DE102019104669A1 - Stator for rotating electrical machine and rotating electric machine - Google Patents

Abstract

A stator for a rotary electric machine has an annular stator core, two insulators disposed on each of the opposite end surfaces in an axial direction of the stator core, windings, and a slot insulating plate. The stator core has an annular yoke, teeth extending in a radial direction from the yoke, and grooves formed between the teeth adjacent to each other in a circumferential direction. Each insulator has at least one projecting piece extending in the axial direction into the groove. The teeth are isolated from the winding inside the groove only by the groove isolation plate in the circumferential direction. Movement of each insulator in the radial direction or in the circumferential direction with respect to the stator core is restricted by abutment of the protruding piece on the flange portion.

Description

background

The present disclosure relates to a stator for a rotary electric machine and a rotary electric machine.

The stator of a rotary electric machine has a stator core, and the stator core has an annular yoke, teeth extending in a radial direction from the yoke, and a groove formed between the teeth adjacent to each other in the circumferential direction. The stator core has a flange portion extending in the circumferential direction of the stator core at the distal ends of the teeth, on a side opposite to the yoke in the radial direction.

Furthermore, as disclosed in Japanese Laid-Open Patent Publication No. 2012-55098, the stator has two annular insulators disposed at each of the opposite end surfaces in the axial direction of the stator core. Each insulator has an annular base portion which abuts against the yoke and extension portions which extend in the radial direction from the base portion. The extension sections abut against the plurality of teeth, respectively. Further, the stator has windings wound around the teeth and the extending portions, and a slot insulating plate disposed between the winding and the teeth inside the groove. Furthermore, each insulator has a wall portion extending in the circumferential direction of the insulator at a distal end on a side opposite to the base portion in the radial direction in the extending portion. The wall portion blocks a part of the groove.

The coil ends, which are the opposite ends of the coil in the axial direction, further project axially from the opposite end surfaces in the axial direction of the stator core. The extension portions of each insulator insulate the coil ends protruding from the stator core from the teeth. The wall portions of each insulator restrict movement of the coil toward the flange portion by abutting the coil. In this way, the wall portion abuts the coil, thereby ensuring an isolation distance between a part of the coil disposed in the groove and the distal end faces of the teeth.

It is preferable that the two insulators are positioned with respect to the opposite end surfaces of the stator core in the axial direction. Therefore, for example, each isolator of Japanese Laid-Open Patent Publication No. 2001-112205 has an inner peripheral surface of the yoke forming the groove and a wall portion for positioning along the surfaces of the teeth. By inserting the wall portion into the groove, positioning of each insulator with respect to the end surface of the stator core is performed.

When the wall portion is inserted into the groove, as in Japanese Laid-Open Patent Publication No. 2001-112205, the filling factor of the winding passing through the groove decreases by an amount of insertion of the wall portion into the groove.

Summary

It is an object of the present disclosure to provide a stator for a rotary electric machine and a rotary electric machine that can perform positioning of an insulator while limiting a reduction in the filling factor of the coil.

According to one aspect of the present disclosure, there is provided a stator for a rotary electric machine having an annular stator core, two insulators, windings, and a slot insulating plate. The ring-shaped stator core has an annular yoke, a plurality of teeth extending in a radial direction from the yoke and having a distal end on a side opposite to the yoke in the radial direction, and grooves formed between the teeth formed in a circumferential direction adjacent to each other. The two insulators are disposed on each of opposite end surfaces in an axial direction of the stator core. Each of the insulators has an annular base portion in which each insulator abuts the yoke, and a plurality of extension portions each extending in the radial direction from the base portion having a distal end on a side opposite to the base portion in the radial direction and which rest against one of the plurality of teeth. The windings are wound around the teeth and the extension portions. The slot insulating pad is disposed between the winding and the teeth inside each groove. The stator core has a flange portion extending in the circumferential direction from the distal end of each of the teeth. Each of the insulators has a wall portion extending in the circumferential direction from the distal end of the extension portion to close a part of the groove, and at least one protruding piece extending in the axial direction from the wall portion into the groove. The wall portion is configured to restrict movement of the coil toward the flange portion by abutting the coil. The teeth are of the winding inside the groove only through the Nutisolationsplättchen isolated in the circumferential direction. Movement of each of the insulators in the radial direction or in the circumferential direction with respect to the stator core is restricted by abutment of the protruding piece on the flange portion.

