40W: a W-phase coil wire; 41: an outgoing line; 42: overlapping wires; 42 a: an outer passage portion; 42 b: an inner passage portion; 42A: an upper side lap joint line; 42B: a lower side lap joint line; 50: a coil; 127: the 1 st projection; 227: a 2 nd protrusion; 24 bA: an upper cutout (1 st cutout); 24 ba: a bottom surface; 24ca, 24 da: a lower surface; 24 bB: a lower cutout (2 nd cutout); j: a central axis.