JP2019213293A - Stator for rotary electric machine - Google Patents

Abstract

To provide a stator for a rotary electric machine capable of suppressing varnish from flowing between a plurality of laminated electromagnetic steel plates and suppressing deterioration in noise and vibration characteristics of the rotary electric machine.SOLUTION: A stator 10 of a rotary electric machine includes a stator core 12 having a plurality of slots 16 and a coil 20 attached to the stator core 12. The stator core 12 is composed of a plurality of laminated electromagnetic steel plates. The coil 20 has a plurality of slot coil sections 21 inserted into a slot 16 via an insulating sheet 30. The plurality of slot coil sections 21 are surrounded by an insulating sheet 30 and fixed by varnish. The slot coil section 21 has a conductor section 211 and an insulating section 212 surrounding an outer peripheral surface of the conductor section 211. A varnish channel 22 is formed in the insulating section 212.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a stator for a rotating electrical machine, and more particularly to a stator for a rotating electrical machine in which a plurality of slot coil portions inserted into slots of a stator core are fixed by a varnish.

  Conventionally, a stator for a rotating electrical machine is known in which insulating paper is disposed in a slot of the stator core, a coil is wound around the stator core via the insulating paper in the slot, and the coil is fixed by a varnish in the slot. . For example, in Patent Document 1, varnish is dropped onto coil ends located at both axial ends of the stator core, and the slot coil portion inserted into the slot of the stator core is impregnated with the varnish so that the slot coil portion is fixed by the varnish. A stator for a rotating electric machine is disclosed.

JP 2006-006054 A

  However, in the battery module of Patent Document 1, when the stator core is composed of a plurality of electromagnetic steel plates stacked, the varnish is dropped on the coil ends located at both ends in the axial direction of the stator core and inserted into the slots of the stator core. When the slot coil portion is impregnated with varnish, the varnish flows between the slot portion and the magnetic steel sheet. When the varnish flowing between the electromagnetic steel sheets solidifies, the holding force between the electromagnetic steel sheets increases, and the rigidity of the stator core increases. As a result, when the rotor of the rotating electrical machine rotates, the excitation force caused by the reaction force (magnetic attractive force, torque ripple, etc.) generated between the stator and the rotor is attenuated by the plurality of laminated magnetic steel sheets. However, there was a problem that the noise and vibration characteristics of the rotating electrical machine deteriorated.

  The present invention provides a stator for a rotating electrical machine that can suppress the flow of varnish between a plurality of laminated electromagnetic steel sheets and suppress the deterioration of noise and vibration characteristics of the rotating electrical machine.

The present invention
A stator core having a plurality of slots;
A coil attached to the stator core,
The stator core is composed of a plurality of laminated electromagnetic steel plates,
The coil has a plurality of slot coil portions inserted into the slot via insulating paper,
The plurality of slot coil portions are a stator of a rotating electrical machine surrounded by the insulating paper and fixed by a varnish,
The slot coil portion has a conductor portion and an insulating portion surrounding an outer peripheral surface of the conductor portion,
A varnish flow path is formed in the insulating portion.

  According to the present invention, when a plurality of slot coil portions are fixed by impregnating the varnish, more varnish flows through the varnish flow path due to capillary action, so that the varnish flows between the plurality of laminated magnetic steel sheets. This can be suppressed. Thereby, it can suppress that the retention strength between electromagnetic steel plates becomes large, and can suppress the deterioration of the noise and the vibration characteristic of a rotary electric machine resulting from the rigidity of a stator core becoming high.

