DE102023201278A1 - Stator for an electrical machine, electrical machine and manufacturing process - Google Patents

Abstract

The invention relates to a stator for an electrical machine and to a method for producing a stator. Such an electrical machine can be a radial flux machine with distributed winding. The invention also relates to an electrical machine with such a stator and to a method for producing a stator.

Description

Technical area

The invention relates to a stator for an electrical machine and to a method for producing a stator. Such an electrical machine can be a radial flux machine with distributed winding. The invention also relates to an electrical machine with such a stator and to a method for producing a stator.

State of the art

In the document EN 11 2016 000 898 T5 describes an armature comprising: a rear yoke portion formed in a ring shape; a plurality of tooth portions arranged in a ring shape on an inner periphery of the rear yoke portion and forming a plurality of slots spaced apart from each other in the circumferential direction and open on an outer peripheral side, the plurality of tooth portions fitted to an inner peripheral surface of the rear yoke portion; a coil received in the plurality of slots; and an intermediate piece disposed between the coil and the rear yoke portion on an opening side of each of the plurality of slots.

Furthermore, the publication WO 2015/132111 A1 describe a stator for a rotating electrical machine, comprising: a first stack of yoke laminations of magnetic material forming an outer yoke, and a second stack of star-shaped laminations of magnetic material forming an inner core, the star plates having an annular base and teeth extending radially outward from the base, the bases and the teeth defining a plurality of notches opening radially from the side of a bore.

The DE 10253235 A1 shows a slip ring and commutator-free electric motor with a rotor driving a rotor shaft and a stator which are arranged coaxially to one another with a stator enclosing the rotor, the stator being formed by a stator core made of magnetizable material which forms pole elements distributed over the circumference and a stator winding carried by the stator core, and the stator core having a plastic insulating coating on its surfaces facing the stator winding which electrically insulates the stator core from the stator winding. A holding body for holding a rotary bearing for the rotor shaft is attached in one piece to the insulating coating on at least one end face of the stator core.

Description of the invention

The invention is based on the object of providing a stator which has improved functionality, in particular a higher power density and an improvement in efficiency, while being of cost-effective construction. Furthermore, there is a requirement for an electrical machine and a corresponding method for producing a stator.

Claim 1 provides a stator for an electrical machine, the stator comprising: a toothed star having a plurality of teeth, stator slots being provided between the teeth, a yoke ring (in particular made of soft magnetic material) which surrounds the toothed star at least in sections, an insulating body being provided which is mounted in the region of the stator slots and separates a winding relatively from the toothed star. Preferably, one winding is accommodated in each of the stator slots. The insulating body extends beyond one end face of the teeth, preferably beyond the end faces of the teeth. According to a preferred embodiment, the insulating body extends over both end faces of the teeth.

The stator according to the invention has the advantage that it is provided with a comparatively inexpensive insulating body. The insertion of slot insulation paper is not necessary.

The non-conductive, electrically insulating material of the insulation body also enables the formation of a stator with direct winding cooling by flooding the stator with oil or another electrically non-conductive cooling medium in order to form a compact and lightweight, cost-effective electrical machine with high power density and high efficiency. Furthermore, the stator flooded with coolant can be encapsulated without having to insert a gap tube into the air gap of the machine. This gap tube would otherwise increase the magnetic air gap of the motor and would result in a lower power density in such an electrical machine.

As previously described, the insulating body extends beyond one end face of the teeth (preferably the end faces). In this way, the area of the stator beyond the end face can be sealed relative to the rotor. It is preferred that the insulating body is formed in one piece.

According to one embodiment, the insulating body has at least partially beyond the Front side of the teeth has a cylindrical or substantially cylindrical shape. According to a modification, however, a step can also be formed in an area beyond the front side of the teeth in order to accommodate, for example, interconnection rings.

The invention is particularly aimed at a stator for a rotating electrical machine in an internal rotor radial flux design, but can also be transferred to all types of electrical machines, both rotary and translatory. Electrical machines can be used both as motors and generators.

According to one embodiment, the insulation section body is formed by casting or overmolding the toothed star. This allows different areas of the insulation body to be formed in one piece, thereby guaranteeing the tightness and/or insulation effect.

