DE102013009621A1 - Electric motor with rotor shaft and housing and method for producing a rotor shaft of an electric motor - Google Patents

Abstract

Electric motor with rotor shaft and housing and method for producing a rotor shaft of an electric motor, wherein a sealing ring, in particular a shaft sealing ring, in particular a radial shaft sealing ring, is accommodated in the housing, the sealing ring being assigned a shaft section of the rotor shaft as a running surface, in particular for a sealing lip of the sealing ring, wherein the shaft section or the running surface isotropically, particularly in the circumferential direction and isotropically in the axial direction, has distributed depressions.

Description

The invention relates to an electric motor with rotor shaft and housing and a method for producing a rotor shaft of an electric motor.

It is well known that after the turning of a shaft section for further fine machining, grinding, hoisting or lapping is applied in order to achieve the lowest possible roughness, these finishing operations being complex and thus costly.

Turning, ie turning, means that a cutting tool, in particular a turning tool, cuts the respective area of the workpiece. In this case, when machining a shaft section, the workpiece, in particular a shaft, rotated and moved axially relative to the tool.

The invention is therefore the object of a shaft portion of a rotor shaft of an electric motor inexpensive and easy to work fine.

According to the invention, the object is achieved in the electric motor with rotor shaft and housing according to the claim 1 and in the method for producing a rotor shaft of an electric motor according to the features indicated in claim 7.

Important features of the invention in the electric motor with rotor shaft and housing are that a sealing ring, in particular shaft seal, in particular radial shaft seal, is accommodated in the housing,
wherein the sealing ring is assigned a shaft section of the rotor shaft as a running surface, in particular for a sealing lip of the sealing ring,
wherein the shaft portion or the tread isotropic, in particular in the circumferential direction and in the axial direction isotropic, distributed depressions.

The advantage here is that on the one hand the swirl freedom is reached, so the machined surfaces are isotropic in the circumferential direction and the axial direction. The formed craters also reduce the contact surface of a sealing lip of a radial shaft sealing ring with the rotor shaft, whereby the friction is reduced, and also form a reservoir for a liquid applied to the rotor shaft, such as lubricant or adhesive. In the case of an adhesive surface, an enlarged surface is produced by means of the craters via the adhesive with the parts adhesively bonded to the rotor shaft. Thus, not only an inexpensive simple finishing is achieved but an improvement in the adhesion of the adhesive and thus increasing the carrying capacity of the adhesive joint between the rotor shaft and adhesive-bonded parts.

Below the sealing edge of the sealing lip, a lubricant exchange can be generated, so that a reduced friction and an improved removal of heat generated at the sealing edge can be achieved. Thus, the temperature of the sealing edge and also the lubricant can be reduced. Therefore, the wear of the shaft and the radial shaft seal can be reduced.

In an advantageous embodiment, the rotor shaft has a shaft section which can be used as an adhesive surface, with permanent-magnet rings or permanent-magnet ring segments being adhesively bondable to the rotor shaft on the shaft section,
wherein the adhesive surface isotropic, in particular in the circumferential direction and in the axial direction isotropic, distributed depressions. The advantage here is that a high tightness in the seal by means of shaft seal against the rotor shaft can be achieved. The adhesive joint between rotor shaft and permanent magnets is also also improved, since the caused by the rotation spiral increases along the rotor shaft increases increases, which cause a deterioration of the isotropy and thus a reduction in adhesion.

In an advantageous embodiment, the depressions are formed in a crater shape and / or are craters,
in particular wherein the recesses are formed substantially rotationally symmetrical and / or wherein the recesses have at least one rotationally symmetric portion, wherein the depth of the respective recess is smaller than its diameter, in particular as its inside diameter. The advantage here is that the surface of a plurality of smaller in the circumferential direction and in the axial direction uniformly arranged recesses. Each crater is recognizable in the micro range. For this purpose, the respective crater has a diameter of less than 1 millimeter, in particular less than 100 microns. The light pulse forms a rotationally symmetric crater, in particular when it is aligned perpendicular to the rotor shaft axis, wherein the axis of symmetry is aligned in the radial direction to the rotor shaft axis.

In an advantageous embodiment, the depressions and / or craters are arranged overlapping. The advantage here is that no increases remain that remain of the previous processing step. Because the overlapping arrangement of the craters causes each increase is at least once melted by the laser beam.

