DE102024000135A1 - Electric motor - Google Patents

Abstract

Electric motor, comprising a rotor shaft, a floating bearing and a bearing shield, wherein the floating bearing is provided for the rotatable mounting of the rotor shaft, wherein the floating bearing has an inner ring and an outer ring, wherein the outer ring of the floating bearing is received in a bearing receptacle formed in the bearing shield, wherein the inner ring is placed on the rotor shaft, wherein the bearing receptacle is interrupted by slots, wherein the slots are spaced apart from one another in the circumferential direction.

Description

The invention relates to an electric motor.

It is generally known that at least two bearings, in particular rolling bearings, are used to support a shaft.

From the EN 10 2008 028 607 A1 The closest state of the art is an electric motor.

From the EN 10 2021 205 788 A1 A floating bearing arrangement is known.

From the DE 20 2007 009 954 U1 An electric motor is known.

From the EN 10 2011 119 603 A1 An electric motor is known.

From the EN 10 2020 120 389 A1 A torsional vibration damper with friction coefficient adjustment is known.

From the EN 10 2020 006 831 A1 An electric motor with a fan cover and a rotor shaft that can rotate relative to the fan cover and an angle sensor is known.

From the EN 10 2019 207 290 A1 A friction brake body for a friction brake of a motor vehicle is known.

From the EP 1 711 642 B1 An iron-containing layer of a sliding surface applied by thermal spraying is known.

From the EN 10 2018 130 798 A1 A regulated powder deposition welding process is known.

From the EN 10 2016 223 009 A1 A storage device is known.

The invention is therefore based on the object of developing an electric motor, whereby operation of the electric motor should be carried out as safely as possible.

According to the invention, the object is achieved in the electric motor according to the features specified in claim 1.

Important features of the invention in the electric motor are that the electric motor has a rotor shaft, a floating bearing and a bearing shield,
wherein the floating bearing is provided for the rotatable mounting of the rotor shaft,
wherein the floating bearing has an inner ring and an outer ring, in particular wherein rolling elements are arranged between the inner ring and the outer ring,
wherein the outer ring of the floating bearing is accommodated in a bearing receptacle formed in the bearing shield, in particular a cup-shaped bearing receptacle and/or blind hole,
the inner ring is placed on the rotor shaft,
the bearing support is interrupted by slots,
wherein the slots are spaced apart from one another in the circumferential direction, in particular regularly,
in particular wherein the circumferential direction is related to the axis of rotation of the rotor shaft.

According to the invention, the bearing holder of the floating bearing is designed with slots.

The advantage here is that the bearing holder has a higher elasticity and thus the outer ring of the floating bearing can be accommodated in the bearing holder with such a transition fit that the outer ring can be prevented from spinning or rotating while still allowing a low level of static friction when the outer ring is moved in the axial direction. This prevents the outer ring from rotating and enables axial displacement with little effort.

The advantage of the invention is that safe operation is possible because the outer ring of the floating bearing is prevented from rotating or spinning. On the one hand, the outer ring of the floating bearing is arranged to be axially displaceable so that thermally induced axial length changes of the rotor shaft are tolerable, but on the other hand, rotation in the circumferential direction for the outer ring is prevented by the outer ring being connected in a rotationally fixed manner to the bearing holder of the bearing shield.

In an advantageous embodiment, the bearing plate has a base body and the bearing holder, which has claw areas that are connected to the base body, in particular at their root areas. The advantage here is that the claw areas on the base body protrude axially and thus the bearing holder can be designed with thin walls and with the slots interrupting the bearing holder. In this way, increased elasticity can be achieved and therefore a corresponding transition fit can be realized that enables the outer ring to be moved in the axial direction with little effort.

In an advantageous embodiment, the base body is integral with the claw areas, in particular one-piece, in particular as a cast part The advantage here is that it is easy to manufacture.

