DE8702998U1 - Micro electric motor - Google Patents

Description

PAP3T-tfOTuREN GmbH & Co KG DE-349 G

7742 St. Georgen - 3 - 011-LE/de

26.02.1987

Micro electric motor

The invention relates to a miniature electric motor according to the preamble of claim 1.

Such miniature motors are already described in DE-OS 34 34 965. However, these motors are not suitable for all drive purposes, as they produce too little torque. To increase the torque, the axial length of the effective air gap would have to be increased, with otherwise identical dimensions, which would also increase the axial length. Angled end plates, which could be attached to both sides of the stator core, could also increase the torque, but this would be more complex. In addition, this motor design requires an external housing that surrounds the stator and rotor. At least one bearing seat, one flange seat and one recess must be provided on this housing, which requires reworking. The eddy current losses in the known motors are also too high.

The invention is based on the object of creating a radially and axially very compact drive motor which, with a simplified structure, enables more economical production, higher torque and lower eddy current losses.

The solution to the problem is specified in the characterizing part of claims 1 and 4.

Reducing the number of components in such engines, which are produced in large series, shortens assembly time.

The one-piece design of the outer housing and stator eliminates the need for post-processing.

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A stator core package overmolded with plastic leads to a further reduction in costs.

Further details and advantageous developments of the invention emerge from the embodiments described below and shown in the drawing, as well as from the dependent claims.

It shows:

Fig. 1 shows a section through an engine according to the invention in an enlarged view,

Fig. 2 shows a part of the engine according to the invention in section, Fig. 3 shows a section along the line III-III in Fig. 2,

Fig. 4 shows a second embodiment of an engine according to the invention in section,

Fig. 5 shows a third embodiment of an engine according to the invention in section and

Fig. 6 shows a part of the engine of the third embodiment in section.

Identical or equivalent parts are designated below with the same reference symbols and are usually only described once.

Fig. 1 shows a miniature electric motor 1 with an internal rotor, on whose carrier 2 a permanent magnet 3 is attached, which is essentially designed as a cylindrical part. The permanent magnet 3 can be in one piece or consist of segments. In this embodiment, the rotor is four-pole.

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The carrier 2 is essentially pot-shaped. A control magnet disk 4 is attached to the outer pot shaft and a rotor shaft 5 is concentrically attached to the reinforced pot base. The shaft 5 runs in a plain bearing 6, which is connected to a flange cover 7. A thrust washer 8 is located on the shaft 5 between a pulley 9 and the plain bearing 6. The axial play of the rotor is determined by this washer 8. Holes 10 in the flange cover 7 are used to attach the motor.

The flange cover 7 is attached to one end face 15 of a motor component 11. The connection of parts 6, 7 and 11 is shown in Fig. 2. The motor component 11 simultaneously forms the outer housing 12 of the motor 1 and the stator iron 13 with the pole shoes 14. The motor component 11 is preferably manufactured in one piece using the sintering process. To avoid high eddy current losses, "Corovac" from Vacuumschmelze Hanau can be used as the sintering material, for example. A circuit board 18 is attached to the other end face 16 of the motor component 11 in a recess 17. Stator coils 19 are controlled by three Hall generators 20, which receive the pulses from the control magnet disk 4. The six stator coils, two of which are connected opposite one another in series, are operated by means of a full bridge. A cover plate 21 is attached at a distance below the circuit board 18 in the recess 17. The distance serves to create space for components on the circuit board 18. The connections and supply lines of the circuit board 18 are led through a side slot 22.

A constriction, the axial dimension of which is shown by the double arrow 23, of the stator iron 13 provides space for the stator coils 19, which also saves axial height of the motor. The axial dimension according to the double arrow 23 can be reduced until magnetic saturation is reached. The pole shoes 14 protrude in the axial direction over the constriction

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according to double arrow 23 and thereby form an extension of the effective air gap 24 between the magnet 3 and the pole shoes 14. The one-piece manufacture of this stator and the outer housing 12 is also more economical to carry out using the sintering process because no rework is required.

Fig. 3 shows a section of the motor component according to Fig. 1 and 2 with, for example, six pole shoes 14, which are designed as distinct poles and are wound in a concentrated manner.

A second embodiment according to the invention is shown in Fig. 4. This design essentially corresponds to that described in Fig. 1. As a further simplification, the flange cover and the plain bearing support part are designed as one piece as a bearing flange 25 with plain bearings 26. The shaft 5 has a rounded end 27 that runs against a bearing plate 28 on the circuit board 18. This arrangement is particularly suitable for the vertical installation position of the motor shown in the drawing. However, this embodiment can also be designed according to the design in Fig. 1 so that it could be used in other installation positions. The plain bearings 26 can be omitted if the plain bearing of the bearing flange 25 is designed like the plain bearing 6 in Fig. 1, namely with two running surfaces 29, 30 that are as far apart as possible in the axial direction.

A further simplification is achieved if the control magnet 4 and the rotor magnet 3 are designed as one piece, i.e. an axial end^would then contain the magnetization required for the control pulses (Fig. 5).

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A third embodiment is shown in Fig. 5. This design also corresponds in construction to that in Fig. 1. The difference lies in the stator. A stator iron 53 consists of a punched stator laminated core 54 with end plates 55, 56 attached to the laminated core at both axial ends. The design of the pole shoes 14 corresponds to the form shown in Fig. 3.

The entire stator iron 53 is overmolded with plastic, whereby the outer casing 57 of the stator iron 53 and the two end faces 58, 59 and the angled areas of the end plates 55, 56 in the area of the winding 19 are overmolded. By overmolded in the specified shape, the stator iron 53 is fixed on the one hand and an outer housing 52 is formed on the other. The motor component 51 thus completed comes out of the injection mold with sufficient surface quality and precision and can be assembled without any further processing.

Claims (9)

PAPST-HOTOREN GmbH & Co KG DE-349 G St. Georgen 26.G2.1987 011-LE/de Claims 1. Microelectric motor containing a permanent magnet, in particular arranged in the rotor, with a maximum air gap dimension of 50 mm, in particular a maximum air gap diameter of 30 mm, characterized in that the outer housing (12) and the stator are designed as a one-piece motor component (11). 2" Small electric motor according to claim 1, characterized in that the motor component (11) is manufactured using a sintering process. 3. Micro electric motor according to one of claims 1 or 2, characterized in that the motor component (II) consists of a material that causes small eddy current losses. 4. Micro electric motor containing a permanent magnet, in particular arranged on the rotor, with a maximum air gap dimension of 50 mm, in particular a maximum air gap diameter of 30 mm, characterized in that an outer housing (52) and a stator iron (53) are designed as a one-piece motor component (51). 5* Micro electric motor according to claim 4, characterized in that the stator iron (53) is a stator laminated core (54) which is overmolded with plastic, the overmold simultaneously forming the outer housing (52). 6. Micro electric motor according to one of the preceding claims, characterized in that the motor is designed as a collectorless direct current motor with a permanent magnet rotor (2, 3) in a cylindrical air gap (24) · -*2 -·* * DE-349 G 011-LE/en 26.02.1987 7. Electro-magnetic motor according to one of the preceding claims, characterized in that, with a cylindrical air gap (24), the stator has six concentratedly wound distinct poles (14), the rotor (2, 3) being four-pole. 8. Micro electric motor according to one of claims 1 to 3, characterized in that with a flat air gap the stator has four or six disc coils. 9. Small electric motor according to one of the preceding claims, characterized in that a flange cover (7) and a plain bearing (6) are formed in one piece as a bearing flange (25).