Permanent magnet type rotor and method of manufacturing the rotor Number:7,151,334 from the United States Patent and Trademark Office (PTO) owispatent A permanent magnet type rotor comprises an inner member 2 having an outer ring portion 21; an approximately annular outer member 1 having soft magnetism and an inner circumference contacting with an outer circumference of the outer ring portion; and plural permanent magnets 3 disposed at equal intervals on the outer circumference of the outer member toward the circumferential direction. At least one of the inner member 2 and the outer member 1 is made from a sintered material, and the inner member 2 and the outer member 1 are mutually sintered and bonded. Thickness and weight of a dynamotor itself can be reduced and high output and high efficiency can be achieved.<H manufacturing, Permanent, Permanent, magne, 7151334.html, Patent, pto, 7151334

Title: Permanent magnet type rotor and method of manufacturing the rotor

Abstract: A permanent magnet type rotor comprises an inner member 2 having an outer ring portion 21; an approximately annular outer member 1 having soft magnetism and an inner circumference contacting with an outer circumference of the outer ring portion; and plural permanent magnets 3 disposed at equal intervals on the outer circumference of the outer member toward the circumferential direction. At least one of the inner member 2 and the outer member 1 is made from a sintered material, and the inner member 2 and the outer member 1 are mutually sintered and bonded. Thickness and weight of a dynamotor itself can be reduced and high output and high efficiency can be achieved.

Patent Number: 7,151,334 Issued on 12/19/2006 to Asaka, et al.

Inventors: Asaka; Kazuo (Matsudo, JP), Arakawa; Tomoaki (Souka, JP), Kagaya; Tsuyoshi (Kashiwa, JP), Shinzaki; Satoru (Wako, JP), Sato; Hiromitsu (Wako, JP), Fukuda; Kenji (Wako, JP), Ogawa; Hirohisa (Wako, JP), Horie; Tatsuro (Wako, JP), Okamura; Akihiro (Wako, JP), Sato; Katsuaki (Wako, JP), Komatsu; Toshiyasu (Wako, JP), Nakahara; Youichi (Wako, JP)
Assignee: Hitachi Powdered Metals Co., Ltd. (Chiba, JP)
Honda Giken Kogyo Kabushiki Kaisha (Tokyo, JP)

Appl. No.: 10/432,607

Filed: September 3, 2002

PCT Filed: September 03, 2002

PCT No.: PCT/JP02/08937

371(c)(1),(2),(4) Date: June 03, 2003

PCT Pub. No.: WO03/021742

PCT Pub. Date: March 13, 2003

Foreign Application Priority Data


Sep 03, 2001 [JP]			2001-266327
Dec 12, 2001 [JP]			2001-378260

Current U.S. Class: 310/156.12 ; 310/156.26; 310/44

Current International Class: H02K 21/12 (20060101)

Field of Search: 310/156.08,156.12-156.15,156.26,156.28,156.29,156.31,44 29/596,598,602.1

References Cited [Referenced By]

U.S. Patent Documents


4641422	February 1987	Weaver
4841186	June 1989	Feigel et al.
5001607	March 1991	Breithaupt
5040286	August 1991	Stark
5190102	March 1993	Arterbury et al.
5402024	March 1995	Watanabe et al.
5500994	March 1996	Itaya
5722032	February 1998	Gay
5881447	March 1999	Molnar
6057621	May 2000	Suzuki et al.
6144130	November 2000	Kawamura
6489696	December 2002	Sashino et al.
2003/0019106	January 2003	Pope et al.
2003/0110617	June 2003	Reppel et al.

Foreign Patent Documents


28 24 257 A 1	Dec., 1979	DE
0 854 558	Jul., 1998	EP
1 424 761	Jun., 2004	EP
58-165653	Sep., 1983	JP
59-95783	Jun., 1984	JP
63056906	Mar., 1988	JP
05260710	Oct., 1993	JP
09-093842	Apr., 1997	JP
09-191589	Jul., 1997	JP
2001-169485	Jun., 2001	JP
2001-178043	Jun., 2001	JP
2001-346345	Dec., 2001	JP
2002-34188	Jan., 2002	JP
2002-159150	May., 2002	JP

Primary Examiner: Nguyen; Tran
Attorney, Agent or Firm: Arent Fox PLLC

Claims

The invention claimed is:

1. A permanent magnet type rotor comprising: an inner member having an outer ring portion; an approximately annular outer member having soft magnetism and an inner circumference contacting an outer circumference of the outer ring portion; and a plurality of permanent magnets disposed at equal intervals along an outer circumference of the outer member toward the circumferential direction; wherein at least one of the inner member and the outer member is made from a sintered material, wherein the inner member and the outer member are mutually diffusion-bonded together by sintering, and wherein the inner member comprises an inner ring portion having one of a shaft or a through hole for a shaft, and is composed by connecting the outer ring portion and the inner ring portion by at least one rib.

2. The permanent magnet type rotor according to claim 1, wherein the at least one rib includes a plurality of connecting ribs disposed at equal intervals in a circumferential direction, and the plurality of permanent magnets are disposed on the outer circumference of the outer member at the connecting ribs of the inner member respectively.

3. The permanent magnet type rotor according to claim 1, wherein the outer member is composed of an ingot steel having a magnetic characteristic of saturated magnetic flux density of 1.0 T or more.

4. The permanent magnet type rotor according to claim 1, wherein the inner member is formed from any one of an ingot steel, a green compact, or a ferrous sintered material containing carbon.

5. A permanent magnet type rotor comprising: an inner member having an outer ring portion; an approximately annular outer member having soft magnetism and an inner circumference contacting an outer circumference of the outer ring portion; and a plurality of permanent magnets disposed at equal intervals along an outer circumference of the outer member toward the circumferential direction; wherein at least one of the inner member and the outer member is made from a sintered material, wherein the inner member and the outer member are mutually diffusion-bonded together by sintering, wherein the outer member is composed of a ferrous sintered material containing C: 0.3% by mass or less, a balance of Fe, and inevitable impurities, and wherein the ferrous sintered material further contains at least one of Si: 3.5% by mass or less, P: 0.7% by mass or less, B: 0.35 by mass or less, and Cu: 3.0% by mass or less.

