WO2013182338A2 - Stator for an electric motor and assembly which comprises the stator - Google Patents

Abstract

The present invention relates to a stator for an electric motor, which extends in an axial direction from a first end to a second end, wherein the stator has an end face which delimits said stator at each of the two ends, wherein the end faces have a first spacing from one another in the axial direction, and wherein the stator also has an outer surface which delimits same and connects the end faces to one another, and which has a second spacing from the axis in the radial direction relative to the axis, wherein the first spacing changes in the axial and/or tangential direction and/or the second spacing changes in the radial and/or tangential direction. The present invention further relates to a stator which is produced from a plurality of laminations and has mounting means which are provided for mounting the stator in a housing which at least partially surrounds said stator, wherein for acoustic decoupling of the stator from the housing the mounting means are at least partially produced from the laminations. The present invention further relates to an assembly having such a stator and a housing which is disposed on the stator.

Description

 description

title

 Stator for an electric machine and assembly that includes the stator prior art

The present invention relates to a stator for an electric machine, which extends along an axis from a first end to a second end, wherein it has an end face delimiting it at both ends and an outer surface bounding it, which connects the end faces, wherein the end faces have a first distance from one another and the outer face a second distance to the axis. The present invention further relates to an assembly having such a stator and a housing which is arranged on the stator.

In electrical machines form mechanical in operation

Deformation waves, which lead to noise. The

Noise is largely determined by the design of the electrical machine, for example, by its groove and pole number, its size, the shape and structure of the stator and rotor, materials used and more. The noise is transmitted to the outside through the connection of the stator with a female housing.

In order to reduce this noise, the document DE 10 2009 027 872 A1 discloses to arrange decoupling rings between the stator and the housing, by means of which the stator is acoustically decoupled from the housing.

Disclosure of the invention Object of the present invention is to provide a stator for an electrical machine and an assembly, the stator and optionally

Components with different thermal expansion coefficients comprises, to provide, the stator or the assembly causes a very low noise, and is inexpensive to produce.

The object is achieved with a stator for an electrical machine, which extends from a first end in an axial direction to a second end, wherein it at the two ends in each case a limiting him

 End face, wherein the end faces in the axial direction a first distance from each other, and wherein it also has a limiting outer surface which connects the end faces together, and which has a second distance from the axis in a radial direction to the axis, wherein the first distance in axial and / or tangential

Direction, and / or the second distance in the radial and / or tangential direction changes.

Since the second distance of the outer surface from the axis varies along the tangential direction and / or along the axis, and / or because the first distance of the end surfaces varies from each other along the radial direction and / or the tangential direction, the contour of the stator changes into axial, tangential and / or radial direction. This will be mechanical

Deformation waves changed, and / or the propagation of mechanical deformation waves that propagate in the axial, radial and / or tangential direction, hindered or even suppressed. Consequently, the

Modified mechanical deformation waves in their amount and their phase so that the noise of an electric machine with the stator according to the invention compared to an electric machine with a conventional stator with the same electromagnetic excitation is lower. Compared to an electric machine with a conventional stator, the electric machine with stator according to the invention therefore allows a higher electromagnetic excitation to the same noise to cause. The magnetic circuits in the electric machine with

Inventive stator can therefore be designed with higher electromagnetic excitations in the air gap. The stator or the electric machine are therefore considerably less expensive to produce.

A stator according to the invention has in its center a through bore arranged concentrically about an axis for receiving a rotor. Preferably, it is made of a plurality of fins, which are arranged lined up in the axial direction, made to avoid eddy current losses in the stator. The slats are preferably joined together to form a disk pack. Further preferably, they are made of iron or a ferrous metal alloy. Most preferably, they are stamped from sheets. It is likewise preferred for the stator to have elevations with respect to a lateral surface of a notional cylinder extending concentrically around the axis, which at least partially forms the outer surface and / or the end faces. The lateral surface preferably forms the parts of the outer surface which have the smallest second distance from the axis, and / or the parts of the

End faces that have the smallest first distance from each other.

