EP3724971A1 - Stator arrangement comprising a winding arrangement - Google Patents

Abstract

A stator arrangement (20) has a stator core (22), a wire guiding arrangement (40) and a winding arrangement (24) with a winding wire (26), and is designed as an external stator arrangement. The winding arrangement (24) is designed as a delta circuit (25) and has a number SC of stator coils (28), for which number SC: SC = N * 3 where N = 1, 2, 3, 4, 5,.... The stator core (22) has a magnetic return path (30), stator poles (32) and slots (34) which are formed between the stator poles (32). The wire guiding arrangement (40) has an associated first contact-making arrangement (41) with a first contact element (51), an associated second contact-making arrangement (42) with a second contact element (52), and an associated third contact-making arrangement (43) with a third contact element (53), and the winding wire (26) runs without interruption from the first contact-making arrangement (41), via at least one of the stator coils (28A, 28B), to the second contact-making arrangement (42), from the second contact-making arrangement (42), via at least one of the stator coils (28C, 28D), to the third contact-making arrangement (43), and from the third contact-making arrangement (43), via at least one of the stator coils (28E, 28F), to the first contact-making arrangement (41), wherein the contact elements (51, 52, 53) are electrically connected to the winding wire (26) in order to serve as winding connections.

Description

 Stator arrangement with winding arrangement

The invention relates to a stator arrangement with a winding arrangement.

Stator arrangements should be able to be produced with as little effort as possible. In particular, the winding may be complicated depending on the stator configuration and the type of winding.

It is therefore an object of the invention to provide a new stator assembly.

This object is achieved by the subject matter of claim 1.

A stator assembly includes a stator core, a wire guide assembly, and a winding assembly having a winding wire and is formed as an external stator assembly. The winding arrangement is designed as a delta connection and has a number SC of stator coils, for which number SC applies:

 SC = N * 3 with N = 1, 2, 3, 4, 5, ....

 The stator core has a magnetic yoke, stator poles, and slots formed between the stator poles. The wire guide arrangement is a first contacting arrangement with a first contact element, a second

Kontaktieranordnung with a second contact element and a third

Contacting associated with a third contact element, and the

Winding wire runs without interruption from the first contacting arrangement via at least one of the stator coils to the second contacting arrangement, from the second contacting arrangement via at least one of the stator coils to the third

Contacting arrangement, and from the third contacting arrangement via at least one of the stator coils to the first contacting arrangement, wherein the contact elements are electrically connected to the winding wire, to serve as winding terminals.

As a result, a simple assembly is possible, in which the winding wire can be used for all stator coils. The number of contact elements can be reduced. According to a preferred embodiment, the Kontaktieranordnungen are offset by at least 110 ° to each other, preferably by 120 °. By dividing the Kontaktieranordnungen it is possible, the symmetry of the

 Increase winding arrangement. This is especially true at fast running

 Electric motors advantageous. Particularly advantageous is the symmetrical resistance when using a current regulator for controlling the winding arrangement. With different resistances, a current regulator requires different voltages in order to introduce equal currents into the phases.

According to a preferred embodiment, the contact elements on the

Wire guide arrangement distributed such that a division of the

Wire guide assembly in three sections of 120 ° is possible, wherein in each of the sections a contact element is provided. This distribution of the contact elements allows a high symmetry of the winding arrangement.

According to a preferred embodiment, the electrical differ

Resistances that exist between each two of the contact elements by less than 3% from each other, preferably by less than 2%, more preferably by less than 1% and more preferably by less than 0.5%. The electrical resistances between the two contact elements are a good and easily verprüfbares measure of the symmetry of the winding assembly. The values mentioned allow an advantageous use of the winding arrangement, in particular for high-speed electric motors (for example 40,000 rpm or 50,000 rpm, but they are also advantageous for lower speeds.

According to a preferred embodiment, the contacting arrangements are at least partially neither central to one of the stator poles nor central to one of the slots

arranged. This arrangement has proved to be advantageous for winding, in particular for the use of a needle winder, which after the

Kontaktieranordnung can dip into the stator interior.