6. A permanent magnet type rotor comprising: an annular outer member composed of a sintered compact; an inner member composed of a sintered compact having a lower density than that of the outer member and an outer circumference contacting with an inner circumference of the outer member; and plural permanent magnets disposed at intervals on the outer circumference of the outer member toward the circumferential direction; the inner member and the outer member being mutually sintered and bonded; the inner member comprising: an inner ring portion; an outer ring portion having an outer circumference contacting with an inner circumference of the outer member; and plural radial ribs radially arranged so as to connect the ring portions; wherein the outer member has an average thickness less than that of the outer ring portion of the inner member.

7. A permanent magnet type rotor comprising: an annular outer member composed of a sintered compact; an inner member composed of a sintered compact having a lower density than that of the outer member and an outer circumference contacting with an inner circumference of the outer member; and plural permanent magnets disposed at intervals on the outer circumference of the outer member toward the circumferential direction; the inner member and the outer member being mutually sintered and bonded; the inner member comprising: an inner ring portion; an outer ring portion having an outer circumference contacting with an inner circumference of the outer member; and plural radial ribs radially arranged so as to connect the ring portions; wherein the outer member has an average thickness not less than that of the outer ring portion of the inner member, and the contacting area between the radial ribs and the outer ring portion is 10% or more of the area of the inner circumference of the outer ring portion.

8. The permanent magnet type rotor according to claim 6, wherein a circumferential rib extending along the circumferential direction contacting with the outer ring portion is provided between the radial ribs.

9. The permanent magnet type rotor according to claim 8, wherein the circumferential rib has a shape in which the intermediate portion thereof between the radial ribs has the maximum volume.

10. The permanent magnet type rotor according to claim 8, wherein the radial rib is inclined with respect to the circumferential direction of the rotor.

Description

FIELD OF THE INVENTION

The present invention relates to a permanent magnet type rotor having a permanent magnet disposed on a rotor surface, and relates to a manufacturing method therefor, and more particularly, the present invention relates to a technology for enhancing the magnetic characteristics and strength of the rotor.

DESCRIPTION OF THE RELATED ART

A permanent magnet type rotor used in a dynamotor mounted in an electric vehicle or a hybrid vehicle is required to have magnetic characteristics of high performance and high productivity. As materials for such a permanent magnet type motor, hitherto, silicon steel plate has been used. Since the rotor is tightened and fixed to the engine shaft, it is required to have high strength and hardness in order to be tightened firmly. However, silicon steel plate is brittle and low in strength, and reinforcing measures are required to obtain a necessary strength, and hence, the rotor is increased in its weight and size. It is difficult to employ a hollow shape to reduce the rotor weight since the strength will be insufficient.

For reduction of weight, there is known an example of a hollow shape made by a casting technique such as the lost wax method by using a material equivalent to S45C of the Japanese Industrial Standards. However, the S45C material has a high carbon content, and the magnetic characteristics are insufficient and satisfactory function as a dynamo or a motor cannot be obtained. Therefore, there has been demanded to provide a permanent magnet type rotor in which thickness and weight of the dynamotor itself can be reduced and high output and high efficiency can be achieved.

DISCLOSURE OF THE INVENTION

The present invention provides a permanent magnet type rotor comprising: an inner member having an outer ring portion; an approximately annular outer member having soft magnetism and an inner circumference contacting with an outer circumference of the outer ring portion; and plural permanent magnets disposed at equal intervals on the outer circumference of the outer member toward the circumferential direction; wherein at least one of the inner member and the outer member is made from a sintered material, and the inner member and the outer member are mutually diffusion-bonded together.

In a permanent magnet type rotor having such a configuration, by forming only the outer member for disposing the permanent magnets of a magnetic material and forming the inner member of a material of high strength, a hollow shape can be realized without reducing magnetic characteristics, and a surface magnet type rotor having a reduced weight and high efficiency can be obtained. Moreover, since at least one of the inner member and outer member is made from a sintered material, and the inner member and outer member are mutually diffusion-bonded together, the bonding strength between both is high, and there is no problem if the rotor is mounted to the shaft of an engine which rotates at high speed.

In the invention, since the inner member is made from a material having high strength, the weight can be reduced by forming the inner member in a hollow shape. In this hollow shape, for example, the inner member comprises an inner ring portion having a shaft or a through hole for a shaft, and is formed by connecting the outer ring portion and the inner ring portion by ribs.

In the invention, since the inner member and the outer member are mutually diffusion-bonded together, at least one of the two members may be made from a sintered material. For example, the outer member may be made from an ingot steel, and the inner member may be made from a sintered material. Alternatively, the inner member may be made from an ingot steel, and the outer member may be made from a sintered material.

Both the inner member and the outer member may be made from sintered materials. In this case, in order to perform sintering and bonding, one of the outer member and the inner member may be a sintered material and the other one may be a green compact, alternatively, both may be green compacts, and both may be mutually fitted and sintered. The ribs are preferably composed of plural connecting ribs disposed at equal intervals in the circumferential direction, and the permanent magnets may be respectively disposed on the outer circumference of the outer member at the connecting ribs of the inner member.

In the invention, the composition of the inner member composed of a sintered material is preferably equivalent to class 3, class 4, or class 5 in SMF specified in JIS Z 2550. As the outer member, a suitable material is a pure ferrous sintered material containing C: 0.3% by mass or less, a balance of Fe, and inevitable impurities. The pure ferrous sintered material preferably further contains at least one of Si: 3.5% by mass or less, P: 0.7% by mass or less, B: 0.3% by mass or less, and Cu: 3.0% by mass or less. Aside from these sintered materials, an ingot steel having a magnetic characteristic of saturated magnetic flux density of 1.0 T or more may be also preferably used.

