WO2011098103A2 - Stator of an electric machine - Google Patents

Abstract

The invention relates to a stator of an electric machine, comprising a stator carrier and individual segments (3a, 3b). A first individual segment (3a) has a curved projection (4) and a second individual segment (3b) has a recess (5), such that, in the assembled state, wherein the individual segments form a stator ring (7) with a force-free assembly, the projection (4) of the first individual segment (3a) is inserted into the recess (5) of the second individual segment (3b). The second individual segment (3b) also has a deformable part (6) that is arranged on the recess (5) and can be deformed when the stator ring (7) is pressed into the stator carrier.

Description

 Stator of an electric machine

The invention relates to a stator of an electric machine according to the preamble of claim 1.

The generic document US 6049153 A describes a stator of an electrical machine. The stator has a stator carrier and individual segments, which are manufactured as separate parts at the beginning of the production of the stator.

The individual segments are then assembled to form a stator ring, wherein the individual segments are in free contact with an adjacent individual segment, which is referred to below as a composite state of the individual segments. In a further manufacturing step, the individual segments assembled to form a stator ring are pressed into the stator carrier, so that the stator carrier

Individual segments braced against each other, which is referred to below as pressed state of the individual segments.

 The stator has a first single segment and a second single segment, wherein the first single segment a bulge and the second single segment a

Having recess, so that in the assembled state, the bulge of the first single segment protrudes into the recess of the second single segment.

In contrast, it is the object of the invention to provide a stator of an electric machine that can be manufactured easily and inexpensively.

According to the invention the object is achieved by a stator of an electric machine with the features of claim 1.

According to the invention, the bulge of the first individual segment and the recess of the second individual segment are formed such that in the assembled state of the individual segments only a portion of the bulge with a portion of the Recess has a contact surface. Between another portion of the bulge and the recess forms a gap, the size depending on

Forming of the bulge and the recess is designed.

Furthermore, according to the invention, the second individual segment has a deformable part which is arranged on the portion of the recess of the second individual segment, which is in contact with the bulge of the first individual segment. The

deformable part is in the pressed state, by the force applied

Pressed in, deformed. Due to the deformation of the deformable part is the

Recess of the second single segment of the bulge of the first single segment adapted so that the contact surface of the bulge of the first single segment with the recess of the second single segment in the pressed state is greater than in the assembled state in which the deformable part is still undeformed. The contact surface between the bulge of the first individual segment and the recess of the second individual segment is greater in the pressed-in state than in the assembled state, so that the magnetic flux in the stator can flow unhindered over the contact surface between the individual segments.

The individual segments are assembled to form a stator ring whose

Outer diameter is predetermined by the stator. Since the

To sum up production tolerances of the individual segments in the stator ring, each individual segment must be produced very precisely and precisely. By the deformable part of the second individual segment and the gap, which is located between the bulge of the first individual segment and the recess of the second individual segment in the

assembled state, the press-in force can compress the outer diameter of the stator ring by deforming the deformable member to the value specified by the stator. The recess of the second individual segment adapts to the pressing-in of the bulge of the first individual segment, so that the bulge projects further into the recess and the outer diameter of the stator ring is reduced. The fault tolerance of the individual segments is increased because production inaccuracies in the pressed state can be compensated by deforming the deformable part. The individual segments are easier and cheaper to manufacture.

In an advantageous development, the stator of an electric machine is characterized in that the deformable part of the single segment is deformable mainly in the radial direction of the stator ring.

The deformable part of the second individual segment has a shape such that a force when pressing the stator ring in the stator in the stator in Circumferential direction, resulting in a radial deformation of the deformable part.

In addition, the deformable part of the second individual segment can have a structural weakening of the individual segment material, which in the region of the contact surface of the bulge of the first individual segment with the recess of the second

Single segment is arranged in the radial direction. The radial arrangement of the structural weakening of the deformable part favors the deformation of the deformable part in the radial direction. The structural weakening can be achieved by a material recess in the deformable part or by a small material thickness in the region of the deformable part.

