WO2020067349A1 - Rotor of electric rotary machine - Google Patents

Abstract

A rotor (10) of an electric rotary machine is provided with: a rotor core (20) having a magnet insertion hole (410); and a permanent magnet (810). The permanent magnet (810) has an inner-diameter-side flat section (815) at a circumferential center section (810C) of an inner-diameter-side curved surface (811). The magnet insertion hole (410) has an inner-diameter-side flat wall surface (415) facing the inner-diameter-side flat section (815) of the permanent magnet (810). A gap section (G) is provided between an outer-diameter-side curved surface (812) of the permanent magnet (810) and an outer-diameter-side wall surface (412) of the magnet insertion hole (410) at the circumferential center section (810C) of the permanent magnet (810).

Description

Rotating electric machine rotor

The present invention relates to a rotor of a rotating electric machine mounted on an electric vehicle or the like.

Conventionally, a so-called IPM motor in which a plurality of permanent magnets are arranged at predetermined intervals in a circumferential direction inside a rotor core has been known as a rotor used in a rotating electric machine. As a means for fixing a permanent magnet to a rotor core in such an IPM motor, for example, techniques described in Patent Literature 1 and Patent Literature 2 are known.

Patent Document 1 discloses a configuration in which a hole for caulking is provided on the outer diameter side of a rotor, the rotor core is caulked with a rivet pin, and the rotor core is deformed by pressing, thereby fixing the rotor core and the arc magnet in surface contact. ing.

In Patent Literature 2, when viewed from the front of the rotor core, the rotor core and the permanent magnet are fixed by contacting the circumferential end surfaces of the arc magnet with support protrusions provided near both circumferential end portions of the magnet insertion hole. An arrangement is disclosed.

Japanese Patent Application Laid-Open No. 2007-306688 Japanese Patent Application Laid-Open No. 2014-100048

However, in the rotors of the rotating electric machines disclosed in Patent Documents 1 and 2, the outer diameter surface of the arc magnet and the outer diameter side wall surface of the magnet insertion hole of the rotor core abut at the center in the circumferential direction of the arc magnet. Therefore, if there is a manufacturing error in the arc magnet, when the rotor rotates at high speed, the centrifugal force of the permanent magnet may cause excessive stress on the outer peripheral surface of the rotor core.

On the other hand, a permanent magnet having a curved surface, such as a circular arc magnet, is more difficult to process than a flat plate magnet having a flat surface, and has low dimensional accuracy. In order to prevent the magnet insertion hole from coming into contact with the outer diameter side wall surface, the magnet insertion hole needs to be sufficiently larger than the arc magnet. However, the larger the gap between the arc magnet and the magnet insertion hole, the lower the output performance of the rotating electric machine.

The present invention provides a rotor for a rotating electrical machine that can prevent the occurrence of excessive centrifugal stress on the outer peripheral surface of a rotor core during rotation of the rotor while suppressing a decrease in output performance of the rotating electrical machine.

The present invention
A substantially annular rotor core having a plurality of magnet insertion holes formed along a circumferential direction,
A plurality of permanent magnets inserted into the plurality of magnet insertion holes,
The permanent magnet has an inner diameter side curved surface curved in a radially inward convex shape on the inner diameter surface, and an outer diameter side curved surface curved in a radially inward convex shape on the outer diameter surface,
The magnet insertion hole has an inner diameter side wall surface facing the inner diameter side curved surface of the permanent magnet, and an outer diameter side wall surface facing the outer diameter side curved surface of the permanent magnet. So,
The permanent magnet has an inner diameter side flat portion at a circumferential center of the inner diameter side curved surface,
The magnet insertion hole has an inner diameter side flat wall surface facing the inner diameter side flat portion of the permanent magnet on the inner diameter side wall surface,
In a state where the inner diameter side flat portion of the permanent magnet and the inner diameter side flat wall surface of the magnet insertion hole are in direct or indirect contact with each other, at the circumferential center of the permanent magnet, A gap is provided between the outer diameter side curved surface and the outer diameter side wall surface of the magnet insertion hole.

According to the present invention, it is possible to prevent the occurrence of excessive centrifugal stress on the outer peripheral surface of the rotor core during rotation of the rotor, while suppressing a decrease in output performance of the rotating electric machine.

FIG. 2 is a front view of the rotor of the rotary electric machine according to the first embodiment of the present invention. FIG. 2 is an enlarged view around an outer diameter side magnet portion of FIG. 1. It is an enlarged drawing of the circumference of the outside diameter side magnet part of the rotor of the rotary electric machine of a 2nd embodiment of the present invention.