According to another aspect of the present disclosure, there is provided a rotary electric machine having a rotor and the above-described stator.

Other aspects and advantages of the present disclosure will become apparent from the following description taken in conjunction with the accompanying drawings which illustrate exemplary embodiments.

list of figures

• 1 ist eine Querschnittsansicht, die eine drehende elektrische Maschine in einem Ausführungsbeispiel darstellt.
• 2 ist eine perspektivische Explosionsansicht, die einen Statorkern und einen Isolator der drehenden elektrischen Maschine von 1 darstellt;
• 3 ist eine perspektivische Ansicht des Stators von 2;
• 4 ist eine Querschnittsansicht eines Isolators und von Wicklungen der drehenden elektrischen Maschine von 1;
• 5 ist eine vergrößerte perspektivische Ansicht, die einen Teil des Isolators von 4 darstellt; und
• 6 ist eine vergrößerte Querschnittsansicht, die einen Teil des Stators von 3 darstellt.

The disclosure may be understood by reference to the following description taken in conjunction with the accompanying drawings.

• 1 FIG. 10 is a cross-sectional view illustrating a rotary electric machine in an embodiment. FIG.
• 2 FIG. 16 is an exploded perspective view illustrating a stator core and an insulator of the rotary electric machine of FIG 1 represents;
• 3 is a perspective view of the stator of 2 ;
• 4 FIG. 12 is a cross-sectional view of an insulator and windings of the rotary electric machine of FIG 1 ;
• 5 FIG. 15 is an enlarged perspective view showing a part of the insulator of FIG 4 represents; and
• 6 FIG. 15 is an enlarged cross-sectional view showing a part of the stator of FIG 3 represents.

Detailed description

A stator 11 for a rotating electric machine and a rotating electric machine 10 according to one embodiment, with reference to 1 to 6 described.

As in 1 is shown, is the rotary electric machine with the annular stator 11 and a rotor 12 provided on the inner side in a radial direction of the stator 11 is arranged. The stator 11 surrounds the rotor 12 , The rotor 12 is on a rotary shaft 13 fixed in a state in which the rotary shaft 13 is inserted, and integrally rotates with the rotary shaft 13 , The rotor 12 has an annular rotor core 12a who is at the rotary shaft 13 is attached.

As in 2 and 3 is shown, is the stator 11 with an annular stator core 21 Provided. The stator core 21 has a ring-shaped yoke 22 and teeth 23 extending toward the radially inner side of the stator core 21 from an inner peripheral surface 22a of the yoke 22 extend. The teeth 23 are at intervals in the circumferential direction of the stator core 21 arranged and extending along the axis of the stator core 21 on the inner circumferential surface 22a of the yoke 22 , A distal end surface 23a from every tooth 23 on the side opposite to the inner peripheral surface 22a from every yoke 22 is curved in an arc shape around the outer circumferential surface of the rotor core 12a to follow.

The yoke 22 has flat end surfaces 22e at the opposite ends of the stator core 21 in the axial direction. Each of the teeth 23 has a flat end surface 23e at the opposite ends of the stator core 21 in the axial direction. The length of the yoke 22 of the stator core 21 in the axial direction and the length of the teeth 23 of the stator core 21 in the axial direction are the same. The respective end surfaces 22e of the yoke 22 are located on the same level as the end face 23e of the tooth 23 , The stator core 21 has end surfaces 21e including end faces 22e and 23e at the opposite ends in the axial direction.

