DE102021125488A1 - Stator of a rotary electric machine and a rotary electric machine - Google Patents

Abstract

The invention relates to a stator of an electrical rotary machine and to the electrical rotary machine itself second direction of extension (3) axially extending stator teeth (4) and between the stator teeth (4) several essentially axially extending slots (10) and in the slots (10) in each case at least one stator tooth (4) wrapped around at least one winding (21) of at least one conductor element (20), wherein in at least one groove (10) there is arranged a wider conductor element section (30) with a cross section having a width which is greater than the width of the cross section of at least one further conductor element section (31) in this groove (10 ), and this slot (10) has a cross-section with several depth sections (11,12) which define different slot widths (14) adapted to the widths of the conductor element sections (30,31).With the stator proposed here and the electrical Rotary machines are provided with facilities that combine an optimized copper fill factor with sufficient insulation strength and support of the conductors to absorb the forces acting on the winding.

Description

The invention relates to a stator of an electrical rotary machine and to the electrical rotary machine itself.

Electrical rotary machines are known in a variety of configurations for a wide variety of applications, in which case they primarily serve as drive units or are also operated as generators.

They each comprise a stator and a rotor arranged to be rotatable in relation thereto. Customary embodiments provide that the rotor is located radially inside the stator or is rotatably mounted there.

Different requirements are placed on the stator. The stator must be able to support or absorb the torque generated by the rotary electric machine and be able to transmit it to a housing or frame. Usually, the stator also at least partially forms a housing of the electrical rotary machine or is permanently connected to the housing. The stator is to be manufactured with a relatively high level of accuracy, so that it is ensured that an air gap between the stator and the rotor is sufficiently large, so that no collision between the rotor and the stator takes place even at high speeds of the rotor and centrifugal forces acting. On the other hand, however, this air gap must be kept small in order to achieve high electrical efficiency of the electric rotary machine. The mechanical attachment of the stator to a housing must be implemented with as little stress as possible, so that no deformation of individual elements of the status, such as laminations of laminated cores of the stator, occur, which in turn could lead to electrical losses.

Electrical conductors are located in slots formed between teeth of the stator in the form of coils of wire wrapped around a plurality of stator teeth. If necessary, these wire windings are glued or clamped to the stator teeth and/or completely encapsulated with an epoxy resin.

The electromagnetic coupling between the winding and the iron of the electric machine results in changing forces on the winding during operation of the electric machine, which increase the risk of wear or fatigue. In particular, with the increasing use of electrical rotary machines as drive units in motor vehicles, there is a requirement for cost-effective and time-efficient production.

The DE 10 2019 125 574 A1 discloses a method for producing a stator for an electrical machine, wherein a stator core with stator slots is provided in a first step, hair-pin elements are provided in a second step, and hair-pin elements in twos in a third step of the stator slots are arranged. The respective hair-pin element is selected from first and second hair-pin elements depending on the predetermined winding position and is arranged at a predetermined winding position in two of the stator slots.

For high power densities, the winding of an electrical machine must have a high copper fill factor. This is usually realized by using solid winding wire conductors. This type of winding is also referred to as bar winding. The conductors are referred to as rods. Rods of mostly rectangular cross-section are often chosen.

The 1 until 5 show conventional embodiments of a typical winding.

First, the general structure of a winding in a slot is shown 1 explained.

A stator yoke 1 forms a plurality of slots 10 . An example is in 1 only one such groove 10 is shown. The slot 10 is formed by stator teeth 4 arranged on both sides and extends in the radial direction along a first direction of extent 2 and in the axial direction along a second direction of extent 3. A plurality of conductor elements 20 or sections thereof are arranged in the slot 10 radially offset from one another. The conductor elements 20 together form a winding 21 . A respective conductor element 20 is formed by an electrically conductive conductor core 22 and an insulating sheathing 23 surrounding this conductor core 22 . The conductor elements 20 are usually arranged so compactly in the slot 10 that they essentially fill the slot 10 along the depth 13 of the slot 10 . Likewise, the conductor elements 10 are dimensioned in such a way that they are essentially as wide as the width 14 of the slot 10 . A high copper fill factor can be achieved in this way.

Due to the electromagnetic forces acting on the conductor elements, it may be necessary to dimension individual conductors or conductor elements with a larger cross section. Such embodiments are in the 2-5 shown.

2 shows an embodiment in which the deepest in the groove 10 arranged ladder element ment section has an insulating jacket 23 that is thicker in width than the other conductor element sections 20. Accordingly, this conductor element section is a wider conductor element section 30 than the further conductor element sections 31 arranged in the slot 10.

3 shows a similar embodiment, in which the conductor element section arranged deepest in the groove 10 has a thicker insulating sheathing 23 all around than the other conductor element sections 20. This also means that this conductor element section is a wider conductor element section 30 than the other conductor element sections of 31 that are arranged in the groove .

4 FIG. 12 shows an embodiment in which the wider conductor element portion 30 is the one located closest to the opening of the slot 10. FIG.