In a preferred embodiment, which also solves the problem, the stator for the electric machine of a plurality of slats, which are arranged lined up in the axial direction, manufactured, the slats in their shape, outer contour, size, thickness, material and / or arrangement to each other so different that the stator relative to a lateral surface of a concentric about the axis extending fictitious cylinder has elevations. The elevations change the mechanical deformation waves and / or hinder the propagation of the mechanical deformation waves.

In a preferred embodiment, the elevations are arranged distributed uniformly in the axial, radial and / or tangential direction. All Particularly preferably, they are distributed in the axial, radial and / or tangential direction in such a way that they reduce or avoid propagation modes of the deformation waves of low order, since these are compared to

Propagation modes of the higher order strain waves have a greater energy content. Very particularly preferred impede the

 Surveys the propagation of first to sixth order modes, or even prevent them. It is preferred that the arrangement of the elevations and / or their number varies, so that the propagation of mechanical deformation waves of certain modes is specifically hindered or even suppressed. But the number of surveys in a preferred

 Embodiment not equal to the number of fashion. In a particularly preferred embodiment, the number of elevations in the axial, radial and / or tangential direction corresponds in each case to a prime number. However, it is also preferred an embodiment in which the elevations are arranged distributed unevenly in the axial, radial and / or tangential direction, so that their distance from each other in the axial, radial and / or tangential direction is different. The elevations form in a particularly preferred embodiment Lagerungsm means for storing the stator in him at least partially surrounding housing. It is particularly preferred that the

Elevations are formed elastically, so that despite different

Thermal expansion coefficient no additional connecting elements for connecting the stator to the housing are required.

Also preferably, the elevations form part of the housing or a bearing plate, another bearing and / or other construction components of the electrical machine.

In a preferred embodiment, which also achieves the object, the stator for the electric machine is made of a plurality of lamellae, which are arranged lined up in the axial direction, and has Lagerungsm ontel, which are provided for supporting the stator in a housing surrounding it at least partially, wherein the Lagerungsm means are made at least partially from the slats. The lamellae forming the stator are therefore used simultaneously in this embodiment for supporting the stator on the housing surrounding it at least partially.

It is preferred that the storage means form elevations, which extend in the axial, radial and / or tangential direction of the stator relative to a lateral surface of a notional cylinder arranged concentrically about an axis of the stator. For the slats preferably differ at least partially in their shape, thickness, size and / or outer contour. Also preferably, they are arranged in a tangential direction to each other twisted. In addition, it is preferred that the slats are made of different materials. Also in this embodiment, the propagation of mechanical deformation waves is therefore hindered and / or suppressed. The lamellae which form the main body of the stator therefore contribute directly to its acoustic decoupling from the housing.

It is further preferred that the bearing means axially and / or radially support the stator. In this case, the stator is preferably on one side or on both sides by depending on the structural conditions

Supporting support supported. For the housing is preferably cylindrical or cup-shaped or designed as a frame construction. The object is further achieved with an assembly comprising such a stator for an electric machine and a housing which surrounds the stator at least partially. Because this stator obstructs or even suppresses the propagation of the mechanical strain waves, the noise level of the assembly is lower compared to a conventional stator assembly.

The housing is preferably fixed to at least one bearing means of the stator, so that no additional components for securing the Stators are needed in the housing. Or also preferably, the elevations form part of the housing.

In addition, the Lagerungsm istel preferred elastic. As a result, when connecting housing, stator and / or optionally other components of the assembly with each other despite their different

Thermal expansion coefficient no additional elements needed. Most preferably, the Lagerungsm means are formed by elastic characteristics.

Preferably, a fastening means, in particular a groove or a web, and on the housing a for

Fastening means corresponding counter-fastening means, in particular a groove corresponding to the web or a groove corresponding to the web provided.