Each of the teeth 23 has a tooth stretching section 24 that extends from the inner peripheral surface 22a of the yoke 22 extends. Furthermore, the stator core has 21 flange 25 extending from the distal end of the tooth 23 in the circumferential direction of the stator core 21 extend. In particular, two flange sections 25 that are on both sides of the stator core 21 protrude in the circumferential direction, at the distal ends of the respective Zahnerstreckungsabschnitte 24 intended. The two flange sections 25 which at the distal end of a Zahnerstreckungsabschnitt 24 are provided as a pair of flange sections 25 designated.

As in 1 is shown, the stator has 11 windings 27 , The stator core 21 has grooves 28 each of which is a space between two teeth 23 is formed in the circumferential direction of the stator core 21 are adjacent to each other. Part of the winding 27 (a middle part of the winding 27 in the axial direction of the stator core 21 ) is in the groove 28 arranged. Each flange section 25 has an area 25a (please refer 4 ) leading to the groove 28 is free. The area 25a is a wall surface, that of the inner peripheral surface 22a in the groove 28 is substantially facing.

The stator 11 is with a Nutisolationsplättchen 29 provided that between the winding 27 and the teeth 23 in every groove 28 is arranged. The Nutisolationsplättchen 29 isolated part of the winding 27 who is in the groove 28 is arranged from the stator core 21 , Each of the slot insulation plates 29 has a shape of an elongated band, and the opposite ends in the transverse direction thereof are curved in a substantially U-shape so as to be close to each other. Each slot insulation plate 29 is in the groove 28 arranged such that its longitudinal direction along the axial direction of the stator core 21 is.

The slot insulation plate 29 extends along the yoke 22 and the teeth 23 that the grooves 28 form. Furthermore, the groove insulation plate extends 29 from a first end to a second end in the axial direction of the stator core 21 , The two flange sections 25 that a groove 28 facing, have a gap between the distal ends of themselves. The gap is a slot opening 30 , There is a gap between the opposite ends of the slot insulation plate 29 in the transverse direction. The gap is an opening 29a , The opening 29a of the slot insulation plate 29 is on the outer side in the radial direction of the groove opening 30 located. The opening 29a extends from the first end to the second end in the longitudinal direction of the Nutisolationsplättchens 29 , Therefore, the opening extends 29a from the first end to the second end in the axial direction of the stator core 21 ,

As in 2 and 3 is shown is the stator 11 with two annular insulators 31 provided on each of the two opposite end surfaces 21e of the stator core 21 (the teeth 23 ) are arranged. The axial direction of the two insulators 31 agrees with the axial direction of the stator core 21 match. In the following description, unless otherwise specified, the terms "axial direction" and "radial direction" refer to directions with respect to the stator core 21 or the insulator 31 ,

Every insulator 31 has an annular base section 32 , Furthermore, each of the insulators has 31 extending portions 33 and insulator flange sections 34 each of which is a wall portion forming part of the groove 28 closes. The extension sections 33 extend from the inner peripheral surface 32a of the base section 32 inward in the radial direction. Two insulator flange sections 34 projecting toward each of the opposite sides in the circumferential direction are at the distal ends of each extending portion 33 on the side opposite to the base section 32 provided in the radial direction. The two insulator flange sections 34 that of an extension section 33 are projected as a pair of insulator flange sections 34 designated.

The base section 32 is located at a position that is the yoke 22 facing in the axial direction. The base section 32 has flat end surfaces 32e at the opposite ends in the axial direction. A first endface 23e that has one of the opposite end faces 32e of the base section 32 is, is with the end face 22e of the yoke 22 in area contact. That's why the base section is located 32 at the yoke 22 on. From two end surfaces 32e of the base section 32 the area on the side is opposite to the yoke 22 a second end surface 32e , An outer diameter of the base section 32 is smaller than an outer diameter of the yoke 22 , An inner diameter of the base section 32 is the same as an inner diameter of the yoke 22 ,

Every insulator 31 has the same number of extension sections 33 as the Zahnerstreckungsabschnitte 24 , The extension sections 33 are arranged at intervals in the circumferential direction and extend to the axis of the base portion 32 on the inner circumferential surface 32a of the base section 32 , The length dimension of each extension section 33 in the circumferential direction is the same as the length dimension of each tooth stretch section 24 in the circumferential direction.

