WO2007068515A1

WO2007068515A1 - Rotor of an electrical machine, in particular of a motor, and method for producing a rotor

Info

Publication number: WO2007068515A1
Application number: PCT/EP2006/067325
Authority: WO
Inventors: Steven Andrew Evans; Tilo Koenig
Original assignee: Robert Bosch Gmbh
Priority date: 2005-12-14
Filing date: 2006-10-12
Publication date: 2007-06-21
Also published as: CN101331664A; JP4878373B2; JP2009519695A; DE102005059587A1; CN101331664B; EP1964240A1

Abstract

The present invention relates to a rotor (13) for electrical machines having a magnetic return path (5), which comprises at least one laminate stack (6) having laminates (1), wherein the laminate (1) has a basic body (2) and at least two fixing elements (4) which are integrated on the basic body (2). At least one permanent magnet (7), which is fixed between two fixing elements (4) of one or more laminates (1) of the rotor (13), is provided on the rotor (13). The fixing elements (4) have lesser permeability than the basic body (2) of the laminate (1). The invention also relates to a method for producing such a rotor (13), in which, in the first step, at least one of the fixing elements (4) is thermally treated until the permeability of the fixing element (4) is 1. In this case, the permeability of the basic body (2) is unchanged. In the second step, the laminate (1) is cooled.

Description

description

title

"Rotor of an electric machine, in particular of an engine, and method of manufacturing a rotor"

State of the art

The present invention relates to a rotor for electrical machines, in particular for motors, with a yoke, which comprises at least one lamination-containing laminated core, and a method for producing a rotor

Inverted rotors are used in brushless DC motors in the prior art. They often have separate surface magnets, which are applied to the magnetically conductive yoke. In a majority of DC motors, the magnets are glued to the outer surface of the yoke. In this case, different magnetic shapes are used, for example shells, cuboids or magnets in D-shape, which are also referred to as "loaves of bread".

The inferences of the motors are either integrally formed of steel or consist of packages comprising a plurality of superimposed lamella plates.

To align the magnets on the inference z. B. auxiliary adapter made of plastic, to position the magnets during the curing of the adhesive. After completion of the curing process, the auxiliary adapters are removed.

In other embodiments, in the conclusion of the rotor fixing elements are integrated, between which the magnets are fitted or clamped. This achieves improved positioning of the magnets. However, the fixing elements are then also made of conductive steel, so that generates a magnetic flux in the rotor which shorts the flux of the permanent magnets. This reduces the overall flow and reduces the torque of the machine, especially the DC motor.

Advantages of the invention

The rotor according to the invention for electrical machines with a conclusion with the features of claim 1 has the advantage that the integrated on a main body of a fin of the yoke fixing have a very low permeability. Between two adjacent fixing elements is a respective

Permanent magnet provided, which is held by the fixing of one or more fins. The fixing elements have a lower permeability than the main body of the lamella. This prevents a short-circuit leakage flux path between two adjacent permanent magnets in the fixing elements being formed. No magnetic flux can form in the fixing elements. This increases the total usable magnetic flux in the rotor and increases the torque of the electric machine.

The subclaims disclose preferred developments of the invention.

Preferably, the blade is formed of a two-state material. In this case, a so-called YEP-FAl material is advantageously used. This material makes it possible to realize areas with different permeabilities. This is necessary, since the lamella consists of a base body and integral fixing elements. The lamella thus has a uniform material. Consequently, the material must be able to assume different states.

Particularly preferably, the material of the lamella comprises iron, chromium and carbon as components. In particular, 17.5% by volume of chromium and 0.5% by volume of carbon are used in combination with the iron. Such a material is particularly suitable because it assumes a high relative permeability in the magnetic state. Preferably, the lamella has a permeability of greater than 500, preferably from about 900. The preferred material of the lamella has the following magnetic properties in the magnetic state. The flux density is 1.28 Tesla at a magnetic field strength of 5 kA / m. The coercivity is about 500 A / m. The mechanical properties of this two-state material in the magnetic state include a tensile strength of 770 MPa, a yield stress of 640 MPa, and a

Hardness of 220 Hv. The elongation is 15%. In the non-magnetic state, the mechanical properties change to a tensile strength of about 930 MPa, a yield stress of 350 MPa. The hardness remains at 220 Hv. The elongation increases to 40%.