In a preferred embodiment, at least one free space is formed between the housing and the stator, which is provided with air, a

Damping mass and / or an elastic and / or plastic component is filled. In this case, the free space is preferably provided in the axial and / or tangential direction between the storage means. The materials introduced into the space air, damping mass, in particular

permanently elastic or hardenable mass, and / or elastic and / or plastic component allow acoustic damping, latent heat storage and / or thermal connection. The damping compound is preferably an adhesive, a gel, rubber, a potting compound such as cast resin, or a thermoplastic and / or thermosetting plastic. It is in addition to a liquid or an elastic and / or plastic component as a damping mass and granules. The elastic and / or plastic component is likewise preferably formed from a thermoplastic and / or thermosetting plastic. It is further preferred that the assembly a bearing plate, a

Motor shaft, bearings for bearing the motor shaft and / or others

Includes construction components. In this embodiment, it is preferred that the elevations and / or storage means form centering means and / or fixing means for the housing, the bearing plate, the bearing and / or the other construction components. Also preferably forms one of the surveys and / or Lagerungsm means the bearing plate, a bearing and / or another structural component. Further preferably, the elevations and / or storage means form stop surfaces, Einpässe, clips and / or

Verstemmflächen.

In addition, it is preferred that further clearances are provided between the bearing plate, the bearing and / or the further construction components and the stator, in which preferably air, damping mass and / or an elastic and / or plastic component is introduced.

The housing is preferably cylindrical or cup-shaped or as

Frame construction formed. In a preferred embodiment, it is made of stamped and bent parts and / or cast.

The object is further achieved with an electrical machine with such an assembly. The electric machine is preferably an electric motor. In principle, the invention is also applicable to other electrical machines, such as a starter or a generator. The electric machine is cheaper and quieter to produce.

The object is further achieved with a Versteilantrieb for a

Motor vehicle with such an electric motor. The object is further achieved with a hand tool with such an electric motor.

In the stator according to the invention a round and / or uniform outer contour is deliberately avoided, so that the propagation of particular rotating mechanical deformation waves is hindered. Through targeted Positioning the surveys, it is possible to spread the

targeted obstruction or even suppressed mechanical deformation waves of certain modes, and their transfer to neighboring

To reduce design elements. The arrangement of the

In principle, elevations vary randomly. In addition, the elevations formed from one or more fins are each simultaneously formed so that they have specific structural design features that ensure, for example, centering, fixation, sealing and / or damping of stator, housing, end shield and / or other design components, or these components partially form yourself.

In the following the invention will be described with reference to figures. The figures are merely exemplary and do not limit the general idea of the invention. Show it

Fig. 1 in (a) an assembly with a stator according to the invention for an electric machine in a perspective view and in (b) a section A - A through the assembly of (a);

Fig. 2 is a section through a further embodiment

 Assembly with a stator according to the invention;

Fig. 3 in (a) and (b) respectively different embodiments of

 Slats for a stator according to the invention;

4 shows in (a) another embodiment of an assembly with a stator according to the invention, and in (b) - (d) different lamellae for the stator; Fig. 5 in (a) and (b) each show a further embodiment of a

Assembly with a stator according to the invention, and in (c) an embodiment of a blade for the stator; 6 shows in (a) - (h) in each case a further embodiment of an assembly with a stator according to the invention; and

Fig. 7 in (a) - (c) each show a further embodiment of an assembly with stator according to the invention.

The assembly 1 of FIG. 1 (a) comprises a stator 2 and a housing 4 shown here only schematically by dashed lines. The stator 2 has teeth 60 which, for the sake of clarity, are also shown schematically only by dashed lines. The teeth 60 are for

 Winding provided with conductor loops, of which only winding heads 6 are shown schematically in the following figures (see, for example, Fig. 1 b). The coils 6 are provided for generating an electromagnetic field. The invention is not limited in terms of the number of teeth 60. It is also applicable to stators 2, which are used to generate the

electromagnetic field permanent magnets (not shown) instead of coils 6 have.

The stator 2 extends from a first end 201 to which it has a

End face 200, in an axial direction 31 along an axis 3 to a second end 202, where it also has an end face 200. The end surfaces 200 define the stator 2 and have a first distance 81 to each other. They are connected to one another on the side facing away from the axis 3 23 of the stator 2 by an outer surface 20 which also limits the stator 2.