The extension sections 33 are the teeth stretching sections 24 each facing in the axial direction. The extension section 33 is a substantially quadrangular prism, and the axial length dimension of the extension portion 33 is smaller than the axial length dimension of the base portion 32 , Each extension section 33 has a flat first end surface 33e and a flat second end surface 33e at the opposite ends in the axial direction. The first endface 33e is located on the same level as the first end surface 32e of the base section 32 , The second endface 33e is removed from the second end surface 32e located in the axial direction.

A pair of insulator flange sections 34 are in the directions opposite to each other from the distal end of the extension portion 33 along the circumferential direction. Each insulator flange section 34 has a flat end surface 34e , which is located on the same level as the end surfaces 32e and 33e , The end surfaces 33e and 34e are with the end face 23e the corresponding teeth 23 in area contact. Therefore, the extension sections lie 33 each on the teeth 23 on.

The insulator 31 has an overhanging wall 35 in the form of a thin plate at the distal ends of each extension section 33 is provided. The overhanging wall 35 hangs in one direction away from the stator core 21 along the axial direction from the second end surface 33e of extending portion 33 and a pair of the insulator flange portions 34 on the opposite sides of it. The length dimension of an overhanging wall 35 in the circumferential direction is the same as the length dimension in the circumferential direction of a portion which is an extension portion 33 and the insulator flange sections 34 on the opposite sides of it. Therefore, the opposite edges extend in the circumferential direction of each overhanging wall 35 in the axial direction, to be continuous with the outer edges in the circumferential direction of a pair of the insulator flange portions 34 to be. Each one of the insulator flange sections 34 has an area 34a , the inner peripheral surface 32a facing, and each of the overhanging walls 35 has an area 35a , the inner peripheral surface 32a is facing. Two surfaces 34a that with an extension section 33 are located on the same level as the area 35a that with the same extension section 33 connected is. The two insulator flange sections 34 and the overhanging wall 35 at the distal end of an extension portion 33 are collectively referred to as a preceding section.

Every insulator 31 has openings 36 , Every opening 36 is a gap formed between two protruding portions aligned in the circumferential direction. The arrangement of the openings 36 agrees with the arrangement of the slot openings 30 in the circumferential direction. Each of the insulators 31 has winding insertion spaces 37 each of which is a space between two extents 33 is formed, which are adjacent to each other in the circumferential direction.

As in 3 is shown standing winding ends 27e facing the opposite ends in the axial direction of the winding 27 are, in the axial direction over the opposite end surfaces 21e of the stator core 21 through the winding insertion space 37 through before (see 2 ). The surfaces 34a from each insulator flange section 34 are with the coil end 27e in contact.

In every insulator 31 there is, between the inner peripheral surface 32a and the overhanging wall 35 , a space that is the second end face 33e of the extension section 33 is facing. The distal ends of the respective coil ends 27e are arranged in this room.

When every coil end 27e with the base section 32 of the corresponding insulator 31 comes in contact, the movement is limited to the outer side in the radial direction. Furthermore, if every coil end 27e with the area 34a of the insulator flange section 34 and the area 35a the overhanging wall 35 comes in contact, the movement restricted to the inner side in the radial direction. Every coil end 27e is from the teeth 23 of the stator core 21 through the extension section 33 of the corresponding insulator 31 isolated.

The winding 27 is for example by winding a conductive wire 26 around the tooth stretch section 24 and the extension section 33 formed by concentration winding while causing the winding nozzles through the opening 36 of the insulator 31 , the groove opening 30 and the opening 29a of the slot insulation plate 29 passes. That's why the windings are 27 through the conductive wires 26 trained around the teeth 23 and the extension sections 33 wrapped around. Alternatively, the winding 27 where the conductive wires 26 wound in a ring in advance, into the groove 28 and the winding insertion space 37 through the slot opening 30 , the opening 29a of the slot insulation plate 29 and the opening 36 of the insulator 31 can be used without using a winding nozzle.

