WO2019076543A1 - Stator and electric machine having a stator - Google Patents

Abstract

The present invention relates to a stator (1) for an electric machine, having a stator laminated core (2) comprising a stator axis (4) and with slots (3) provided in the stator laminated core (2), the slots (3) each comprising a slot base (3.1) and a slit-shaped slot opening (3.2) facing away from the slot base (3.1), an electrically insulating support element (6.1) for slot insulation (6) being arranged in each of the slots (3), which support element receives a number of electrical conductors (5) of an electrical winding, and at least one conductive shielding element (6.2) of the slot insulation (6) being arranged on the slot opening side is arranged on the support element (6.1), characterized in that the support element (6.1) is designed as a single part and overlaps itself in a region (9), the support element (6.1) forming a closed cross-section as a result of the overlap.

Description

 description

title

 Stator and electric machine with stator state of the art

The invention is based on a stator of an electric machine. Furthermore, the invention is based on an electric machine comprising the stator.

From the state of the art slot closures are mechanical

Closing the grooves and for electrical insulation between

Winding wires and the disk set of the stator known. Between the uppermost conductor in a stator slot and a rotor of an electric machine, an electric field arises, which due to the control by means of a pulse inverter leads to a high-frequency alternating voltage induced on the rotor and to high-frequency leakage currents when the rotor shaft is not insulated. These described effects affect to a very considerable extent the required electromagnetic compatibility. Furthermore, the charge induced by the electric field on the rotor leads to electrical breakdowns in a greasy film of the bearings, in particular

Ball bearing, which can drastically shorten their life.

Disclosure of the invention

The invention relates to a stator according to the preamble of independent claim 1, namely a stator of an electric machine, with a Statorachse having Statorblechpaket and provided in Statorblechpaket grooves, wherein the grooves each have a groove bottom and a groove bottom facing away from the slot-shaped groove opening, wherein in the grooves in each case an electrically insulating support member of a slot insulation is arranged, which receives a number of electrical conductors of an electrical winding and wherein at least one conductive and Nutöffnungsseitig arranged

Shielding element of the slot insulation is arranged on the carrier element. The Carrier element is formed in one piece, wherein the carrier element overlaps in a region and forms a closed cross-section through the overlap. In this case, the closed cross section can be understood as a substantially closed cross section. The overlapping region is formed by end regions of the carrier element. The shielding element is preferably arranged at least in the slot opening or in the area of the slot opening.

Furthermore, the invention is based on an electric machine according to the preamble of independent claim 13, namely an electric machine with a stator.

According to the invention, an electrically conductive shielding element which effects a shielding of the electric field is provided as soon as the

Shielding element suitably electrically connected to the stator lamination stack and to ground or so close to a Nutinnenoberfläche - without

necessarily galvanic contact - placed so that only the resulting capacitive connection to the suitably connected to ground stator to a sufficient electrical field minimizing

Charge shift leads. In order to produce this contact safely, a side surface of the slot insulation can be provided with the shielding, since due to tolerance addition of the conductor a secure contact force of

Shielding, for example, can not be guaranteed on tooth heads in the radial direction.

A reduction of the axial conductivity by segmentation may be necessary if the magnetic alternating flux in the yoke leads to an induced voltage surrounding the yoke cross section, which otherwise could lead to a burnup of the shield.

Preferably, the at least one shielding element of the slot insulation is arranged on the side of the carrier element facing away from the electrical conductors.

As a result, the electric field can be shielded towards the rotor of the electric machine.

The measures listed in the dependent claims are advantageous Further developments and improvements of the main claim specified stator possible.

The shielding element preferably has a coating which is formed as a lacquer layer, a foil or a metal sheet.

Advantageously, the overlapping region is arranged in the groove base, wherein the shielding element is on the overlapping region

located opposite side of the support element. Alternatively, the overlapping region is arranged in the groove opening or in the region of the groove opening, wherein the shielding element is located at least on the overlapping region of the carrier element.