The stator 2 is formed from a plurality of lamellae 21 lined up in the axial direction 31. The slats 21 are for example by means of

Punching packages linked together. However, the invention is not limited to stators 2 formed of fins 21, but also applicable to stators 2 formed of a solid body. At its center, the stator 2 has a through hole 30, which is arranged concentrically about the axis 3 and for receiving a rotor (not shown) is provided. In the through hole 30 provided for winding with the conductor loops teeth 60 are arranged.

The stator 2 limiting outer surface 20 has a second distance 82, 82 'to the axis 3, which varies here in the axial direction 31. Namely, the outer surface 20 here in a respective deformed region 25 at the two ends 201, 202 of the stator 2 further from the axis 3, as in an undeformed region 26 between the ends 201, 202 of the stator 2. The distance 82, 82 'of the outer surface 20 of the axis 3 and the outer diameter d, d' of the stator 2 changes abruptly here. Compared to a lateral surface 70 of a fictitious cylinder, which extends concentrically around the axis 3 and the same distance 82 from the axis 3, as the outer surface 20 in the undeformed region 26, the stator 2 therefore

 Bumps 22, which hinder the propagation of mechanical deformation waves in the axial direction 31. For this purpose, the lamellae 21 of the stator 2 in the deformed region 25 each have a larger outer diameter d 'than the outer diameter d of the lamellae 21 in the undeformed region 26. This sudden change in the outer contour of the stator 2 causes the lamellae

Propagation of a mechanical deformation wave in the axial direction 31 is hindered.

It can be seen in FIG. 1 (b) that the elevations 22 are used as storage means for supporting the housing 4 of the assembly 1. At this

Assembly 1 is the number of fasteners (not shown) for

Set the housing 4 on the stator 2 therefore reduced accordingly. In the following, the terms surveys 22 and storage means are used synonymously.

It is also apparent that a clearance 5 is formed between the stator 2 and the housing 4 in the undeformed region 26 between the bearing means 22. By way of example, it is shown in Fig. 1 (b) that the space 5 with Air 52 and / or a damping mass 51 or a

elastic and / or plastic component 51 can be filled.

The stator 2 of Fig. 2 (a) differs from the stator 2 of Fig. 1 in that it has in its deformed portions 25 at the two ends 201, 202 each have an end plate 27 which is thicker than the lamellae 21st in the undeformed area 26. The outer diameter d 'of each one

End lamella 27 is larger than the outer diameter d of the lamellae 21 in the undeformed region 26, so that the respective one end lamella 27 forms the elevation 22 or the storage means 22 for the housing 4. The outer surface 20 of the stator 2 therefore also in the deformed region 25 has a greater distance 82 'from the axis 3 than the distance 82 of the outer surface 20 from the axis 3 in the undeformed region 26. Again, the remaining space 5 in undeformed Area 26 with a

Damping means 51 filled.

On the other hand, the stator 2 of FIG. 2 (b) differs from the stator 2 of FIG. 2 (a) in that in the axial direction 31 it has approximately a further deformed region 25 in the center, in which a protrusion 22 is arranged at the same time as Lagerungsm means 22 for the surrounding the stator 2 housing 4 is used.

Slats 21 of the deformed region 25 are shown by way of example in FIGS. 3 (a) and (b). Here, the teeth 90 are not shown for clarity. In contrast to the lamellae 21 of the stator 2 of FIG. 1 (a) in the deformed region 25, which in the tangential direction 33, ie over the entire circumference, a larger outer diameter d ', than the lamellae 21 of this stator 2 in undeformed Region 26, the lamellae 21 of FIG. 3 have formed as segments elevations 22 which extend in the tangential direction 33 only over a partial angle 9. in the

The terms segments and elevations 22 are also used synonymously below. The segments 22 are arranged distributed uniformly in the tangential direction 33. Its outer diameter d 'is greater than the outer diameter d of the blade 21 between the segments 22, which here equal to the

Outside diameter d of the lateral surface 70 of the notional cylinder is. Since the lateral surface 70 has the smallest distance 82 of the outer surface 20 of the stator 2 from the axis 3, the outer diameter d of the lamella 21 between the segments 22 corresponds to an outer diameter d of the stator 2 in the undeformed region 26. The lamellae 21 of FIG. a) and (b) each have four segments 22. The number of segments 22 is basically arbitrary and may vary depending on the mechanical deformation waves to be obstructed. The two slats 21 shown differ by their outer contour, which is formed in the case of the blade 21 of FIG. 3 (a) abruptly and in the case of the blade 21 of FIG. 3 (b) rounded.