Hereinafter, embodiments of the rotor of the rotating electric machine according to the present invention will be described with reference to the accompanying drawings.

First, the rotor of the rotary electric machine according to the first embodiment of the present invention will be described with reference to FIGS.

As shown in FIG. 1, a rotor 10 of a rotary electric machine according to one embodiment includes a rotor core 20 attached to an outer peripheral portion of a rotor shaft (not shown), and a plurality of rotor cores 20 formed inside the rotor core 20 at predetermined intervals in a circumferential direction. (In this embodiment, twelve), and is disposed on the inner peripheral side of a stator (not shown).

The rotor core 20 is formed by laminating a plurality of substantially annular electromagnetic steel sheets 200 having the same shape in the axial direction. The rotor core 20 has a rotor shaft hole 21 that is concentric with the center of the circular ring C. Further, the center axis of each magnetic pole part 30 connecting the center of the circular ring C and the center of each magnetic pole part 30 is d-axis (d-axis in the figure), and the axis separated by 90 ° in electrical angle from the d-axis is q-axis. In the case of (q-axis in the drawing), the rotor core 20 has an outer diameter side magnet insertion hole 410 formed across the d axis on the outer diameter side of the rotor core 20 so as to correspond to each magnetic pole portion 30; A pair of inner magnet-side magnet insertion holes 421 and 422 formed in a substantially C-shape extending radially outward across the d-axis on the inner-diameter side of the outer-magnet-side magnet insertion hole 410, and an inner-magnet-side magnet insertion hole 421. , 422, each having a pair of ribs 510, 520 extending in the radial direction, and a gap 60 formed between the pair of ribs 510, 520. Each of the outer-diameter magnet insertion holes 410 and the inner-diameter magnet insertion holes 421 and 422 has an arc shape that is convex inward in the radial direction.

Each magnetic pole part 30 has a magnet part 300 including an outer diameter side magnet part 310 and an inner diameter side magnet part 320. The outer diameter side magnet part 310 is inserted into the outer diameter side magnet insertion hole 410, and includes an outer diameter side permanent magnet 810 arranged so as to be convex inward in the radial direction. The inner diameter side magnet part 320 is inserted into a pair of inner diameter side magnet insertion holes 421, 422, respectively, and is constituted by a pair of inner diameter side permanent magnets 821, 822 arranged so as to protrude radially inward.

The outer diameter side permanent magnet 810 and the pair of inner diameter side permanent magnets 821 and 822 are magnetized in the radial direction. Further, the outer diameter side permanent magnet 810 and the pair of inner diameter side permanent magnets 821 and 822 have different magnetization directions from the adjacent magnetic pole portions 30, and are arranged such that the magnetic pole portions 30 alternately have different magnetization directions in the circumferential direction. .

Here, in the front view of the rotor 10, when the annular center C is viewed downward and the outer diameter side in the d-axis direction is viewed upward, the pair of inner-diameter-side magnet insertion holes 421 and 422 are located on the left side with respect to the d axis. The inner diameter side magnet insertion hole 421, the second inner diameter side magnet insertion hole 422 is disposed on the right side, and the pair of ribs 510 and 520 are arranged with the first rib 510 on the left side and the second rib 520 on the right side with the d axis interposed therebetween. The pair of inner diameter side permanent magnets 821 and 822 have a first inner diameter side permanent magnet 821 on the left side and a second inner diameter side permanent magnet 822 on the right side with respect to the d-axis.

Further, the distance D11 between the first inner permanent magnet 821 and the outer permanent magnet 810 and the distance D12 between the second inner permanent magnet 822 and the outer permanent magnet 810 are all changed from the q axis to the d axis. It gets longer as you get closer.

(4) Since the circumferential length of the magnetic pole portion 30 can be suppressed from increasing, the rotor 10 can be prevented from increasing in size. Further, a magnetic path along the q-axis (hereinafter, also referred to as a q-axis magnetic path) in the rotor 10 can be widened and the reluctance torque of the rotating electric machine can be increased, so that the output performance of the rotating electric machine can be improved. Further, the magnetic flux generated by the first inner diameter side permanent magnet 821 and the second inner diameter side permanent magnet 822 and the outer diameter side permanent magnet 810 is easily concentrated on the d-axis, and the magnet torque of the rotating electric machine can be efficiently used. The output performance of the rotating electric machine can be improved.