In an advantageous embodiment, the claw areas are spaced apart from one another in the circumferential direction by means of the slots. The advantage here is that the elasticity of the claw areas is increased. In particular, the deflection of the respective claw area in the radial direction is facilitated, in particular the elasticity at the respective circumferential angular position is increased.

In an advantageous embodiment, the bearing holder is conically shaped on its inside. The advantage here is that the pressure acting on the radial outer circumference of the outer ring of the floating bearing does not change when the floating bearing is axially displaced, in particular as long as this displacement remains below a critical amount. This is because if the outer ring is positioned closer to the base body of the bearing shield, i.e. positioned deeper in the bearing holder, the amount of deflection in the claw area is smaller, but due to the conical shape and thus the greater expansion when the outer ring is positioned deeper, the radial distance between the outer ring of the floating bearing and the inside of the respective claw area and/or the bearing holder remains constant. For this purpose, however, the cone angle of the conical shape must be dimensioned appropriately, in particular exactly in such a way that the pressure of the bearing holder on the radial outer circumference of the outer ring of the floating bearing is independent of the axial depth of the outer ring in the bearing holder.

In an advantageous embodiment, the clear diameter of the bearing mount increases with decreasing distance from the base body of the bearing shield in the axial direction. The advantage here is that the pressure acting on the radial outer circumference of the outer ring of the floating bearing does not change when the floating bearing is axially displaced, in particular as long as this displacement remains below a critical amount. This is because if the outer ring is positioned closer to the base body of the bearing shield, i.e. positioned deeper in the bearing mount, the amount of deflection in the claw area is smaller, but due to the increase in the clear diameter, the radial distance between the outer ring of the floating bearing and the inside of the respective claw area and/or the bearing mount remains constant when the outer ring is positioned deeper. The increase in the clear diameter preferably occurs in such a way that the pressure of the bearing mount on the radial outer circumference of the outer ring of the floating bearing is independent of the axial depth of the outer ring in the bearing mount.

The radial direction and the circumferential direction are always related to the axis of rotation of the rotor shaft; the axial direction is aligned parallel to the axis of rotation of the rotor shaft.

In an advantageous design, the slots pass through the bearing holder in a radial direction. The advantage here is that the claw areas can be elastically deflected independently of one another, thus enabling optimized adaptation to the outer ring, with additional transverse forces acting on the rotor shaft being optimally distributed and diverted around the circumference.

In an advantageous embodiment, a spring washer is arranged in the axial direction between the outer ring and the bearing plate, in particular the bottom of the bearing receptacle, wherein the spring washer has a coating at least on first and second surface areas or is roughened by sandblasting or is laser-structured, in particular with elevations that extend further in the radial direction than in the circumferential direction.

The advantage here is that safe operation is possible because the outer ring of the floating bearing is prevented from rotating or spinning. On the one hand, the outer ring of the floating bearing is arranged so that it can be moved axially, so that thermally induced axial changes in the length of the shaft are tolerable, but on the other hand, rotation in the circumferential direction for the outer ring is prevented by the outer ring being connected in a rotationally fixed manner to the bearing holder of the bearing shield. The spring washer is axially deflected by the thermally induced axial changes in length, but the outer ring is prevented from rotating in the circumferential direction by means of the spring washer. This is achieved by the increased adhesion or friction that can be brought about by means of the coatings, particularly in comparison to an uncoated spring washer, which is made of sheet steel and is accommodated in the steel bearing holder, whereby the outer ring is also made of steel. Thus, a simple rubber coating of the spring washer can achieve a high level of adhesion between the spring washer and the bearing shield and between the spring washer and the outer ring. However, if adhesive is used as a coating at the contact points between the spring washer and the bearing plate and between the spring washer and the outer ring, a particularly torsion-resistant connection can be achieved and thus the outer ring can be prevented from spinning or rotating.