Such slats 21, in the tangential direction 33 segments 22 as

Have elevations 22, hinder the propagation of mechanical deformation waves in the tangential direction 33rd

Fig. 4 shows a further embodiment of such slats 21 with

Segments 22 for the deformed region 26. In comparison to the lamellae 21 of FIG. 3, the partial angle 9 of the segments 22 is selected to be smaller. In addition, the lamella 21 of FIG. 4 (a) has only two segments 22, while the lamella 21 of FIG. 4 (b) has four segments 22.

FIG. 4 (c) shows a plurality of lamellae 21 arranged one behind the other, the first visible lamella 21 having two segments 22. A total of eight equally distributed in the tangential direction 33 segments 22 are visible. Since the number of lamellae 21 is not recognizable here, this arrangement can only be formed of lamellae 21 of FIG. 4 (a), which are arranged in tangential direction 33 to one another. Or it is formed of a combination of blades 21 of Figs. 4 (a) and (b). It is also conceivable that the blade 21 of Fig. 4 (a) for this arrangement is combined with blades 21 having, for example, three, six or eight segments 22.

Depending on the number of segments 22 and the arrangement of the fins 21 in the tangential direction 33 to each other, the propagation of various mechanical deformation waves in the axial and / or

tangential direction 31, 33 impeded.

In FIG. 5 (a), the deformed portion 25 is simultaneously used as a bearing member 22 for the housing 4 and for sealing the clearance 5 between the housing 4 and the stator 2 and / or for damping transmission of mechanical deformation waves to the housing 4 , For this purpose, a 0-ring 28 is arranged in the deformed region 25. It is also conceivable

Production of at least some lamellae 21 in the deformed region 25 made of a plastic.

The distance 82 of the outer surface 20 from the axis is chosen to be smaller in the undeformed region 26 than the distance 82 "of the outer surface 20 from the axis 3 in the deformed region 25. In addition, the distance 82 'of the outer surface 20 in the region of the O-ring 28 is smaller than the otherwise deformed area 25, but chosen to be larger than in the undeformed area 26. The contour of the stator 2 therefore runs here in the axial direction 31 in a deliberately multi-stage manner.

A deliberately multi-level contour is also shown in FIG. 5 (b). However, here no 0-ring 28 is provided, but the deformed area can be used here in addition to the storage of the housing 4 for arranging, in particular clamping, other construction components (not shown) of the assembly 1. 5 (c) shows the lamella 21 of FIG. 3 (a), wherein in each segment 22, a fastening means 29 is additionally provided here, with which the lamella 21 can be fastened to the housing 4. The fastening means 29 is formed as a groove, so that a manufactured with this blade 21 stator 2 in a housing 4th is inserted, in the corresponding to this groove webs as

Gegenbefestigungsmittel (not shown) are provided. These segments 22 therefore form the bearing means 22 for supporting the housing 4. In the stator 2 of FIGS. 6 (a) - (d), the lamellae 21 are deformed

Area 25 not only a larger outer diameter d \ d "on compared to the outer diameter d of the fins 21 in the undeformed area 26th

But they are also deformed in the axial direction 31, namely angled. As a result of this change in the shape of the lamellae 21, the distance 81, 81 'of the end faces 200 of these stators 2 therefore changes in the radial direction 32 from one another. In addition, it also changes, if necessary, into a tangential one

Direction 33, for example, when using lamellae 21 with segments 22. This configuration of the stator 2 therefore hinders both the propagation of mechanical deformation waves in the radial 32 and in the axial direction 31, and for example when using segments 22 in the tangential direction 33rd