Hereinafter, in the present specification and the like, for simplicity and clarity of description, in the front view of the rotor 10, the annular center C is defined as lower, and the outer diameter side in the d-axis direction is defined as upper. 2 and 3, the upper part of the rotor 10 is indicated by U, the lower part by D, the left side by L, and the right side by R.

As shown in FIG. 2, the outer diameter side permanent magnet 810 has a circumferential central portion 810C, a circumferential left end portion 810L, and a circumferential right end portion 810R formed integrally with each other, and has a radial inner side having the same arc center C10. An inner diameter side curved surface 811 and an outer diameter side curved surface 812 having an arc shape convex toward the right side, a left end surface 813, and a right end surface 814. Furthermore, an inner diameter side flat portion 815 formed in a direction substantially perpendicular to the d axis is provided at a circumferential central portion 810C of the inner diameter side curved surface 811 of the outer diameter side permanent magnet 810. In addition, the outer diameter side left end flat portion 816 and the outer diameter right right end flat portion 816 formed in a direction substantially perpendicular to the d-axis are provided on both circumferential end portions 810L and 810R of the outer diameter side curved surface 812 of the outer diameter side permanent magnet 810. A part 817 is provided. In the present embodiment, the inner diameter side flat portion 815 of the outer diameter side permanent magnet 810 is formed so as to cut out the circumferential central portion 810C of the inner diameter side curved surface 811 of the outer diameter side permanent magnet 810.

The outer-diameter magnet insertion hole 410 has an arc-shaped inner wall surface 411 that faces the inner-diameter curved surface 811 of the outer-diameter permanent magnet 810, and an arc that faces the outer-diameter curved surface 812 of the outer-diameter permanent magnet 810. It has an outer diameter side wall surface 412, a left wall surface 413, and a right wall surface 414. Further, an inner diameter side flat wall surface 415 facing the inner diameter side flat portion 815 of the outer diameter side permanent magnet 810 is provided at a circumferential center of the inner diameter side wall surface 411 of the outer diameter side magnet insertion hole 410. The outer diameter side opposed to the outer diameter side left end flat portion 816 and the outer diameter side right end flat portion 817 of the outer diameter side permanent magnet 810 are provided at both circumferential ends of the outer diameter side wall surface 412 of the outer diameter side magnet insertion hole 410. A side left end flat wall surface 416 and an outer diameter side right end flat wall surface 417 are provided.

Here, the length L85 of the inner diameter side flat portion 815 of the outer diameter side permanent magnet 810 is shorter than the length L45 of the inner diameter side flat wall surface 415 of the outer diameter side magnet insertion hole 410. The arc radius r10 of the outer diameter curved surface 812 of the outer diameter permanent magnet 810 is smaller than the arc radius r42 of the outer diameter side wall surface 412 of the outer diameter magnet insertion hole 410.

発 泡 Furthermore, a foam sheet 90 is provided between the inner diameter side flat portion 815 of the outer diameter side permanent magnet 810 and the inner diameter side flat wall surface 415 of the outer diameter side magnet insertion hole 410.

At the time of manufacturing the rotor 10, after the foam sheet 90 is attached to the flat portion 815 on the inner diameter side of the outer permanent magnet 810, the outer permanent magnet 810 is inserted into the outer magnet insertion hole 410 and foamed by heating or the like. The sheet 90 is foamed. When the foam sheet 90 foams, the outer diameter side permanent magnet 810 is pressed to the outer diameter side, and the outer diameter side curved surface 812 is in contact with the outer diameter side wall surface 412 of the outer diameter side magnet insertion hole 410. Are fixed to the rotor core 20.

The length L85 of the inner diameter side flat portion 815 of the outer diameter side permanent magnet 810 is shorter than the length L45 of the inner diameter side flat wall surface 415 of the outer diameter side magnet insertion hole 410. The inner diameter side flat portion 815 indirectly contacts the inner diameter side flat wall surface 415 of the outer diameter side magnet insertion hole 410 with the foam sheet 90 interposed therebetween.

As a result, the contact surface between the inner diameter side flat portion 815 of the outer diameter side permanent magnet 810 and the inner diameter side flat wall surface 415 of the outer diameter side magnet insertion hole 410 is stabilized, so that the outer diameter side permanent magnet 810 is fixed to the rotor core 20. The variation in the position to be performed can be reduced.