Thus, parts of the support element overlap either in the region of the groove bottom or alternatively in the region of the groove opening, wherein the

 Shielding element is arranged nutseitig. The shielding element is arranged on an outer circumferential surface of the carrier element. Preferably, the overlapping parts are the legs of the carrier element. Preferably, a first leg of the carrier element overlaps a second one

Leg of the support member completely when the overlap is disposed in the groove opening. Preferably, the shielding element completely overlaps the first leg. Particularly preferably, the shielding element extends at least on one side to about half the height of a side edge of the groove.

Further advantageously, the overlapping region is arranged on the side facing away from the electrical conductors.

Further advantageously, in each case a plurality of shielding elements in the axial direction with respect to the stator axis are arranged on at least one of the support elements, which are electrically separated from each other and electrically connected at least on one side with the stator lamination. This has the advantage that the shielding elements do not short-circuit the lamellae of the laminated stator core over the entire length of the groove or of the laminated stator core, but only over a limited axial section, so that the through magnetic field induction parasitic current is kept sufficiently small in the axial direction.

Preferably, the at least one shielding element extends from the slot opening along at least one side edge of the groove wholly or partially. Preferably, the shielding element can also be guided completely over the cross section of the carrier element.

Further advantageously, at least one of the support elements in each case a plurality of shielding elements arranged in the axial direction with respect to the stator axis, which are electrically separated from each other, wherein the shielding elements have a transverse width measured to the axial direction, which is smaller than the width of the slot opening of the associated groove, and which are electrically connected via at least one web to the stator lamination.

Preferably, the at least one web extends from the slot opening along at least one side edge of the groove wholly or partially. Preferably, the web can also be guided completely over the cross section of the carrier element. Under a web can be understood an electrical contact lug.

Further advantageously, the adjacent shielding in the axial direction distances in the range between 10 μηη to 200 μηη, in particular 50 μηη on.

Despite the interruptions formed between the shielding elements, the shielding elements have a large area on the carrier element, so that the shielding effect is only insignificantly reduced by the interruptions.

Further advantageously, in each case a single, strip-shaped shielding element is provided on at least one of the carrier elements, which has a width measured transversely to the axial direction, which is smaller than the width of the slot opening of the associated groove, and electrically connected via at least one web to the stator lamination is.

This has the advantage that the shielding the slats of the

Statorblechpakets not over the entire length of the groove or the Stator laminations short-circuits, but only in the region of at least one ridge of the shielding. This will be by magnetic

Field induction resulting parasitic current in the axial direction almost completely suppressed. The surface of the shielding element is at the second

Embodiment because of the lack of interruptions greater than in the first embodiment, so that here too the shielding effect is sufficiently given.

Preferably, the at least one web extends from the slot opening along at least one side edge of the groove wholly or partially. Preferably, the

Bridge also be fully guided over the cross section of the support element.

Further advantageously, in each case a single shielding element is provided on at least one of the support elements, which has an elevation having a width measured transversely to the axial direction, which is smaller than the width of the slot opening of the associated groove, and which has a longitudinal extent in the axial direction and having a bridge electrically connected to the Statorblechpaket with the same height as the increase, wherein on the non-elevated areas which are lower relative to the increase, electrically insulating means are arranged. This will be another alternative

Design for the slot insulation allows.

Preferably, the at least one web extends from the slot opening along at least one side edge of the groove wholly or partially. Preferably, the web can also be guided completely over the cross section of the carrier element.

Further advantageously, a width of the shielding element is at most 2/3 of the thickness of the slot insulation less than a width of the slot opening and / or an axial length of the web measures a maximum of 5% of the laminated core length in the axial direction.

Preferably, the at least one shielding element is in each case on the

Carrier element glued, welded, painted, sprayed, in particular thermally sprayed on, dropped or vapor-deposited. Preferably, the at least one shielding element is not ferromagnetic, eg of aluminum, tin, copper, silver, gold.

Further advantageously, the shielding element in the longitudinal direction has a length in the range of 3 mm to 5 cm and / or the layer thickness of the at least one shielding element is in the range of 1 μηη and 100 μηη.

Preferably, the at least one shielding element is designed to be longer in the axial direction than at least one of the axial stator ends

Stator lamination.