It is principal part sectional drawing of the stator of the rotary electric machine in one Embodiment of this invention. It is the perspective view which looked at the slot coil part of FIG. 1 from diagonally upward. It is a perspective view of the 1st modification of the slot coil part of the stator of the rotary electric machine in one Embodiment of this invention. It is a perspective view of the 2nd modification of the slot coil part of the stator of the rotary electric machine in one Embodiment of this invention. It is a perspective view of the 3rd modification of the slot coil part of the stator of the rotary electric machine in one Embodiment of this invention. It is a perspective view of the 4th modification of the slot coil part of the stator of the rotary electric machine in one Embodiment of this invention. It is a top view of the slot coil part of FIG. 6A. It is a perspective view of the 5th modification of the slot coil part of the stator of the rotary electric machine in one Embodiment of this invention.

  Hereinafter, an embodiment of a stator for a rotating electrical machine according to the present invention will be described with reference to the accompanying drawings.

<Stator>
As shown in FIG. 1, a stator 10 of a rotating electrical machine according to this embodiment includes a stator core 12 formed by laminating a plurality of annular electromagnetic steel plates made of a magnetic material, and a coil 20. The stator core 12 includes a plurality of teeth 14 that protrude radially inward at predetermined intervals along the circumferential direction, and a slot 16 that is a space between adjacent teeth 14.

  The coil 20 has a plurality (eight in FIG. 1) of slot coil portions 21 that are arranged from the inside in the radial direction to the outside in the slot 16. The slot coil portion 21 includes a conductor portion 211 and an insulating portion 212 formed on the outer peripheral surface of the conductor portion 211 by film processing (see FIG. 2). The slot coil portion 21 has a quadrangular cross section. The slot coil portion 21 may be a part of a U-shaped segment coil in which two slot coil portions 21 are connected, or may be a single linear or crank-shaped segment coil. It may be part of a distributed or continuous winding coil.

  Further, the eight slot coil portions 21 arranged side by side in the radial direction of the stator core 12 are inserted into the slots 16 via the insulating paper 30. The insulating paper 30 is disposed along the opening 16 </ b> A, the bottom wall 16 </ b> U, and the side wall 16 </ b> S of the slot 16, and the eight slot coil portions 21 are surrounded by the insulating paper 30.

  The coil 20 is fixed to the stator core 12 together with the insulating paper 30. Specifically, when the varnish is dropped from one or both axial ends of the stator core 12 to the coil 20, the varnish flows into the slot 16, particularly the region on the inner peripheral side of the insulating paper 30, and the eight slots The coil portions 21 and the eight slot coil portions 21 and the insulating paper 30 are fixed. Note that the varnish appropriately flows in a region on the outer peripheral side of the insulating paper 30, that is, between the insulating paper 30 and the slot 16, so that the eight slot coil portions 21 are connected to the stator core 12 via the insulating paper 30. Fixed to. On the other hand, when an excessive varnish flows between the insulating paper 30 and the slot 16, the holding force between the laminated electromagnetic steel sheets increases, which causes the noise and vibration characteristics of the rotating electrical machine to deteriorate. Therefore, the slot coil portion 21 is provided with a varnish flow path 22 as described below.

<Slot coil section>
As shown in FIG. 2, the slot coil portion 21 having a square cross section has four surfaces. In the following description, for convenience, the surface facing the bottom wall 16U of the slot 16 is referred to as the upper surface 21U, the surface facing the opening 16A is referred to as the lower surface 21D, and the surfaces facing the side wall 16S are referred to as the left side surface 21L and the right side surface 21R.

  An upper surface 21U and a lower surface 21D are adjacent to each other in the slot coil portion 21 other than the slot coil portion 21 disposed closest to the opening 16A in the slot 16 and the slot coil portion 21 disposed closest to the bottom wall 16U. It is in contact with the slot coil portion 21. In the slot coil portion 21 disposed closest to the opening 16A in the slot 16, the upper surface 21U is in contact with the adjacent slot coil portion 21, and the lower surface 21D faces the opening 16A of the slot 16. The slot coil portion 21 disposed on the most bottom wall 16U side in the slot 16 has a lower surface 21D that is in contact with the adjacent slot coil portion 21, and an upper surface 21U that is in contact with the bottom wall 16U of the slot 16 via an insulating paper 30. . Further, the left side surface 21L and the right side surface 21R of the slot coil portion 21 are in contact with the side wall 16S of the slot 16 via the insulating paper 30 (see FIG. 1).