Further, since the length L85 of the inner diameter side flat portion 815 of the outer diameter side permanent magnet 810 is shorter than the length L45 of the inner diameter side flat wall surface 415 of the outer diameter side magnet insertion hole 410, the outer diameter side permanent magnet 810 can be easily inserted into the outer diameter side magnet insertion hole 410, and productivity is improved.

Further, since the foam sheet 90 is provided between the inner diameter side flat portion 815 of the outer diameter side permanent magnet 810 and the inner diameter side flat wall surface 415 of the outer diameter side magnet insertion hole 410, when the rotor 10 is manufactured, What is necessary is just to stick the foamed sheet 90 to the inner side flat part 815 of the radial side permanent magnet 810, the positioning of the foamed sheet 90 is easy, and productivity is improved.

Further, an outer diameter side left end flat portion 816 and an outer diameter side right end flat portion 817 are provided at both circumferential end portions 810 </ b> L and 810 </ b> R of the outer diameter side curved surface 812 of the outer diameter side permanent magnet 810. At both ends in the circumferential direction of the outer diameter side wall surface 412 of the magnet insertion hole 410, the outer diameter side left end flat wall surface 416 facing the outer diameter left end flat portion 816 and the outer diameter right end flat portion 817 of the outer diameter permanent magnet 810. Since the outer diameter side right end flat wall surface 417 is provided, when the outer diameter side permanent magnet 810 is pressed to the outer diameter side by foaming of the foam sheet 90, the outer diameter side permanent magnet 810 becomes the outer diameter side. The left side flat end portion 816 and the outer side right end flat portion 817 are fixed to the rotor core 20 in a state of contacting the outer side left end flat wall surface 416 and the outer side right end flat wall surface 417 of the outer side magnet insertion hole 410. You.

に よ り Thereby, the variation in the position where the outer diameter side permanent magnet 810 contacts the outer diameter side magnet insertion hole 410 can be reduced. Further, since the foam sheet 90 attached to the inner diameter side flat portion 815 foams, it is possible to reduce variation in the pressing direction of the outer diameter side permanent magnet 810 toward the outer diameter side. Therefore, variation in the position where the outer diameter side permanent magnet 810 is fixed to the rotor core 20 can be reduced.

Further, the outer diameter side permanent magnet 810 can be fixed to the rotor core 20 without having to inject resin or the like into the outer diameter side magnet insertion hole 410.

Further, since the outer diameter side permanent magnet 810 is pressed to the outer diameter side and fixed to the rotor core 20, the outer diameter side permanent magnet 810 can be disposed on the outer diameter side, and the output performance of the rotating electric machine can be improved. Can be improved.

In addition, since the foamed sheet 90 is attached to the inner flat portion 815 of the outer permanent magnet 810, when the outer permanent magnet 810 is inserted into the outer magnet insertion hole 410 in manufacturing the rotor 10. In addition, the foam sheet 90 can be prevented from peeling off from the outer diameter side permanent magnet 810. Further, the positioning of the foam sheet 90 is easy when manufacturing the rotor 10, and the productivity is improved.

A gap G is formed between the outer curved surface 812 of the outer permanent magnet 810 and the outer wall surface 412 of the outer magnet insertion hole 410 at the center 810C in the circumferential direction of the outer permanent magnet 810. Is provided.

As a result, the outer diameter side permanent magnet 810 and the outer diameter side magnet insertion hole 410 do not come into contact with each other at the circumferential central portion 810C of the outer diameter side permanent magnet 810, so that the outer peripheral surface of the rotor core 20 is excessively large when the rotor 10 rotates. Generation of centrifugal stress can be avoided. Furthermore, the deformation of the outer diameter side permanent magnet 810 and the rotor core 20 can be allowed by the gap G, so that the thermal stress of the outer diameter side permanent magnet 810 and the rotor core 20 can be reduced.

Further, since the arc radius r10 of the outer diameter side curved surface 812 of the outer diameter side permanent magnet 810 is smaller than the arc radius r42 of the outer diameter side wall surface 412 of the outer diameter side magnet insertion hole 410, the outer diameter side permanent magnet At the circumferential center 810C of the magnet 810, a gap G is securely secured between the outer curved surface 812 of the outer permanent magnet 810 and the outer sidewall 412 of the outer magnet insertion hole 410. it can.