In particular, the first surface areas are spaced apart from one another in the circumferential direction and the second surface areas are spaced apart from one another in the circumferential direction. the first surface areas are arranged in the axial direction on the front side of the spring washer and the second surface areas are arranged in the axial direction on the rear side of the spring washer. The advantage here is that

In particular, the spring washer can also be described as a spring wave washer, since the spring washer is designed as a ring-shaped perforated disk, the edge area of which runs in a wave-like manner in the circumferential direction in the axial direction. As the circumferential angle increases, the axial position of the spring washer fluctuates. This means that the axial position of the spring washer runs as a periodic function of the circumferential angle.

Instead of coating, it is also possible to roughen the surface, in particular by means of sandblasting or laser structuring. In the latter case, it is advantageous to create elongated structures in the micro range in the radial direction so that the static friction prevents the spring washer or the outer ring of the floating bearing from rotating as effectively as possible.

In an advantageous design, the spring washer rests on both the bearing plate, in particular on the base of the bearing holder, and on the outer ring. The advantage here is that increased adhesion and thus resistance to twisting can be achieved.

In an advantageous embodiment, the axial position of the spring washer, in particular the axial position of the mean value of the area covered by the spring washer in the axial direction, is a periodic, in particular non-vanishing, function of the circumferential angle position. The advantage here is that the spring washer periodically swings back and forth in the circumferential direction as the circumferential angle in the axial direction increases. Thus, the installation of the spring washer between the outer ring and the bearing mount causes an elastic deflection of the spring washer, which thus sets or generates the bearing tension. The ring axis, in particular the central axis of the spring washer, is aligned parallel to the axial direction.

In an advantageous embodiment, the outer ring is accommodated in the bearing holder with an overfit. The advantage here is that if the rotor shaft changes length due to thermal factors, the floating bearing, in particular the outer ring of the floating bearing, can be moved in the axial direction. It is important that the static friction is kept correspondingly low. This can be achieved by designing the bearing holder to be sufficiently widened so that the outer ring can be accommodated with a transition fit, with the transition fit being tolerated in such a way that the floating bearing can be moved axially in the event of thermally induced changes in length. However, in order to prevent the outer ring from rotating in the circumferential direction relative to the axis of rotation of the rotor shaft in this widened bearing holder, the coatings of the spring washer are selected such that the outer ring is connected in a rotationally fixed manner to the bearing plate via the spring washer, in particular in the bearing holder.

In an advantageous embodiment, the outer ring is accommodated in the bearing holder with such a precise fit that the static friction moment that is generated in the operative connection of the outer ring accommodated in the bearing holder with the bearing plate is smaller than any static friction moment that can be generated by means of the operative connection of the spring washer with the outer ring and than any static friction moment that can be generated by means of the operative connection of the spring washer with the bearing plate. The advantage here is that, on the one hand, a rotationally fixed, materially bonded and/or force-fit connection between the outer ring and the bearing plate is achieved by means of the spring washer, but on the other hand, an axial displacement of the floating bearing is possible without force or with only a small amount of force.

In an advantageous embodiment, the coating is an adhesive, a rubber coating and/or a plastic layer. The advantage here is that a force-fitting and/or material-fitting, rotationally fixed connection between the outer ring and the bearing plate can be achieved by means of the spring washer. A carbide layer can preferably be used as the coating.

In an advantageous embodiment, the coating has a metallic layer. This allows the coating to have a long service life.

In particular, the coating has a carbide layer, in particular a metal carbide layer, in particular wherein this carbide layer is applied to a surface of the spring washer that is roughened in particular by means of a laser and/or wherein the carbide layer is applied to the spring washer by means of a high-speed laser deposition welding process (HS-LMD).

In an advantageous embodiment, the first surface areas provided with the coating are those areas of the spring washer that are the farthest away from the outer ring. The advantage here is that only a small amount of material is required, since only the contact areas between the spring washer and the outer ring and between the spring washer and the bearing plate need to be provided with a coating.

In an advantageous embodiment, the second surface areas provided with the coating are those areas of the spring washer which have the smallest distance to the outer ring, in particular those which touch the outer ring. The advantage here is that only a small amount of material is required, since only the contact areas between the spring washer and the outer ring and between the spring washer and the bearing plate need to be provided with a coating.

