WO2018099728A1

WO2018099728A1 - Stator for an electrical machine, a production method, and an electrical machine for a motor vehicle

Info

Publication number: WO2018099728A1
Application number: PCT/EP2017/079445
Authority: WO
Inventors: Mike Fippl; Lars WETTERAU
Original assignee: Volkswagen Aktiengesellschaft
Priority date: 2016-12-02
Filing date: 2017-11-16
Publication date: 2018-06-07
Also published as: CN110024263A; EP3549236A1; DE102016224066A1

Abstract

The invention relates to a stator for an electrical machine, the stator comprising a stator body (100) formed of individual stator laminations (110) and designed with axial boreholes (140). The stator body (100) has protrusions (130) on its outer peripheral surface, in which protrusions the axial boreholes (140) are arranged. The invention also relates to a production method for this stator and an electrical machine comprising such a stator.

Description

description

Stator for an electric machine, manufacturing process and

electric machine for a motor vehicle

The invention relates to a stator for an electric machine according to the preamble of

Patent claim 1.

The invention further relates to a manufacturing method for a stator and an electric machine for a motor vehicle.

An electric machine is generally understood to mean an electromechanical converter which converts electrical energy into mechanical energy and / or mechanical energy into electrical energy. An electric machine is in particular an electric motor (electric motor) and / or generator with a fixed stator or stator and a rotatably mounted in the stator rotor or rotor (inner rotor). The stator has a stator or

Stator body and at least one stator winding on. The stator body may be formed from individual stator laminations, which are combined to form a so-called laminated stator core. The prior art is made to DE 10 2008 007 578 A1.

The stator laminations can be perforated, wherein the perforations in the laminated stator core are axial

Form holes that then, for example, for the attachment of end plates or end caps, bearing caps or bearing shields, housing parts, etc., and / or for bracing the

Stator sheets are provided. This is shown, for example, in US 6,088,905 A (see

Reference numeral 62).

The object of the invention is to provide a trained with axial bores or axial bores stator, which is space and weight optimized.

This object is achieved by a stator according to the invention having the features of patent claim 1. With independent claims, the invention also extends to a manufacturing method and to an electric machine with a stator according to the invention. Preferred developments and embodiments of the invention will become apparent for all subject matter of the dependent claims, the following description and the drawings. The stator according to the invention has a stator body formed from individual stator laminations, which is formed with axial bores, in particular through-bores, wherein the stator body is provided with (radially projecting) on its outer circumferential or circumferential surface.

Projections is formed, in which the axial bores are arranged. Preferably, a plurality of projections distributed over the circumference are provided, wherein in each projection at least one axial bore is formed. The projections preferably extend over the entire axial length of the stator body or of the stator lamination stack formed from the stator laminations. Since there are voids between the projections, considerable space and weight or mass can be saved with the invention.

There may be provided three or four projections, in particular in the same

Angular distances, d. H. with 120 ° or 90 °, spaced from each other.

A first embodiment provides that the individual stator laminations, in particular all the stator laminations, are formed on the outer circumference with perforated, ear-like tabs which are aligned one above the other in the laminated stator core and form the projections.

A second embodiment provides that the projections as separate parts or

Individual parts are formed and attached to the outer peripheral surface of the stator body.

Preferably, the projections are by means of interlocking form-locking elements on

Stator body or attached to the laminated stator core. The interlocking elements may be designed for an undercut connection, preferably with a Verastungsgeometrie, which allows snapping by pressing. The positive locking elements are

in particular designed so that a dovetail joint can form. The projections can, in particular in one piece, be formed from metal, for example aluminum, or plastic, also fiber-reinforced plastic. Preference is given to injection-molded parts or cut extruded profile parts.

The second embodiment is particularly advantageous for a dip-impregnated stator. In dip impregnation, the entire stator is immersed in an impregnation medium, such as resin, and soaked. Subsequently, the resin is cured by supplying energy. The immersion impregnation allows a fixation of the stator laminations and a coating of the stator body and stator winding in a single process step. By the

Dipping impregnation is further ensured that the stator forms an internally optimally insulated as well as against abrasion protected overall system. The

Impregnation can also serve the sealing. The prior art is on the

EP 2 887 507 A1. When dip impregnation or similar impregnation process (eg trickle or Tröpfelimprägnierung), however, resin droplets and resin runners (resin lugs) can form on the stator, which then interfere with the installation or installation of the stator and, for example, to

Lead to misalignments. By one of the dip impregnation subsequent attachment of the projections, which then further example. Also act as a housing support surfaces and / or as a screw head bearing surfaces, this is prevented.

The production of an impregnated and in particular dip-impregnated stator can then comprise, for example, the following steps:

- Assembly of the stator, in particular by packaging the stator laminations and generating at least one stator winding;

- Impregnating and in particular dip impregnating the stator, preferably by

Immersing in a resin bath, draining and thermosetting the resin;

- Attaching the projections on the impregnated stator, in particular by pressing or shrinking (i.e., by creating a shrink connection), including the

Projections or the stator are heated or residual heat can be used by hot curing.