In addition, the inner diameter side flat portion 815, the outer diameter side left end flat portion 816, and the outer diameter side right end flat portion 817 of the outer diameter side permanent magnet 810 can be formed by any method, for example, by cutting a circular arc magnet. . A flat surface can be processed with higher precision than a curved surface such as an arc shape. For this reason, the outer diameter side permanent magnet 810 having the inner diameter side flat portion 815, the outer diameter side left end flat portion 816, and the outer diameter side right end flat portion 817 has higher dimensional accuracy than a normal arc magnet.

This allows the outer diameter side magnet insertion hole 410 to be reduced in size, thereby suppressing a decrease in output performance of the rotating electric machine.

Here, the outer diameter side permanent magnet 810, the first inner diameter side permanent magnet 821, and the second inner diameter side permanent magnet 822 are formed by, for example, cutting a ring-shaped magnet formed by molding using a hot working process in the radial direction. Arc magnets can be used.

In general, when forming a ring-shaped magnet by molding using a hot working process such as hot extrusion, by hot extrusion, the crystal group of the ring-shaped magnet material that has been randomly oriented is radially oriented. The compressive stress acts, and the crystal group of the ring-shaped magnet material is oriented in the same direction as the compressive stress direction. As a result, an anisotropic ring-shaped magnet oriented in the radial direction is obtained.

Therefore, in order to obtain a ring-shaped magnet having high-performance magnetization characteristics, it is desirable that the stress acting on the crystal group of the ring-shaped magnet material be uniform over the entire region. However, when the ring radius of the ring-shaped magnet material is small and the wall thickness of the ring-shaped magnet material is large, the stress acting on the crystal group of the ring-shaped magnet material becomes non-uniform, and the degree of orientation of the ring-shaped magnet decreases. I will. Also, when the thickness of the ring-shaped magnet material is not uniform, the stress acting on the crystals of the ring-shaped magnet material becomes uneven, and the degree of orientation of the ring-shaped magnet is reduced. Therefore, in order for the stress acting on the crystal group of the ring-shaped magnet material to be uniform over the entire region, the value of (thickness of the ring-shaped magnet material) / (ring radius of the ring-shaped magnet material) must be within a predetermined range. In order to increase the number of arc magnets in order to arrange arc magnets having high-performance magnetization characteristics in a plurality of layers, it is necessary to increase the arc radius of the arc magnet in accordance with the plate thickness.

The plate thickness d21 of the first inner permanent magnet 821 and the plate thickness d22 of the second inner permanent magnet 822 are larger than the plate thickness d10 of the outer permanent magnet 810. Thereby, the magnet amount of the first inner diameter side permanent magnet 821 and the second inner diameter side permanent magnet 822 can be increased, and the magnet torque of the rotating electric machine can be increased, so that the output performance of the rotating electric machine can be improved.

In addition, as the plate thickness d21 of the first inner permanent magnet 821 and the plate thickness d22 of the second inner permanent magnet 822 are increased, the arc radius r21 of the first inner permanent magnet 821 and the second inner permanent magnet 822 are increased. The arc radius r22 is larger than the arc radius r10 of the outer diameter side permanent magnet 810. Thus, the outer diameter side permanent magnet 810, the first inner diameter side permanent magnet 821, and the second inner diameter side permanent magnet 822 having high performance magnetization characteristics can be used, so that the output performance of the rotating electric machine can be improved. Note that the arc radius r10 of the outer diameter side permanent magnet 810, the arc radius r21 of the first inner diameter side permanent magnet 821, and the arc radius r22 of the second inner diameter side permanent magnet 822 are the arc surfaces from the center of the arc to the inner circumference of the permanent magnet. Length.

Here, d10 / r10, which is the ratio of the arc radius r10 of the outer diameter side permanent magnet 810 to the plate thickness d10 of the outer diameter side permanent magnet 810, the arc radius r21 of the first inner diameter side permanent magnet 821, and the first D21 / r21, which is the ratio of the plate thickness d21 of the inner diameter side permanent magnet 821, the arc radius r22 of the second inner side permanent magnet 822, and d22 / r, which is the ratio of the plate thickness d22 of the second inner side permanent magnet 822. r22 is preferably substantially the same value within a predetermined range. More preferably, the arc radius r21 of the first inner permanent magnet 821 and the arc radius r22 of the second inner permanent magnet 822 are the same, and the plate thickness d21 of the first inner permanent magnet 821 and the second inner permanent magnet 821 are equal. The plate thickness d22 of the magnets 822 is the same, and the first inner permanent magnet 821 and the second inner permanent magnet 822 have the same shape.