In every groove 28 correspond to the windings 27 which are adjacent to each other in the circumferential direction, phases different from each other (a U-phase, a V-phase or a W-phase). For example, every winding has 27 a first connection line at a winding start end portion of the conductive wire 26 , The first leads of the winding 27 are collected for each phase and are electrically connected to power supply terminals (not shown) of the respective phases. In addition, every winding has 27 a second lead at a winding termination end portion of the conductive wire 26 , The second connection lines of the windings 27 that correspond to the same phase are electrically connected to each other at a neutral point coupling portion (not shown). Then turn when a current passes through the winding 27 flows, the rotor 12 and the rotary shaft 13 in one piece.

As in 4 is shown, as viewed from the axial direction, the surface 34a of the insulator flange section 34 closer to the base section 32 located as the plane 25a the corresponding flange sections 25 which are aligned in the axial direction, that is, on the outer side in the radial direction. Furthermore, the area 25a of the flange portion 25 a flat surface which is inclined with respect to the circumferential direction and the radial direction to move away from the yoke 22 with increasing distance from the Zahnerstreckungsabschnitt 24 with which the flange section 25 is connected to remove. In 4 For simplicity of illustration, the groove isolation plate is shown 29 not shown.

Because the area 34a of the insulator flange section 34 closer to the base section 32 is located as the area 25a of the flange portion 25 , is a room 38 between a part of the winding 27 (a middle part in the axial direction) and the surface 25a in every groove 28 educated. The space 38 is between the two insulators 31 formed in the axial direction, and more specifically, between some parts (the outer part in the radial direction) of the two insulator flange portions 34 , which face each other in the axial direction formed.

As in 5 is shown, each Isolatorflanschabschnitt 34 a protruding piece 40 that in the room 38 is arranged. The above piece 40 extends in the axial direction of the Isolatorflanschabschnitt 34 to the interior of the groove 28 , In this embodiment, there are two protruding pieces 40 a pair of insulator flange sections 34 on each of the surfaces 25a the two flange sections 25 which are aligned in the circumferential direction, wherein a groove opening 30 is arranged between these.

Each of the above pieces 40 is an elongated thin flat plate that has a first flat contact surface 40a has that on the flange section 25 is applied. Every contact surface 40a extends along the surface 25a to be in contact with this. The above piece 40 is a region of the endface 34e in front of that to the room 38 exposed.

An operation of the present embodiment will now be described.

As in 6 is shown, is each coil end 27e with the appropriate area 34a of the insulator 31 in contact. Therefore, the insulator flange portion restricts 34 the movement of the winding 27 toward the flange portion 25 , Inside the groove 28 are the teeth 23 and the winding 27 isolated from each other only by the Nutisolationsplättchen in the circumferential direction. In addition, a part (a middle part in the axial direction) of the winding 27 inside the groove 28 arranged in a state in which the room 38 between the winding 27 and the area 25a of the flange portion 25 is trained. As a result, there is a distance for insulation between a part of the winding 27 who is in the groove 28 is arranged, and the distal end surface 23a of the tooth 23 available.

Furthermore, the above piece is 40 inside the groove 28 in the room 38 between the winding 27 and the area 25a of the flange portion 25 arranged, and the contact surface 40a comes with the area 25a in area contact. As a consequence, the movement of the insulator 31 in the radial direction or the circumferential direction with respect to the end surface 21e of the stator core 21 limited.