In a particularly preferred embodiment, the fixing elements of the slats are heat treated. This reduces the permeability of the fixing elements. The local heat treatment of the material or the lamella leads to the fact that the high permeability of the lamella at the heated places is significantly reduced. The heat treatment of the fixing elements of the slats can either be done successively for each slat. In this case, a fixing element of a blade is heated one after the other. It is also possible to heat all or more fixing elements of a lamella at the same time. Of course, several laminations can also be heated at the same time, so that the process of "demagnetization" of the fixing elements can be accelerated.The cooling of the laminations can then take place either after all the fixing elements of a lamination have been heat-treated, or the cooling of a single fixing element takes place directly its heat treatment takes place.

The fixing elements preferably have a permeability of less than or equal to 1.01.

Thus, the permeability of the fixing preferably corresponds to that of air. Thus, by the heat treatment, it is possible to create regions in the two-state material whose permeability is less than or equal to 1.01, with other regions having a relative permeability in the region of 900.

In a preferred embodiment, the rotor is constructed so that the permanent magnets are arranged on the circumference of the rotor. The permanent magnets are held between two adjacent fixing elements. In this case, the lamella preferably has a substantially rectangular or square cross-section. At the outsides are the magnets arranged. The fixing elements are integrated at the corners. By suitable choice of the permanent magnets, for example in D-shape, a rotor can be produced in this way, whose cross-section is substantially round.

In a preferred embodiment, an electric machine with the rotor according to the invention is formed with a return path, which comprises at least one lamination-containing laminated core. Such an electrical machine, in particular a motor, has the advantage that the permanent magnets arranged on the circumference of the return path are clamped and held between the integrated fixing elements of the lamellae. Since no magnetic flux flows between two adjacent permanent magnets through the fixing element of the blade enclosed by the permanent magnets, the total usable flux of the rotor of the electric machine is greater, so that the torque of the machine is improved. The reason for this are the non-magnetic fixing elements, between which the permanent magnets are arranged.

According to the invention, the method for producing a rotor having a plurality of lamellae with a base body and fixing elements integrated on the base body has the advantage that the permeability of the fixing elements is reduced by heat treatment until its permeability corresponds to that of air. Thus, the fixing elements are non-magnetic. The fixing elements thus have no influence on the magnetic flux which is formed between adjacent permanent magnets. For this purpose, according to the method, a two-state material is used, from which the lamellae consist.

In a first step, at least one of the fixing elements of the slats is now heat-treated. The heat treatment happens spatially limited. The main body of the lamella is not heat treated. For heat treatment of the fixing elements known methods can be used. Thus, the fixing elements can be placed in an oven, acted upon by external heat radiation or heated in any other known manner. The heating takes place only locally, so that only the fixing elements change their permeability. The fixative demente are heated until they have a permeability of about 1. Make sure that the permeability is less than or equal to 1.01, so the permeability of the fixing elements corresponds to that of air. The permeability of the body is not changed during the local heat treatment. Thus, the body itself has a high permeability. Subsequently, the slats or the fixing elements are cooled.

drawings

The invention will be described in detail below with reference to preferred embodiments. In the drawing is:

1 shows a blade of a rotor for an electrical machine;

Figure 2 is a rotor consisting of a plurality of laminations having laminated cores;

FIG. 3 shows the rotor from FIG. 2 with fixed permanent magnets;

Figure 4 is a section through a motor with the rotor of Figure 3; and

Figure 5 shows a detail of the motor of Figure 4 with magnetic field lines.

Description of the embodiments

The structure of an engine with a rotor according to the invention will be described below with reference to FIG. Figure 1 shows a blade 1 with an im

Essentially square base body 2. In the middle of the base body 2, a bore 3 is provided, through which extends the motor shaft, not shown. At each corner, the lamella has a fixing element 4, which is integrally connected to the base body 2 of the lamella 1.

The fixing element 4 is designed as a spring tongue. The slat 1 is produced by punching in one operation. The lamella 1 can be produced with the integrated fixing elements 4 also by laser cutting or another known manufacturing method. Two adjacent fixing elements 4 are facing each other and form a couple. In FIG. 1, the upper and lower fixing elements 4 face each other. The lamella 1 consists of a two-state material. The base body 2 is magnetic and has a permeability in the range of 900. The fixing elements 4 are non-magnetic after heat treatment. The permeability of the fixing elements 4 is in the range of 1.

FIG. 2 shows a conclusion 5 of a rotor 13, which consists of two laminated cores 6. The laminated cores 6 of the yoke 5 are each composed of a plurality of laminated lamellae 1. In each case, six fins 1 form a partial package 16. The laminated core 6 is assembled from several sub-packages 16, wherein two sub-packages 16 are offset by 90 degrees from each other. Due to the twist angle of 90 degrees, the shape shown in Figure 2 of the rotor 13 according to the invention is generated. Due to the structure of the laminated core 6 of several each 90 degrees against each other twisted sub-packages 16 production-related and systematic thicknesses and shape tolerances of the slats 1 are compensated.

