DE10216476A1 - Rotor for electrical machine, especially motor, has pressed iron powder rotor body in one piece enclosing permanent magnets with good magnetic conductivity, preferably in 3 main directions - Google Patents

Abstract

The rotor has a rotor body (11) and permanent magnets (13) offset in the direction of rotation by especially an identical pole division and integrated into the rotor body. The rotor body is a pressed iron powder part (10) in one piece enclosing the permanent magnets with good magnetic conductivity, preferably in three main directions. The pressed part consists of a soft magnetic composite material of high relative permeability. AN Independent claim is also included for the following: a method of manufacturing an inventive device.

Description

State of the art

The invention is based on a rotor for an electrical Machine, especially for an electric motor, according to the Preamble of claim 1.

A known rotor with permanent magnet poles of this type (EP 0 909 003 A2) has a rotor body which is used for Reduction of eddy current losses from a variety of thin circular, disc-shaped lamellae or sheets is composed. In the rotor body are in the axial direction extending slots on the front of the Rotor body are open, incorporated. The slots are in Equidistantly arranged circumferentially next to each other. In each slot is a flat, rectangular permanent magnet inserted. In the diaphragm walls are axially extending grooves incorporated with an adhesive are filled. The adhesive provides an adhesive connection the permanent magnet forth, so that each permanent magnet against axial displacement is secured in the slots.

Advantages of the invention

The rotor according to the invention has the major advantage Simplified production and thus a cost saving manufacturing and assembly. In contrast to the known as Laminated core assembled rotor body is not a subsequent one Installation of the permanent magnets in tolerant slots necessary and also the gluing of the permanent magnets in the There is no slitting. Despite the massive rotor body due to its good magnetic conductivity in the three Main directions with still acceptable eddy current losses a high power density and thus a high torque yield achieved in the electrical machine.

By the measures listed in the other claims are advantageous further developments and improvements of the Claim 1 specified rotor possible. The one for manufacturing of the rotor are required individual process steps specified in claim 3.

drawing

The invention is based on one shown in the drawing Embodiment in the description below explained. Show it:

Fig. 1 is a perspective view of a rotor body for an electric machine,

Fig. 2-5, respectively, a manufacturing stage in the manufacture of the rotor in FIG. 1.

Description of the embodiment

The rotor shown in perspective in Fig. 1 for an electrical machine, which is preferably used for an electric drive motor in motor vehicle technology, has a rotor body 11 and a rotor shaft 12 on which the rotor body 11 is rotatably, for. B. by press fit. The rotor shaft 12 is mounted in a known manner in a machine housing receiving the stator of the electrical machine. The rotor body 11 has an even number of magnetic poles offset from one another in the circumferential direction by a constant pole pitch, in the exemplary embodiment of FIG. 1 a total of four, which are designed as permanent magnets 13 and are integrated in the rotor body 11 . The permanent magnets 13 have the shape of shell-shaped segments and the rotor body 11 is a one-piece iron powder pressed part 10 which surrounds the permanent magnets 13 on all sides and has good magnetic conductivity in three main directions, that is to say in the axial, radial and circumferential directions.

Preferably, the iron powder press part consists of a so-called. SMC (Soft Magnetic Composite) material with a possible large relative permeability.

The rotor body 11 shown in FIG. 1 is manufactured by a method, the stages of which are illustrated step by step in FIGS. 2-5.

A press mold 14 shown in perspective in FIG. 2 has a fully cylindrical inner molded part 141 and a hollow cylindrical outer molded part 142 that concentrically encloses the inner molded part 141 with a predetermined radial distance. In the space 143 between the inner molded part 141 and the outer molded part 142 , the four permanent magnets 13 are inserted in the correct position in the arrangement shown in FIG. 3 and aligned in the space such that each permanent magnet 13 is surrounded by a free space, that is to say both a clear distance from the inner molded part, as well as clear distance to the outer molded part 142 , as well as distance to the two adjacent permanent magnets 13 in the circumferential direction ( FIG. 4). Now the SMC material, which is in powder form, is filled into the intermediate space 143 , all the spaces between the permanent magnets 13 and the compression mold 14 being completely filled ( FIG. 5). Then the iron powder filling 15 is pressed and then the mold 14 , that is the inner molded part 141 and the outer molded part 142 , is removed from the compact. If SMC material has been used as the iron powder filling, the compact is then thermally aftertreated. The resulting rotor body 11 is completed with the rotor shaft 12 to form the rotor shown in FIG. 1.

Claims (5)

1. Rotor for an electrical machine, in particular for an electric motor, with a rotor body ( 11 ) and with permanent magnets ( 13 ) which are offset in the rotor direction of rotation by in particular the same pole pitch and which are integrated in the rotor body ( 11 ), characterized in that Rotor body ( 11 ) is a one-piece iron powder pressed part ( 10 ) enclosing the permanent magnets ( 13 ) and preferably having good magnetic conductivity in three main directions. 2. Rotor according to claim 1, characterized in that the iron powder pressed part ( 10 ) consists of SMC (Soft Magnetic Composite) material with high relative permeability. 3. A process for the manufacture of the rotor according to claim 1 or 2, characterized in that the permanent magnets ( 13 ) designed as shell-shaped segments exist in a press mold ( 1 ) consisting of a cylindrical inner molded part ( 141 ) and a hollow cylindrical outer molded part ( 142 ) arranged concentrically with radial spacing. 14 ) are used in the correct position so that the intermediate space ( 143 ) between the inner molded part ( 141 ) and the outer molded part ( 142 ) is filled with the iron powder, that the iron powder filling ( 15 ) is pressed and that the compact is then removed from the mold ( 14 ) becomes. 4. The method according to claim 3, characterized in that the compact is subjected to a thermal aftertreatment becomes. 5. The method according to claim 3 or 4, characterized in that the alignment of the permanent magnets ( 13 ) in the press mold ( 14 ) is carried out so that each permanent magnet ( 13 ) is surrounded on all sides by a space that can be filled with the iron powder.