Further advantageous is used as a shielding unkalandriertes or partially calendered insulation paper.

Brief description of the drawings

Hereinafter, embodiments of the invention will be described in detail with reference to the accompanying drawings. In the drawings:

Figure 1 is a sectional view of a stator according to the invention according to a first embodiment;

Figure 2 is a plan view of one of the grooves of the stator of Figure 1;

Figure 3 is a plan view of a folding sheet for the production

 Slot insulation according to the first embodiment;

Figure 4 is a schematic view of a fully folded groove insulation

 Sectional view according to the first embodiment;

Figure 5 is a sectional view of a stator according to the invention according to a second embodiment;

Figure 6 is a plan view of one of the grooves of the stator of Figure 5; Figure 7 is a plan view of a slot insulation folded sheet for

 Production of a slot insulation according to the second embodiment;

Figure 8 is a schematic view of a fully folded groove insulation

 Sectional view according to the second embodiment;

Figure 9 is a plan view of a slot insulation folded sheet for

 Production of an alternative slot insulation;

Figure 10 is a plan view of a slot insulation folded sheet for

 Production of a further alternative slot insulation;

Figure 1 1 is a plan view of one of the grooves of an inventive

 Stators according to another embodiment; and

Figure 12 is a sectional view of a stator according to the invention according to a further embodiment.

Embodiments of the invention

FIG. 1 shows a sectional view of a stator according to the invention of an electrical machine according to a first exemplary embodiment.

The stator 1 has a laminated stator core 2 and in the laminated stator core 2

provided grooves 3, which extend for example in the direction of a stator 4 of the stator lamination 2 and in which a number of electrical conductors 5 are arranged at least one electrical winding. The laminated stator core 2 is formed from a stack of laminations made of electrical steel, between each of which insulation may be provided to avoid eddy currents. The grooves 3 of the stator 1 are each formed between teeth 1 .1 of the stator 1 and each have a groove bottom 3.1 and a groove bottom 3.1 facing away from the slot-shaped groove opening 3.2. The cross-section of the slot openings 3.2 of the stator 1 is in each case narrowed, since the teeth 1.1 of the stator 1 at 5 their end facing away from the groove bottom 3.1 each having a cantilever tooth head 1 .2 projecting shoulder-shaped into the respective groove 3. In the groove 3 is a conductor 5 of the electrical winding receiving

Carrier element 6.1 a groove insulation 6 arranged. The slot insulation 6 comprises in each case an electrically insulating carrier element 6.1 and at least one shielding element 6.2 arranged on the carrier element 6.1 made of electrically conductive

Material. The electrically conductive shielding 6.2 are on the

Carrier element 6.1 arranged. The support member 6.1 is integrally formed and has a closed cross-section, resulting as a result

Overlapping of the support element 6.1 results. Due to the overlap, a region 9 is formed. In other words, the carrier element 6.1 of the slot insulation 6 closes the slot openings 3.2 of the slots 3, wherein the carrier element completely surrounds or surrounds the conductors 5 of the electrical winding. The carrier element 6.1 holds the electrical conductors 5 within the respective groove 3. The overlapping region 9 is arranged on the side facing away from the electrical conductors 5. Parts 6.1 .1 and 6.1 .2 of the support element 6.1 overlap in the region of the groove bottom 3.1. The overlapping parts 6.1 .1 and 6.1 .2 can be understood as the legs of the support element 6.1. The at least one shielding element 6.2 of the slot insulation 6 is arranged on the side facing away from the electrical conductors 5 side of the support element 6.1 and serves to shield the electric field to the rotor 8 of the electric machine. In this case, the at least one shielding element 6.2 is a coating, a

Lacquer layer, a foil or a sheet metal. This can be at least one

Shielding element 6.2 of the slot insulation 6 each glued to the support member 6.1, welded, painted, sprayed, dropped or vapor-deposited.

The support element 6.1 may preferably be an uncalendered or partially calendered insulation paper. Alternatively, the support member 6.1 may be made of a synthetic aromatic polyamide polymer, or an insulating film or an insulating tape. According to the first exemplary embodiment, the at least one shielding element 6.2 is applied in each case to the slot insulation 6 in a first step.