The present invention further provides a manufacturing method for a permanent magnet type rotor, the method comprising: fitting a green compact for an inner member formed by compressing a mixed powder mainly composed of a ferrous alloy powder or an Fe powder and having an outer ring portion into an approximately annular outer member having an inner circumference contacting with an outer circumference of the inner ring portion; sintering both to integrate the inner member and the outer member; and disposing and fixing permanent magnets on the outer circumference of the outer member.

The green compact for the inner member preferably has a shape in which plural connecting ribs disposed at equal intervals toward the circumferential direction connect the outer ring portion and an inner ring portion having a shaft or a through hole for a shaft, and the permanent magnets are respectively disposed on the outer circumference of the outer member at the connecting ribs.

The outer member may be made from an ingot steel having a magnetic characteristic of saturated magnetic flux density of 1.0 T or more. Alternatively, the outer member may be a green compact formed by compressing an outer member forming mixed powder composed of an Fe powder mixed with a forming lubricant. Thus, by using a rigid material (a material other than the green compact) as the outer member, the green compact for the inner member expands more than the outer member during sintering, and a tensile stress occurs in the outer member; therefore, the bonding of both will be more securer. However, the invention is not limited to such manufacturing method, and it is also one of the preferred embodiments to compose the outer member by using a pure ferrous green compact formed by compressing an outer member forming mixed powder composed of an Fe powder mixed with a forming lubricant.

As the outer member, instead of the pure ferrous green compact or pure ferrous sintered compacts, it is also possible to use a ferrous green compact produced by an outer member forming mixed powder which is a mixed powder which is mixed an Fe--P powder, or an Fe powder and an Fe--P powder, and a forming lubricant, with a P content of 0.7% by mass or less, or a ferrous sintered compact formed by sintering such a ferrous green compact. It is further possible to use a ferrous green compact produced by an outer member forming mixed powder which further contains at least one of Si powder, Fe--Si powder, Fe--B powder, iron alloy powder containing B, Cu powder, and Cu--B powder, with a Si content of 3.5% by mass or less, a B content of 0.3% by mass or less, and a Cu content of 3.0% by mass or less, or a ferrous sintered compact formed by sintering such ferrous green compact.

In a manufacturing method for the permanent magnet type rotor of the invention, the green compact for the inner member preferably has a composition in which the thermal expansion of the inner member is greater than that of the outer member in the high temperature range of 800.degree. C. or more during sintering process. Moreover, the inner member is preferably fitted into the outer member along a contacting surface by passing fit with a gap of 5 m or less between the inner diameter of the outer member and the outer diameter of the inner member, or by tightening fit with a tightening interference of within 0.0025 times the diameter of the contacting surface. In addition, green compact for the inner member is preferably formed by using a forming lubricant containing zinc, and is sintered in a carburizing atmosphere.

Preferred embodiments and characteristics of the permanent magnet type rotor of the invention will be more specifically explained hereinafter. In the permanent magnet type rotor of the invention, since both strength and magnetic characteristics are obtained, the inner member requiring strength is made from a ferrous sintered material containing carbon, and the outer member requiring magnetic characteristics is made from a magnetic material. The material for the inner member may be equivalent to class 3, class 4, or class 5 in SMF specified in JIS Z 2550, so that a sufficient strength is obtained. The material for the outer member may be a pure ferrous sintered material or a sintered material containing at least one of Si: 3.5% by mass or less, P: 0.7% by mass or less, B: 0.35 by mass or less, and Cu: 3.0% by mass or less in addition to the pure ferrous composition, so that the magnetic characteristics thereof may be superior. The reasons for limiting these components are as follows.

Si: It is preferable to contain Si since it promotes phase sintering, so that Fe grain becomes coarse and increases the magnetic permeability, and also the specific resistance is increased and the iron loss of magnetic force is decreased. However, if Si is contained excessively, the compressive property is deteriorated, whereby the sintering density decreases and the magnetic permeability decreases, and hence, the upper limit of Si is preferably 3.5% by mass.

P: P promotes sintering and increases grain size, so that the magnetic characteristics are improved. P inhibits diffusion of carbon contained in the inner member into the outer member, thereby inhibiting decrease of the magnetic characteristics. It is therefore preferred to contain a proper content of P. However, when the content of P increases, the magnetic permeability decreases. Furthermore, when P is contained in excess, impurities precipitate at grain boundaries, so that the size precision is deteriorated. Hence, the upper limit of the content of P is preferred to be 0.7% by mass.

B: B promotes sintering as well as P and increases grain size, and inhibits diffusion of carbon contained in the inner member into the outer member, thereby demonstrating the same advantages as P and enhancing the magnetic characteristics. It is therefore preferred to contain a proper content of B. However, when the content of B increases, the magnetic permeability decreases. Furthermore, when B is excessively contained, impurities precipitate at grain boundaries, and the compressive property is deteriorated, whereby the sintering density decreases and the magnetic permeability decreases. Hence, the upper limit of the content of B is preferred to be 0.3% by mass.

Cu: When Cu is added by up to 1.5% by mass, an effect of improving the magnetic characteristics can be sufficiently obtained. However, when more than that amount of Cu is added, the magnetic characteristic is deteriorated due to expansion of Cu. When more Cu is added, the bonding condition is deteriorated due to expansion of Cu. Hence, the upper limit of the content of Cu is preferred to be 3% by mass.

The outer member diffuses into and bonds with the inner member containing C, and hence contains C diffused from the inner member. When the content of C is 0.3% by mass or less, there is no problem since decrease of the magnetic characteristics is slight.

As the outer member, it is also possible to use ingot steel having magnetic characteristics such as electromagnetic soft iron or silicon steel such as SS, SPC, S10C to S30C, SUM11 to SUM 32, SUY, and the like, specified in the JIS instead of the above-mentioned sintered material.

As mentioned above, the permanent magnet type rotor in which at least one of the inner member and the outer member is made from a sintered material has been explained. A permanent magnet type rotor in which both the inner member and the outer member are made from sintered material will be explained hereinafter.