According to a preferred embodiment, the winding wire is partially guided so that it after winding one of the stator poles in one of

Kontaktieranordnungen is guided from radially outside to radially inside. On the radial inner side of the winding wire can be performed so directly to a stator coil, and it is winding wire length and thus increased resistance avoided.

According to the invention, at least one of the contacting arrangements has a first one

Receiving opening for receiving the contact element and a second

Receiving opening for receiving the winding wire. This will be the

 Positioning of the winding wire and the contact element clearly and precisely predetermined by the contacting.

According to a preferred embodiment, the second receiving opening of the contacting arrangement extends in the radial direction. For winding is the radial

Direction advantageous, but in principle, other directions are possible.

According to a preferred embodiment, the first receiving opening extends in an axial direction of the stator assembly. This allows insertion of a contact element in the axial direction.

According to a preferred embodiment, the first receiving opening extends in a direction of the stator assembly, which deviates from the axial direction. As a result, other angles between the contact element and the winding wire can be achieved, which allow a favorable electrical connection with a larger area.

According to a preferred embodiment, the first receiving opening is formed at least partially crossing the second receiving opening. Especially with insulation displacement contacts is an accurate spatial allocation by the

Kontaktieranordnung advantageous, but also with other contacts.

According to the invention, at least one of the contacting arrangements extends on a first side of the second receiving opening in an axial direction farther away from the stator core than on the second side opposite the first side, in order to allow the winding wire to be caught during winding of the winding wire.

This embodiment has led to a significant simplification of the winding process and in particular to a higher process reliability. According to a preferred embodiment, the number N is at least 2, and the winding wire between the contacting arrangements extends over at least two of the stator coils. The winding wire can thus be used between two contact elements for a plurality of stator coils, and the number of contact elements can be kept small.

According to a preferred embodiment, the winding wire interconnects at least two of the stator coils in series between the contacting arrangements. This allows a series connection with the winding wire.

According to a preferred embodiment, the first contact element, the second contact element and the third contact element are formed as insulation displacement contact elements. These enable fast and reliable contacting.

According to a preferred embodiment, at least two of the

Kontaktieranordnungen the same design. This facilitates the insertion of the

Contact elements, and the making.

According to a preferred embodiment, the first contact element, the second contact element and the third contact element are the same. Such

Training is possible with the design, and it facilitates handling and storage with respect to the contact elements.

According to a preferred embodiment, at least two winding wires are provided, which are wound together. With exactly two winding wires one speaks of a bifilar winding. The electrical resistance is thereby lowered. Co-winding saves time and allows for better symmetry.

According to a preferred embodiment, the wire guide arrangement has at least one winding post on which the winding wire abuts, in order to allow a guidance of the winding wire and an influence on the length of the winding wire between two contact elements. By a suitable arrangement of the winding posts, the symmetry of the winding arrangement can be further increased. According to a preferred embodiment, an electric motor has a corresponding stator arrangement and a rotor arrangement. As a result, the electric motor can be easily manufactured.

According to a preferred embodiment, the electric motor is associated with a current regulator for controlling the current through the winding arrangement. The combination of the current regulator with the stator arrangement leads to a very advantageous electric motor.

Further advantages, embodiments, features and details of the invention will become apparent from the following description of preferred embodiments and from the drawings. The above features and

Feature combinations as well as the features and feature combinations mentioned below in the description of the figures and / or shown alone in the figures are not only in the respectively indicated combination, but also in others

Combinations or used alone. Identical or functionally identical elements are assigned the same reference numerals. For reasons of clarity, it is possible that the elements are not provided with reference numbers in all figures, but without losing their assignment. It shows:

1 is a plan view of a stator assembly with a stator core,

Fig. 2 in a cross section an electric motor with a rotor and with the

 Stator arrangement of Fig. 1,

3 is a plan view of a first axial side of the stator assembly of FIG. 2,

FIG. 4 is a plan view of a second axial side of the stator assembly of FIG. 2; FIG.