 The deformable part is shaped in such a way that during pressing in a clearance between the deformable part and the stator results in the material of the deformable part during deformation is pressed. In the pressed state, the deformable part has the same volume as before the deformation. There are no additional forces and stresses due to material compression, which burden the material of the single segment. A material recess on the radially outer region of the stator ring in the region of the deformable part causes a structural weakening of the area and forms with the stator support a free space into which the deformable part is deformable. The material recess prevents a material overhang, which is a hindrance to the press-in process in the stator.

In an advantageous development, the stator of an electrical machine is characterized in that in the pressed state of the individual segments have at least 90 percent of a surface of the bulge of the first single segment with a surface of the recess of the second single segment contact.

Due to the stator, the magnetic flux flows, which is affected by material transitions. At the contact surfaces between the individual segments of the magnetic flux flows undisturbed, so that the largest possible contact surface between the individual segments of the stator favors the magnetic flux.

In an advantageous development, the stator of an electric machine is characterized in that the first individual segment has a recess and the second individual segment has a bulge.

 The bulge of the individual segments is in the assembled state of

Single segments toothed with the recess of the adjacent single segment. In the stator ring, each individual segment has an adjacent individual segment, with which it forms a toothing, so that the stability of the stator ring is increased. The production inaccuracy of the individual segments adds up in the stator ring and results in an inaccuracy of the outer diameter of the stator ring. Corresponds to the accumulated production inaccuracy of all individual segments of the maximum possible change in the circumference of the stator, which can be generated by the deformation of a deformable part of a single segment, only exactly a single segment with a deformable part is necessary so that the outer diameter of the stator is adapted to the stator.

 If the cumulative production inaccuracy is greater than can be corrected by exactly one deformable part of a single segment, a plurality of individual segments with a deformable part are provided in the stator ring, so that the outer diameter of the stator ring can be adapted to the stator carrier. Are the individual segments with the

deformable part distributed symmetrically in the stator, are the forces that act when pressed into the stator, symmetrical, so that the assembly is easily possible.

In an advantageous development, the stator of an electrical machine is characterized in that all the individual segments have the same shape.

This facilitates production, since only one shape of the single segment has to be produced and the position of a single segment within the ring is indefinite. Thus, when assembling the stator ring is not on the position and

Pay attention to the order of the individual segment.

 If each individual segment has a deformable part, the deformation of precisely one deformable part in the pressed-in state can correct the production inaccuracy of exactly one individual segment. The production is facilitated by a high fault tolerance of the individual segments.

In an advantageous development, the stator of an electrical machine is characterized in that each individual segment is constructed from a laminated core.

The shape of the single segment can be particularly easily by punching the

Produce single segment from a sheet metal strip. To get out of the shape of the

Single segment with the depth of a sheet metal strip to get the required axial depth of the single segment for the stator, several punched-out forms are built into a laminated core. In addition, the material of the metal strip provides a favorable magnetic property. Further embodiments of the invention will become apparent from the description and the drawings. Embodiments of the invention are shown in simplified form in the drawing and explained in more detail in the following description.

The invention will be explained in more detail with reference to the following embodiments. Showing:

 1 shows a stator of an electrical machine, which is composed of individual segments,

Fig. 2 shows a detail of a stator of individual segments, in a

 Stator is pressed

Fig. 3 is an enlarged detail of a stator of individual segments, in which the individual segments are assembled before being pressed into the stator and

Fig. 4 is an enlarged detail of a stator of individual segments, in which the individual segments are pressed into the stator.