1. (1) Der Isolator 31 hat ein vorstehendes Stück 40, das sich in der Axialrichtung von dem Isolatorflanschabschnitt 34 zu dem Inneren der Nut 28 erstreckt. Der Raum 38 der Nut 28 ist ein vorhandener Raum, der zum Vorsehen eines Abstands zur Isolation zwischen einem Teil der Wicklung 27, der in der Nut 28 angeordnet ist, und der distalen Endfläche 23a des Zahns 23 notwendig ist. Des Weiteren ist das vorstehende Stück 40 im Inneren des Raums 38 der Nut 28 angeordnet. Deshalb verringert sich, selbst falls das vorstehende Stück 40 im Inneren der Nut 28 angeordnet ist, der Füllfaktor der Wicklung 27 in der Nut 28 nicht. Des Weiteren, da das vorstehende Stück 40 an der Fläche 25a anliegt, ist die Bewegung in der Radialrichtung oder der Umfangsrichtung mit Bezug auf die Endfläche 21e des Statorkerns 21 beschränkt. Deshalb ist es möglich, eine Positionierung des Isolators 31 durchzuführen, während die Verringerung des Füllfaktors der Wicklung 27 begrenzt wird.
2. (2) Das vorstehende Stück 40 ist eine Platte, die die Anlagefläche 40a hat, die an der Fläche 25a des Flanschabschnitts 25 anliegt. Demgemäß, da die Anlagefläche 40a mit der Fläche 25a in Flächenkontakt kommt, ist es beispielsweise im Vergleich zu einem Fall, in dem das vorstehende Stück 40 mit der Fläche 25a in Linienkontakt oder Punktkontakt kommt, möglich, die Positionierungsgenauigkeit des Isolators 31 mit Bezug auf die Endfläche 21e des Statorkerns 21 zu verbessern.
3. (3) Um den Isolator 31 mit Bezug auf den Statorkern 21 zu positionieren, liegt der Isolator 31 nicht an der Seitenfläche des Zahnerstreckungsabschnitts 24 an, sondern liegt an der Fläche 25a über das vorstehende Stück 40 an. Als eine Folge ist die Bewegung des Isolators 31 in der Radialrichtung oder der Umfangsrichtung mit Bezug auf die Endfläche 21e des Statorkerns 21 beschränkt. Deshalb ist es im Vergleich zu einem Fall, in dem bewirkt wird, dass ein Teil des Isolators 31 an der Seitenfläche des Zahnerstreckungsabschnitts 24 anliegt, um eine Positionierung des Isolators 31 mit Bezug auf den Statorkern 21 durchzuführen, möglich, eine Positionierung des Isolators 31 durchzuführen, während die Verringerung des Füllfaktors der Wicklung 27 begrenzt wird.
4. (4) Ein Paar der Flanschabschnitte 25, die an dem distalen Ende von einem Zahnerstreckungsabschnitt 24 vorgesehen sind, hat zwei Flächen 25a, die in Richtungen geneigt sind, die sich voneinander mit Bezug auf die Radialrichtung und die Umfangsrichtung unterscheiden. In ähnlicher Weise wie die zwei geneigten Flächen 25a, sind die zwei vorstehenden Stücke 40, die an einem Paar der Isolatorflanschabschnitte 34 vorgesehen sind, Platten, die angeordnet sind, um mit Bezug auf die Radialrichtung und die Umfangsrichtung geneigt zu sein. Deshalb ist es möglich, die relative Bewegung des Isolators 31 in der Radialrichtung und der Umfangsrichtung wirksam zu begrenzen, unter Verwendung des plattenartigen vorstehenden Stücks 40. Deshalb kann beispielsweise die Positionierungsgenauigkeit des Isolators 31 im Vergleich zu einem Fall verbessert werden, in dem das plattenartige vorstehende Stück 40 nur an einer Fläche 25a eines Paars der Flanschabschnitte 25 anliegt.
5. (5) Jeder Isolator 31 hat vorstehende Stücke 40, die jeweils in die Nuten 28 einzusetzen sind. Deshalb ist es beispielsweise im Vergleich zu dem Isolator 31, der nur ein vorstehendes Stück 40 hat, das in eine der Nuten 28 einzusetzen ist, möglich, die Positionierungsgenauigkeit des Isolators 31 mit Bezug auf die Endfläche 21e des Statorkerns 21 zu verbessern.
6. (6) Um die zwei Isolatoren 31 mit Bezug auf den Statorkern 21 zu positionieren, gibt es keine Notwendigkeit, den Statorkern 21 zu bearbeiten. Diese Gestaltung vermeidet das Auftreten von Problemen wie eines Einflusses auf den magnetischen Fluss, der durch den Statorkern 21 fließt, oder eine aufwändige Arbeit zum Herstellen des Statorkerns 21.