5 is a side view of the stator assembly of Fig. 2,

6 shows a detail VI of FIG. 3,

7 shows a detail VII of FIG. 3, Fig. 8 in a side view corresponding to FIG. 5, a first step of

 Winding process,

Fig. 9 in a side view corresponding to FIG. 5 shows a second step of

 Winding process,

10 is a longitudinal sectional view of a contacting arrangement with a contact element,

Fig. 11 in a parallel to Fig. 10 section the contacting arrangement with the

 Contact element of Fig. 10,

12 is a schematic representation of the winding connection of the stator arrangement of FIG. 3, FIG.

Fig. 13 in a more detailed schematic representation of the winding interconnection of

 Stator arrangement of Fig. 3, and

Fig. 14 shows the detail of Fig. 7 with bifilar winding.

1 shows a stator arrangement 20 with a stator core 22, which is designed, for example, as a laminated stator core or as a sintered component. The stator core 22 has a plurality of stator poles 32, between each of which grooves 34 are formed.

Preferably, the stator core 22 has a magnetic yoke 30, which magnetically connects the stator poles 32 together.

2 schematically shows an electric motor 10 with the stator arrangement 20 and a rotor arrangement 12. The rotor arrangement 12 has a rotor 13 and a schematically illustrated bearing arrangement 14, via which the rotor 13 is mounted rotatably about an axis of rotation 16. The bearing assembly 14 has, for example, a plain bearing, a roller bearing or a magnetic bearing, and the rotor 13 is, for example, a permanent magnetic rotor or a squirrel cage. The rotation axis 16 defines an axial direction and a radial direction of the electric motor 10 and the stator assembly 20, respectively. A slot insulation 48 is provided to insulate the stator slots 34.

A stator coil 28 of a winding assembly 24 is shown schematically. The stator coils 28 may be provided around the stator poles 32 in the region of the slots 34.

The stator assembly 20 is preferably formed as an outer stator assembly, and the rotor assembly 12 as an inner rotor assembly. But it is also a combination Innenstatoranordnung and outer rotor assembly possible.

The stator core 22 preferably has an outer diameter of 35 mm, but may be, for example, 30 mm or 50 mm or a value therebetween.

3 shows a top view of a first axial side 71 (see FIG

Stator assembly 20 of FIG. 2. On the first axial side 71 of the stator core 22, a wire guide assembly 40 is provided. The wire guide assembly 40 is preferably formed electrically non-conductive at least on its outer side, for example. Plastic. In the exemplary embodiment, the wire guide assembly 40 also extends into the region of the stator poles 32 to at least partially provide the slot insulation 48 for the winding assembly 24. However, the insulation between the stator core 22 and the winding arrangement 24 can also be effected by an additional component, for example by a plastic shell or an insulating paper.

The wire guide assembly 40 has a first contacting arrangement 41 with a first contact element 51, a second contacting arrangement 42 with a second contact element 52, and a third contacting arrangement 43 with a third

Contact element 53.

The winding arrangement 24 has a winding wire 26, which without interruption from the first contacting arrangement 41 via the stator coils 28A, 28D to the second contacting arrangement 42, from the second contacting arrangement 42 via the stator coils 28E, 28B to the third contacting arrangement 43, and from the third contacting arrangement 43 via the stator coils 28C, 28F extend back to the first contacting arrangement 41. There are thus in a six-pole stator each opposite lying stator coils are driven by one of the three phases. For better understanding, the winding wire 26 is shown drawn through between the first contacting arrangement 41 and the second contacting arrangement 42, shown in wide dashed lines between the second contacting arrangement 42 and the third contacting arrangement 43, and between the third contacting arrangement 43 and the first

 Kontaktieranordnung 41 shown in dashed lines. A winding post 83 is shown, on which the winding wire 26 can be fixed at the beginning and at the end of the winding process, for example by a few turns around the winding post. The winding post is preferably associated with a winding device. Particularly preferably, a needle winder device can be used as the winding device. After attaching the contact elements 51, 52, 53 of the winding wire 26 is fixed in the

Winding arrangement, and the two wire ends are cut off, for example, on the radially outer side of the first Kontaktieranordnung 41. Subsequently, the winding post 83 can be removed, and as waste only two short pieces of wire remain. This is very environmentally friendly and due to the extensive purity of variety (preferably pure enameled wire without additional plastic waste from the

Wire guide assembly) well recyclable. Alternatively, the winding post can be removed before the wire ends are cut off, or even before the contact elements 51, 52, 53 are set.