5 shows an embodiment with 2 wider conductor element sections 30, which are arranged closer to the opening of the groove 10 than the other conductor element sections 31

It can be seen that in the known embodiments with differently dimensioned conductor cross sections, an optimal fixation of the conductors in the slot and/or an optimal copper fill factor is not always achieved, since the arrangement of at least one wider conductor element section 30 gives the slot 10 a corresponding width 14 must.

Proceeding from this, the object of the present invention is to provide a stator and an electrical rotary machine comprising this stator that combine an optimized copper fill factor with sufficient insulation strength and support of the conductors to absorb the forces acting on the winding.

This object is achieved by the stator according to claim 1 and by the electrical rotary machine according to claim 8. Advantageous configurations of the stator are specified in subclaims 2 to 7.

The features of the claims can be combined in any technically meaningful way, with the explanations from the following description and features from the figures also being able to be used for this purpose, which include supplementary configurations of the invention.

The invention relates to a stator of an electrical rotary machine, which comprises a substantially hollow-cylindrical stator yoke and stator teeth distributed in the circumferential direction, starting from the stator yoke and extending radially in a first direction of extension and axially in a second direction of extension. Furthermore, the stator between the stator teeth comprises a plurality of essentially axially extending slots and in the slots in each case at least one winding of at least one conductor element wraps around at least one stator tooth, wherein in at least one slot a wider conductor element section with a cross-section with a width that is greater is arranged than the width of the cross section of at least one further conductor element section in this groove. This groove has a cross-section with several depth sections that define different groove widths that are adapted to the widths of the conductor element sections.

In the context of the present invention, the terms “radial”, “axial” and “circumferential direction” always refer to the axis of rotation of a rotor of the electric rotary machine according to the invention or to the arrangement of the stator teeth.

This means that the stator has at least one groove and in particular a plurality of grooves, which are of different widths along the depth of the groove, in adaptation to conductor element sections of different widths. The depth of the groove is defined here in the radial direction. The width is to be measured in the circumferential direction.

The relevant cross-section of the slot is defined here in a direction perpendicular to the axis of rotation of an electrical rotary machine, of which the present stator is a part.

A respective conductor element or its conductor element sections includes or include a metallic conductor core for electrical conduction and a sheathing made of insulating material. A respective conductor element can in particular have a rectangular cross section.

A conductor element forms at least one turn of the winding or a loop or a part thereof.

A wrap does not necessarily have to wrap around one or more stator teeth completely, but possibly also only partially.

An advantageous embodiment of the stator provides that a wider depth section of the slot, which has a greater width than an adjacent further depth section, is as deep as the depth of only one wider conductor element section arranged in it.

Alternatively, the stator can be designed in such a way that a wider depth section, which has a greater width than an adjacent further depth section, is as deep as the sum of the depths of a plurality of conductor element sections arranged in it.

As a result, the region of greater groove width extends as deep as the depth of a plurality of conductor element sections positioned radially one above the other. In this case, a plurality of conductor element sections positioned radially one above the other are also arranged in this region of greater slot width.

In particular, a wider depth section, which has a greater width than any further depth section of the groove, can be implemented in a radially deepest region of the groove. Accordingly, it is provided that the wider depth section is formed radially at the outermost point in the groove.

In one embodiment it is provided that the winding is a hairpin winding.

A hairpin technology is to be understood as a winding technology for stators in electric motors and generators, which is used in particular in traction motors for electric vehicles. Hairpin technology is based on plug-in coils that are inserted into the stator slots of the laminated core. These plug-in coils are called hairpins and resemble hairpins in their geometry.

Plug-in coils in U-geometry, or in so-called I-pin technology, or also in the concept of wave winding, as so-called continuous hairpins, can be used here as hairpins.

I-Pins are formed from straight copper wire elements that are inserted into the stator slots. Contact is made on both axial sides of the stator. In the case of the wave winding concept, so-called winding mats are produced from the conductor elements and then inserted into the slots from radially inside. If hair-pin technology is used, the individual conductor element sections can form complete pins.

A conductor element section that is wider in each case can be at least 20% wider than another conductor element section in the respective slot that has a smaller width.

Furthermore, the stator can be designed in such a way that the conductor element sections in the slot each have a conductor core and an insulating sheathing surrounding the conductor core, the width of the conductor core of the conductor element sections in a slot being the same and the width of the insulating sheathing of the wider conductor element section being greater than the width of the insulation covering of the further conductor element section, which has a smaller width.

A further aspect of the present invention is an electrical rotary machine which has a rotor and a stator according to the invention.

• 1: eine teilweise Seitenansicht einer zweiten herkömmlichen Ausführungsform eines Stators,
• 2: eine teilweise Seitenansicht einer zweiten herkömmlichen Ausführungsform eines Stators,
• 3: eine teilweise Seitenansicht einer dritten herkömmlichen Ausführungsform eines Stators,
• 4: eine teilweise Seitenansicht einer vierten herkömmlichen Ausführungsform eines Stators,
• 5: eine teilweise Seitenansicht einer fünften herkömmlichen Ausführungsform eines Stators, und
• 6: eine teilweise Seitenansicht einer erfindungsgemäßen Ausführungsform eines Stators.