The embodiment described above has the following advantages.

1. (1) The insulator 31 has a protruding piece 40 extending in the axial direction from the insulator flange portion 34 to the interior of the groove 28 extends. The space 38 the groove 28 is an existing space for providing a clearance for isolation between a part of the coil 27 who is in the groove 28 is arranged, and the distal end surface 23a of the tooth 23 necessary is. Furthermore, the above piece is 40 inside the room 38 the groove 28 arranged. Therefore, even if the projected piece decreases 40 inside the groove 28 is arranged, the fill factor of the winding 27 in the groove 28 Not. Furthermore, since the above piece 40 on the surface 25a is applied, the movement in the radial direction or the circumferential direction with respect to the end surface 21e of the stator core 21 limited. Therefore, it is possible to position the insulator 31 while reducing the fill factor of the winding 27 is limited.
2. (2) The above piece 40 is a plate that has the contact surface 40a has that on the surface 25a of the flange portion 25 is applied. Accordingly, since the contact surface 40a with the area 25a comes into surface contact, it is, for example, compared to a case where the protruding piece 40 with the area 25a in line contact or point contact comes, possible, the positioning accuracy of the insulator 31 with respect to the endface 21e of the stator core 21 to improve.
3. (3) To the insulator 31 with reference to the stator core 21 to position, lies the insulator 31 not on the side surface of the tooth extension section 24 but lies on the surface 25a about the above piece 40 on. As a consequence, the movement of the insulator 31 in the radial direction or the circumferential direction with respect to the end surface 21e of the stator core 21 limited. Therefore, it is compared to a case in which causes a part of the insulator 31 on the side surface of the tooth extension section 24 is applied to a positioning of the insulator 31 with reference to the stator core 21 possible, a positioning of the insulator 31 while reducing the fill factor of the winding 27 is limited.
4. (4) A pair of the flange portions 25 which at the distal end of a Zahnerstreckungsabschnitt 24 are provided, has two surfaces 25a that are inclined in directions that differ from each other with respect to the radial direction and the circumferential direction. In a similar way as the two inclined surfaces 25a , are the two prominent pieces 40 attached to a pair of insulator flange sections 34 are provided, plates which are arranged to be inclined with respect to the radial direction and the circumferential direction. Therefore, it is possible the relative movement of the insulator 31 in the radial direction and the circumferential direction, using the plate-like protruding piece 40 , Therefore, for example, the positioning accuracy of the insulator 31 be improved compared to a case in which the plate-like protruding piece 40 only on one surface 25a a pair of the flange portions 25 is applied.
5. (5) Each insulator 31 has prominent pieces 40 , each in the grooves 28 are to be used. That is why it is for example compared to the insulator 31 , which is just a protruding piece 40 has that in one of the grooves 28 is possible, possible, the positioning accuracy of the insulator 31 with respect to the endface 21e of the stator core 21 to improve.
6. (6) To the two insulators 31 with reference to the stator core 21 There is no need to position the stator core 21 to edit. This design avoids the occurrence of problems such as an influence on the magnetic flux passing through the stator core 21 flows, or a laborious job of making the stator core 21 ,

The embodiment described above may be modified as follows.

In the embodiment described above, the insulator 31 a yoke abutment portion extending in the axial direction from the base portion 32 to the interior of the groove 28 extends and on the inner peripheral surface 22a of the yoke 22 directly or via the slot insulation plate 29 is applied. The yoke abutment section is between the windings 27 arranged adjacent to each other in the circumferential direction. Accordingly, it is possible to position the insulator 31 perform more accurately, while the reduction of the filling factor of the winding itself is limited by the Jochanlageabschnitt.