[Second embodiment]
Next, a rotor 10 according to a second embodiment of the present invention will be described with reference to FIG. In the following description, the same components as those of the rotor 10 of the first embodiment will be denoted by the same reference numerals, and the description thereof will be omitted or simplified. Differences from the rotor 10 of the first embodiment will be described in detail. I do. The inner diameter side flat portion 815 of the outer diameter side permanent magnet 810 of the first embodiment has a shape in which a circumferential central portion 810C of the inner diameter side curved surface 811 of the outer diameter side permanent magnet 810 is cut out.

On the other hand, as shown in FIG. 3, the inner diameter side flat portion 815 of the outer diameter side permanent magnet 810 of this embodiment is formed so as to protrude radially inward from the inner diameter side curved surface 811 of the outer diameter side permanent magnet 810. ing.

Thereby, the inner diameter side flat portion 815 can be formed without reducing the magnet amount of the outer diameter side permanent magnet 810, so that the inner diameter side flat portion 815 can be formed without lowering the output performance of the rotating electric machine. it can.

The above-described embodiment can be appropriately modified, improved, and the like.

For example, in the first embodiment and the second embodiment, the inner radius side curved surface 811 and the outer radius side curved surface 812 of the outer radius side permanent magnet 810 are arcs having the same arc center C10 and projecting radially inward. For example, in the outer diameter side permanent magnet 810, the arc radius of the inner diameter side curved surface 811 is larger than the arc radius of the outer diameter side curved surface 812. It may be a substantially crescent shape in which the plate thickness decreases from the central portion 810C in the direction toward both ends 810L and 810R in the circumferential direction. Further, the inner diameter side curved surface 811 and the outer diameter side curved surface 812 of the outer diameter side permanent magnet 810 are not limited to the arc shape, and may have any shape curved convexly inward in the radial direction. .

In the first embodiment and the second embodiment, the outer diameter side permanent magnet 810 has been described. However, the first inner diameter side permanent magnet 821 and the second inner diameter side permanent magnet 822 are similar to the outer diameter side permanent magnet 810. May be provided. Furthermore, in the first embodiment and the second embodiment, the first inner permanent magnet 821 and the second inner permanent magnet 822 of the inner magnet portion 320 can be omitted. That is, the magnet unit 300 may be composed of only the outer permanent magnet 810 of the outer magnet unit 310.

少 な く と も In addition, at least the following matters are described in this specification. In addition, although the corresponding components in the above-described embodiment are shown in parentheses, the present invention is not limited to this.

(1) a substantially annular rotor core (rotor core 20) having a plurality of magnet insertion holes (outer diameter side magnet insertion holes 410) formed along the circumferential direction;
A plurality of permanent magnets (outside diameter permanent magnets 810) inserted into the plurality of magnet insertion holes,
The permanent magnet has an inner diameter side curved surface (inner diameter side curved surface 811) curved radially inwardly convex on the inner diameter surface, and an outer diameter side curved surface (outside diameter curved surface) curved radially inwardly convexly on the outer diameter surface. And a radially curved surface 812).
The magnet insertion hole has an inner diameter side wall surface (inner diameter side surface 411) facing the inner diameter side curved surface of the permanent magnet, and an outer diameter side wall surface (outside diameter side) facing the outer diameter side curved surface of the permanent magnet. A wall surface 412) of the rotating electric machine (rotor 10),
The permanent magnet has an inner diameter side flat portion (inner diameter side flat portion 815) at a circumferential center portion (a circumferential center portion 810C) of the inner diameter side curved surface,
The magnet insertion hole has an inner diameter side flat wall surface (inner diameter side flat wall surface 415) facing the inner diameter side flat portion of the permanent magnet on the inner diameter side wall surface,
In a state where the inner diameter side flat portion of the permanent magnet and the inner diameter side flat wall surface of the magnet insertion hole are in direct or indirect contact with each other, the permanent magnet is positioned at a circumferential central portion (a circumferential central portion 810C). A rotor for a rotating electric machine, wherein a gap (gap G) is provided between the outer diameter side curved surface of the permanent magnet and the outer diameter side wall surface of the magnet insertion hole.

