DE102022207900A1 - Stator for an electric motor and electric motor comprising such a stator - Google Patents

Abstract

The invention relates to a stator (1) for an electric motor (2), in particular for an external rotor motor, comprising a stator unit (3), having a laminated core (7) at least partially encased by an insulator (6), and a stator carrier (4), wherein the insulator (6) has a base body (6a), from which essentially radially outwardly directed winding supports (6b) extend, a wedge-shaped connecting element (8) being formed on at least one of the winding supports (6b), which in the assembled state of the Stator (1) engages in a wedge-shaped recess (9) formed on the stator carrier (4) and complementary to the connecting element (8), so that there is a press fit between the respective connecting element (8) and the stator carrier (4). The invention further relates to an electric motor (2), comprising such a stator (1).

Description

The invention relates to a stator for an electric motor, in particular for an external rotor motor. The invention also relates to an electric motor, in particular an external rotor motor, comprising such a stator.

Electric motors that are designed as external rotor direct current motors have radially projecting armatures. Due to the design of such direct current motors as external rotors, vibrations can occur in the stator during operation of the electric motor, which result in audible high frequencies.

It is known from the prior art to cast such stators in order to reduce the vibration of the armatures. This method places high demands on process reliability, is cost-intensive and, depending on the design of the electric motor, may not be feasible at all. In addition, the electric motor can no longer be dismantled after casting, for example for possible maintenance measures, especially repairs.

From the EP 1 298 772 B1 an external rotor motor with a stator and a rotor surrounding the stator is known. A bearing support tube for fastening a motor flange is connected to a centrally arranged base body of the stator, which accommodates a shaft of the rotor in its interior. The central base body of the stator and the bearing support tube are formed in one piece.

The object of the present invention is to further develop a stator for an electric motor, in particular for an external rotor motor, in particular to reduce the susceptibility of the stator armatures to vibration. The task is solved by a stator with the features of independent patent claim 1 and by an electric motor with the features of patent claim 8. Advantageous embodiments are the subject of the subclaims, the following description and the figures.

A stator according to the invention for an electric motor, in particular for an external rotor motor, comprises a stator unit, having a laminated core at least partially encased by an insulator, and a stator carrier, the insulator having a base body from which essentially radially outwardly directed winding carriers extend, whereby A wedge-shaped connecting element is formed on at least one of the winding carriers, which, in the assembled state of the stator, engages in a wedge-shaped recess formed on the stator carrier and designed to complement the connecting element, so that there is a press fit between the respective connecting element and the stator carrier. In other words, when the stator unit is mounted on the stator carrier, a frictional connection is generated between the insulator and the stator carrier in relation to a longitudinal axis of the stator or a rotation axis of the electric motor, which secures the stator unit axially on the stator carrier. At the same time, a positive connection is created between the insulator and the stator carrier, which secures the stator unit to the stator carrier in the circumferential direction, i.e. in the rotational or tangential direction. The respective elastically prestressed, compressible connecting element also dampens the vibrations that occur in the winding carriers.

The stator unit is constructed in such a way that the laminated core is encased in the material of the insulator. The insulator is preferably made of plastic, so that the laminated core can, for example, be overmolded. The turns of a winding which is connected to an electrical voltage source are wound around the insulator, in particular around the winding supports of the insulator. A winding carrier is to be understood as meaning an armature of the stator or the stator unit, which protrudes essentially in the radial direction from a sleeve-shaped section of the stator unit, in particular from the insulator and from the laminated core.

In addition to the radial section, the stator carrier includes an axial section which is connected in one piece and onto which the stator unit is threaded during assembly. During assembly, the stator unit is pushed onto the axial section of the stator carrier and, depending on requirements, pressed, screwed and/or otherwise fixed to it. At the same time, the respective connecting element is axially pressed into the associated recess, the shape and dimensions of the connecting element and the recess being selected such that a firm press fit is created between the insulator and the stator carrier.

Due to the frictional connection between the respective connecting element and the stator carrier, the respective winding carrier is prestressed and damped on the stator carrier. Additional coupling or support of the winding carriers on the stator carrier therefore prevents vibration and the associated annoying noises. In addition, a further connection point to the stator carrier is created without influencing the design and manufacturing process of the electric motor or the electric machine.