Furthermore, the stator can be designed to guide a liquid cooling medium through the stator slots. With direct winding cooling by flooding the stator with oil or another electrically non-conductive cooling medium, it is possible to cool the winding of the electrical machine more efficiently and to make greater use of it in order to form a compact and lightweight, cost-effective electrical machine with high power density and high efficiency.

According to a further embodiment, the stator comprises a slot insulation closure element which is attached to at least one stator slot such that an open region of the stator slot is closed. In particular, the slot insulation closure element is attached to a radially outer side of the stator slot. By attaching the slot insulation closure element in a stator slot, it is fixed and thus it is ensured that the slot insulation closure elements close the stator slot.

In order to securely fix the slot insulation closure element in the stator slot, the slot insulation closure element can have one or more locking elements that penetrate or snap into corresponding recesses.

It is preferred that the toothed star and/or the yoke ring has several segments in the circumferential direction. The toothed star and/or the yoke ring can thus be assembled segment by segment during assembly.

According to a further embodiment, the insulation section body has a greater thickness in sections in the region of a groove base, so that one or more channel-like structures are formed.

According to another embodiment, the insulation section body can be flat in the region of a slot base and thus adapted to the shape of the winding.

Furthermore, according to the invention, an electrical machine is provided which has a stator according to one of the preceding aspects. The stator can be accommodated in a housing of the electrical machine.

It is preferred that a rotor is also provided, which is preferably designed as an internal rotor. Such an electrical machine can be used both as a motor and as a generator.

The electric machine can have a first sealing ring arranged on a cover of the housing and/or a second sealing ring arranged on the housing, wherein the insulating body is in contact with the first and/or second sealing ring. Thus, a section in the region of the stator is separated from a section in the region of the rotor by the insulating body, and a cooling liquid can be passed through the stator without impairing the function of the rotor.

According to a further aspect of the invention, a method for producing a stator (or an electrical machine) is provided, which method comprises the following steps: providing a toothed star having a plurality of teeth (in particular made of soft magnetic material, such as stacked electrical sheet or soft magnetic composites/metal powder), with stator slots being provided between the teeth, forming an insulating body in the region of the stator slots and on an end face of the stator, preferably on end faces of the stator, inserting a winding into the stator slots provided with an insulating body, in particular closing the slots together with the winding using slot insulation closure elements, and attaching a yoke ring (in particular made of soft magnetic material) to the toothed star in such a way that it surrounds the toothed star at least in sections.

One of the advantages of the method is that the access when inserting the winding into a stator slot is relatively easy due to the access from the outside, meaning that the method can be better automated and is more cost-effective. For further advantages, please refer to the explanations on the stator or the electrical machine.

Preferably, the insulating body extends beyond one end face of the teeth.

It is preferred that the method is used to produce a stator or an electrical machine according to one of the aforementioned aspects. In this way, the region of the stator located beyond the front side can be sealed relative to the rotor. It is preferred that the insulating body is formed in one piece.

According to one embodiment, the insulating body has a cylindrical or substantially cylindrical shape at least in sections beyond the front side of the teeth. According to a modification, however, a step can also be formed in an area beyond the front side of the teeth in order to accommodate, for example, interconnection rings.

The insulation body can be formed by casting or overmolding the toothed star. This makes it possible to form the insulation body in one piece. A non-conductive, electrically insulating material is used for this, which also enables the formation of a stator with direct winding cooling.