The present invention further provides a permanent magnet type rotor comprising: an annular outer member composed of a sintered body; an inner member composed of a sintered body having a lower density than that of the outer member and an outer circumference contacting with an inner circumference of the outer member; and plural permanent magnets disposed at intervals on the outer circumference of the outer member toward the circumferential direction; the inner member and the outer member being mutually sintered and bonded; the inner member comprising: an inner ring portion; an outer ring portion having an outer circumference contacting with an inner circumference of the outer member; and plural radial ribs radially arranged so as to connect the ring portions; wherein the outer member has an average thickness less than that of the outer ring portion of the inner member.

The permanent magnet type rotor is also configured by sintering and bonding the outer member and the inner member and disposing plural permanent magnets on outer member. The inner member is mounted to a corresponding part such as an engine shaft. The outer member on which the permanent magnets are disposed may be a sintered compact produced by a pure ferrous powder with low carbon content and superior magnetic characteristics, and the inner member may be a sintered compact produced by a ferrous powder with high carbon content and high strength, so that a rotor having superior magnetic characteristics and high strength can be obtained. That is, the inner member is employed for strength and the outer member is employed for superior magnetic characteristics. The inner member comprises an inner ring portion, an outer ring portion, and radially arranged plural radial ribs. In this configuration, a space is formed between the radial ribs to form hollows, so that weight reduction and compact design as well as increased strength can be obtained. In the rotor of the invention, the inner member and the outer member are compacted, and the green compacts are fitted each other and sintered, so that these members are bonded and integrated. In the sintering and bonding, thermal expansion occurs in both members. When the compositions of the members, or the like, are adjusted so that the thermal expansion of the inner member is greater than that of the outer member, pressure in which the outer circumference of the inner member exerts pressure on the inner circumference of the outer member is generated. In particular, the portion of outer circumference of the outer ring portion at the radial rib is affected by large volume expansion of the radial rib, so that the pressure pushing the inner circumference of the outer member is significantly large compared to other portion. Therefore, the diffusion and bonding in the portion of outer circumference of the outer ring portion at the radial rib remarkably promotes, and the outer member and the inner member are securely bonded at the above portion. Furthermore, in the rotor of the invention, the average thickness of the outer member is less than that of the outer ring portion of the inner member. As a result, the portion of the inner member except for the ribs, which have a relatively low density, is not retracted inwardly in the radial direction by the outer member during sintering. Therefore, secure bonding is formed between the inner member and the outer member.

The present invention further provides a permanent magnet type rotor comprising: an annular outer member composed of a sintered compact; an inner member composed of a sintered compact having a lower density than that of the outer member and an outer circumference contacting with an inner circumference of the outer member; and plural permanent magnets disposed at intervals on the outer circumference of the outer member toward the circumferential direction; the inner member and the outer member being mutually sintered and bonded; the inner member comprising: an inner ring portion; an outer ring portion having an outer circumference contacting with an inner circumference of the outer member; and plural radial ribs radially arranged so as to connect the ring portions; wherein the outer member has an average thickness not less than that of the outer ring portion of the inner member, and the contacting area between the radial ribs and the outer ring portion is 10% or more of the area of the inner circumference of the outer ring portion.

In the permanent magnet type rotor, the average thickness of the outer member is not less than that of the outer ring portion of the inner member. When such a structure is employed, the portion of the inner member except for the ribs, which has a relatively low density, may usually be retracted by the outer member during sintering. In contrast, in the invention, the contacting area between the radial ribs and the outer ring portion is 10% or more of the area of the inner circumference of the outer ring portion. Therefore, in a pressure condition in which the outer circumference of the inner member exerts pressure on the inner circumference of the outer member as mentioned above, the portion of the outer circumference of the outer ring portion of the outer member at the radial rib has an area sufficient to receive the large volume expansion in the radial rib. Therefore, secure bonding can be obtained between the inner member and the outer member during sintering.

In two inner members according to the invention, a circumferential rib extending along the circumferential direction contacting with the outer ring portion may be provided between the radial ribs. According to this embodiment, the volume expansion of the inner member accommodating the bonding with the outer member is added not only by the radial rib but also by the circumferential rib. That is, the circumferential rib disposed between the radial ribs expands with heat according to its volume during sintering and bonding, so that the portion of the outer ring portion at the circumferential rib is securely pushed to the outer member and bonded thereto. Therefore, the bonding rate between the outer member and the inner member can be increased, and secured portions and portions which are not secured are arranged in the circumferential direction with a good balance.

According to preferable embodiment of the invention, the circumferential rib may have a shape in which the intermediate portion thereof between the radial ribs has the maximum volume. According to this embodiment, the volume expansion of the circumferential rib is maximum at the intermediate of the radial ribs, so that the bonding strength at that portion balances with that at the bonding portion by the radial rib, and increase of the weight for improving the bonding rate can be inhibited within the minimum range.

According to a more preferable embodiment of the invention, the radial rib may be inclined with respect to the circumferential direction of the rotor. According to this embodiment, the radial ribs stir and cause to flow the air therearound during rotation of the rotor, and the air flow cools the rotor itself. Therefore, reducing of the electrical generation performance due to temperature elevation can be inhibited.

Materials for the outer member and the inner member in the permanent magnet type rotors in which both the inner member and the outer member are made from sintered materials will be mentioned hereinafter. Compositions equivalent to class 3, class 4 or class 5 in SMF specified in JIS Z 2550 are preferable for the inner member. Compositions containing C: 0.3% by mass or less, a balance of Fe, and inevitable impurities are preferable for the outer member. The pure ferrous sintered material may further contain at least one of Si: 3.5% by mass or less, P: 0.7% by mass or less, B: 0.35 by mass or less, and Cu: 3.0% by mass or less.

In the permanent magnet type rotors, in order to ensure the bonding strength, the inner member may be fitted into the outer member along a contacting surface by passing fit with a gap of 5 m or less, or by tightening fit with a tightening interference of within 0.0025 times the diameter of the contacting surface before sintering.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1A is a plan view of an embodiment of a permanent magnet type rotor according to the invention, and FIG. 1B is a cross sectional view taken at line 1B--1B in FIG. 1A.