FIG. 3 shows the rotor 13 according to the invention with the yoke 5 and permanent magnets 7 arranged on the outer sides of the lamellae 1. The permanent magnets 7 have a D-shaped cross section. They thus have the shape of a "loaf of bread." With their base side 8, the permanent magnets 7 lie on the outside of the laminated cores

6 on. The permanent magnets 7 are fixed between the adjacent fixing elements 4 and can not be moved out of their position. In addition, the permanent magnets 7 can be held with an adhesive to the laminated core 6. As a rule, however, the fixation is sufficient due to the fixing elements 4 designed as spring tongues.

FIG. 4 shows a cross section through a motor 9 with the rotor 13 according to the invention. The motor 9 has a stator 10 with six pole shoes 11. In this way, a 4-pole, 3-phase brushless motor 9 can be produced. The rotor 13 is arranged in the center of the stator 10. Shown is in the cross section of Figure 4, a blade 1 of the rotor 13. In the middle of the blade 1, a motor shaft 12 is inserted. To the

Outer sides of the lamella 1, the four permanent magnets 7 are arranged. Each of the permanent magnets 7 is held by two fixation dements 4. FIG. 5 shows a section of the motor 9 from FIG. 4. In this case, two pole shoes 11 are shown which belong to the stator 10. The rotor 13 of the motor 9 is rotated so that the fixing element 4 is located between the two pole pieces 11. In the plan view of FIG. 5, in addition to the fixing element 4 of the uppermost slat 1, a free end 14 of the fixing element 4 of the uppermost slat 1 of the sub-package 16 lying underneath can also be seen.

The two partially shown permanent magnets 7 are applied to the outside of the blade 1. The permanent magnets 7 are held between each two fixing elements 4.

In FIG. 5, the lines show the magnetic flux in the motor 9. Because the

Fixing elements 4 after the heat treatment have a permeability of about 1 and are non-magnetic, form no flux lines of the magnetic field in the fixing element 4. The flux lines extend from the first pole piece 11 via a rotor air gap 15 formed between rotor 13 and stator 10 through the permanent magnet 7. The flux lines then proceed through the main body 2 to the adjacent permanent magnet 7, via the rotor air gap 15 into the next pole piece 11 no short-circuit stray flux paths in the fixing element 4. The engine 9 has an increased torque compared to a conventional engine.

Claims

claims

1. Rotor for electrical machines with a conclusion, the at least one lamellae

(1) comprising sheet metal package (6), wherein a lamella (1) has a base body

(2) and at least two fixing elements (4) integrated integrally on the base body (2), at least one permanent magnet (7) is provided, which is fixed between two fixing elements (4) of one or more blades (1) of the rotor (13) , and the fixing elements (4) have a lower permeability than the main body (2) of the lamella (1).

2. Rotor according to claim 1, characterized in that the lamella (1) consists of a

Two-state material consists, preferably of YEP-FAl material.

3. Rotor according to claim 2, characterized in that the material of the lamella (1) comprises iron, chromium and carbon, in particular 17.5 vol% chromium and 0.5 vol% carbon.

4. Rotor according to one of the preceding claims, characterized in that the lamellae (1) have a permeability of greater than 500, preferably the permeability is in the range of 900.

5. Rotor according to one of the preceding claims, characterized in that the fixing elements (4) of the slats (1) are heat-treated in order to reduce the permeability of the fixing elements.

6. Rotor according to one of the preceding claims, characterized in that the

Permeability of the fixing elements (4) is less than or equal to 1.01.

7. Rotor according to one of the preceding claims, characterized in that the permeability of the fixing elements (4) corresponds to that of air.

8. Rotor according to one of the preceding claims, characterized in that the permanent magnets are arranged on the circumference of the rotor (13).

9. Electrical machine with a rotor (13) according to one of the preceding

Claims.

10. A method for producing a rotor having a plurality of blades (1) with a

Base body (2) and on the base body (2) integrated fixing elements (4), wherein the lamellae (1) consist of a two-state material, with the following

steps:

Heat-treating at least one of the fixing elements (4) until the fixing element (s) (4) have a permeability of about 1, the permeability of the base body (2) of the lamella (1) remaining unchanged; and cooling the blade (1).