In a second step, the finished slot insulation 6 are inserted as a component in the respective groove 3. The shield 6.2 extends on both sides to about half the circumference of the support member 6.1.

The slot insulation 6 are inserted into the grooves 3 such that their support elements

6.1 respectively in the associated groove 3 immediately below the tooth tips 1 .2 and their at least one shielding 6.2 each at least partially in the slot-shaped groove opening 3.2 between the tooth tips 1 .2 is arranged. In order to ensure electrical contact of the at least one shielding 6.2 to the laminated stator core 2 after installation of the slot insulation 6, the

Shielding elements 6.2 in the first embodiment, in each case running wider than the slot openings 3.2 of the stator 1, so that the shielding 6.2 respectively beyond their slot opening 3.2 out in the region of the groove 3 below the respective tooth heads

1 .2 run and are each electrically contacted by the shoulders of the tooth tips 1.2. In addition, the shielding elements 6.2 extend on both sides to approximately half the height of the side edges 3.3, 3.4 of the groove 3. FIG. 2 shows a plan view of one of the grooves 3 of the invention

 Stator according to FIG. 1.

According to the first embodiment, a plurality of shielding elements 6.2 in the axial direction x with respect to the stator axis 4 are arranged one behind the other on at least one, for example on each of the slot insulation 6, wherein these

Shield 6.2 electrically separated from each other and each

at least one side, for example, on both sides, are electrically connected to the stator lamination 2. The shielding 6.2 of the stator 1 are after the first

 Embodiment each made of aluminum, copper, silver or gold.

The distance A between the example rectangular or

square shielding elements 6.2, for example, in each case between 10 μηη to 200 μηη, in particular 50 μηη. Through this small distance

between the shielding 6.2 is in spite of the interruptions between the shielding 6.2 still achieves a sufficient shielding effect. For example, the shielding elements 6.2 each have a thickness of between 1 μηη and 100 μηι, in particular 5 μηη.

The slot insulations 6 protrude out of their grooves 3, for example in the axial direction x with respect to the stator axis 4. As a result, the shielding elements 6.2 of the slot insulation 6 can additionally exert a shielding effect in a region between a winding head of the stator 1 and a short-circuit ring of the rotor 8, since in this way a capacitive coupling between the rotor

Winding the stator 1 and the short-circuit ring or the balance disk or parts of the rotor 8 is prevented.

FIG. 3 shows a plan view of a slot insulation folded sheet for forming the slot insulation 6 according to the first exemplary embodiment. The folded sheet has the support element 6.1, wherein on the support element 6.1 rectangular or

cuboid shielding 6.2 arranged at a distance A behind the other. At folding lines 7, the folded sheet can be folded to achieve a slot insulation 6, as shown in Figure 4.

Figure 5 shows a sectional view of a stator according to the invention according to a second embodiment and Figure 6 shows a plan view of one of the grooves of a stator according to the invention according to the second embodiment.

The second exemplary embodiment differs from the first exemplary embodiment in that a single, strip-shaped shielding element 6.2 is provided on at least one of the slot insulation 6, which has a width B1 measured transversely to the axial direction x, that is to say in a direction z, which is smaller in each case is as the width B2 of the slot opening 3.2 of the associated groove 3, and which is electrically connected via at least one, for example, two webs 10 with the stator lamination 2.

The shielding element 6.2 is thereby electrically connected exclusively via the at least one web 10 to the laminated stator core 2, wherein the at least one web 10 has a width B3 measured in the axial direction x with respect to the stator axis 4, which corresponds to the thickness D of one or more laminations of the Stator laminations 2 may correspond and, for example, in the range between 3 millimeters and 5 centimeters.

According to the second embodiment, the shielding 6.2 are each designed as a continuous, rectangular strip on which, for example, the webs 10 are provided centrally and on both sides. The at least one web 10 of the shielding 6.2 protrudes as in the first embodiment under the tooth tips 1 .2 of the respective groove 3 and is contacted in this way at the shoulders of the tooth tips 1 .2 electrically. An axial length of the webs 10 measures a maximum of 5% of the laminated core length in the axial direction x.