In an advantageous embodiment, the spring washer is made from a steel sheet to which the coatings are applied. The advantage here is that a high modulus of elasticity can be provided. The spring washer can therefore be produced cost-effectively and generates a high spring force even with a small axial deflection.

In an advantageous embodiment, the outer ring is arranged to be displaceable in the axial direction, in particular in the bearing receptacle, and/or the outer ring is connected to the bearing plate in a rotationally fixed manner by means of the spring washer. The advantage here is that in the event of a thermally induced change in the length of the rotor shaft, the floating bearing is arranged to be axially displaceable, although it is connected to the bearing plate in a rotationally fixed manner, in particular in a materially bonded and/or force-locked manner.

In an advantageous design, the spring washer touches both the outer ring and the bearing plate. The advantage here is that the bearing tension is provided by the spring washer and, as a result of the coating, the rotationally fixed connection of the outer ring to the bearing plate is ensured.

In an advantageous embodiment, the bearing plate is connected to a stator housing of the electric motor,
wherein a bearing flange is connected to the stator housing on the side of the stator housing axially facing away from the bearing shield,
wherein the bearing flange accommodates an outer ring of a fixed bearing, the inner ring of which is placed on the rotor shaft,
in particular, wherein the inner ring of the fixed bearing is positioned against a shaft step and is axially limited by a retaining ring which is arranged in an annular groove of the rotor shaft,
in particular, the outer ring of the fixed bearing rests axially on the one hand against the base of the bearing seat of the bearing flange and is axially positioned against a retaining ring arranged in an annular groove of the bearing flange. The advantage here is that the stator housing causes thermally induced length changes, particularly in the axial direction, by means of power loss in the stator winding. Depending on the material and geometry, these can be different from the length change of the rotor shaft. To compensate, the floating bearing is arranged so that it can be moved in the axial direction.

In an advantageous embodiment, the rotor shaft projects through a recess in the bearing plate and a fan is connected in a rotationally fixed manner to the rotor shaft on the side of the bearing plate axially facing away from the floating bearing,
wherein, to seal the recess, a shaft seal is accommodated in the bearing plate, in particular in the recess of the bearing plate, and seals against the rotor shaft, in particular by a sealing lip of the shaft seal touching the rotor shaft. The advantage here is that the bearing plate can be cooled by the air flow conveyed by the fan and thus the changes in length can be reduced.

In an advantageous embodiment, the rotor shaft projects through a bore through the bearing flange,
wherein a further shaft seal is accommodated in the bore on the side of the fixed bearing axially facing away from the floating bearing and seals off the rotor shaft, in particular by a sealing lip of the further shaft seal touching the rotor shaft. The advantage here is that the shaft seal accommodated in the bearing shield and the shaft seal accommodated in the bearing flange together seal the interior of the electric motor from the environment and thus no dirt or dust can penetrate into the bearing mount, which could make it difficult or impossible to move the floating bearing.

In an advantageous embodiment, a stator laminated core with stator winding is accommodated in the stator housing and a squirrel cage is attached to the rotor shaft and connected in a rotationally fixed manner. The advantage here is that the stator housing and also the rotor shaft can be exposed to different levels of waste heat depending on the operating state of the motor. The resulting changes in length can be compensated for by the spring washer according to the invention.

Further advantages arise from the subclaims. The invention is not limited to the combination of features in the claims. The person skilled in the art will recognize further useful combination options of claims and/or individual claim features and/or features of the description and/or the figures, in particular from the task and/or the task arising from a comparison with the prior art.

• In der 1 ist ein erfindungsgemäßer Elektromotor in Schnittansicht dargestellt.
• In der 2 ist ein Lagerschild 3 mit einer Federscheibe 2 und einem Loslager 1 des Elektromotors explodiert in Schrägansicht dargestellt.
• In der 3 ist eine Schrägansicht der Federscheibe 2 dargestellt.
• In der 4 ist eine Seitenansicht der Federscheibe 2 dargestellt.
• In der 5 ist ein erfindungsgemäßes Lagerschild 51 explodiert in Schrägansicht dargestellt.