According to (1), a gap is provided between the outer diameter side curved surface of the permanent magnet and the outer diameter side wall surface of the magnet insertion hole at the circumferential center of the permanent magnet. At the center in the circumferential direction, the permanent magnet does not contact the magnet insertion hole. Thereby, it is possible to avoid occurrence of excessive centrifugal stress on the outer peripheral surface of the rotor core when the rotor rotates. Further, since the deformation of the permanent magnet and the rotor core can be allowed by the gap, the thermal stress of the permanent magnet and the rotor core can be reduced.
Further, the inner diameter surface of the permanent magnet has an inner diameter side flat surface provided at a circumferential center portion, and the inner diameter side wall surface of the magnet insertion hole is provided at an inner diameter flat surface provided at a circumferential center portion of the magnet insertion hole. Having. Since the flat surface can be processed with high accuracy, the dimensional accuracy of the permanent magnet and the magnet insertion hole is improved. As a result, the magnet insertion hole can be made smaller, and a decrease in output performance of the rotating electric machine can be suppressed.

(2) The rotor of the rotary electric machine according to (1),
Seen from the front of the rotor core,
The length of the inner diameter side flat portion (length L85) of the permanent magnet is shorter than the length of the inner diameter side flat wall surface (length L45) of the magnet insertion hole.

According to (2), the length of the inner diameter side flat portion of the permanent magnet is shorter than the length of the inner diameter side flat wall surface of the magnet insertion hole, so that the permanent magnet is inserted into the outer diameter side magnet insertion hole. And the productivity is improved.
In addition, since the length of the inner diameter side flat portion of the permanent magnet is shorter than the length of the inner diameter side flat wall surface of the magnet insertion hole, the inner diameter side flat portion of the permanent magnet is reliably directly or indirectly magnetized. It comes into contact with the flat wall surface on the inner diameter side of the insertion hole. This stabilizes the contact surface between the inner-diameter flat portion of the permanent magnet and the inner-diameter flat wall surface of the magnet insertion hole, thereby reducing the variation in the position where the permanent magnet is fixed to the rotor core.

(3) The rotor of the rotary electric machine according to (1) or (2),
A rotor for a rotating electric machine, wherein a foamed sheet (foamed sheet 90) is provided between the inner diameter side flat portion of the permanent magnet and the inner diameter side flat wall surface of the magnet insertion hole.

According to (3), since the foamed sheet is provided between the inner diameter side flat portion of the permanent magnet and the inner diameter side flat wall surface of the magnet insertion hole, the positioning of the foamed sheet is easy in manufacturing the rotor. , And productivity is improved. Furthermore, since the foam sheet arranged on the flat surface foams, it is possible to reduce variation in the position where the permanent magnet abuts on the outer diameter side wall surface of the magnet insertion hole. Thus, it is possible to reduce variation in the position where the permanent magnet is fixed to the rotor core.

(4) The rotor of the rotary electric machine according to any one of (1) to (3),
The outer diameter side curved surface of the permanent magnet has a circular arc shape convex toward the radially inward side,
The outer diameter side wall surface of the magnet insertion hole has an arc shape convex toward the radially inward side,
The rotor of the rotating electric machine, wherein an arc radius (arc radius r10) of the outer diameter side curved surface of the permanent magnet is smaller than an arc radius (arc radius r42) of the outer diameter side wall surface of the magnet insertion hole.

According to (4), the radius of the arc of the outer diameter side curved surface of the permanent magnet is smaller than the radius of the arc of the outer diameter side wall surface of the magnet insertion hole. Between the outer diameter side curved surface and the outer diameter side wall surface of the magnet insertion hole.

(5) The rotor of the rotary electric machine according to any one of (1) to (4),
At both ends in the circumferential direction (both ends 810L and 810R in the circumferential direction) of the outer diameter side curved surface of the permanent magnet, outer diameter side flat portions (outer diameter left end flat portion 816, outer diameter right right end flat portion 817) are provided. Is provided,
A rotor of a rotating electric machine, wherein outer peripheral side flat wall surfaces (outer radial side left end flat wall surface 416, outer radial side right end flat wall surface 417) are provided at both circumferential end portions of the outer diameter side wall surface of the magnet insertion hole. .

According to (5), outer diameter side flat surfaces are provided at both ends in the circumferential direction of the outer diameter side curved surface of the permanent magnet, and at both ends in the circumferential direction of the outer diameter side wall surface of the magnet insertion hole, Since the outer diameter side flat wall surface is provided, when the permanent magnet moves to the outer diameter side, the outer diameter side flat portion of the permanent magnet comes into contact with the outer diameter side flat wall surface of the magnet insertion hole. Thereby, the variation in the position where the permanent magnet contacts the magnet insertion hole can be reduced, and the variation in the position where the permanent magnet is fixed to the rotor core can be reduced.