Short description of the drawings

• 1 zeigt einen Zahnstern eines Stators in einer Ausführung ohne Steg zwischen den Zähnen und einem Isolationskörper mit zylinderartiger Fortführung des Isolationskörpers im Bereich der Wickelköpfe.
• 2a zeigt eine Schnittansicht des Zahnsterns gemäß 1, wobei der Isolationskörper am zum Luftspalt zwischen Stator und Rotor weisenden Nutgrund einen Kanal aufweist, wobei ferner eine Stufe in radialer Richtung sowohl am Zahn als auch im Isolationsköper zu erkennen ist.
• 2b ist eine Modifikation des in 2a dargestellten Zahnsterns, wobei der Isolationskörper am Nutgrund ohne Kanal ausgebildet ist.
• 3 zeigt eine Schnittansicht einer zweiten Ausführungsform eines Zahnsterns, wobei der Zahnstern mit einem Steg ausgebildet ist und ein Isolationskörper am Nutgrund einen Kanal aufweist.
• 4a veranschaulicht einen Zahnstern gemäß einer dritten Ausführungsform mit einem Doppel-Steg.
• 4b ist eine Schnittansicht eines Abschnitts des Zahnsterns gemäß 4a.
• 5a zeigt den Zahnstern gemäß 4a mit dem Isolationskörper, mit einer eingebrachten Wicklung und mit einem elektrisch isolierenden Nutisolationsverschlusselements zum Verschließen der Nut.
• 5b ist eine weitere Ansicht der in 5a dargestellten Ausführungsform mit aufgesetztem Jochring.
• 6a zeigt eine vierte Ausführungsform eines Nutisolationsverschlusselements mit Rastnasen, die in einen jeweiligen Hinterschnitt an einem Zahn eingreifen.
• 6b ist eine Detailansicht des in 6a dargestellten Nutisolationsverschlusselements mit Rastnasen.
• 7 zeigt eine elektrische Maschine in Radialfluss-Innenläuferbauart mit gegen einen Rotor gekapseltem Stator.
• 8 zeigt eine weitere Ausführungsform einer elektrischen Maschine in Radialfluss-Innenläuferbauart, wobei der Isolationskörper in einem Bereich jenseits der Stirnseite der Zähne eine Stufe aufweist.

Further features and advantages of the invention will become apparent from the following description of embodiments with reference to the accompanying drawings.

• 1 shows a toothed star of a stator in a design without a web between the teeth and an insulating body with a cylindrical continuation of the insulating body in the area of the winding heads.
• 2a shows a sectional view of the tooth star according to 1 , wherein the insulating body has a channel at the bottom of the groove facing the air gap between the stator and the rotor, wherein furthermore a step in the radial direction can be seen both on the tooth and in the insulating body.
• 2b is a modification of the 2a shown tooth star, whereby the insulating body at the bottom of the groove is formed without a channel.
• 3 shows a sectional view of a second embodiment of a toothed star, wherein the toothed star is formed with a web and an insulating body has a channel at the groove base.
• 4a illustrates a tooth star according to a third embodiment with a double bar.
• 4b is a sectional view of a portion of the toothed star according to 4a .
• 5a shows the tooth star according to 4a with the insulating body, with an inserted winding and with an electrically insulating slot insulation closure element for closing the slot.
• 5b is another view of the 5a illustrated embodiment with attached yoke ring.
• 6a shows a fourth embodiment of a slot insulation closure element with locking lugs which engage in a respective undercut on a tooth.
• 6b is a detailed view of the 6a shown slot insulation closure element with locking lugs.
• 7 shows an electrical machine in radial flux internal rotor design with a stator encapsulated against a rotor.
• 8 shows a further embodiment of an electrical machine in radial flux internal rotor design, wherein the insulating body has a step in a region beyond the front side of the teeth.

Description of embodiments

Exemplary embodiments of the invention will be described clearly with reference to the accompanying figures. Certain modifications of the embodiments explained below can be combined with one another to form further variants.

1 shows a toothed star 1 according to a first embodiment. The toothed star 1 is part of the iron core of the stator and is provided with windings as explained below. Furthermore, a stator comprises a yoke ring (in 1 not shown), which is arranged according to the design of the first embodiment on the outer peripheral side of the toothed star 1. In addition, in this context, reference is already made to the 5b shown view, which shows a stator with toothed star and yoke ring.

In the 1 In the state shown, the toothed star 1 according to the first embodiment is prepared for further processing (fitting with windings). The toothed star 1 comprises a plurality of teeth 10, with stator slots being formed between the teeth 10, into which windings are introduced in a further work step.

According to the first embodiment, the teeth 10 of the tooth star 1 are provided separately from one another (without a web) and have an insulating body 15 on their flanks (the side facing the stator slot). The insulating body 15 extends along the respective tooth 10 to the slot base and provides electrical insulation of a winding to be introduced into the stator slot relative to the tooth star 1. Furthermore, an inner area towards the rotor of the respective stator slot is sealed with the insulating body 15, so that a cooling liquid can flow through the stator slot in the axial direction, but does not escape radially from the stator in the direction of the rotor.