In the embodiment described above, each insulator 31 Designed to be one or more protruding pieces 40 that are designed to fit in just one area 25a a pair of the flange portions 25 that has a slot opening 30 train to abide.

In the embodiment described above, each insulator 31 at least one protruding piece 40 to have. In short, the number of protruding pieces 40 attached to the insulator 31 are not particularly limited.

In the embodiment described above, the projecting piece is 40 is not limited to an elongated thin flat plate and may be, for example, a columnar shape or may be in line contact or point contact with the surface 25a of the flange portion 25 his.

In the embodiment described above, the insulator 31 an annular wall portion having the distal ends of the extension portions 33 connects to each other and extends over the entire circumference in the circumferential direction.

In the embodiment described above, the winding 27 by winding the conductive wire 26 around the tooth stretch section 24 and the extension section 33 which are aligned in the axial direction are formed with the distributed winding.

In the embodiment described above, the rotary electric machine 10 a rotating electric machine 10 be the outer rotor type, in which a rotor is disposed on the outer side of the stator in the radial direction. The rotating electric machine 10 the outer rotor type is provided with teeth extending radially outwardly from the outer peripheral surface of the yoke 22 extend. Every insulator 31 has an extension portion extending from the outer peripheral surface of the base portion 32 extends radially outward.

A stator for a rotary electric machine has an annular stator core, two insulators disposed on each of the opposite end surfaces in an axial direction of the stator core, windings, and a slot insulating plate. The stator core has an annular yoke, teeth extending in a radial direction from the yoke, and grooves formed between the teeth adjacent to each other in a circumferential direction. Each insulator has at least one projecting piece extending in the axial direction into the groove. The teeth are isolated from the winding inside the groove only by the groove isolation plate in the circumferential direction. Movement of each insulator in the radial direction or in the circumferential direction with respect to the stator core is restricted by abutment of the protruding piece on the flange portion.

Claims (4)

Stator for a rotating electrical machine with: an annular stator core having an annular yoke, a plurality of teeth extending in a radial direction from the yoke and having a distal end on a side opposite to the yoke in the radial direction, and grooves formed between the teeth; which are adjacent to each other in a circumferential direction; two insulators disposed at each of opposite end surfaces in an axial direction of the stator core, each of the insulators having an annular base portion in which each insulator abuts against the yoke, and a plurality of extension portions each extending in the radial direction from the base portion extend, which have a distal end on a side opposite to the base portion in the radial direction and which abut against one of the plurality of teeth; Windings wound around the teeth and the extension portions; and a groove isolation plate disposed between the coil and the teeth inside each groove, wherein the stator core has a flange portion extending in the circumferential direction from the distal end of each of the teeth, each of the insulators has a wall portion extending in the circumferential direction from the distal end of the extension portion to close a part of the groove, and has at least one protruding piece extending in the axial direction from the wall portion into the groove, the wall portion is configured to restrict movement of the coil toward the flange portion by abutting the coil; the teeth are insulated from the winding inside the groove only by the groove insulating plate in the circumferential direction, and Movement of each of the insulators in the radial direction or in the circumferential direction with respect to the stator core is restricted by abutment of the protruding piece on the flange portion. Stator for a rotating electric machine behind Claim 1 wherein the protruding piece is a plate having an abutment surface abutting the flange portion. Stator for a rotating electric machine behind Claim 1 or 2 wherein each of the insulators has a yoke abutting portion extending in the axial direction from the base portion to the inside of the groove, and the yoke abutting portion between the windings adjacent to each other in the circumferential direction is direct or at the peripheral surface of the yoke to rest over the groove insulation plate. Rotary electric machine with: a rotor; and the stator for a rotary electric machine according to any one of Claims 1 to 3 ,

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