FIG. 2A is a plan view of another embodiment of a permanent magnet type rotor according to the invention, and FIG. 2B is a cross sectional view taken at line 2B--2B in FIG. 2A.

FIG. 3 is a plan view showing a bonding condition in which an inner member was fitted into an outer member and these were then sintered together.

FIG. 4A is a plan view of another embodiment of a permanent magnet type rotor according to the invention, and FIG. 4B is a cross sectional view taken at line 4B--4B in FIG. 4A.

FIG. 5A is a plan view of another embodiment of a permanent magnet type rotor according to the invention, and FIG. 5B is a cross sectional view taken at line 5B--5B in FIG. 5A.

FIG. 6A is a plan view of another embodiment of a permanent magnet type rotor according to the invention, FIG. 6B is a cross sectional view taken at line 6B--6B in FIG. 6A.

FIG. 7 is a cross section showing an outer member and an inner member manufactured in an example of the invention.

FIG. 8 is a photograph showing the distribution of bonding strength in a rotor manufactured in an example of the invention.

BEST MODE FOR CARRYING OUT THE INVENTION

The permanent magnet type rotor of the invention is described in detail while referring to the accompanying drawings.

First Embodiment

FIG. 1A is a plan view of a permanent magnet type rotor in a first embodiment, and FIG. 1B is a sectional view thereof. In FIGS. 1A and 1B, reference numeral 1 is an outer member and reference numeral 2 is an inner member. The inner member 2 is composed of a ring-shaped outer ring portion 21 and an inner ring portion 22 which are connected together by means of a disk-shaped rib 23 as shown in FIG. 1. The thickness of the rib 23 is less than that of the outer ring portion 21 or the inner ring portion 22, and hence the weight is reduced. The outer member 1 is shaped like a ring, and its outer circumference is processed in a regular polygonal shape, and permanent magnets 3 are fixed thereon.

Second Embodiment

FIGS. 2A and 2B show a second embodiment of the invention, in which the outer ring portion 21 and inner ring portion 22 are connected through a plurality of connecting ribs 23a disposed at equal intervals in the circumferential direction, and hollow spaces 24 are provided and the weight is further reduced.

In the permanent magnet type rotor shown in FIGS. 1A and 1B or FIGS. 2A and 2B, a ferrous alloy powder or mixed powder is compressed into a green compact having the shape of the inner member 2, and a pure ferrous powder is compressed to a green compact having an approximately annular shape. The green compact for the inner member 2, and green compact for the outer member or a sintered compact obtained by sintering it, or an outer member manufactured from an ingot steel to have an approximately annular shape are fitted together and sintered. Since the thermal expansion amount of the inner member 2 containing carbon is greater than that of the outer member 1, these members tightly contact, and sufficient diffusion bonding can be obtained and high bonding strength can be obtained. Subsequently, the outer circumference of the outer member 1 is machined to a regular polygonal shape, and permanent magnets 3 are disposed and fixed thereto, so that a weight-reduced permanent magnet type rotor having both magnetic characteristics and strength is obtained.

FIG. 3 shows a condition before machining the outer member 1 of the permanent magnet type rotor shown in FIG. 2. In this permanent magnet type rotor, the thermal expansion amount of the portion of the outer ring portion 21 at the connecting rib 23a during the sintering process is greater than the portion of the outer ring portion 21 at the hollow spaces 24. Therefore, diffusion bonding is promoted most at the portion of the outer circumference of the inner member 2 and the portion of the inner circumference (part A in FIG. 3) of the outer member at the rib 23a, and the bonding strength is heightened. However, in the progress of the diffusion bonding, since carbon diffuses from the inner member 2 to the outer member 1, the magnetic characteristics of the outer member lare deteriorated.

Accordingly, in this embodiment, the permanent magnets 3 fixed on the outer circumference of the outer member 1 are disposed on the portion of the outer circumference of the outer member 1 at the connecting ribs 32a of the inner member 2 at which the magnetic characteristics are decreased, and the side of the permanent magnets 3 is positioned to be opposite to the hollow spaces 24 of the inner member 2. In the portions facing the hollow spaces 24 of the inner member 2 (part B in FIG. 3), the diffusion bonding is inhibited compared to the portions at the connecting ribs 23a (part A), so that diffusion of carbon from the inner member 2 is decreased and the magnetic characteristics can be maintained. Therefore, by disposing the side of the permanent magnets 3, in which the magnetic flux is most concentrated, at this area (part B), sufficient bonding strength can be obtained, and a permanent magnet type rotor having further superior magnetic characteristics can be obtained.

When ferrous green compacts are sintered and bonded together, as long as the two members are tightly contacted with each other at least in part of a high temperature range of about more than 800.degree. C. in the sintering process (the required time differs according to the temperature, but may be estimated as time until the diffusion depth of the alloy components reaches about 5 m), sufficient bonding strength can be obtained. Sintering is usually solid phase sintering. When sintering is performed in a partly liquid phase state, the diffusion bonding is further promoted. In this case, when the generation of the liquid phase is within 5%, there is no problem in erosion or deformation. However, it is preferred that this be kept within 3% in order to maintain a sufficient size precision of the sintered compact.

Furthermore, by containing zinc in the green compact for the inner member, and without containing zinc in the green compact for the outer member or an ingot steel for the outer member, both members may be fitted together and sintered in a carburizing atmosphere. As a result, in the green compact for the inner member containing zinc, carburizing from the atmosphere occurs and contraction of its volume due to progress of sintering is suppressed, and the thermal expansion amount is greater than in the case in which zinc is not contained. Accordingly, diffusion bonding is promoted by sintering in a condition of the outer member 1 relatively tightening the inner member 1, and the two members are bonded more securely.