The insulating body 15 also extends in the axial direction beyond a front side of the teeth 10 of the toothed star 1 in order to provide a fluid-tight seal in this area as well. The insulating body 15 extends in a substantially axial direction. The insulating body 15 extends beyond the front side of the teeth in a cylindrical or substantially cylindrical shape.

According to a modification, however, a step can also be formed in an area outside the front side of the teeth 10 of the toothed star 1, for example to accommodate interconnection rings (see the embodiment described below in 8 ).

During manufacture, the insulating body 15 is formed along the axial length of the teeth 10 by casting or overmolding the tooth star 1 and is thus attached to and around the teeth 10. In this way, the insulating body 15 adheres flatly to the teeth 10 and provides a continuous insulating layer as well as a seal against the cooling liquid between the adjacent bodies.

2a shows a sectional view of a section of the toothed star 1, wherein the insulating body 15 has a greater thickness in sections in the area of the slot base and thus, viewed in the axial direction, forms one channel (or several). Thus, a cooling liquid that flows through the stator slots during operation and cools the windings inserted into the stator slots can also be guided in the channel formed in the area of the slot base, which results in particularly efficient cooling in the area of the air gap adjacent to the rotor.

The channel-like design of the section of the insulating body 15 in the area of the groove base can be achieved by inserts present in the injection molding machine or in the tool, along which a liquid plastic flows in. After the plastic has at least partially hardened and the insulating body 15 has thus been formed, the inserts are removed or the tool of the injection molding machine opens.

2b shows a modification of the 2a An insulating body 15' is formed during manufacture along the axial length of the teeth 10' by casting or overmolding the tooth star 1'. In the modification according to 2b the insulating body 15' is essentially flat at the bottom of the slot formed between the teeth 10' so that the coolant flows and cools mainly between the individual layers of the winding.

3 shows a sectional view of a section of a second embodiment of a toothed star 1a. The toothed star 1a according to the second embodiment differs essentially from the toothed star 1 of the first embodiment in that the toothed star 1a has webs 11a which connect the adjacent teeth 10a to one another. The toothed star 1a can also be formed by a plurality of tooth segments and thus be segmented all the way around (this is in a so-called double web variant ( 4a and 4b) The segmentation in the axial direction by a large number of thin electrical sheets is not shown in the figures and is of course only used in the field of electrical machines.

Similar to the first embodiment described above, sections of an insulating body 15a are provided on the teeth 10a in the stator slots. This can be done by casting or overmolding the tooth star 1a. According to the second embodiment, the insulating body 15a is designed similarly to that in 2a the first embodiment, but it is clear that the 2b The modification shown can be provided with a flat formation in the area of the groove base.

The insulating body 15a, similar to the insulating body of the first embodiment, also extends in the axial direction beyond a front side of the teeth 10a of the toothed star 1a in order to provide a fluid-tight seal in this area as well.

With regard to further components of the toothed star 1a of the second embodiment, reference is made to the explanations for the first embodiment.

4a shows a toothed star 1b according to a third embodiment. The toothed star 1b comprises a plurality of teeth 10b, wherein Stator slots are formed between the teeth 10b. The tooth star 1b is, as shown in 4a As can be seen, it is formed by means of a large number of tooth segments which, in this embodiment, are connected to one another in segments both circumferentially and in the axial direction. On a side of the teeth 10b pointing inwards in the radial direction, a cylindrical continuation is formed in the area of the winding heads/windings, which connects the teeth 10b to one another on its outer peripheral side and seals against the air gap to the rotor or the bore of the stator.

The toothed star 1b according to the third embodiment is, as can be seen more clearly in the sectional view according to 4b As can be seen, it is formed with a double web, the double web connecting adjacent teeth 10b of the toothed star 1b to one another. The double web has a first web section 12b and a second web section 13b, which are separated from one another by a recess 14b. During the overmolding of the toothed star to produce the insulation body 15b, a further embodiment provides that the recesses 14b are only partially filled, whereby preferably cylindrical channels are formed after the tool is opened. These channels or tubes 16b can also guide coolant through the machine parallel to the slots with winding.