  A varnish flow path 22 is formed in the insulating portion 212 of the upper surface 21U and the lower surface 21D of the slot coil portion 21. The varnish flow path 22 has a first groove portion 221 formed in the insulating portion 212 and extending in parallel with the axis of the stator core 12. The varnish flow path 22 having the first groove portion 221 may be formed on one of the upper surface 21U and the lower surface 21D of the slot coil portion 21.

  When the varnish is dropped from one or both axial ends of the stator core 12 onto the coil 20 having the slot coil portion 21 configured as described above, the varnish is introduced into the slot 16 and then varnished by capillary action. 22 is more guided to the first groove 221 extending in parallel with the axis of the stator core 12, which is 22. Therefore, the varnish is prevented from flowing between the plurality of electromagnetic steel plates on which the stator core 12 is laminated. Thereby, since it can suppress that the retention force between electromagnetic steel plates becomes large with a varnish, the deterioration of the noise and the vibration characteristic of a rotary electric machine resulting from the rigidity of a stator core becoming high can be suppressed.

  Moreover, since the varnish flow path 22 is formed in the insulating part 212 of the upper surface 21U and the lower surface 21D of the slot coil part 21 which is a contact surface with the adjacent slot coil part 21, the contact surface with the adjacent slot coil part 21 A large amount of varnish is supplied to the slot coil portion 21 and the adhesion between the slot coil portions 21 is improved.

  Further, since the varnish flow path 22 is formed in the insulating portion 212, it is possible to suppress the deterioration of the noise and vibration characteristics of the rotating electrical machine without lowering the space factor of the coil 20 in the slot 16.

  Furthermore, since the varnish flow path 22 is formed by the first groove portion 221 extending in parallel with the axis of the stator core 12, the varnish flow path 22 can be easily formed.

[First Modification]
As shown in FIG. 3, a concave portion 211 a is formed on the outer peripheral surface of the conductor portion 211 of the slot coil portion 21, and the varnish flow path 22 may be formed on the outer periphery of the concave portion 211 a of the conductor portion 211. .

  In this case, when the slot coil portion 21 is manufactured, the first groove portion 221 can be formed by forming the recess portion 211 a on the outer peripheral surface of the conductor portion 211 and then coating the insulating portion 212 on the conductor portion 211. Thereby, it is not necessary to process the insulating part 212 formed by film processing, and the varnish flow path 22 can be easily formed.

[Second Modification]
As shown in FIG. 4, the varnish flow path 22 formed in the slot coil portion 21 includes a first groove portion 221 provided on each of the upper surface 21U, the lower surface 21D, the left side surface 21L, and the right side surface 21R, and the first groove portions 221. And a second groove portion 222 that extends continuously from the upper surface 21U, the lower surface 21D, the left side surface 21L, and the right side surface 21R. The first groove part 221 and the second groove part 222 may intersect at a right angle, or may intersect at a predetermined angle.

  Note that the first groove portion 221 does not have to be formed on all surfaces, and may be provided on at least one surface. Preferably, the first groove portion 221 is formed on a contact surface with the adjacent slot coil portion 21, that is, on the upper surface 21U and the lower surface 21D of the slot coil portion 21. Moreover, the 2nd groove part 222 does not need to connect the 1st groove parts 221 formed in a different side surface, and it continues over the side surface different from this side surface from the side surface in which the 1st groove part 221 was formed. As long as it extends.