The invention will now be explained in more detail using schematic illustrations:

• In the 1 an electric motor according to the invention is shown in sectional view.
• In the 2 A bearing plate 3 with a spring washer 2 and a floating bearing 1 of the electric motor is shown exploded in an oblique view.
• In the 3 an oblique view of the spring washer 2 is shown.
• In the 4 a side view of the spring washer 2 is shown.
• In the 5 an inventive bearing plate 51 is shown exploded in an oblique view.

As shown in the figures, the electric motor has a stator housing 9 which is connected at its first axial end region to a bearing shield 3 and at its other axial end region to a bearing flange 8. The stator housing 9 is thus arranged axially between the bearing flange 8 and the bearing shield 3.

A fixed bearing 7 is accommodated in the bearing shield 3, the inner ring of which is placed on a rotor shaft 4 of the electric motor and is positioned against a shaft step of the rotor shaft 4. The outer ring of the fixed bearing 7 is accommodated in a bearing holder formed on the bearing flange 8 and is axially limited by a locking ring arranged in an annular groove of the bearing flange 8. A further locking ring arranged in an annular groove of the rotor shaft 4 limits the inner ring of the fixed bearing. The fixed bearing is thus axially fixed. Thermally induced expansion of the rotor shaft 4 must therefore be compensated by a floating bearing 1.

The outer ring of the floating bearing 1 is accommodated in the bearing shield 3. The inner ring of the floating bearing 1 is placed on the rotor shaft 4 and, on its side facing the fixed bearing, is positioned against a shaft step formed on the rotor shaft 4.

A spring washer 2 is arranged on the side of the floating bearing 1 facing away from the fixed bearing 7. In particular, the spring washer 2 is arranged axially between the bottom of the bearing holder and the outer ring of the floating bearing 1.

The spring disk 2, in particular a wave disk or even an elastically deformable and/or springy wave disk, is designed as an annular perforated disk, the ring axis of which is aligned coaxially with the axis of rotation of the rotor shaft 4 and the edge region of which runs in a wave-like manner in the circumferential direction, in particular with the wave amplitude being variable in the axial direction. In particular, the wave amplitude or the axial position of the spring disk 2 fluctuates with increasing circumferential angle. This means in particular that the axial position of the spring disk 2 runs as a periodic function of the circumferential angle.

When installed in the electric motor, the spring washer 2 generates the bearing tension and is elastically deformed, in particular preloaded.

For this purpose, the spring washer 2 is manufactured as a deformed stamped sheet metal part, in particular as an annular sheet steel body, in particular wherein the perforated disk punched out of sheet metal is bent as a bent part in such a wavy manner that the axial position of the spring washer 2 is a periodic function as a function of the circumferential angular position relative to the axis of rotation of the rotor shaft 4. The period length in the circumferential direction is preferably 360° / N, where N is a natural number, in particular greater than two. The spring washer therefore has N maxima in the axial direction and N minima in the axial direction on the circumference, in particular wherein the maxima press elastically preloaded onto the outer ring of the floating bearing 1 and touch it, and wherein the minima press elastically preloaded onto the bearing plate 3 and touch it.

The axis of rotation of the rotor shaft 4 is thus aligned coaxially to the ring axis of the spring disk 2, which is designed as a wavy perforated disk.

The sheet thickness, especially the wall thickness, of the spring washer 2 is constant everywhere.

At those points of the spring washer 2 which have the greatest distance from the outer ring of the floating bearing 1, in particular at the minima, the spring washer 2 has adhesive 30 on its side facing away from the floating bearing 1.

At those points of the spring washer 2 which have the smallest distance to the outer ring of the floating bearing 1, in particular at the maxima, the spring washer 2 has adhesive 40 on its side facing the floating bearing 1.