Shown is a six-pole or sechnutiger stator core 22. In a three-pole stator core 22 of the winding wire 26 would accordingly form between each two of Kontaktieranordnungen 41, 42, 43, a single stator coil 28. In a higher pole stator with, for example, 9, 12, 15 or 18 stator poles 32 would be with the

Winding wire 26 corresponding to a larger number of coils between each two of Kontaktieranordnungen 41, 42, 43 are formed.

The invention is well suited for a number SC of stator poles 32 and stator coils 28, for which number SC:

SC = N * 3 with N = 1, 2, 3, 4, 5, ....

In other words, the number SC of stator coils 28 is three or a multiple thereof. Preferably, the value of N is at least two. The contact elements 51, 52, 53 are preferably electrically connected to the winding wire 26, respectively, to serve as winding terminals and phase terminals, respectively. The electrical connection can for example be done by a solder joint. However, an embodiment of an electrical and mechanical connection by forming the contact elements 51, 52, 53 as insulation displacement contact elements is particularly preferred.

The Kontaktieranordnungen 41, 42, 43 are arranged offset in the embodiment by 120 ° to each other. Thus, when rotating the stator assembly 20 through 120 °, a contacting assembly 41, 42, 43 is positioned at the same locations as before rotation. This same distribution of Kontaktieranordnungen 41, 42, 43 and the contact elements 51, 52, 53 is advantageous because it is easier, the wire lengths between the individual Kontaktieranordnungen 41, 42, 43 in about the same length

form, as in an arrangement in which the Kontaktieranordnungen 41, 42, 43 are arranged side by side. Same wire lengths between the

Kontaktieranordnungen 41, 42, 43 cause the resistance of the

Winding wire 26 between each two adjacent Kontaktieranordnungen 41,

42, 43 is about the same. This results in a symmetrical course of

Voltages and currents, and especially at high speeds, such as. 60,000 rev / min, the electric motor 10 works better. The term resistance is used synonymously for the electrical resistance.

The wire lengths of the winding wire 26 between the contact elements 51, 52, 53 are relevant to the electrical resistance of the winding assembly 24. On the one hand, these are difficult to measure because the winding arrangement has to be separated for this purpose. On the other hand, the electrical resistance also depends on the

Tensile stress at which the winding wire 26 is wound. At high

Tensile stress, the winding wire 26 is thinner, and he has a larger

electrical resistance. The symmetry of the winding can be determined in a simple manner by measuring the resistance between the individual winding terminals, for example by measuring the electrical resistance between the contact elements 51, 52 and 52, 53 and 53, 51 measured electrical resistance on the one hand by the phase in the direct

On the other hand, but also on the other connected in series both phases. For example, in a measurement of the resistance between the contact elements 51, 52, the resistance of a parallel circuit of

 Winding wire section which is directly between the contact elements 51, 52nd

 is arranged, and the winding portion, which extends from the contact element 51 via the contact element 53 to the contact element 52, measured. The measurement is preferably carried out in the non-rotating state or without rotor in order to prevent an influence by induced stress due to the rotation.

For the evaluation of the symmetry, the above-mentioned resistances between the contact elements 51-52, 52-53 and 53-51 can be measured, and these

The electrical resistances determined differ preferably by less than 3%, more preferably by less than 2%, more preferably by less than 1% and more preferably by less than 0.5%. At these values, a good current pattern results in the winding assembly 24, and high speeds can also be achieved. When determining the differences, in each case the percentage difference between two determined resistance values is calculated, for example the difference between the resistance between the first contacting arrangement 41 and the second one

Kontaktieranordnung 42 and the resistance between the second

Kontaktieranordnung 42 and the third Kontaktieranordnung 43. In a prototype with a number of turns of 22 turns per stator coil 28, the resistance between each two adjacent Kontaktieranordnungen 41, 42, 43 was about 106 mO

(Milliohms). The maximum difference in resistance was 0.5 itiW, and this gives a deviation of less than 0.5%, which also corresponds to a corresponding difference in wire lengths. Differences in wire lengths of less than 3% are already good, at less than 2%, the winding arrangement works well at least at not too high speeds, and values less than 1% and less than 0.5% are excellent and suitable for high performance drives ,

The Kontaktieranordnungen 41, 42, 43 need not be exactly offset by 120 °, but preferably they are at least 110 ° offset from each other, for example. 110 °, 120 ° and 130 °.