Thus, by cooling the area towards the rotor, better cooling of the rotor and thus higher performance of the electric machine can be achieved.

In the stator slots of the toothed star 1b according to the third embodiment, sections of an insulating body 15b are provided (attached to the inner sides of the teeth by casting or overmolding), which insulate the teeth 10b relative to the winding to be introduced into the stator slot. Similar to what has already been described in the context of the first and second embodiments, the insulating body 15b serves for electrical insulation. Furthermore, an inner region of the respective stator slot can be sealed so that a cooling liquid can flow through the stator slot.

The insulating body 15b also extends in the axial direction beyond a front side of the teeth 10b of the toothed star 1b in order to provide a fluid-tight seal in this area as well. However, a step or other type of structure can also be formed in an area beyond the front side of the teeth 10b in order to accommodate, for example, interconnection rings.

The sections of the insulating body 15b are formed flat in the region of the teeth 10b essentially similar to those of the modification of the first embodiment in the region of the groove base.

5a shows the tooth star according to 4a with the insulation body 15b and a winding 50b introduced into the respective stator slot. In addition, a slot insulation closure element 30b made of electrically insulating material is provided at an output section of the respective stator slot, which closes the respective stator slot and also creates a separation between the winding 50b and the adjacent teeth 10b and the yoke ring 40b (see 5b) provides.

In 5b the third embodiment of the toothed star 1 is shown in a further view, wherein according to the view of 5b Additionally, a yoke ring 40b is shown, which is arranged on an outer peripheral side of the toothed star.

6a shows a fourth embodiment of a toothed star 1c, which has slot insulation closure elements 30c for closing the stator slot each accommodating a winding 50c.

6b shows that the slot insulation closure element 30c comprises a base portion 31c and two webs 32c which extend substantially at right angles from the base 31c and ensure an overlap of the electrically insulating material with that of the insulating body 15c.

The webs 32c each have a locking element 32c-1 which, when the slot insulation closure element 30c is attached in the stator slot, penetrates into or rests on a corresponding recess in or a step on the insulation body 15c, and thus fixes the slot insulation closure elements 30c with the winding 50c located underneath for further assembly, and ensures that the slot insulation closure elements 30c close the stator slot.

7 shows an electrical machine 100 in radial flux internal rotor design with a stator encapsulated against a rotor, which provides direct cooling of the motor winding. The stator according to the electrical machine 100 has a toothed star 1 and an insulating body 15 according to the first embodiment, whereby alternatively the toothed star or the insulating body according to one of the other embodiments or modifications can also be used.

The electrical machine 100 comprises a housing 101, which accommodates the stator 150 and a rotor 160 and is closed with a cover or by the bearing plate 102. The stator comprises the toothed star 1, which accommodates the windings 50, and the yoke ring 40. Furthermore, the insulation An insulation body 15 is provided which extends beyond one end face of the teeth on both sides and is in contact with a first sealing ring 103a which is arranged on the bearing plate 102 and with a second sealing ring 103b which is arranged on the housing 101. Thus, a section in the area of the stator 150 is separated from a section in the area of the rotor 160 by the insulation body.

The housing 101 or the bearing shield(s) have an inlet 110 and an outlet 111 for a cooling liquid, which cooling liquid flows through the area between the teeth of the toothed star 1 and thus "directly" along the winding. The arrangement of the insulating body 15 ensures that the cooling liquid does not reach the area of the rotor 160.

8 shows a further embodiment of an electrical machine in radial flux internal rotor design, wherein an insulating body 15d has a step in a region beyond the front side of the teeth of the toothed star 1d.

Windings 50d extend beyond the toothed star 1d and the yoke ring 40d surrounding the toothed star 1d. The step of the insulating body 15d provides additional installation space to accommodate interconnection rings 170d.

• Zunächst wird der Zahnstern bereitgestellt, wobei je nach Ausführungsform die Zähne einzeln oder segmentweise zusammengefügt werden. Nachfolgend wird der Isolationskörper insbesondere mittels Vergießens oder mittels Umspritzens um den Zahnstern angebracht, insbesondere durch ein Kunststoff-Spritzgussverfahren.