FIG. 7 shows a plan view of a slot insulation folded sheet for forming the slot insulation 6 according to the second exemplary embodiment. The folded sheet has the carrier element 6.1, wherein a shielding element 6.2 is arranged on the carrier element 6.1. The shielding 6.2 has a shape that as a

Plus sign or is designed as a cross. At fold lines 7 of the

Folding sheets are folded to obtain a slot insulation 6, as shown in Figure 8, for a stator. An overlap of parts 6.1 .1 and 6.1 .2 of the

Carrier element 6.1 takes place in the region of the groove bottom 3.1 as soon as the slot insulation 6 is inserted into a stator slot. Alternatively, overlapping can also take place in the region of the slot opening 3.2.

FIG. 9 shows an alternative slot insulation folded sheet. The slot insulation folding sheet has the carrier element 6.1, wherein a shielding element 6.2 is arranged on the carrier element 6.1. The shielding 6.2 has a rectangular base. The shielding element 6.2 has a first region 1 1, which is formed higher or thicker than second regions 12, which are formed flatter or thinner. The first region 1 1 has a shape that is formed as a plus sign or as a cross. On the second, flat areas 12 is an additional insulation layer 6.3. arranged or applied. At folding lines 7, the folded sheet can be folded to achieve a slot insulation 6 for a stator. An overlapping of parts 6.1 .1 and 6.1.2 of the support element 6.1 takes place in the region of the groove bottom 3.1, as soon as the slot insulation 6 is inserted into a groove of the stator. FIG. 10 shows a further alternative slot insulation folding sheet. in the

In contrast to the slot insulation folded sheet according to FIG. 9, the slot insulation folding sheet is designed such that overlapping of parts 6.1 .1 and 6.1 .2 of the support element 6.1 occurs in the region of the slot opening 3.2 as soon as the slot insulation 6 is inserted into a groove of the stator ,

Figure 1 1 shows a plan view of one of the grooves of a stator according to the invention according to another embodiment. The further

Embodiment combines features of Figures 2 and 5.

The stator 1 has a plurality of shielding elements 6.2, which are arranged one behind the other in the axial direction x with respect to the stator axis 4. Each of the shielding element 6.2 has a width B1 measured transversely to the axial direction x. The measured width B1 is in each case smaller than the width B2 of the slot opening 3.2 of the associated groove 3. The shielding element 6.2 is electrically connected to the stator laminated core 2 via at least one, for example two webs 10.

The shielding element 6.2 is thereby electrically connected exclusively via the at least one web 10 to the laminated stator core 2, wherein the at least one web 10 has a width B3 measured in the axial direction x with respect to the stator axis 4, which corresponds to the thickness D of one or more laminations of the

Stator laminations 2 may correspond and, for example, in the range between 3 millimeters and 5 centimeters.

According to the further embodiment, the shielding 6.2 are each designed as a single rectangular strip on which, for example, the webs 10 are provided centrally and on both sides. The at least one web 10 of the shielding 6.2 protrudes, as in the first embodiment, under the tooth heads 1 .2 of the respective groove 3 and is contacted in this way at the shoulders of the tooth tips 1 .2 electrically.

FIG. 12 shows a sectional view of a stator according to the invention of an electric machine according to a further exemplary embodiment. In contrast to FIG. 1, the parts 6.1 .1 and 6.1 .2 of the carrier element 6.1 are arranged such that the overlap is arranged in the region of the slot opening 3.2. At this Variant, the shielding 6.2 is still arranged in the region of the slot opening 3.2. The shield 6.2 is located at the opposite end to the overlapping region 9 of the slot insulation 6. The first leg 6.1 .1 completely overlaps the second leg 6.1.2, wherein the first

Leg 6.1.1 is completely overlapped by the shield 6.2. The

 Shielding element 6.2 extends on one side to approximately half the height of the right side edge 3.4 of the groove 3. This provides a further alternative embodiment for the slot insulation 6 allows.