While the atmosphere is not carburizing in the sintering process, although the green compact for the inner member contains zinc, the effect of increase of expansion amount does not occur. When the atmosphere is carburizing, the expansion amount of the green compact is slightly increased if zinc is not contained. However, in a composite component of inner member and outer member, this phenomenon occurs similarly in both the outer member and the inner member, so that the relative difference is not apparent, and there is no effect on the bonding. When the atmosphere is carburizing and both members contain zinc, the expansion amount increases but is compensated for, and the result is the same. Zinc may be added to the green compact for the inner member, but when added in a form of zinc stearate to be used also as a forming lubricant, the labor can be saved, and it is preferred also from the viewpoint of uniform dispersion. As the atmospheric gas, a refined exothermic gas produced by natural gas or methane hydrocarbon (for example, carburizing degenerated butane gas) is preferable.

For improving of bonding strength, it is also important to define the fitting dimensional difference (the difference between the inside diameter of the hole of the outer member and the outside diameter of the inner member) when the inner member is fitted into the outer member. In this case, it is preferred to set the outside diameter of the inner member to be slightly larger (tightening fit), and press-fit the inner member into the outer member, and the tightening interference should be larger in order to achieve a higher tightness of both. However, to avoid breakage of the outer member which is low in strength before sintering (green compact) due to excessive tensile stress, the tightening interference should be preferably kept within 0.0025 times the diameter of the contacting surface. If passing fit is selected, the gap should be smaller, preferably within 5 m.

Third Embodiment

FIG. 4A is a plan view of a permanent magnet type rotor in a third embodiment, and FIG. 4B is a cross sectional view taken at line 4B--4B. In FIG. 4, reference numeral 31 is an annular outer member and 32 is a cylindrical inner member. The inner member 32 is composed of an inner ring portion 51, an outer ring portion 52 of which the outer circumference contact with the inner circumference of the outer member 31, and radial ribs 53 which coaxially connect and integrate the inner ring portion 51 and the outer ring portion 52. The radial ribs 53 extend along the radial direction, and are disposed at equal intervals in the circumferential direction. A hollow portion 54 is formed between the radial ribs 53. The area rate of the bonding portion (portion indicated by numeral 55 in FIGS. 4A and 4B) of the radial rib 53 and the outer ring portion 52 with respect to the inner circumference of the outer ring portion 52 is appropriately established so as to obtain a required bonding rate (30% or more) which allows practical use for a rotor between the outer member 31 and the inner member 32 after sintering.

A recess 56 is formed at the center of the inner ring portion 51 of the inner member 32, and the circumference thereof is formed to be a thick portion 57. The radial rib 53 has approximately the same height (axial thickness) as the thick portion 57. Plural screw holes 58 are formed in the opened end surface of the recess 56 in the thick portion 57 at equal intervals along the circumferential direction. The rotor is mounted to, for example, a transmission using the screw holes 58. Plural permanent magnets (not shown) are secured on the outer circumference of the outer member 31 at equal intervals.

In the embodiment shown in FIGS. 4A and 4B, when the average thickness of the outer member 31 is equal to or greater than that of the outer ring portion 52 of the inner member 32, the proportion of the contacting area of the radial rib 53 and the outer ring portion 52 with respect to the inner circumference of the outer ring portion 52 is 10% or more. As a result, the outer ring portion 52 is provided with a sufficient area to receive the large volume expansion of the radial ribs 53, so that the inner member 32 and the outer member 31 are securely bonded each other during sintering. When the average thickness of the outer member 31 is less than that of the outer ring portion 52 of the inner member 32 (not shown), the portion of the inner member 32 except for the ribs 53, which have a relatively low density, is not retracted inwardly in the radial direction by the outer member 31 during sintering. Therefore, secure bonding is formed between the inner member 32 and the outer member 31.

Fourth Embodiment

FIG. 5A is a plan view of a permanent magnet type rotor in a fourth embodiment, and FIG. 5B is a cross sectional view taken at line 5B--5B. The rotor comprises an annular outer member 31 and a cylindrical inner member 32 as well as the rotor in the third embodiment. The inner member 32 is composed of an inner ring portion 51, an outer ring portion 52, and radial ribs 53. The radial ribs 53 have an approximately the same thickness as the inner ring portion 51, the height of the outer ring portion 52 (axial direction) is approximately the same as that of the outer member 31. A hollow portion 54 is formed between the radial ribs 53. In the embodiment, the area rate of the bonding portion (portion indicated by numeral 55 in FIG. 5A) of the radial rib 53 and the outer ring portion 52 with respect to the inner circumference of the outer ring portion 52 is also appropriately established so as to obtain a required bonding rate (30% or more) which allows ptactical use for a rotor between the outer member 31 and the inner member 32 after sintering. In the embodiment, a circumferential rib 59 is formed between the radial ribs 53, and is integrally formed with the outer ring portion 52 and is extended along the circumferential direction. Plural permanent magnets 33 are secured on the outer circumference of the outer member 31 at equal intervals.

The permanent magnet type rotors in the third and fourth embodiments are manufactured as follows. First, a green compact for the outer member 31 is obtained by compressing a pure ferrous powder into the shape of the outer member 31, or a sintered compact for the outer member 31 is obtained by sintering the green compact. A green compact for the inner member 32 is obtained by compressing a ferrous alloy powder or mixed powder into the shape of the inner member 32. In this case, the density of the green compact for the inner member 32 is lower than that of the green compact for the outer member 31 or the sintered compact for the outer member 31. Then, these compacts are fitted each other and sintered, and subsequently, the outer member 31 is appropriately machined and the permanent magnets 33 are arranged and secured thereon. In the sintering process, atomic dispersion occurs at the contacting surface between the outer member 31 and the inner member 32, whereby both members are bonded.

According to the above permanent magnet type rotor, the inner member 32 is a sintered compact with a low density and superior magnetic characteristics, and the inner member 32 is a sintered compact with a high carbon content and high strength, so that a rotor has superior magnetic characteristics and high strength. That is, the inner member 32 is employed for strength and the outer member 31 is employed for superior magnetic characteristics. The inner member 32 comprises the inner ring portion 51, the outer ring portion 52, and radial ribs 53 which are radially arranged and connect these portions 51 and 52. In this configuration, the hollow portion 54 is formed between the radial ribs 53, so that weight reduction and compact design as well as increased strength can be obtained.