The respective wedge-shaped connecting element is designed to be compressible or elastically deformable in order to allow it to be pressed into the associated one To enable recess to create the press fit with the associated deformation of the connecting element.

The respective connecting element has legs that converge to a point starting from the insulator. Preferably, the respective connecting element consists of two legs, which extend separately starting from the winding support of the insulator and extend toward one another in such a way that they meet at the tip of the respective connecting element. In other words, the respective connecting element is designed as a tapered wedge. Due to the material of the insulator, preferably plastic, the respective connecting element can be specifically tuned in terms of its compressibility in the tangential direction to the forces and/or vibrations that occur.

The respective connecting element has a substantially triangular shape in plan view, with a free space being formed between the legs in order to enable the deformation of the respective connecting element during the production of the press fit. In this sense, the legs of the respective connecting element are elastically deformable in the tangential direction of the stator unit. When assembling the stator, the stator unit is pushed with a defined axial force in the direction of the stator carrier, the respective connecting element being compressed in the tangential direction by being pressed into the associated recess, in that the legs of the respective connecting element are elastically deformed and thereby pressed towards one another . In other words, the recess in the circumferential direction of the stator has a smaller width than the respective connecting element in its initial state, so that the connecting element is forced into the aforementioned deformation during joining.

According to one exemplary embodiment, the respective wedge-shaped recess is formed on an axial projection on a radial section of the stator carrier. As a result, the stator carrier, in particular the radial section of the stator carrier, continues to have the necessary stability or, conversely, is not weakened at certain points. The projection has a V-shape when viewed with the wedge-shaped recess. If the stator carrier is of a corresponding size or if there is not enough installation space available, it is alternatively possible to form the respective wedge-shaped recess directly on the radial section. The respective recess can be removed from the mold directly during the production of the stator carrier by die casting and advantageously does not require any machining, which is cost-neutral for the production of the electric motor.

The invention includes the technical teaching that the stator unit comes to rest axially on an end stop of the stator carrier when the stator is in the assembled state. When assembling the stator, the stator unit is pushed with a defined axial force against the end stop on the stator carrier, which preferably creates a first press fit. At the same time, the respective compressible connecting element pushes into the associated wedge-shaped recess and compresses in a tangential direction.

Another advantage of the respective connecting element is that it does not significantly increase the size of the insulator, so that the winding of the stator can take place unaffected in series production, which has a cost-neutral effect on the production of the electric motor. In addition, no new machines or adjustments to existing or known machines are required to manufacture the individual components. The complexity of the tools for manufacturing, especially for demoulding the insulator, remains unchanged.

Preferably, a wedge-shaped connecting element is formed on several, preferably all, winding supports of the insulator, which engages in an associated wedge-shaped recess on the stator support when the stator is in the assembled state. The higher the number of press fits between the insulator and stator carrier, the more precisely the damping properties can be adjusted and the more uniform the support and preload of the stator unit on the stator carrier, and vice versa.

One connecting element and one associated recess form a wedge pairing. The number and placement of wedge pairs can be varied depending on the application. This enables better adjustment to the forces occurring as well as the flexibility to provide space for additional components such as Hall sensors.

The stator according to the invention is suitable for use in an electric motor or an electric machine. In this sense, an electric motor according to the invention comprises a stator according to the previous embodiments, wherein the stator is fixed to the housing and is arranged spatially within a rotor arranged rotatably thereto.

The above definitions and statements on technical effects, advantages and advantageous embodiments of the stator according to the invention also apply mutatis mutandis to the electric motor according to the invention, and vice versa.

• 1 eine stark schematische Teillängsschnittdarstellung eines erfindungsgemä-ßen Elektromotors gemäß einer bevorzugten Ausführungsform,
• 2 eine schematische Explosionsdarstellung eines erfindungsgemäßen Stators des erfindungsgemäßen Elektromotors nach 1, insbesondere zur Veranschaulichung einer Montagereihenfolge,
• 3 eine schematische Explosionsdarstellung einer Statoreinheit des erfindungsgemäßen Stators nach 2,
• 4 eine schematische Perspektivdarstellung eines Isolators der Statoreinheit nach 3,
• 5 eine schematische Teilperspektivdarstellung des Isolators nach 4,
• 6 eine schematische Perspektivdarstellung eines Statorträgers des erfindungsgemäßen Stators nach 1 und 2, und
• 7 eine schematische Teilperspektivdarstellung des Statorträgers nach 6.