FIG. 1 shows an axial view of a stator ring 7 which has individual segments 3a, 3b. The stator ring 7 has a first individual segment 3a and an adjacent, second individual segment 3b, the first individual segment 3a having a bulge 4 and the second individual element 3b having a recess 5. In the assembled state, in which the individual segments are assembled without force to form a stator ring 7, the bulge 4 is arranged on the side of the first individual segment 3a facing the second individual segment 3b, and the recess 5 on the side of the second individual segment facing the first individual segment 3a 3b arranged. The bulge 4 of the first individual segment 3 a protrudes into the recess 5 of the second individual segment 3 b and the bulge 4 touches the recess 5. In the illustrated embodiment of the stator ring 7, all the individual segments have the same shape. The bulge 4 and the recess 5 interlock the individual segments with each other and stabilize the stator ring 7. The stator 7 has a

Outside diameter 8 on.

FIG. 2 shows a detail of a stator 1, which has a stator carrier 2 and

Individual segments 3a, 3b, as in Figure 1, has. In the section, the adjacent individual segments 3a, 3b are shown, wherein the bulge 4 of the individual segment 3a projects into the recess 5 of the individual segment 3b and is in contact therewith. The first individual segment 3a has at the, the bulge 4 opposite side via a recess 5 'and the second single segment 3b has at the, the

Recess 5 opposite side on a bulge 4 '. In the illustrated embodiment of the stator 1, the individual segments have the same shape, so that in this case, the bulge 4 and 4 ', and the recess 5 and 5' have a same shape.

 An illustrated configuration of the bulge 4 of the single segment 3a is a continuation arranged centrally on the circumferential side surface to the adjacent individual segment 3b, which consists in the axial view in the basic form of a trapezoid followed by a triangle,

with the apex of the triangle rounded off, the side surfaces of the triangle with the side surfaces of the trapezoid enclose an angle smaller than 180 °, so that the triangle is steeper than the trapezoid and the bottom sides of the trapezoid flush with both the triangle and with the single segment 3a to lock.

For simplified punching of the individual segments 3a, 3b of sheet metal strips, the transitions of the individual forms are rounded into one another.

The recess 5 is centered on a side surface of the single segment 3b in

Circumferentially arranged to the single segment 3a. A shape of the recess 5 corresponds to the basic shape of the bulge 4 from a combination of a trapezoid and a rounded triangle, wherein the aspect ratios between triangle and trapezium in the recess 5 to the aspect ratios of the bulge 4 differ. Due to the difference of the aspect ratios, the shape of the bulge 4 resembles the shape of the recess 5, but the shape is not the same.

The individual segment 3b has a deformable part 6, which is arranged on the recess 5. The detail shows the individual segments in a pressed-in state in which the individual segments 3a, 3b are pressed into the stator carrier 2. By pressing into the stator 2, the deformable part 6 is deformed such that the recess 5 of the bulge 4 is adjusted. The bulge 4 touches the

Recess 5 almost with the entire surface, whereby the magnetic flux in the stator of material transitions is unaffected.

FIG. 3 shows an enlarged section of the two adjacent individual segments 3 a, 3 b from FIG. 2 in the assembled state, in which the individual segments 3 a, 3 b are assembled without force to the stator ring 7 and not yet compressed in the stator carrier 2. In the assembled state, the deformable part 6 is still undeformed and so shown in the magnification. The bulge 4 touches the recess 5 only in a portion 4a. The subregion 4a forms with a subregion 5a of the recess 5 a contact surface 9a between the two adjacent individual segments 3a, 3b. To the Part 5a of the recess 5, the deformable part 6 is arranged. Another portion 4c of the bulge 4 forms with the recess 5 a gap. At the

Pressing into the stator 2, the deformable part 6 is deformed such that the recess 5 of the bulge 4 is adjusted and the gap is closed, so that the bulge 4 touches the recess 5 almost over the entire surface.

The deformable part 6 is designed so that when pressed into the stator 2, the press-in force deforms the deformable part 6, especially radially outward. In the

Enlargement can also be seen that the radial embedding of the deformable part 6 is smaller than the outer diameter 8 of the composite stator ring 7. When pressed into the stator 2, the outer diameter 8 is defined by the stator 2. The deformable part 6 is thus deformed radially outwards during pressing into the stator carrier 2 without the radial extent of the deformable part 6 being greater than the outer diameter 8 of the stator ring 7.