In an alternative advantageous embodiment, the recesses and / or craters are arranged not overlapping. The advantage here is that a faster processing is executable. In this case, the distance of the craters is not chosen to be too large, so that the increases remaining from the rotation are also melted and thus the machined surface is isotropic and uniform.

In an advantageous embodiment, the depressions are produced by treating the surface with a load beam, in particular with a pulsed load beam. The advantage here is that a very fast, inexpensive and easy processing is possible, in particular wherein the processing in that machine tool is executable, in which the rotating machining was performed previously. Thus, no further clamping of the workpiece, in particular the rotor shaft, necessary.

Important features in the method for producing a rotor shaft of an electric motor are that the rotor shaft has a shaft section which can be used as a bearing seat, a shaft section which can be used as a running surface for a shaft sealing ring and / or a shaft section which can be used as an adhesive surface,
wherein the respective shaft section is machined and then treated with a pulsed load beam,
so that the respective shaft portion has isotropic, in particular in the circumferential direction and in the axial direction isotropic, distributed depressions.

The advantage here is that a uniform surface in the region of the running surface for shaft seal and the intended as an adhesive surface shaft sections can be produced.

In an advantageous embodiment, the wells are each filled with lubricant or adhesive. The advantage here is that a lubricant reservoir is formed and the contact surface between the shaft seal, in particular between the sealing lip of a shaft seal, and rotor shaft can be reduced and thus also the friction and heat. The lubricant arranged between the sealing lip and the rotor shaft can flow between the sealing lip and the rotor shaft. This improved lubricant exchange also allows a further reduction of friction and improved heat dissipation. When filling with adhesive is advantageous that an enlarged by means of the craters surface is created so that the adhesive joint undergoes improved adhesion to the rotor shaft, whereby the load capacity of the compound is improved, so the engine may have a higher allowable speed. Because the adhesively bonded permanent magnets are kept safer. The permanent magnets are designed ring-shaped section.

In an advantageous embodiment, the respective usable as a bearing seat shaft section is processed as the last processing step with turning. The advantage here is that not the entire surface of the rotor shaft must be processed but only the running surface for the shaft seal and the adhesive surface for the permanent magnets.

Further advantages emerge from the subclaims. The invention is not limited to the combination of features of the claims. For the skilled person, further meaningful combination possibilities of claims and / or individual claim features and / or features of the description and / or figures, in particular from the task and / or posing by comparison with the prior art task arise.

The invention will now be explained in more detail with reference to figures:

In the 1 a rotor shaft of an electric motor according to the invention is shown.

In the 2 is the rotor shaft with bonded permanent magnets 20 shown.

In the 3 is the rotor shaft with arranged on the rotor shaft bearing 30 shown.

In the 4 the abortive part of the engine according to the invention is shown cut, wherein the rotor shaft on the bearing 30 in a housing part 41 is shown stored and one on the tread 2 running shaft seal 42 the rotor shaft against the housing part 41 seals. The housing part acts here 41 as a bearing flange and is with a housing part 40 connected, which acts as a motor housing part, that surrounds the stator of the motor at least partially housing forming.

Thus, the electric motor has a housing in which two bearings, in particular ball bearings, are accommodated, which are used for mounting the in 1 serve shown rotor shaft. The housing is a multipart of housing parts ( 40 . 41 ) built up.

The rotor shaft is machined using turning. The rotor shaft is manufactured as a rotating body.

Thus, there are two bearing seats 3 machined for the bearings rotating. In addition, a cylindrically shaped adhesive surface 4 rotatably machined, are attached to the active parts, and a tread 2 against which seals a sealing lip of a radial shaft seal.

The rotating machining leaves in the micro range, spirally extending elevations whose spiral axis is aligned in Rotorwellenachsrichtung. So the spiral extends along the rotor shaft. These elevations can also be described as a twist, ie as a deviation from the isotropy in the circumferential direction and in the axial direction. The parameters characterizing the elevations depend on the cutting speed during turning, on the axial feed, on the radial feed of the tool and on the rotational speed of the rotor shaft during turning.

As active parts are permanent magnets with the adhesive surface 4 adhesive connected. The permanent magnets are designed as a hollow cylinder or hollow cylinder segments. In the circumferential direction is the direction of magnetization of the permanent magnets alternately, so alternately. Thus follows in the circumferential direction on a north pole a south pole. The number of poles is greater than 3, in particular greater than 5

Furthermore, the rotor shaft has a tread 2 for a also recorded in the housing of the electric motor radial shaft seal. A sealing lip of the radial shaft seal touches the tread 2 , with lubricant in the intermediate area between the sealing lip and the tread 2 is provided.