(6) The rotor of the rotary electric machine according to any one of (1) to (5),
The rotor of the rotating electric machine, wherein the inner diameter side flat portion of the permanent magnet is formed to protrude radially inward from the inner diameter side curved surface of the permanent magnet.

According to (6), the flat portion on the inner diameter side of the permanent magnet is formed so as to protrude radially inward from the curved surface on the inner diameter side of the permanent magnet. A part can be formed.

This application is based on a Japanese patent application filed on Sep. 28, 2018 (Japanese Patent Application No. 2018-185522), the contents of which are incorporated herein by reference.

10 Rotor 20 Rotor core 410 Outer diameter side magnet insertion hole (magnet insertion hole)
411 inner diameter side wall surface 412 outer diameter side wall surface 415 inner diameter side flat wall surface 416 outer diameter side left end flat wall surface (outer diameter side flat wall surface)
417 Outer diameter side right end flat wall surface (outer diameter side flat wall surface)
810 Outer diameter side permanent magnet (permanent magnet)
810C Circumferential center part 810L Circumferential left end (both circumferential ends)
810R Circumferential right end (circumferential ends)
811 inner diameter side curved surface 812 outer diameter side curved surface 815 inner diameter side flat portion 816 outer diameter side left end flat portion (outside diameter flat portion)
817 Outer diameter side right end flat part (outer diameter side flat part)
90 Foam sheet G Gap L45, L85 Length r10, r42 Arc radius

Claims (6)

1. A substantially annular rotor core having a plurality of magnet insertion holes formed along a circumferential direction,
   A plurality of permanent magnets inserted into the plurality of magnet insertion holes,
   The permanent magnet has an inner diameter side curved surface curved in a radially inward convex shape on the inner diameter surface, and an outer diameter side curved surface curved in a radially inward convex shape on the outer diameter surface,
   The magnet insertion hole has an inner diameter side wall surface facing the inner diameter side curved surface of the permanent magnet, and an outer diameter side wall surface facing the outer diameter side curved surface of the permanent magnet. So,
   The permanent magnet has an inner diameter side flat portion at a circumferential center of the inner diameter side curved surface,
   The magnet insertion hole has an inner diameter side flat wall surface facing the inner diameter side flat portion of the permanent magnet on the inner diameter side wall surface,
   In a state where the inner diameter side flat portion of the permanent magnet and the inner diameter side flat wall surface of the magnet insertion hole are in direct or indirect contact with each other, at the circumferential center of the permanent magnet, A rotor for a rotating electric machine, wherein a gap is provided between an outer diameter side curved surface and the outer diameter side wall surface of the magnet insertion hole.
2. It is a rotor of the rotary electric machine according to claim 1, wherein
   Seen from the front of the rotor core,
   The rotor of the rotating electric machine, wherein a length of the inner diameter side flat portion of the permanent magnet is shorter than a length of the inner diameter side flat wall surface of the magnet insertion hole.
3. It is a rotor of the rotating electric machine according to claim 1 or 2,
   A rotor for a rotating electric machine, wherein a foam sheet is provided between the inner diameter side flat portion of the permanent magnet and the inner diameter side flat wall surface of the magnet insertion hole.
4. The rotating electric machine rotor according to any one of claims 1 to 3, wherein
   The outer diameter side curved surface of the permanent magnet has a circular arc shape convex toward the radially inward side,
   The outer diameter side wall surface of the magnet insertion hole has an arc shape convex toward the radially inward side,
   The rotor of the rotating electric machine, wherein an arc radius of the outer diameter side curved surface of the permanent magnet is smaller than an arc radius of the outer diameter side wall surface of the magnet insertion hole.
5. The rotor of the rotating electric machine according to any one of claims 1 to 4, wherein
   At both ends in the circumferential direction of the outer diameter side curved surface of the permanent magnet, an outer diameter side flat portion is provided,
   A rotor for a rotating electric machine, wherein outer peripheral side flat wall surfaces are provided at both circumferential ends of the outer peripheral side wall surface of the magnet insertion hole.
6. The rotor of the rotating electric machine according to any one of claims 1 to 5, wherein
   The rotor of the rotating electric machine, wherein the inner diameter side flat portion of the permanent magnet is formed to protrude radially inward from the inner diameter side curved surface of the permanent magnet.

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