In this way, a material-locking connection is created between the spring washer 2 and the outer ring of the floating bearing 1 and between the spring washer 2 and the bearing plate 3. This prevents the spring washer 2 from spinning or the outer ring of the floating bearing 1 from rotating.

In addition, the bearing mount is designed with a transition fit so that the The outer ring is only accommodated in the bearing holder with a low level of static friction. In this way, when the rotor shaft 4 expands due to thermal factors, the outer ring of the floating bearing 1 can be axially displaced without the outer ring being taken along. This is because the elastic preload changes during the axial displacement, but the bearing tension is still provided by the spring washer 2.

The static friction torque, which is provided by means of the transition fit in the bearing holder for the outer ring of the floating bearing 1 to prevent rotation in the circumferential direction, is smaller than the critical torque, if exceeded the adhesive connection between the spring washer 2 and the bearing plate 3 and/or the adhesive connection between the spring washer 2 and the outer ring of the floating bearing 1 fails.

A fan 5 is connected in a rotationally fixed manner to the rotor shaft 4 on the side of the bearing plate 3 that is axially remote from the fixed bearing 7. This enables efficient passive heat dissipation.

A fan cover 6 surrounds the fan 5 and is connected to the bearing plate 3.

A stator 10, in particular a stator laminated core with stator winding, is accommodated in the stator housing 9.

In the 5 a bearing plate 51 according to the invention is shown exploded in an oblique view, on which the pot-shaped bearing holder for the floating bearing 1 has slots 50 that are spaced apart from one another in the circumferential direction, in particular slots 50 that are directed axially.

The bearing holder protrudes axially from the bearing plate 51, in particular on the side of the bearing plate 51 facing the fixed bearing 7, and is - as in the embodiment according to the 1 to 4 - designed in one piece with the rest of the bearing plate 51, in particular as a single piece.

The side wall, in particular the cup wall of the cup-shaped bearing holder, is essentially like a hollow cylinder, although the axially directed slots 50 are incorporated and the inside of the hollow cylinder has a conical shape. The cone tip points towards the fixed bearing 7. The inside diameter of the bearing holder therefore increases with increasing distance from the fixed bearing 7. This ensures that the pressure is independent of the joining depth of the outer ring of the floating bearing 1 in the axial direction. If the outer ring is therefore moved further away from the fixed bearing 7 in the axial direction, the pressure on the outer ring, in particular from the bearing plate to the radial outer circumference of the outer ring, remains essentially the same.

By means of the slots 50, the bearing holder consists of claw areas that are spaced apart from one another in the circumferential direction. The claw areas merge at their axial end area into the rest of the bearing plate 3, in particular the base body, whereby these transition areas are referred to as the root area.

The base body is designed like a perforated disc, with the rotor shaft 4 protruding through the hole of the perforated disc.

The clear diameter of the bearing seat therefore increases in the axial direction with decreasing distance to the root areas.

The cone angle of the conical shape of the bearing holder of the floating bearing 1 is preferably so small that the clear diameter per centimeter in the axial direction increases by less than two tenths, in particular less than two hundredths, of a millimeter with increasing distance from the fixed bearing 7.

The number of slots 50 is preferably three or a larger natural number, preferably the number is odd. The maximum extension of a respective slot 50 is less than 360°/N, where N is the number of slots on the circumference of the bearing holder. Preferably the number N is an odd number.

The base body and the claw areas including their root areas are formed in one piece, in particular as a one-piece, in particular as a cast part.

The rotor shaft is therefore rotatably supported via the floating bearing 1 and the fixed bearing 7.

In further embodiments according to the invention, in a bearing holder designed with slots 50, the spring washer 2 is additionally provided according to the embodiment according to 1 to 5 between the outer ring of the floating bearing 1 and the bearing plate 3. The coating thus creates a rotationally fixed connection between the outer ring and the bearing plate by means of the spring washer 2.

Due to the low pressure due to the elastically deflectable slots 50 and in particular the pressure which is always the same regardless of the axial position of the outer ring, rotation of the outer ring is prevented and yet enables thermally induced axial displacement of the outer ring.