The rotating processing leaves spiral-shaped, ie extending in the circumferential direction and in the axial direction, grooves or protrusions.

To reduce the friction and to improve the tightness, the surface, in particular in the region of the sealing surface and in the region of the adhesive surface, processed with a pulsed laser.

The pulse duration and pulse energy is selected such that high temperatures are generated by each light pulse in a region of the surface in such a way that the material is melted in this region and a depression, in particular a crater, is generated by each light pulse.

During machining, the rotor shaft is rotated and axially displaced relative to the light beam. The displacement is realized by a deflection mirror, which deflects the light beam accordingly.

This relative movement between the workpiece, so rotor shaft, and light beam is performed such that the arrangement of the craters in the tread area 2 and in the area of the adhesive surface 4 is carried out in the circumferential direction and in the axial direction is substantially isotropic.

Preferably, the distance between the craters is small or even disappears, so the craters are overlapping.

In this way, then an essential part of the respective surface in the tread area 2 and the adhesive surface 4 melted and solidified again, with the small depressions, ie craters, for receiving adhesive in the area of the adhesive surface 4 or for the absorption of lubricant in the area of the tread 2 are provided.

In this way, by means of the depressions in the Beriech the adhesive surface 4 the surface increases and thus the adhesive bond between in the area of the adhesive surface 4 attached and thus by means of the adhesive with the rotor shaft in the region of the adhesive surface 2 improved adhesive bonded permanent magnet.

In the area of the tread 2 The craters reduce the contact surface between the sealing lip and the rotor shaft and thereby reduce the friction. The lubricant in the crater also acts as a lubricant reservoir and seals between the sealing lip and the rotor shaft. Between the sealing lip and the rotor shaft is thus in the circumferential direction, a lubricant film of lubricant, wherein the thickness of the lubricating film is variable, so varies.

In a further embodiment of the invention further surfaces are processed by means of the pulsed laser beam, in particular a bearing seat for a bearing of the rotor shaft.

LIST OF REFERENCE NUMBERS

1

axial end portion of the shaft

2

Tread for radial shaft seal

3

bearing seat

4

adhesive surface

20

permanent magnets

30

camp

40

housing part

41

housing part

42

Shaft seal

Claims (9)

Electric motor with rotor shaft and housing, wherein a sealing ring, in particular shaft seal, in particular radial shaft seal, is accommodated in the housing, wherein the sealing ring is associated with a shaft portion of the rotor shaft as a running surface, in particular for a sealing lip of the sealing ring, characterized in that the shaft portion or the tread isotropic, in particular in the circumferential direction and in the axial direction has isotropic, distributed recesses. Electric motor according to at least one of the preceding claims, characterized in that the rotor shaft has a usable as an adhesive surface shaft portion, wherein the permanent magnet rings or permanent magnet ring segments are adhesively bonded to the rotor shaft on the shaft portion, wherein the adhesive surface isotropic, in particular in the circumferential direction and in the axial direction isotropic, distributed depressions having. Electric motor according to at least one of the preceding claims, characterized in that the recesses are formed krater-shaped and / or craters, in particular wherein the recesses are formed substantially rotationally symmetrical and / or wherein the recesses have at least one rotationally symmetric portion, wherein the depth of the respective recess smaller than its diameter, especially as its clear width. Electric motor according to at least one of the preceding claims, characterized in that the recesses and / or craters are arranged overlapping. Electric motor according to one of claims 1 or 2, characterized in that the recesses and / or craters are arranged not overlapping. Electric motor according to at least one of the preceding claims, characterized in that the depressions are produced by treating the surface with a load beam, in particular with a pulsed load beam. A method for producing a rotor shaft of an electric motor, in particular according to at least one of the preceding claims, wherein the rotor shaft has a shaft portion usable as a bearing seat, usable as a running surface for a shaft seal shaft portion and / or usable as an adhesive surface shaft portion, characterized in that the respective shaft portion is then machined and then treated with a pulsed load beam, so that the respective shaft portion has isotropic, in particular in the circumferential direction and in the axial direction isotropic, distributed depressions. Method according to at least one of the preceding claims, characterized in that the recesses are each filled with lubricant or adhesive. Method according to at least one of the preceding claims, characterized in that the respective usable as a bearing seat shaft portion is processed as the last processing step with turning.

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