FIG. 4 shows a section of the two adjacent sections analogous to FIG

Individual segments 3a, 3b in which the individual segments 3a, 3b are pressed into the stator 2. The same or equivalent components which have already been described in FIG. 3 are adopted for this illustration and are not explicitly listed again. The deformable part 6 is deformed by the pressing in the stator 2 in the radial direction outwards and so shown in the enlargement. The radial extent of the deformable part 6 extends through the deformation mainly in the radial direction to the stator 2, the inner diameter of the

Outside diameter 8 of the stator 7 defines.

 A portion 4b of the bulge 4 forms a contact area 9b with a portion 5b of the recess 5. The surface of the contact surface 9b is larger than the surface of the contact surface 9a, which forms between the individual segments 3a and the single segment 3b in the assembled state in Figure 2. Another portion 4d of the bulge 4 is not in contact with the recess 5 and forms a gap between the portion 4d of the bulge 4 and the recess 5. The shape of the bulge 4 is selected such that the largest possible proportion of the surface of the bulge. 4 the contact surface 9b to the recess 5 forms. The magnetic flux in the stator flows undisturbed over the contact surface 9b from the individual segment 3a

Single segment 3b.

Another possible basic shape of the bulge would be a Gaussian curve-shaped outline, wherein the recess would also have an outline in Gaussian curve shape with other parameters. By a different Curvature along the Gauss-curve-shaped outline results in the assembled state of the individual segments also a portion of the bulge, which forms a contact surface with the recess and another portion of the bulge, which forms a gap with the recess. The basic shape of the outline of the convexity and the recess in Gaussian curve shape has the same functional features as the illustrated shape of the bulge 4 and recess 5 as a combination of a trapezium with a rounded triangle.

Claims

claims

1. stator of an electric machine,

 which has a stator carrier (2), a first individual segment (3a) and a second individual element (3b),

 wherein the first single segment (3a) has a bulge (4) and the second

 Single element (3b) has a recess (5),

 so that in an assembled state of the first individual segment (3a) with the second individual segment (3b), the bulge (4) of the first

 Single segment (3a) protrudes into the recess (5) of the second individual segment (3b),

 characterized in that

 the bulge (4) of the first individual segment (3a) and the recess (5) of the second individual segment (3b) are formed such that in the assembled state of the individual segments (3a, 3b) only a portion (4a) of the bulge (4) a partial area (5a) of the recess (5) has a first contact surface (9a),

 and the second individual segment (3b) has a deformable part (6) which is arranged on the subregion (5a) of the recess (5) in such a way that in the pressed state of the assembled individual segments (3a, 3b) into the stator carrier (2 ) the deformable part (6) by the force of the

 Injection is deformed such that the recess (5) of the bulge (4) is adapted so that in the pressed state of the individual segments (3a, 3b) in the stator (2), the bulge (4) with the recess (5) has a larger second contact surface (9b) than in the assembled state of

Individual segments (3a, 3b).

2. Stator according to claim 1,

 characterized in that

 the deformable part (6) of the single segment (3b) is deformable mainly in the radial direction.

3. Stator according to one of the preceding claims,

 characterized in that

 in the pressed-in state of the individual segments (3a, 3b) in the stator carrier (2), at least 90 percent of a surface of the bulge (4) of the first individual segment (3a) have contact with a surface of the recess (5) of the second individual segment (3b).

4. Stator according to one of the preceding claims,

 characterized in that

 the first individual segment (3a) via a recess (5 ')

 and the second single segment (3b) has a bulge (4 ').

5. Stator according to one of the preceding claims,

 characterized in that

 all individual segments (3a, 3b) have a same shape.

6. Stator according to one of the preceding claims,

 characterized in that

 that each individual segment (3a, 3b) is formed from a laminated core.