Functions for bonding the outer member 31 and the inner member 32 in the sintering process will be explained hereinafter. In the sintering, thermal expansion occurs in both members 31 and 32. Since the inner member 32 has a lower rate of thermal expansion than that of the outer member 31, the thermal expansion of the inner member 32 is greater than that of the outer member 31, so that pressure is exerted by the outer circumference of the inner member 32 on the inner circumference of the outer member 31.

In particular, the portion of outer circumference of the outer ring portion 52 at the radial rib 53 is affected by large volume expansion of the radial rib 53, so that the pressure pushing the inner circumference of the outer member 31 is significantly large compared to other portions. Therefore, the diffusion bonding in the portion of the outer circumference of the outer ring portion 32 at the radial rib 53 is remarkably promoted, and the outer member 31 and the inner member 32 are securely bonded at the above portion. The rate of the contacting area 55 between the radial ribs 53 and the outer ring portion 52 with respect to the area of the inner circumference of the outer ring portion 52 is appropriately established, so that a required bonding rate which allows practical use for a rotor between the outer member 31 and the inner member 32 after sintering can be obtained. Therefore, both members 31 and 32 are overall securely bonded. In the embodiment, the portion in which both members are securely bonded is specified as the portion at the radial rib 53, so that the area rate can be easily established so as to securely bond both members 31 and 32.

Next, functions and advantages specified by the fourth embodiment will be explained hereinafter. In the fourth embodiment, the circumferential rib 59 extending along the circumferential direction is formed between the radial ribs 53. As a result, the volume expansion of the inner member 32 accommodating the bonding with the outer member 31 is added not only by the radial rib 53 but also by the circumferential rib 59. That is, the circumferential rib 59 expands with heat according to its volume during sintering and bonding, so that the portion of the outer ring portion 52 at the circumferential rib 59 is securely pushed to the outer member 31 and is bonded thereto. Therefore, the bonding rate between the outer member 31 and the inner member 32 can be increased and secured portions and portions which are not secured are arranged in the circumferential direction with a good balance.

In the third and fourth embodiments, the radial rib 53 may be inclined with respect to the circumferential direction of the rotor. According to this configuration, the radial ribs 53 stir and cause to flow the air therearound during rotation of the rotor, and the air flow cools the rotor itself. Therefore, reducing of the electrical generation performance due to temperature elevation can be inhibited.

In the fourth embodiment, the circumferential rib 59 preferably has a shape in which the intermediate portion thereof between the radial ribs 53 has the maximum volume. In order to have such a configuration, for example, the width (thickness in the axial direction) and/or the height (radial direction) of the circumferential rib 59 may be changed. According to the configuration, the volume expansion of the circumferential rib 59 is maximum at the intermediate of the radial ribs 53, so that the bonding strength at that portion balances with that at the bonding portion by the radial rib 53, and increase in the weight for improving the bonding rate can be inhibited within the minimum range.

Fifth Embodiment

FIG. 6A is a cross sectional view taken at line 6A--6A of FIG. 6B showing a permanent magnet type rotor in a fifth embodiment, and FIG. 6B is a cross sectional view taken at line 6B--6B in FIG. 6A. In FIGS. 6A and 6B, the reference numeral 31 is an annular outer member and 32 is a cylindrical inner member 32, and these members consist of sintered compacts. As shown in FIG. 6B, the inner member 32 is composed of a boss 60 inwardly disposed and an annular portion 61 outwardly disposed. The thickness of the annular portion 61 is less than that of the boss 60. Plural permanent magnets 33 are secured on the outer circumference of the outer member 31 at equal intervals.

As shown in FIG. 6A, plural ribs 62 which contact with the inner circumference of the outer member 31 are formed on the outer circumference of the annular portion 61 of the inner member 32 along the circumferential direction at equal intervals. A hollow portion 63 is formed between the ribs 62. The area rate of the bonding portion (portion indicated by numeral 64 in FIG. 6A) of the rib 62 and the outer member 31 with respect to the inner circumference of the outer member 31 is appropriately established so as to obtain a required bonding rate (30% or more) which allows practical use for a rotor between the outer member 31 and the inner member 32 after sintering.

In the rotor according to the fifth embodiment, the inner member 32 is a sintered compact with a density lower than that of the outer member 31, and both members are sintered and bonded each other, as well as the third and fourth embodiments. In the fifth embodiment, the bonding surface 64 on the rib 62 formed on the radially outside of the annular portion 61 of the inner member 32 is directly contacted and bonded with the inner circumference of the outer member 31. During sintering and bonding, the rib 62 expand with heat and a pressure in which the bonding surface 64 exerts pressure on the inner circumference of the outer member 31 is generated, so that both members 31 and 32 are securely bonded. By appropriately establishing the rate of the contacting area between the ribs 62 and the outer member 31 with respect to the area of the inner circumference of the outer member 31, a required bonding rate which allows ptactical use for a rotor between the outer member 31 and the inner member 32 after sintering can be obtained. Therefore, both members 31 and 32 are overall securely bonded. In the embodiment, the portion in which both members are securely bonded is specified as the bonding surface 64 of the rib 62, so that the area rate can be easily established so as to securely bond both members 31 and 32.

EXAMPLES

First Example

A green compact for an inner member was prepared by using an iron powder to which was added a powder containing a copper powder: 1.5% by mass, a graphite powder: 1.0% by mass, and zinc stearate as a forming lubricant, and compressing the mixed powder to a density of 6.5 g/cm.sup.3 into a shape as shown in FIG. 7. In FIG. 7, the unit is millimeter. Outer member was prepared by using an iron powder to which was added zinc stearate as a forming lubricant, and compressing the mixed powder to a density of 7.0 g/cm.sup.3 into in a shape as shown in FIG. 7 to obtain a green compact for an outer member 71. Another outer member was prepared by sintering the green compact for an outer member in nitrogen atmosphere at 850.degree. C. for 30 minutes. Moreover, a pure iron ingot steel in a shape as shown in FIG. 7 was prepared as an ingot steel for an outer member.