Considering the contact elements 51, 52, 53, a circumferentially distributed arrangement of the contacting arrangements 41, 42, 43 can be described as in that the contact elements 51, 52, 53 are distributed on the wire guide arrangement 40 such that a division of the wire guide arrangement 40 into three sections of 120 ° is possible, wherein a contact element 51, 52, 53 is provided in each of the sections. In the illustrated stator assembly 20, for example, a first portion may be selected from the center of the stator coil 28F to the center of the stator coil 28B, a second portion from the center of the stator coil 28B to the center of the stator coil 28D, and a third portion from the center of the stator coil 28B Stator coil 28D to the center of the stator coil 28F.

The wire guide assembly 40 has in the embodiment in addition to the

 Kontaktieranordnungen 41, 42, 43 more winding posts 46, to which the

Winding wire 26 is applied or around which the winding wire is guided. Flierdurch is a guide of the winding wire 26 between the stator coils 28 and

between the Kontaktieranordnungen 41, 42, 43 and the contact elements 51, 52, 53 allows. Due to the position of the winding posts 46, the wire length of the

Winding wire 26 are influenced, and to adjust the wire lengths between the contact elements 51, 52, 53, a winding post 46, for example. In the CAD system further inward or further outward. Preferably, the winding posts 46 also serve as hold-down, which axial movement of the

Limit winding wire 26 during the winding process and so slipping the

Prevent winding wire 26 during the winding process.

Preferably, the contacting arrangements 41, 42, 43 are arranged neither centrally to one of the stator poles 32 nor centrally to one of the grooves 34. This has the advantage that the winding wire 26 can extend from the respective contacting arrangement 41, 42, 43 directly into the groove 34. In an arrangement centrally to the groove 34 of the

Winding wire 26, however, run obliquely through the groove to the respective stator 32 during the winding process and would take up unnecessary space. An arrangement in the middle of the stator pole 32 would result in an oblique course in the course between the contacting arrangement 41, 42, 43 and the associated stator coil 28, and this is disadvantageous during the winding process with a needle winder and leads to a greater wire length.

The winding wire 26 is guided in the Kontaktieranordnungen 42 and 43 such that it after winding one of the stator poles 32 from radially outside to radially inside in the corresponding contacting arrangement 42, 43 is guided. This is advantageous since the winding wire 26 can be guided directly on the radially inner side to form the stator coil 28. This results in short distances. The fact that the winding wire 26 is guided from radially outside to radially inside, does not mean that the

 Winding wire 26 must extend exactly in the radial direction, but he must run from further out to the inside, and this can also be done obliquely.

In the contacting arrangement 41, both wire ends of the winding wire 26 are preferably on the radially outer side, and thereby cutting off the

Winding wire 26 is facilitated after the winding process and a faulty

Cutting the winding wire 26 avoided. In the embodiment, a winding wire 26 is shown, which is wound through. It is alternatively possible to provide two or more winding wires that are wound through. Preferably, these can be wound together, and thereby a difference in the wire lengths is reduced. In a bifilar winding so for example wound in pairs.

4 shows the second axial side 72 (see FIG. 5) of the stator arrangement 20 opposite the first axial side 71. An end disk 49 is provided, which is preferably formed integrally with the wire guide arrangement 40 and the slot insulation 48. The training can, for example, be done by an injection molding process or another original molding process. Alternatively, the wire guide assembly 40 and the end plate 49 may be formed as half shells, each forming a portion of the slot insulation. It is also possible to provide the wire guide assembly 40, the end plate 49 and the slot insulation 48 as separate components.