In further embodiments according to the invention, the slots 50 are rounded at their end region facing away from the fixed bearing 7. The slots 50 thus protrude into the respective root regions with a rounded end region. In this way, increased resistance to fracture can be achieved.

In further embodiments according to the invention, a rubber coating or another coating is used instead of the adhesive, which generates sufficient static friction in operative connection with the material of the bearing plate or with the material of the outer ring of the floating bearing 1.

The static friction torque, which is provided by means of the transition fit in the bearing holder for the outer ring of the floating bearing 1 to prevent rotation in the circumferential direction, is smaller than the maximum static friction torque that can be provided by the friction partners, i.e. spring washer 2, bearing plate 3 and/or outer ring of the floating bearing 1, in particular in the circumferential direction.

In further embodiments according to the invention, a carbide layer applied by means of HS-LMD is used instead of the adhesive.

In further embodiments according to the invention, the surface is roughened instead of the coating or the adhesive. Either sandblasting or laser structuring can be used for this. Sandblasting can be carried out inexpensively, but instead of isotropic elevations in the micro range to increase the static friction, laser structuring also enables the creation of depressions and elevations that extend further in the radial direction than in the circumferential direction. Since the depressions and elevations created by the laser extend further in the radial direction than in the circumferential direction, a high static friction moment can be generated, i.e. a relative rotational movement of the spring washer 2 relative to the respective friction partner, in particular the bearing plate 3 or the outer ring of the floating bearing 1.

In further development, one of the above-mentioned coatings can be applied to the roughened surface.

List of reference symbols

1

Floating bearing

2

Spring washer

3

Bearing shield

4

Rotor shaft

5

Fan

6

Fan cover

7

Fixed bearing

8th

Bearing flange

9

Stator housing

10

Stator, in particular stator laminated core with stator winding

30

adhesive

40

adhesive

50

slot

51

Bearing shield

QUOTES INCLUDED IN THE DESCRIPTION

This list of documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA accepts no liability for any errors or omissions.

Cited patent literature

• DE 102008028607 A1 [0003]
• DE 102021205788 A1 [0004]
• DE 202007009954 U1 [0005]
• DE 102011119603 A1 [0006]
• DE 102020120389 A1 [0007]
• DE 102020006831 A1 [0008]
• DE 102019207290 A1 [0009]
• EP 1711642 B1 [0010]
• DE 102018130798 A1 [0011]
• DE 102016223009 A1 [0012]

Claims (15)