The projections attached subsequently to the impregnation process are thus resin-free on their outer surfaces, which may in particular act as contact surfaces or support surfaces, and on end surfaces, which may furthermore function in particular as screw head support surfaces. As a result, flat or even supports of the assembly stator (ZSB stator) are ensured despite impregnation. Subsequent processing to produce planarity and / or removal of resin drops and runners is not required. The stator can thus be installed without additional processing and, for example, be installed in a housing.

The invention will now be described by way of example and not by way of limitation with reference to the drawings. The features shown in the drawings and / or explained below may, even independently of specific combinations of features, be general features of the invention and further develop the invention.

Fig. 1 shows an axial plan view of a stator with projections.

Fig. 2 shows an axial plan view of a section of another stator body with separately formed projections.

Fig. 3 shows a perspective view of a projection formed as a separate part for attachment to the stator shown in Fig. 2. The stator body or carrier 100 shown in FIG. 1 is approximately circular cylindrical and is formed from a plurality of identical stator laminations 110, which are stacked in the axial direction L (perpendicular to the plane of the page) and form a laminated stator core. The stator winding grooves 120 for receiving a stator winding not shown are formed on the inner circumferential surface (internally-grooved stator).

On its outer peripheral surface, the stator body 100 is formed with four protrusions 130 through which axial through holes 140 extend. The through holes 140 are, for example, for the attachment of end plates or end caps, bearing caps or

End shields, housing parts, other assembly or functionally necessary components, etc. and / or for clamping the stator laminations 1 10 provided by means of through bolts or bolts. The through holes 140 may also be provided for mounting the stator in a housing. The projections 130 may also be used as attachment or

Anschraubvorsprünge be designated. However, the projections 130 can also serve as mounting or mounting surfaces and / or as spacers when installing or installing the stator, which is why manufacturing tolerances must be observed. The stator body 100 further includes a dip impregnated resin impregnation 150, which is only partially illustrated.

In the case of the first embodiment variant shown in FIG. 1, each stator lamination 10 has four tabs or ears 15 which are radially outwardly projecting and perforated and which form the projections 130 in the laminated stator core.

In the embodiment shown only partially in Fig. 2, all projections 130 are formed as separate parts or body 135 which are secured by means of dovetail 160 form-fitting manner on the outer peripheral surface of the stator 100 also formed of stator laminations. The axial length of the separate projections 130/135 corresponds to the axial length of the stator body or the stator lamination 100. Die

Dovetail connection 160 extends over the entire axial connection length.

FIG. 3 shows such a projection 130 formed as a separate part, which is already formed with a through-bore 140, with support surfaces 138 adapted to the outer circumferential surface of the stator body 100 and with a dovetail-shaped groove 137. (The other separate projections 130 are identical.) The stator 100 is formed with corresponding Nutzapfen 107, resulting from a corresponding

Outside contour 1 17 of the stator 1 10 result. The Nutzapfen 107 and the groove 137 form corresponding form-fitting elements. The projections 130 formed as separate parts 135 are preferably fastened to the stator body 100 only after a possible impregnation and are thus resin-free (ie the contact surfaces functioning as housing contact surfaces and / or as screw head contact surfaces are free of impregnation). Manufacturing tolerances can be better adhered to, in addition, the protrusions 130 are also free of resin drops and resin runners.

LIST OF REFERENCE NUMBERS

100 stator body

107 positive locking element (useful journal)

110 stator plate

1 15 tab

1 17 contour

120 grooves

130 advantage

135 separate part

137 positive locking element (groove)

138 support surface

140 bore

150 impregnation

160 dovetail joint

L axial direction

R radial direction

Claims

WO 2018/099728 """PCT / EP2017 / 079445 Claims

1. stator for an electric machine, with a stator of individual stator (1 10) formed stator (100) which is formed with axial bores (140), in particular through holes,

characterized in that

the stator body (100) is formed on its outer peripheral surface with projections (130) in which the axial bores (140) are arranged.

2. Stator according to claim 1,

characterized in that

the projections (130) extend over the entire axial length of the stator body (100).

3. Stator according to claim 1 or 2,

characterized in that

three or four projections (130) are provided, which are arranged at equal angular intervals.

4. Stator according to claim 1, 2 or 3,

characterized in that

the stator laminations (1 10) are formed with perforated tabs (1 15), which form the projections (130).

5. Stator according to claim 1, 2 or 3,

characterized in that

the projections (130) as separate parts (135) and formed on the

Outer peripheral surface of the stator (100) are attached.

6. Stator according to claim 5,

characterized in that

the separate projections (135) are secured by means of interlocking form-locking elements (107, 137).

7. stator according to claim 6,

characterized in that

the positive locking elements (107, 137) form a dovetail joint (160).

8. Stator according to claim 5, 6 or 7,

characterized in that

the separate projections (135) are integrally formed of metal or plastic.

9. A method of manufacturing a stator according to any one of claims 5 to 8, wherein the stator further comprises a dip impregnation, comprising the steps of:

- Assembly of the stator;

- dip impregnation of the stator;

- Attaching the projections (135).

10. Electrical machine, in particular alternator for a motor vehicle and / or traction motor for a motor vehicle with electric or hybrid drive, with a stator which is constructed according to one of claims 1 to 8 and / or produced by the method according to claim 9.