The invention described above is explained in detail below against the relevant technical background with reference to the accompanying drawings, which show preferred embodiments. The invention is in no way limited by the purely schematic drawings, it being noted that the exemplary embodiments shown in the drawings are not limited to the dimensions shown. It is shown in

• 1 : a partial side view of a second conventional embodiment of a stator,
• 2 : a partial side view of a second conventional embodiment of a stator,
• 3 : a partial side view of a third conventional embodiment of a stator,
• 4 : a partial side view of a fourth conventional embodiment of a stator,
• 5 : a partial side view of a fifth conventional embodiment of a stator, and
• 6 1: a partial side view of an embodiment of a stator according to the invention.

On those representing the state of the art 1-5 has already been received. 6 shows an embodiment of a stator designed according to the invention. Here, too, a stator yoke 1 forms a plurality of slots 10 . An example is in 1 only one such groove 10 is shown. The slot 10 is formed by stator teeth 4 arranged on both sides and extends in the radial direction along a first direction of extent 2 and in the axial direction along a second direction of extent 3. A plurality of conductor elements 20 or sections thereof are arranged in the slot 10 radially offset from one another. The conductor elements 20 together form a winding 21 . A respective conductor element 20 is formed by an electrically conductive conductor core 22 and an insulating sheathing 23 surrounding this conductor core 22 . The conductor elements 20 are arranged in the groove 10 so compactly that they essentially fill the groove 10 along the depth 13 of the groove 10 .

The group of conductor elements 20 accommodated in the groove 10 comprises a wider conductor element section 30 and further conductor element sections 31, which have a smaller width than the wider conductor element section 30. The groove 10 is designed in such a way that it has a wider depth section 11 for accommodating the wider conductor section 30 has, and has a further depth section 12 for receiving the further conductor element sections 31. Accordingly, the width 14 of the groove 10 is dimensioned such that it is adapted in different depth sections 11,12 to the widths of the conductor element sections 30,31 respectively received there.

In this way, an optimal copper fill factor can be achieved, while at the same time providing optimal support for the conductor element sections 30, 31 and with optimized insulation strength.

With the stator proposed here and the electric rotary machine equipped with it, devices are made available which combine an optimized copper fill factor with sufficient insulation strength and support of the conductors to absorb the forces acting on the winding.

Reference List

1

stator yoke

2

first extension direction

3

second extension direction

4

stator tooth

10

groove

11

wider depth section

12

further depth section

13

depth

14

Broad

20

ladder element

21

winding

22

conductor core

23

insulation jacket

30

wider conductor element section

31

further conductor element section

QUOTES INCLUDED IN DESCRIPTION

This list of documents cited 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 assumes no liability for any errors or omissions.

Patent Literature Cited

• DE 102019125574 A1 [0007]

Claims (8)

Stator of an electrical rotary machine, comprising a substantially hollow-cylindrical stator yoke (1) and stator teeth (4 ) and between the stator teeth (4) several essentially axially extending slots (10) and in the slots (10) in each case at least one stator tooth (4) wrapping around at least one winding (21) of at least one conductor element (20), wherein in at least one groove (10) a wider conductor element section (30) with a cross section with a width that is greater than the width of the cross section of at least one further conductor element section (31) is arranged in this groove (10), and this groove (10) has a cross section with has a plurality of depth sections (11,12) which define different groove widths (14) adapted to the widths of the conductor element sections (30,31). stator after claim 1 , characterized in that a wider depth section (11) of the groove (10), which has a greater width (14) than an adjacent further depth section (12), is as deep as the depth of only one wider conductor element section (30) arranged in it . stator after claim 1 , characterized in that a wider depth section (11), which has a greater width (14) than an adjacent further depth section (12), is as deep as the sum of the depths of several conductor element sections arranged in it. Stator according to one of the preceding claims, characterized in that a wider depth section (11), which has a greater width (14) than each further depth section (12) of the slot (10), is implemented in a radially deepest region of the slot (10). is. Stator according to one of the preceding claims, characterized in that the winding (21) is a hairpin winding. Stator according to one of the preceding claims, characterized in that the wider conductor element section (30) is at least 20% wider than a further conductor element section (31) in the respective slot (10), which has a smaller width. stator after claim 6 , characterized in that the conductor element sections (30, 31) in the groove (10) each have a conductor core (22) and an insulating sheathing (23) surrounding the conductor core (22), the width of the conductor core (22) of the conductor element sections (30 , 31) is the same size in a groove (10), and the width of the insulating sheathing (23) of the wider conductor element section (30) is greater than the width of the insulating sheathing (23) of the further conductor element section (31), which has a smaller width. Electrical rotary machine, comprising a rotor and a stator according to one of Claims 1 until 7 .

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