5 shows the stator arrangement 20 in a side view. The contacting arrangements 41, 42, 43 with the contacting elements 51, 52, 53 and the winding posts 46 protrude in the axial direction from the stator core 22. The formation of the winding post 46 as hold-down can be seen, and this is provided on the radially outer side of a groove for guiding the winding wire 26.

On the contacting arrangements 41, 43 sliding surfaces 68 are visible, which are described in FIGS. 6 to 9. FIG. 6 shows the detail VI of FIG. 3. The contacting arrangement 41 has a first one

 Receiving opening 64 for receiving the contact element 51 and a second

 Receiving opening 66 for receiving the winding wire 26. The second

 Receiving opening 66 may also be referred to as a channel or groove, and the winding wire 26 or a plurality of winding wires 26 may be inserted into this. In a second step, the contact element 51 in the first

 Receiving hole 64 inserted, and the first receiving opening 64 may also be referred to as a bag. Preferably, the first receiving opening 64, the second receiving opening 66 formed at least partially crossing. Thereby, the insulation displacement contact 51 can be assembled in one step and at the same time the insulation displacement connection with the winding wire or wires 26 can be produced. The traversing angle is preferably 90 °, but it may for example be 85 ° or 60 °. If for the contact element 51 another technique (eg.

Soldering) is used, preferably a different training can be done. The contacting arrangement 41 preferably has a housing section 60 with a

Plug surface 62, and on the side of the plug surface 62, the contact element 51 can be inserted into the contacting arrangement 41. Preferably, the contacting arrangement 41 has a first side surface 73 (for example radially outward) and / or a second side surface

Side surface 74 (for example, radially inward). If both the first side surface 73 and the second side surface 74 are provided, preferably, the second receiving opening extends between the first side surface 73 and the second

Side surface 74.

In the exemplary embodiment, two free wire ends of the winding wire 26 are arranged on the radially outer side of the contacting arrangement 41. The projection 69 of the winding wires 26 in the region of the winding wire ends is preferably at most 0.8 mm. On the one hand, this makes it possible to cut well and, on the other hand, it reduces the risk of a winding wire end on the radially outer side becoming one

Short circuit with another electrically conductive component leads. A preferred supernatant is in the range 0.5 ± 0.3 mm.

The sliding surface 68 is rounded to a sliding of the

Winding wire 26 to allow along the sliding surface and thereby reduce the risk of tearing of the winding wire 26. A first side 81 of the second receiving opening 66 and a second side 82 of the second receiving opening 66 opposite the first side 81 are shown on the contacting arrangement 41.

The other contacting arrangements 42, 43 may be the same or different.

Fig. 7 shows the detail VII of Fig. 3 with the Kontaktieranordnung 42. It is in

 Following on the preferred differences to the contacting arrangement 41 of FIG. 6. During winding, the winding wire is guided radially inwards from the radially outer side of the contacting arrangement through the second receiving opening 66 and extends further into the groove 34. It is wound in a monofilament

Winding arrangement only one winding wire in the region of the second receiving opening 66 is provided, which is contacted by the contact element 52. The sliding surface 68 is on the radially outer side, since the winding wire is supplied during winding on the radially outer side.

A first side 81 of the second receiving opening 66 and a second side 82 of the second receiving opening 66 opposite the first side 81 are shown on the contacting arrangement 42.

8 shows a schematic representation of a winding process with the winding wire 26 on the second contacting arrangement 42. The winding wire 26 is wound around the

Winding post 46 out and from there on the radially outer side of the second

Kontaktieranordnung 42 led to this. Due to the design of the winding post 46 as a hold-down device, the hold-down device can be designed to be axially low, without the winding wire 26 slipping off from it. The contacting assembly 42 extends on the first side 81 of the second receiving opening 66 in an axial direction farther away from the stator core 22 than on the first side 81

opposite second side 82. This allows the needle winder 80 from

Winding posts 46 are guided along the radially outer side of the stator assembly 20 until it is in the vicinity of the second receiving opening 66 in the region of the second contacting arrangement 42. From there, the needle winder 80 can move radially inwards In this case, the winding wire 26 is caught by the contacting arrangement 42 on the first side 81, so that it does not slip off the contacting arrangement 42. Thus, a kind of threading aid is provided by the axially longer configuration on the first side 81.