In the stator 2 of FIG. 6 (a), the elevations 22, which are used as Lagerungsm means 22 for the housing 4, each angled outwards, so that the distance 81, 81 'of the end faces 200 in the radial direction 32 for Housing 4 out increased. A mechanical deformation wave propagating in the radial direction 31 has a larger one in this stator 2

Wavelength and thus a lower energy content, in comparison to a stator 2, in which the storage means 22 are not angled outwards. In addition, these support means 22 allow the stator 2 to vibrate elastically. As a result, they are on the surrounding

Design components of the assembly 1 acting excitation and / or deformation energies for the mechanical deformation waves reduced. Optionally, sub-segments 220 of the protrusions 22 may also be angled inwardly to improve the statics of the assembly 1, as shown schematically in FIG. 6 (b). The stator 2 shown in Fig. 6 (c) is formed in both the axial and in the radial direction 31, 32 in the deformed region 25 multi-stage.

The elevations 22 of the stator 2 of Fig. 6 (d) are each angled at right angles and rounded. They therefore simultaneously form a mating surface during insertion of the stator 2 into the housing 4.

The assemblies of Figs. 7 (a) and (b) each have a cup-shaped housing 4, with a cylindrical wall 42 concentrically extending about the axis 3, and a base 41 arranged transversely to the cylindrical wall 42, in which a Bearing 44 is arranged for the stator 2.

In the case of both stators 2, the elevations 22 arranged at each of the ends 201, 202 are designed as storage means 22.

In the stator 2 of Fig. 7a, the arranged in the bearing 44 of the housing 4 Lagerungsm means 22 is bent at the first end 201 at right angles to the outside, so that not only the second distance 82, 82 ', 82 "of

Outside surface 20 of the stator 2 from the axis 3 in the axial and / or tangential direction 31, 33 changes in several stages, but also changes the first distance 81, 81 'of the end faces 200 in the radial and / or tangential direction 32, 33 from each other. The Lagerungsm means 22 at the second end 202 corresponds to the bearing means 22 shown in Figs. 1 and 2. Both Lagerungsm means 22 may be formed segment-shaped. The stator 2 is therefore mounted at the first end 201 in the axial direction 31 and at the second end 202 in the radial direction 32.

In the assembly of FIG. 7b, a bearing plate 43 is inserted into the housing 4 at the second end 202. The stator 2 is axially mounted in the bearing plate 43 and in the bottom 41 of the housing 4. For this purpose, the stator 2 at its two ends 201, 202 each have elevations 22 relative to the end face 200, which are formed from a plurality of right angles angled outward slats 21. As a result, the second distance 82, 82 ', 82 "of the Outer surface 20 of the stator 2 from the axis 3 in the axial and / or tangential direction 31, 33 in several stages, and the first distance 81, 81 'of the end faces 200 from each other. The bearings 44 for the stator 2 are in the bottom 41 and in the

End shield 43 each formed by a recess into which the

Lagerungsm means 22 of the stator 2 are inserted. They are secured against displacement by a preferably elastic clamping means 45, for example a ring or a spring.

When stored in the axial direction 31 propagating waves propagating in the radial direction 31 are reduced or not transmitted to the housing 4.

 Depending on the structural conditions, it may be necessary to form the housing 4 of the assembly 1 at both ends 201, 202 of the stator 2 differently. Such conditions are shown in FIGS. 8 (a) and (b) by way of example.

In both illustrated assemblies 1 only the end faces 200 of the stator 2 are partially surrounded by the housing 4 respectively. At both ends 201, 202 of the stator 2 4 edges 47 are provided on the housing, which are at least partially surrounded by elevations 22, which are formed from a few fins 21 of the stator 2. It is also conceivable that the edges 47 components of other components of the

Module 1 are, for example, a bearing plate. Then the lamellae can also be used for centering and fixing these components.

The stators 2 of Fig. 9 have elevations 22 which are not only

Lagerungsm means 22 form for the housing 4, but at the same time

End shield. They also form here a bearing 300 for a shaft (not shown) of the electric machine. In these stators 2, the elevations 22 are bent only after the winding of the stator 2. In the case of the stator 2 of FIG. 10, the elevations 22 form part of the housing 400. In the case of the embodiment of the stator shown here, moreover

Damping elements and / or elements for thermal connection 53 fixed to the survey 22. A bearing 46 for the shaft is formed here by a non-stator 2 housing part 4.