  Thereby, for example, the slot coil portion 21 other than the contact surface with the adjacent slot coil portion 21 in which the first groove portion 221 extending in parallel with the axis of the stator core 12 is formed, that is, the upper surface 21U and the lower surface 21D of the slot coil portion 21. The varnish flowing between the left side 21L and the right side 21R and the insulating paper 30 can also be introduced into the varnish flow path 22 from the second groove 222, and the varnish flows between a plurality of laminated electromagnetic steel sheets. Can be suppressed.

[Third Modification]
As shown in FIG. 5, the varnish flow path 22 formed in the slot coil portion 21 may be a spiral groove portion 223 extending spirally on the outer peripheral surface of the slot coil portion 21.

  Thus, for example, the varnish flowing between the left side surface 21L and the right side surface 21R of the slot coil portion 21 and the insulating paper 30 other than the upper surface 21U and the lower surface 21D of the slot coil portion 21 which are contact surfaces with the adjacent slot coil portion 21. Moreover, it can introduce | transduce into the varnish flow path 22, and can suppress more that a varnish flows between the some electromagnetic steel plates laminated | stacked.

  Further, the varnish flow path 22 extending spirally on the outer peripheral surface of the slot coil portion 21 and the varnish flow path 22 extending spirally on the outer peripheral surface of the adjacent slot coil portion 21 are spirals in opposite directions, and at least one By overlapping the portions, a flow path extending along the axis of the stator core 12 may be formed. In this case, the slot coil portion 21 is a contact surface between the slot coil portion 21 and the adjacent slot coil portion 21 by the varnish flow path 22 of the slot coil portion 21 and the varnish flow path 22 of the adjacent slot coil portion 21. A channel that extends along the axial direction of the stator core 12 is formed on the upper surface 21U and the lower surface 21D.

  As a result, the varnish flow path area can be increased by the varnish flow path 22 of the slot coil section 21 and the varnish flow path 22 of the adjacent slot coil section 21 on the contact surface with the adjacent slot coil section 21. This can improve the adhesion between the slot coil portions 21.

[Fourth Modification]
As shown in FIGS. 6A and 6B, the varnish flow path 22 formed in the slot coil portion 21 includes a plurality of inclined groove portions 224 </ b> U inclined at a predetermined angle from the axis of the stator core 12 on the upper surface 21 </ b> U of the slot coil portion 21. The lower surface 21D of the coil portion 21 may have a plurality of inclined groove portions 224D inclined from the axis of the stator core 12 by a predetermined angle in the opposite direction to the inclined groove portions 224U. At this time, the plurality of inclined groove portions 224U formed on the upper surface 21U of the slot coil portion 21 are at least partially connected to the plurality of inclined groove portions 224D formed on the lower surface 21D of the slot coil portion 21 in contact with the upper surface 21U of the slot coil portion 21. Are overlapping. The stator core 12 includes a plurality of inclined groove portions 224U formed on the upper surface 21U of the slot coil portion 21 and a plurality of inclined groove portions 224D formed on the lower surface 21D of the slot coil portion 21 in contact with the upper surface 21U of the slot coil portion 21. It arrange | positions so that the varnish flow path 22 extended in an axial center direction may be formed.

  As a result, the varnish flow path area of the slot coil portion 21 and the varnish flow path 22 of the adjacent slot coil portion 21 on the contact surface with the adjacent slot coil portion 21 can be easily processed to reduce the flow area of the varnish. Can be bigger.

  Here, the first groove part 221, the second groove part 222, the spiral groove part 223, and the inclined groove parts 224U and 224D can be formed by an arbitrary processing method such as cutting or pressing, but preferably formed by pressing. Is done.

  Thereby, when bending the slot coil portion 21, stress concentration can be reduced in the first groove portion 221, the second groove portion 222, the spiral groove portion 223, and the inclined groove portions 224U and 224D which are the varnish flow paths 22. The possibility that the insulating portion 212 is damaged can be reduced.