Exemplary embodiments of the invention are explained in more detail below with reference to the schematic drawings, with the same or similar elements elements are provided with the same reference number. This shows

• 1 a highly schematic partial longitudinal sectional view of an electric motor according to the invention according to a preferred embodiment,
• 2 a schematic exploded view of a stator according to the invention of the electric motor according to the invention 1 , especially to illustrate an assembly sequence,
• 3 a schematic exploded view of a stator unit of the stator according to the invention 2 ,
• 4 a schematic perspective view of an insulator of the stator unit 3 ,
• 5 a schematic partial perspective view of the insulator 4 ,
• 6 a schematic perspective view of a stator carrier of the stator according to the invention 1 and 2 , and
• 7 a schematic partial perspective view of the stator carrier 6 .

1 shows very schematically an electric motor 2 according to the invention as an external rotor motor, comprising a rotor 5, which is arranged spatially outside a stator 1 according to the invention so as to be rotatable about a longitudinal axis L. The stator 1 is - in a manner not shown here - fixed to the housing and therefore arranged in a rotationally fixed manner.

The structure of the stator 1 is described in more detail using the following figures. The stator 1 includes, as in particular in 2 is shown, a stator unit 3 and a stator carrier 4. According to 2 A method for assembling the stator 1 is to be illustrated. The stator unit 3 is pressed onto an axial section 4b of the stator carrier 4, with a positive connection already being achieved between the stator unit 3 and the axial section 4b of the stator carrier 4. The stator unit 3 comes to rest axially against an end stop 10 of the stator carrier 4 in the assembled state of the stator 1. The end stop 10 is formed on the axial section 4b of the stator carrier 4.

The stator unit 3 is composed of several components, where 2 shows the stator unit 3 in the assembled state. According to 3 the stator unit 3 has a laminated core 7 partially encased by an insulator 6 made of plastic, the insulator 6 comprising a sleeve-shaped base body 6a and winding supports 6b which extend essentially radially outwards. In particular, the winding carriers 6b are wrapped by a winding 11, which is separated on the left side of the 3 you can see. In the present case, the stator unit 3 has twelve winding supports 6b.

4 shows the insulator 6 from one in contrast to 3 Another perspective, whereby it can be clearly seen that a wedge-shaped connecting element 8 is formed radially on the outside of eight adjacent winding carriers 6b, which is designed to, in the assembled state of the stator 1, into a wedge-shaped one which is formed on the stator carrier 4 and is complementary to the connecting element 8 Recess 9 to intervene in order to secure the stator unit 3 both in the axial direction and in the circumferential direction. Accordingly, the remaining four adjacent winding supports 6b do not have a connecting element 8. A press fit is therefore created between the respective connecting element 8 and the stator carrier 4. The axial securing is achieved by a frictional connection between the connecting element 8 formed on the respective winding carrier 6b and the stator carrier 4, on which the recess 9 is formed, while the tangential securing is achieved by a positive connection between the respective connecting element 8 and the stator carrier 4, so that each winding carrier 6b is protected from unwanted vibrations during operation of the electric motor 2.

In 5 one of the connecting elements 8 is shown as an example, with all connecting elements 8 being identical and connected in one piece to the respective winding carrier 6b of the insulator 6. In other words, the insulator 6 is manufactured together with the connecting elements 8 in one step, in particular cast, preferably injection molded. Starting from the respective winding support 6b of the insulator 6, the connecting element 8 has legs 8a, 8b that converge to a point and which meet at the tip of the connecting element 8. The tip can be of any design. In the present case the tip is shown rounded. The legs 8a, 8b of the respective connecting element 8 are designed such that they are elastically deformable in the tangential direction of the stator unit 3. In other words, the legs 8a, 8b deform during joining in such a way that they move due to the dimensions of the associated recess 9, as shown in 6 and 7 are shown moving towards one another in the circumferential direction of the stator unit 3.