As can be seen in FIG. 8, the further extent in the axial direction on the first side 81 of the second exception opening 66 is on both sides of the first

Exception opening 64 is provided to reduce the risk of incorrect threading of the winding wire in the second exception opening 66 and to facilitate the insertion of the winding wire 26.

FIG. 9 then shows, on FIG. 8, how the needle winder 80 is moved downwards or into the stator arrangement 20 in the radially inner region of the stator arrangement 20. In this movement of the needle winder 80, the winding wire 26 slides along the sliding surface 68 into the second receiving opening 66 for the winding wire 26. The sliding surface 68 is preferably rounded, thereby allowing a good sliding of the winding wire 26 in the longitudinal direction, and on the other hand

Destruction of the winding wire 26 or a possibly provided on this

Paint layer prevented.

10 shows a longitudinal section through a further embodiment of the

Contact element 51, and Fig. 11 shows a relative to the longitudinal section of Fig. 10 parallel offset section outside the first receiving opening 64. From the figures results in the operation of the contact element 51 for contacting the

Winding wire 26. The winding wire 26 runs along the second

Receiving opening 66, and the contact element 51 is from above into the first

Receiving opening 64 is inserted. The contact element 51 has a slot 54, and when inserting the contact element 51 into the first receiving opening 64 of the winding wire 26 is inserted into the slot 54. In other words, the contact element 51 includes the winding wire 26 by means of the slot 54 pliers. The winding wire 26 usually has an electrical insulation, for. B. an outer lacquer layer or another plastic insulating layer, so that no short circuit between the individual turns of the stator coils 28 is formed. By the

Moving the winding wire 26 along the slot 54 becomes the insulating layer abraded, and there is an electrical connection between the winding wire 26 and the contact element 51. The contact element 51 preferably has barbs 56 in order to prevent a falling out after the assembly of the contact element 51. The contact element 51 has in the embodiment on the upper side of a pin 55, via which a connection can be made, for example. To a power amplifier with

Power semiconductors.

12 shows a circuit diagram of the interconnection of the winding arrangement 24. This circuit already described can be referred to as a triangular series connection.

Fig. 13 shows a further schematic representation of the interconnection of

Winding arrangement 24 indicating the winding direction to the individual

Stator poles.

Fig. 14 shows the detail of Fig. 7, but with a bifilar winding in which two winding wires 26 are wound in parallel or in pairs, that are simultaneously wound by the needle winder.

Naturally, various modifications and modifications are possible within the scope of the present application.

LIST OF REFERENCE NUMBERS

 10 electric motor

 12 rotor assembly

 13 rotor

 14 bearing arrangement

16 axis of rotation

 0 stator arrangement

 2 stator cores

 4 winding arrangement

 5 delta connection

 6 winding wire

 8 stator coils

 0 conclusion

 2 stator poles

 4 grooves

 0 wire guide assembly

 1, 42, 43 contacting arrangement

 6 wrapping posts

 8 slot insulation

 9 end plate

 1, 52, 53 contacting element

 4 slot

 0 housing section

 2 mating surface

 4 first receiving opening

 6 second receiving opening

 8 sliding surface

 1, 72 first and second axial side

 3, 74 first and second side surface 0 winding device or Nadelwickler 1, 82 first and second side

3 winding posts

Claims

claims

 A stator assembly (20) comprising a stator core (22), a

 Wire guide assembly (40) and a winding assembly (24) having a winding wire (26) and is formed as an external stator, which winding assembly (24) is formed as a delta connection (25) and a number SC of stator coils (28), for which number SC applies:

SC = N ^* 3 with N = 1, 2, 3, 4, 5, ...,

 which stator core (22) has a magnetic yoke (30), stator poles (32) and grooves (34) formed between the stator poles (32),

 which wire guide arrangement (40) has a first contact arrangement (41) associated with a first contact element (51), a second contact arrangement (42) with a second contact element (52) and a third contact arrangement (42) with a third contact element (53),

 and which winding wire (26) is uninterrupted from the first one

 Contacting arrangement (41) via at least one of the stator coils (28A, 28B) to the second contacting arrangement (42), from the second contacting arrangement (42) via at least one of the stator coils (28C, 28D) to the third contacting arrangement (43), and from the third contacting arrangement (43) extends over at least one of the stator coils (28E, 28F) to the first contacting arrangement (41),

 wherein the contact elements (51, 52, 53) are electrically connected to the winding wire (26) to serve as winding terminals, wherein

 at least one of the Kontaktieranordnungen (41, 42, 43) has a first receiving opening (64) for receiving the contact element (51) and a second receiving opening (66) for receiving the winding wire (26) and

at least one of the contacting arrangements (41, 42, 43) extends on a first side (81) of the second receiving opening (66) in an axial direction farther away from the stator core (22) than on the second side opposite the first side (81) ( 82) to facilitate trapping of the winding wire (26) during winding of the winding wire (26).

2. Stator arrangement according to claim 1, wherein the contacting arrangements (41,

42, 43) are offset by at least 110 ° to each other, preferably by 120 °.

3. Stator arrangement according to claim 1 or 2, wherein the contact elements (51, 52, 53) on the wire guide assembly (40) are distributed such that a

 Division of the wire guide assembly (40) in three sections of 120 ° is possible, wherein in each of the sections, a contact element (51, 52, 53) is provided.

4. Stator arrangement according to one of the preceding claims, in which the electrical resistances, which between each two of the contact elements (51,

52; 52, 53; 53; 51) to distinguish less than 3% from each other, preferably by less than 2%, more preferably by less than 1% and more preferably by less than 0.5%.

5. Stator arrangement according to one of the preceding claims, wherein the Kontaktieranordnungen (41, 42, 43) at least partially neither centrally to one of the stator poles (32) nor centrally to one of the grooves (34) are arranged.

6. Stator arrangement according to one of the preceding claims, wherein the winding wire (26) is partially guided such that it led after winding one of the stator poles (32) in one of the Kontaktieranordnungen (41, 42, 43) from radially outside to radially inside is.

7. stator assembly according to claim 1, wherein the second receiving opening (66) of the contacting arrangement (41, 42, 43) extends in the radial direction.

8. A stator assembly according to claim 1 or 7, wherein the first

 Receiving opening (66) in an axial direction of the stator assembly (20) extends.

9. stator assembly according to claim 1 or 7, wherein the first

Receiving opening (66) extends in a direction of the stator assembly (20) which deviates from the axial direction.

10. Stator arrangement according to one of claims 1 to 9, wherein the first

 Receiving opening (64), the second receiving opening (66) is formed at least partially crossing.

A stator assembly according to any one of the preceding claims, wherein the number N is at least 2, and wherein the winding wire (26) extends between the contacting arrangements (41, 42, 43) over at least two of the stator coils.

12. Stator arrangement according to claim 11, wherein the winding wire (26)

 between the Kontaktieranordnungen (41, 42, 43) at least two of

 Stator coils (28) connected in series.

13. Stator arrangement according to one of the preceding claims, wherein the first contact element (51), the second contact element (52) and the third

 Contact element (53) are designed as insulation displacement contact elements.

14 stator assembly according to one of the preceding claims, in which

 at least two of the Kontaktieranordnungen (41, 42) are formed the same.

15. Stator arrangement according to one of the preceding claims, wherein the first contact element (51), the second contact element (52) and the third

 Contact element (53) are formed the same.

16. Stator arrangement according to one of the preceding claims, in which

 at least two winding wires (26, 26 ') are provided, which are wound together.

17. Stator arrangement according to one of the preceding claims, in which the wire guide arrangement (40) has at least one winding post (46) against which the winding wire (26) abuts to guide the winding wire (26) and influence the length of the winding wire (26 ) between two contact elements (51; 52; 53).

18. Electric motor (10) with a stator assembly according to one of the preceding claims and with a rotor assembly (12).