[Fifth Modification]
As shown in FIG. 7, the varnish flow path 22 formed in the slot coil portion 21 may be formed by roughing the outer peripheral surface of the insulating portion 212. Thereby, a cutting process, a press work, etc. are unnecessary, and the varnish flow path 22 can be easily formed in the slot coil part 21. FIG. Further, due to the rough surface processing, many gaps are formed on the contact surface with the adjacent slot coil portion 21, and this gap becomes the varnish flow path 22, so that the varnish flow path 22 can ensure a large flow path area. Thereby, the adhesiveness between the slot coil parts 21 improves.

  It should be noted that the above-described embodiment can be modified, improved, etc. as appropriate. For example, in the present embodiment, the slot coil portion 21 has a rectangular cross section, but may have any shape, and may be a polygon such as a triangle or a hexagon, or a combination of different polygons. . In this way, it becomes possible to arrange the slot coil portion 21 with no gap between the adjacent slot coil portions 21, the space factor of the coil 20 in the slot 16 is improved, and the adhesiveness between the slot coil portions 21 is improved. Will improve.

  In the present embodiment, the number of the first groove portions 221 is one for the same surface of the upper surface 21U, the lower surface 21D, the left side surface 21L, and the right side surface 21R of the slot coil unit 21, but a plurality of the first groove portions 221 may be provided on the same surface. . If it does in this way, it will become possible to enlarge the channel area of a varnish, without making the width | variety of the 1st groove part 221 wide, and more varnish can be guide | induced to the varnish flow path 22.

  In addition, at least the following matters are described in this specification. In addition, although the component etc. which respond | correspond in the above-mentioned embodiment are shown in a parenthesis, it is not limited to this.

(1) a stator core (stator core 12) having a plurality of slots (slots 16);
A coil (coil 20) attached to the stator core,
The stator core is composed of a plurality of laminated electromagnetic steel plates,
The coil has a plurality of slot coil portions (slot coil portions 21) inserted into the slots via insulating paper (insulating paper 30),
The plurality of slot coil portions are stators (stator 10) of a rotating electrical machine surrounded by the insulating paper and fixed by varnish,
The slot coil portion has a conductor portion (conductor portion 211) and an insulating portion (insulating portion 212) surrounding the outer peripheral surface of the conductor portion,
A stator of a rotating electrical machine, wherein a varnish flow path (varnish flow path 22) is formed in the insulating portion.

According to (1), when fixing a plurality of slot coil portions by impregnating the varnish, more varnish flows through the varnish flow path due to capillary action, so that the varnish is interposed between the laminated electrical steel sheets. Flow can be suppressed. Thereby, it can suppress that the retention strength between electromagnetic steel plates becomes large, and can suppress the deterioration of the noise and the vibration characteristic of a rotary electric machine resulting from the rigidity of a stator core becoming high.
Further, since the varnish flow path is formed in the insulating portion, it is possible to suppress the deterioration of noise and vibration characteristics of the rotating electrical machine without lowering the space factor of the slot coil portion.

(2) The stator of the rotating electric machine according to (1),
The conductor portion has a recess (recess 211a) formed on the outer peripheral surface,
The varnish flow path is a stator of a rotating electrical machine formed on the outer periphery of the recess.

  According to (2), since the conductor portion has a recess formed on the outer peripheral surface and the varnish flow path is formed on the outer periphery of the recess, the conductor portion is insulated after the recess is formed on the outer peripheral surface of the conductor portion. A varnish flow path can be formed by coating the part into a conductor part. Thereby, a varnish flow path can be formed easily.

(3) A stator for a rotating electrical machine according to (1) or (2),
The varnish flow path has a groove (first groove 221) extending in parallel with the axis of the stator core.

  According to (3), since the varnish flow path can be formed by a groove portion extending in parallel with the axis of the stator core, the varnish flow path can be easily formed.

(4) The stator of the rotating electric machine according to (3),
The slot coil portion has a polygonal cross section,
The groove portion is a stator of a rotating electrical machine formed on a contact surface with at least one adjacent slot coil portion.