The stator carrier 4 with the wedge-shaped recesses 9 formed on it is exemplified in 6 shown. In the present case, the recesses 9 are formed on an axial projection 12 on an end face of the radial section 4a of the stator carrier 4 facing the stator unit 3. The recesses 9 are arranged at a distance on the radial section 4a of the stator carrier 4 in such a way that that a recess 9 is assigned to a connecting element 8 on the insulator 6. The recesses 9 are also designed identically and are connected in one piece to the stator carrier 4. The shape of the recesses 9 is adapted to the shape of the connecting elements 8. In the present case, the recesses 9 are V-shaped, as in 7 is shown, whereas the connecting elements 8 are correspondingly designed in the shape of an arrow, cf. 5 .

The recesses 9 are also designed in such a way that they also form an end stop for the stator unit 3. If the stator unit 3 comes into contact with the end stop 10 during its assembly on the stator carrier 4, the connecting elements 8 also reach the desired axial position in the recesses 9, in which the desired press fit is present.

The number of coupling pairs, each consisting of a connecting element and an associated recess 9, depends, among other things, on the extent to which the available installation space must be used by other components of the electric motor - not shown here - for example sensors or the like. Depending on the design of the material of the insulator 6 as well as the connection as well as the design and shape of the interacting parts, the damping properties of the stator unit 3 can be set specifically.

The invention is not limited to the disclosed embodiments. Other embodiments or variations will become apparent to those skilled in the art upon use of the present invention and upon careful analysis of the drawings, description and claims. It is conceivable, for example, that coupling pairs are fully designed or arranged to protect each winding carrier 6b from vibrations. It is also conceivable that the recesses 9 are integrated on the radial section 4a of the stator carrier 4, that is to say that they are designed as recesses on the stator carrier 4.

Reference symbols

1

stator

2

Electric motor

3

Stator unit

4

Stator carrier

4a

radial section of the stator carrier

4b

axial section of the stator carrier

5

rotor

6

insulator

6a

Basic body

6b

winding carrier

7

Sheet metal package

8th

connecting element

8a

First leg of the connecting element

8b

Second leg of the connecting element

9

recess

10

End stop of the stator carrier

11

winding

12

head Start

L

Longitudinal axis

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 assumes no liability for any errors or omissions.

Cited patent literature

• EP 1298772 B1 [0004]

Claims (8)

Stator (1) for an electric motor (2), in particular for an external rotor motor, comprising a stator unit (3), having a laminated core (7) at least partially encased by an insulator (6), and a stator carrier (4), the insulator ( 6) has a base body (6a), from which essentially radially outwardly directed winding carriers (6b) extend, a wedge-shaped connecting element (8) being formed on at least one of the winding carriers (6b), which is in the assembled state of the stator ( 1) engages in a wedge-shaped recess (9) formed on the stator carrier (4) and designed to complement the connecting element (8), so that there is a press fit between the respective connecting element (8) and the stator carrier (4). stator (1). Claim 1 , wherein the respective connecting element (8) has legs (8a, 8b) that converge to a point starting from the insulator (6). stator (1). Claim 2 , wherein the legs (8a, 8b) of the respective connecting element (8) are elastically deformable in the tangential direction of the stator unit (3). Stator (1) according to one of the preceding claims, wherein the respective wedge-shaped recess (9) is formed on an axial projection (12) on a radial section (4a) of the stator carrier (4). Stator (1) according to one of the preceding claims, wherein the insulator (6) is made of plastic. Stator (1) according to one of the preceding claims, wherein the stator unit (3) comes to rest axially on an end stop (10) of the stator carrier (4) in the assembled state of the stator (1). Stator (1) according to one of the preceding claims, wherein a wedge-shaped connecting element (8) is formed on several winding supports (6b) of the insulator (6), which, when the stator (1) is assembled, fits into an associated wedge-shaped recess (9). Stator carrier (4) engages. Electric motor (2), comprising a stator (1) according to one of the preceding claims, wherein the stator (1) is arranged fixed to the housing and spatially within a rotor (5) arranged rotatably thereto.

Images