The green compact for an inner member was tightly fitted into the green compact for an outer member, the sintered compact for an outer member, and the ingot steel for an outer member with a tightening interference of 60 m to integrate them, and this was sintered in a degenerated butane gas at 1130.degree. C. for 40 minutes. The bonding strength, the weight, and the magnetic flux density as magnetic characteristics in the obtained samples were measured. The results of the measurement are shown in Table 1. By way of comparison, a conventional silicon steel plate was machined into a shape as shown in FIG. 1, and a material equivalent to S45C in the JIS was cast into a shape having hollow portions by a lost wax method. The weight and the magnetic flux density were evaluated, and the results are shown in Table 1.

In following Tables 1 to 5, .circleincircle.: good in practical use, .smallcircle.: capable of practical use, .DELTA.: limit to practical use, and X: usable.

TABLE-US-00001 TABLE 1 Inner Composition Fe-1.5Cu-1.0C member Composition Fe Fe S45C Outer Con- Green Sintered Ingot Silicon (hollow member dition compact compact steel steel shape) Bonding strength .largecircle. .largecircle. .largecircle. -- -- Weight .largecircle. .largecircle. .largecircle. X .largecircle. Magnetic characteristic (B) .largecircle. .largecircle. .largecircle. .largecircle. X

As is clear from Table 1, the sample from the silicon steel plate was superior in magnetic characteristic, but was heavy, and the lost wax sample from S45C material of JIS was light in weight because of the hollow shape, but was poor in magnetic characteristics. In contrast, in the sample obtained by sintering and bonding using the green compact for an inner member with the combination of the green compact for an outer member; the sintered compact for an outer member; and the ingot steel for an outer member; the weight was low, the bonding strength was high, and the magnetic characteristics were superior.

Second Example

A green compact for an inner member was prepared by using an iron powder to which was added a powder containing a copper powder: 1.5% by mass, a graphite powder: 1.0% by mass, and zinc stearate as a forming lubricant, and compressing the mixed powder to a density of 6.5 g/cm.sup.3 into a shape as shown in FIG. 7. For the outer member, an iron powder (Fe powder); an Fe-20Si powder containing Si: 20% by mass, and the balance of Fe and inevitable impurities; an Fe-20P powder containing P: 20% by mass %, and the balance of Fe and inevitable impurities; an Fe-0.6P powder containing P: 0.6% by mass, and the balance of Fe and inevitable impurities; Fe-20B powder containing B: 20% by mass, and the balance of Fe and inevitable impurities; and a copper powder (Cu powder) were prepared. These powders were mixed together with zinc stearate in the blending ratios shown in Table 2, and the obtained mixed powder for forming an outer member in the composition as shown in Table 2 were compressed in the same conditions as in the first example, and thereby obtaining samples 1 to 22 of green compacts for an outer member. The green compacts for an inner member were fitted into the green compacts for an outer member in the same conditions as in the first example, and they were sintered. The bonding strength and the magnetic flux density in samples 1 to 22 were evaluated, and the results are shown in Table 2.

TABLE-US-00002 TABLE 2 Blending ratio, mass % Composition of Sample Fe-20Si Fe-20P Fe-0.6P Fe-20B Cu mixed powder, mass % Bonding Magnetic No. Fe powder powder powder powder powder powder Fe Si P B Cu strength Cha- racteristics B Remarks 01 Balance Balance .largecircle. .largecircle. 02 Balance 5.0 Balance 1.0 .largecircle. .largecircle. 03 Balance 15.0 Balance 3.0 .largecircle. .largecircle. 04 Balance 17.5 Balance 3.5 .largecircle. .DELTA. 05 Balance 20.0 Balance 4.0 .largecircle. X Si Content out of upper limit 06 Balance 0.5 Balance 0.1 .largecircle. .largecircle. 07 Balance 1.5 Balance 0.3 .largecircle. .largecircle. 08 Balance 3.0 Balance 0.6 .largecircle. .largecircle. 09 Balance 3.5 Balance 0.7 .largecircle. .largecircle. 10 Balance 5.0 Balance 1.0 .largecircle. X P Content out of upper limit 11 Balance Balance 0.6 .largecircle. .largecircle. 12 Balance 0.5 Balance 0.1 .largecircle. .largecircle. 13 Balance 1.0 Balance 0.2 .largecircle. .largecircle. 14 Balance 1.5 Balance 0.3 .largecircle. .largecircle. 15 Balance 2.0 Balance 0.4 .DELTA. X B content out of upper limit 16 Balance 1.0 Balance 1.0 .largecircle. .largecircle. 17 Balance 2.0 Balance 2.0 .largecircle. .largecircle. 18 Balance 3.0 Balance 3.0 .DELTA. .DELTA. 19 Balance 5.0 Balance 5.0 X X Cu content out of upper limit 20 Balance 1.0 2.0 Balance 0.2 2.0 .largecircle. .largecircle. 21 Balance 3.0 2.0 Balance 0.6 2.0 .largecircle. .largecircle. 22 Balance 1.0 2.0 Balance 0.2 2.0 .largecircle. .largecircle.

As is clear from Table 2, in sample 4 in which the Si content was 3.5% by mass, the magnetic flux density was slightly reduced although within a practical range, and in sample 5 in which the Si content was more than 3.5% by mass, the magnetic flux density was reduced. In sample 10 in which the P content was more than 0.7% by mass, impurities precipitated at grain boundaries, and the magnetic flux density was reduced. In sample 15 in which the B content was more than 0.3% by mass, impurities precipitated at grain boundaries, and the magnetic flux density was reduced, and also the bonding strength was slightly reduced.

In sample 18 in which the Cu content was 3% by ma