  According to (4), the slot coil portion has a polygonal cross section, and the groove portion is formed on the contact surface with the adjacent slot coil portion. The varnish is supplied, and the adhesion between the slot coil portions is improved.

(5) The rotating electrical machine stator according to (1) or (2),
The slot coil portion has a polygonal cross section,
The varnish flow path has a first groove portion (first groove portion 221) extending in parallel with the axis of the stator core, and a second groove portion (second groove portion 222) intersecting the first groove portion,
The second groove portion is a stator of a rotating electrical machine that continuously extends from a side surface on which the first groove portion is formed to a side surface different from the side surface.

  According to (5), the slot coil portion has a polygonal cross section, and the varnish flow path extends from the side surface on which the first groove portion is formed to the second groove portion continuously extending from the side surface different from the side surface. Therefore, the varnish flowing outside the side surface where the first groove is formed can also be introduced into the varnish flow path. Thereby, it can suppress more that a varnish flows between several laminated | stacked electromagnetic steel plates.

(6) The rotating electric machine stator according to (5),
The slot coil portion has a polygonal cross section,
The stator of a rotating electrical machine, wherein the first groove portion and the second groove portion are formed on a contact surface with at least one adjacent slot coil portion.

  According to (6), the slot coil portion has a polygonal cross section, and the first groove portion and the second groove portion are formed on the contact surface with at least one adjacent slot coil portion. Many varnishes are supplied to the contact surface with the part, and the adhesion between the slot coil parts is improved.

(7) The stator of the rotating electrical machine according to (1) or (2),
The varnish flow path has a groove portion (spiral groove portion 223) extending spirally on the outer peripheral surface of the slot coil portion.

  According to (7), since the varnish flow path has a groove extending spirally on the outer peripheral surface of the slot coil part, the varnish flowing between the insulating paper and the slot coil part can also be introduced into the varnish flow path. .

(8) The stator of the rotating electric machine according to (7),
The slot coil portion has a polygonal cross section,
The varnish flow path is arranged so that a flow path extending in the axial direction of the stator core is formed by overlapping at least partly with the varnish flow path provided in the adjacent slot coil portion. , Stator of rotating electrical machines.

  According to (8), the varnish flow path is arranged such that a flow path extending in the axial direction of the stator core is formed by overlapping at least part of the varnish flow path provided in the adjacent slot coil portion. Therefore, the flow area of the varnish flow path in the contact surface with the adjacent slot coil part can be increased, and the adhesion between the slot coil parts is improved.

(9) The stator of the rotating electric machine according to (1) or (2),
The slot coil portion has a polygonal cross section,
The varnish flow path has a plurality of groove portions (inclined groove portions 224U and 224D) inclined at a predetermined angle from the axis of the stator core on a contact surface with the adjacent slot coil portion, and is provided in the adjacent slot coil portion. A stator of a rotating electrical machine, wherein the stator is disposed such that a flow path extending in an axial direction of the stator core is formed by overlapping at least a part of the formed varnish flow path.

  According to (9), the slot coil portion has a polygonal cross section, and the varnish flow path has a plurality of grooves inclined at a predetermined angle from the axis of the stator core on the contact surface with the adjacent slot coil portion. Since the varnish flow path provided in the adjacent slot coil part and the flow path extending in the axial direction of the stator core are formed by overlapping at least partly, it is adjacent by easy processing. The channel area of the varnish channel on the contact surface with the slot coil portion can be increased, and the adhesion between the slot coil portions is improved.

(10) The stator of the rotating electrical machine according to any one of (1) to (9),
The varnish flow path is a stator of a rotating electrical machine formed by pressing.

  According to (10), since the varnish flow path is formed by press working, when the slot coil portion is bent, stress concentration on the varnish flow path portion can be alleviated and the insulating portion may be damaged. Can be reduced.