Claims

claims

1 . Stator (1) of an electric machine, with a stator axis (4)

 having stator laminated core (2) and provided in the laminated stator core (2) grooves (3), wherein the grooves (3) each have a groove bottom (3.1) and a the

 Nutgrund (3.1) facing away slot-shaped groove opening (3.2), wherein in the grooves (3) each having an electrically insulating support member (6.1) of a slot insulation (6) is arranged, which receives a number of electrical conductors (5) of an electrical winding, and wherein at least one conductive shielding element (6.2) of the slot insulation (6) arranged on the carrier element (6.1) is provided, characterized in that the carrier element (6.1) is integrally formed and overlaps in a region (9), the carrier element (6) 6.1) forms a closed cross section through the overlap.

2. stator (1) according to claim 1, characterized in that the

 overlapping region (9) in the groove base (3.1) is arranged, wherein the shielding (6.2) on the overlapping region (9)

 opposite side of the support element (6.1) is located.

3. stator (1) according to claim 1, characterized in that the

 overlapping region (9) in the groove opening (3.2) or in the region of the groove opening (3.2) is arranged, wherein the shielding element (6.2) is located at least on the overlapping region (9) of the carrier element (6.1).

4. Stator according to one of the preceding claims, characterized in that the overlapping region (9) on the electrical conductors (5) facing away from the side is arranged.

5. stator (1) according to one of the preceding claims, characterized in that on at least one of the carrier elements (6.1) each have a plurality of shielding (6.2) in the axial direction (x) with respect to the stator (4) are arranged one behind the other, electrically separated from each other and are electrically connected at least on one side with the stator lamination stack (2). Stator (1) according to one of the preceding claims, characterized in that in each case a plurality of shielding elements (6.2) are arranged one behind the other in the axial direction (x) with respect to the stator axis (4) on at least one of the carrier elements (6.1) are, wherein the shielding (6.2) have a transversely to the axial direction (x) measured width (B1), which is smaller than the width (B2) of the slot opening (3.2) of the associated groove (3), and over at least one Footbridge (10) with the

Stator laminated core (2) are electrically connected.

Stator (1) according to one of claims 5 to 6, characterized in that the adjacent shielding elements (6.2) in the axial direction (x) have distances in the range between 10 μηη to 200 μηη, in particular 50 μηη.

Stator (1) according to one of Claims 1 to 4, characterized in that a single, strip-shaped shielding element (6.2) is provided on at least one of the carrier elements (6.1), which has a width (B1) measured transversely to the axial direction (x). each of which is smaller than the width (B2) of the groove opening (3.2) of the associated groove (3), and which is electrically connected via at least one web (10) with the stator lamination stack (2).

Stator (1) according to one of claims 1 to 4, characterized in that on at least one of the support elements (6.1) each have a single shielding element (6.2) is provided which has an elevation (1 1) which is transverse to the axial direction ( x) measured width (B1), which is smaller than the width (B2) of the slot opening (3.2) of the associated groove (3), and the one

Has longitudinal extent in the axial direction and one with the

Stator laminated core (2) electrically connected web (10) having the same height as the increase (1 1), wherein on the non-elevated areas (12) which lie opposite the elevation (1 1), electrically insulating means (6.3) are arranged.

Stator (1) according to one of Claims 6 to 9, characterized in that a width of the shielding element (6.2) is at most 2/3 of the thickness of the slot insulation (6) smaller than a width of the slot opening (3.2) and / or an axial one Length of the web (10) measures a maximum of 5% of a laminated core length in the axial direction (x).

1 1. Stator (1) according to one of the preceding claims, characterized in that the shielding element (6.2) in the longitudinal direction has a length in the range of 3 mm to 5 cm and / or that the layer thickness of the at least one shielding element (6.2) in the range of 1 μηη and 100 μηη lies.

12. stator (1) according to one of the preceding claims, characterized in that as a shielding (6.2) uncalendered or partially calendered insulation paper is used. 13. Electrical machine with a stator (1) according to one of the preceding claims.