Electric motor, having a rotor shaft, a floating bearing and a bearing shield, wherein the floating bearing is provided for the rotatable mounting of the rotor shaft, wherein the floating bearing has an inner ring and an outer ring, in particular wherein rolling elements are arranged between the inner ring and the outer ring, wherein the outer ring of the floating bearing is received in a bearing receptacle formed in the bearing shield, in particular molded, in particular a pot-shaped bearing receptacle and/or designed as a blind hole, wherein the inner ring is placed on the rotor shaft, characterized in that the bearing receptacle is designed to be interrupted by slots, wherein the slots are spaced apart from one another in the circumferential direction, in particular regularly, in particular wherein the circumferential direction is related to the axis of rotation of the rotor shaft. Electric motor according to Claim 1 , characterized in that the bearing plate has a base body and the bearing holder, which has claw regions which are connected to the base body, in particular at their root regions. Electric motor according to one of the preceding claims, characterized in that the base body is formed integrally with the claw regions, in particular in one piece, in particular as a cast part. Electric motor according to one of the preceding claims, characterized in that the claw regions are spaced apart from one another in the circumferential direction by means of the slots. Electric motor according to one of the preceding claims, characterized in that the bearing holder is conically shaped on its inner side, wherein the clear diameter of the bearing holder increases with decreasing distance from the base body of the bearing shield in the axial direction. Electric motor according to one of the preceding claims, characterized in that the slots pass through the bearing holder in the radial direction. Electric motor according to one of the preceding claims, characterized in that a spring washer, in particular a resilient wave washer, is arranged in the axial direction between the outer ring and the bearing plate, in particular the bottom of the bearing receptacle, wherein the spring washer has a coating at least on first and second surface areas or is roughened by sandblasting or is laser-structured, in particular with elevations that extend further in the radial direction than in the circumferential direction, in particular wherein the first surface areas are spaced apart from one another in the circumferential direction and wherein the second surface areas are spaced apart from one another in the circumferential direction. Electric motor according to one of the preceding claims, characterized in that the spring washer rests both on the bearing plate, in particular on the bottom of the bearing holder, and on the outer ring. Electric motor according to one of the preceding claims, characterized in that the axial position of the spring washer, in particular the axial position of the mean value of the area covered by the spring washer in the axial direction, is a periodic, in particular non-vanishing, function of the circumferential angular position, and/or that the outer ring is accommodated in the bearing receptacle with an overfit, and/or that the outer ring is accommodated in the bearing receptacle with such a precise fit that the static friction moment which is generated in the operative connection of the outer ring accommodated in the bearing receptacle with the bearing plate is smaller than the static friction moment which can be generated by means of the operative connection of the spring washer with the outer ring and than the static friction moment which can be generated by means of the operative connection of the spring washer with the bearing plate, and/or that the coating is an adhesive, a rubber coating and/or a plastic layer, or that the coating has a metallic layer or that the coating has a carbide layer, in particular wherein the carbide layer is applied to a surface of the spring washer which has been roughened in particular by means of a laser and/or wherein the carbide layer is applied to the spring washer by means of a high-speed laser cladding process (HS-LMD). Electric motor according to one of the preceding claims, characterized in that the first surface areas to be coated are those areas of the spring washer which have the greatest distance from the outer ring. Electric motor according to one of the preceding claims, characterized in that the second surface areas provided with the coating are those areas of the spring washer which have the smallest distance from the outer ring, in particular which touch the outer ring, and/or that the spring washer is made of a steel sheet to which the coatings are applied. Electric motor according to one of the preceding claims, characterized in that the outer ring is arranged so as to be displaceable in the axial direction, in particular in the bearing receptacle, and/or that the outer ring is connected to the bearing plate in a rotationally fixed manner by means of the spring washer, and/or that the spring washer touches both the outer ring and the bearing plate. Electric motor according to one of the preceding claims, characterized in that the bearing plate is connected to a stator housing of the electric motor, wherein a bearing flange is connected to the stator housing on the side of the stator housing axially facing away from the bearing plate, wherein an outer ring of a fixed bearing is accommodated in the bearing flange, the inner ring of which is placed on the rotor shaft, in particular wherein the inner ring of the fixed bearing is positioned against a shaft step and is axially delimited by a locking ring which is arranged in an annular groove of the rotor shaft, in particular wherein the outer ring of the fixed bearing axially rests on the one hand on the bottom of the bearing receptacle of the bearing flange and axially on the other hand is positioned against a locking ring arranged in an annular groove of the bearing flange. Electric motor according to one of the preceding claims, characterized in that the rotor shaft projects through a recess in the bearing plate and a fan is connected in a rotationally fixed manner to the rotor shaft on the side of the bearing plate axially facing away from the floating bearing, wherein a shaft sealing ring is accommodated in the bearing plate, in particular in the recess of the bearing plate, to seal the recess and seals towards the rotor shaft, in particular in that a sealing lip of the shaft sealing ring touches the rotor shaft. Electric motor according to one of the preceding claims, characterized in that the rotor shaft projects through a bore through the bearing flange, wherein a further shaft sealing ring is accommodated in the bore on the side of the fixed bearing axially facing away from the floating bearing and seals towards the rotor shaft, in particular in that a sealing lip of the further shaft sealing ring touches the rotor shaft, and/or that a stator laminated core with stator winding is accommodated in the stator housing and a squirrel cage is plugged onto the rotor shaft and connected in a rotationally fixed manner.

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