(11) The stator of the rotating electric machine according to (1),
The slot coil portion has a polygonal cross section,
The varnish flow path is a stator of a rotating electrical machine, which is formed by roughening the outer peripheral surface of the insulating portion.

  According to (11), since the varnish flow path is formed by roughing the outer peripheral surface of the insulating portion, the varnish flow path can be easily formed without the need for cutting or pressing. . Further, due to the rough surface processing, many gaps are formed on the contact surface with the adjacent slot coil portions, and these gaps become varnish passages, so that a large passage area can be secured in the varnish passages. Thereby, the adhesiveness between slot coil parts improves.

DESCRIPTION OF SYMBOLS 10 Stator 12 Stator core 16 Slot 20 Coil 21 Slot coil part 211 Conductor part 211a Concave part 212 Insulating part 22 Varnish flow path 221 First groove part 222 Second groove part 223 Spiral groove part 224U, 224D Inclined groove part 30 Insulating paper

Claims (11)

A stator core having a plurality of slots;
A coil attached to the stator core,
The stator core is composed of a plurality of laminated electromagnetic steel plates,
The coil has a plurality of slot coil portions inserted into the slot via insulating paper,
The plurality of slot coil portions are a stator of a rotating electrical machine surrounded by the insulating paper and fixed by a varnish,
The slot coil portion has a conductor portion and an insulating portion surrounding an outer peripheral surface of the conductor portion,
A stator of a rotating electrical machine, wherein a varnish flow path is formed in the insulating portion. A stator for a rotating electrical machine according to claim 1,
A concave portion is formed on the outer peripheral surface of the conductor portion,
The varnish flow path is a stator of a rotating electrical machine formed on the outer periphery of the recess. A stator for a rotating electrical machine according to claim 1 or 2,
The stator of a rotating electrical machine, wherein the varnish flow path has a groove portion extending in parallel with the axis of the stator core. A stator for a rotating electrical machine according to claim 3,
The slot coil portion has a polygonal cross section,
The groove part is a stator of a rotating electrical machine formed on a contact surface with at least one adjacent slot coil part. A stator for a rotating electrical machine according to claim 1 or 2,
The slot coil portion has a polygonal cross section,
The varnish flow path has a first groove extending in parallel with the axis of the stator core, and a second groove intersecting the first groove.
The second groove portion is a stator of a rotating electrical machine that continuously extends from a side surface on which the first groove portion is formed to a side surface different from the side surface. A stator for a rotating electrical machine according to claim 5,
The stator of a rotating electrical machine, wherein the first groove portion and the second groove portion are formed on a contact surface with at least one adjacent slot coil portion. A stator for a rotating electrical machine according to claim 1 or 2,
The varnish flow path is a stator of a rotating electrical machine having a groove extending spirally on the outer peripheral surface of the slot coil portion. A stator for a rotating electrical machine according to claim 7,
The slot coil portion has a polygonal cross section,
The varnish flow path is arranged so that a flow path extending along the axis of the stator core is formed by overlapping at least partly with the varnish flow path provided in the adjacent slot coil portion. The stator of a rotating electrical machine. A stator for a rotating electrical machine according to claim 1 or 2,
The slot coil portion has a polygonal cross section,
The varnish flow path has a plurality of grooves inclined at a predetermined angle from the axis of the stator core on a contact surface with the adjacent slot coil part, and the varnish flow path provided in the adjacent slot coil part; The stator of the rotating electrical machine is arranged such that a flow path is formed along the axial center direction of the stator core by overlapping at least partly. A stator for a rotating electrical machine according to any one of claims 1 to 9,
The varnish flow path is a stator of a rotating electrical machine formed by pressing. A stator for a rotating electrical machine according to claim 1,
The slot coil portion has a polygonal cross section,
The varnish flow path is a stator of a rotating electrical machine, which is formed by roughening the outer peripheral surface of the insulating portion.

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