The sequence for assembling the stator can be as follows when using a star gear with toothed star segments:

• First, the toothed star is prepared, whereby, depending on the design, the teeth are joined together individually or in segments. The insulation body is then attached around the toothed star, in particular by means of casting or by overmolding, in particular by means of a plastic injection molding process.

After the insulation body has hardened, the windings/coils are inserted into the stator slots and then the slot insulation closure elements are attached in the opening area of the stator slots. In a further production step, a yoke ring, which has several segments, for example, is arranged around the toothed star.

QUOTES INCLUDED IN THE DESCRIPTION

This list of documents listed 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 accepts no liability for any errors or omissions.

Cited patent literature

• EN 112016000898 T5 [0002]
• WO 2015132111 A1 [0003]
• DE 10253235 A1 [0004]

Claims (15)

Stator for an electrical machine (100), comprising a toothed star (1, 1', 1a, 1b, 1c, 1d) having a plurality of teeth (10, 10a, 10b, 10c, 10d), stator slots being provided between the teeth (10, 10a, 10b, 10c, 10d), a yoke ring (40, 40b) which surrounds the toothed star (1, 1a, 1b, 1c, 1d) at least in sections, further comprising an insulating body (15, 15', 15a, 15b, 15c, 15d) which is mounted in the region of the stator slots and insulates a winding (50, 50b) from the stator, the insulating body (15, 15', 15a, 15b, 15c, 15d) extends beyond a front side of the teeth (10, 10a, 10b, 10c, 10d). Stator according to Claim 1 , wherein the insulating body (15, 15', 15a, 15b, 15c, 15d) is formed in one piece. Stator according to Claim 1 or 2 , wherein the insulating body (15, 15', 15a, 15b, 15c, 15d) is formed by casting or overmolding the toothed star (1, 1', 1a, 1b, 1c, 1d). Stator according to one of the preceding claims, wherein the stator is arranged to guide a liquid cooling medium through the stator slots. Stator according to one of the preceding claims, further comprising a slot insulation closure member (30c) attached to at least one stator slot such that an open region of the stator slot is closed. Stator according to Claim 5 , wherein the slot insulation closure element (30c) has one or more locking elements (32c-1). Stator according to one of the preceding claims, wherein the toothed star (1, 1', 1a, 1b, 1c, 1d) and/or the yoke ring (40, 40b) has a plurality of segments in the circumferential direction. Stator according to one of the preceding claims, wherein the insulating body (15, 15a, 15b, 15c, 15d) has a greater thickness in sections in the region of a slot base. Stator according to one of the Claims 1 - 7 , wherein the insulating body (15') is flat in the region of a groove base. Stator according to one of the preceding claims, wherein the insulating body (15d) forms a step in a region beyond the front side of the teeth (10d). Electric machine (100) comprising a housing (101) accommodating a stator according to one of the preceding claims. Electrical machine (100) according to Claim 11 , comprising a rotor (160) of internal rotor design. Electrical machine (100) according to Claim 11 or 12 , comprising a first sealing ring (103a) arranged on a cover (102) of the housing (101) and/or a second sealing ring (103b) arranged on the housing (101), wherein the insulating body (15, 15', 15a, 15b, 15c, 15d) is in contact with the first and/or second sealing ring. Method for producing a stator, comprising the steps: Providing a toothed star (1, 1', 1a, 1b, 1c, 1d) having a plurality of teeth, wherein stator slots are provided between the teeth (10, 10a, 10b, 10c, 10d), Forming an insulating body (15, 15', 15a, 15b, 15c, 15d) in the region of the stator slots, Inserting a winding (50, 50b) into the stator slots provided with an insulating body (15, 15', 15a, 15b, 15c, 15d), and Attaching a yoke ring (40, 40b) to the toothed star (1, 1', 1a, 1b, 1c, 1d) in such a way that the toothed star (1, 1', 1a, 1b, 1c, 1d) at least in sections. Procedure according to Claim 14 , wherein the formation of the insulating body (15, 15', 15a, 15b, 15c, 15d) comprises casting or overmolding the toothed star (1, 1', 1a, 1b, 1c, 1d).