It is also conceivable for the stator 2 of FIG. 10 that the elevations 22 simultaneously form a mechanical connection with the housing part 4, so that the additional damping elements 53 can be dispensed with.

By the projections 22, the propagation of circumferential mechanical deformation waves is hindered or even suppressed. In addition, her

Transmission to the housing 4 in response to the storage of the stator 2 in the housing 4 at least reduced or prevented. The noise generated by an electric machine with stator 2 according to the invention is therefore significantly reduced.

Claims

Expectations

1 . Stator (2) for an electrical machine, which extends from a first end (201) in an axial direction (31) to a second end (202), with a boundary defining it at each of the two ends (201, 202). Has end face (200), wherein the end faces (200) have a first distance (81) from each other in the axial direction (31), and wherein it also has an outer surface (20) delimiting it, which connects the end faces (200) to one another, and which has a second distance (82) from the axis (3) in a radial direction (32) to the axis (3), characterized in that

the first distance (81) changes in the axial (31) and/or a tangential direction (33), and/or the second distance (82) changes in the radial (32) and/or tangential direction (33).

2. Stator (2) according to claim 1, characterized in that it is made from a plurality of lamellae (21) which are arranged in a row in the axial direction (31). 3. Stator (2) for an electrical machine, in particular according to one of the

previous claims, which is made from a plurality of slats (21) which are arranged in a row in an axial direction (31), characterized in that

the slats (21) differ in their shape, outer contour, size, thickness, material and/or arrangement from one another in such a way that the stator (2) has elevations relative to a lateral surface (70) of a fictitious cylinder extending concentrically around the axis (3). (200).

Stator (2) according to one of the preceding claims, characterized in that the elevations (22) are arranged evenly distributed in the axial, radial and/or tangential direction (31, 32, 33), or in particular the elevations (22) in the axial, Radial and / or tangential direction (31, 32, 33) are each provided distributed so that they reduce or avoid propagation modes of low-order deformation waves.

Stator (2) according to one of the preceding claims, characterized in that the elevations (22) form storage means for arranging a housing (4) that at least partially surrounds the stator (2).

Stator (2), in particular according to one of the preceding claims, for an electrical machine, which is made from a plurality of slats (21) which are arranged in a row in an axial direction (31), and which has storage means (200). , which are provided for storing the stator (2) in a housing (4) that at least partially surrounds it,

characterized in that

the storage means (200) are at least partially made from one or more slats (21).

Stator (2) according to one of the preceding claims, characterized in that the bearing means (200) support the stator (2) axially and/or radially.

Assembly comprising a stator (2) for an electrical machine according to one of the preceding claims and a housing (4) which at least partially surrounds the stator (2).

Assembly (1) according to claim 8, characterized in that

Housing (4) is fixed to at least one storage means (200) of the stator (2).

10. Assembly according to one of claims 8 - 9, characterized in that the storage means (22) is designed to be elastic.

1 1 . Assembly (1) according to one of claims 8 - 10, characterized in that on the storage means (22) there is a fastening means (201),

in particular a groove, and on the housing (4) a counter-fastening means (41) corresponding to the fastening means (201), in particular a web corresponding to the groove, are provided.

12. Assembly (1) according to one of claims 8 - 1 1, characterized in that a free space (5) is at least partially formed between the housing (4) and the outer surface (20) of the stator (2), which is filled with air ( 52), a damping mass (51), a mass for latent heat storage, and/or an elastic and/or plastic component.

13. Assembly (1) according to one of claims 8 - 12, characterized in that it comprises a bearing plate (43).

14. Assembly (1) according to one of claims 8 - 13, characterized in that the housing (4) is cylindrical or cup-shaped () or as

Frame construction is formed.

15. Electric machine, in particular electric motor, with an assembly according to one of claims 8 - 14.