Support structure for a laminated core of a stator segment

Abstract

The invention relates to a support structure (17) for a laminated core (9) of a stator segment (13) of a dynamoelectric machine having an external rotor, the support structure (17) having two joint plates (6) and two curved pressure plates (1), the respective longitudinal faces of which are in each case mutually opposed, and which encompass a predefinable space and can be connected at their abutting edges. The support structure also has substantially radial bars or ribs (3) between the pressure plates (1) and at least one element having polygonal cut-outs, which element is connected to a longitudinal face of the ribs (3) and forms a base plate of the support structure (17).

Claims

1. A support structure for a laminated core of a stator segment of a dynamoelectric machine having an external rotor, said support structure comprising: two joint plates configured to establish a mechanical contact of the stator segment, when installed, with a further stator segment disposed directly adjacent in a peripheral direction; two curved pressure plates having longitudinal faces in opposite disposition, the curved pressure plates and the joint plates encompassing a predefined space and connectable at their abutting edges; substantially radial bars or ribs extending between the pressure plates and in parallel relation to the joint plates; and an element having polygonal cut-outs and connected to a longitudinal face of the ribs, said element forming a base plate of the support structure and having a mesh-type structure to form a mesh sheet, wherein the space encompassed by the joint plates and the pressure plates is demarcated on a concave side by the element and on a convex side by the laminated core which is fitted and welded from the convex side onto the support structure and thereby integrate a supporting property of the laminated core into the support structure so that the laminated core of the stator segment assumes an electromagnetic function for forming and directing a electromagnetic field and at a same time a mechanical supporting function.

2. The support structure of claim 1, wherein the element is made of sheet metal.

3. The support structure of claim 1, wherein the mesh sheet has a mesh size which corresponds to a gap in the ribs or to an integer multiple of the gap in the ribs.

4. A stator segment of a dynamoelectric machine, said support segment comprising: a laminated core; and a support structure comprising two joint plates configured to establish a mechanical contact of the stator segment, when installed, with a further stator segment disposed directly adjacent in a peripheral direction, two curved pressure plates having longitudinal faces in opposite disposition, the curved pressure plates and the joint plates encompassing a predefined space and connectable at their abutting edges, substantially radial bars or ribs extending between the pressure plates and in parallel relation to the joint plates, an element having polygonal cut-outs and connected to a longitudinal face of the ribs, said element forming a base plate of the support structure and having a mesh-type structure to form a mesh sheet, wherein the space encompassed by the joint plates and the pressure plates is demarcated on a concave side by the element and on a convex side by the laminated core which is fitted and welded from the convex side onto the support structure and thereby integrate a supporting property of the laminated core into the support structure so that the laminated core of the stator segment assumes an electromagnetic function for forming and directing a electromagnetic field and at a same time a mechanical supporting function, and radial pressure fingers arranged radially on end faces of the laminated core which together with the pressure plates axially fasten the laminated core.

5. A stator segment of a dynamoelectric machine, said support segment comprising: a laminated core having a plurality of laminations; and a support structure comprising two joint plates configured to establish a mechanical contact of the stator segment, when installed, with a further stator segment disposed directly adjacent in a peripheral direction, two curved pressure plates having longitudinal faces in opposite disposition, the curved pressure plates and the joint plates encompassing a predefined space and connectable at their abutting edges, substantially radial bars or ribs extending between the pressure plates and in parallel relation to the joint plates, an element having polygonal cut-outs and connected to a longitudinal face of the ribs, said element forming a base plate of the support structure and having a mesh-type structure to form a mesh sheet, wherein the space encompassed by the joint plates and the pressure plates is demarcated on a concave side by the element and on a convex side by the laminated core which is fitted and welded from the convex side onto the support structure and thereby integrate a supporting property of the laminated core into the support structure so that the laminated core of the stator segment assumes an electromagnetic function for forming and directing a electromagnetic field and at a same time a mechanical supporting function, wherein an axial fastening of the laminated core is realized by the pressure plates and by bonding a last ones and first ones of the laminations of the laminated core via bonding varnish.

6. A stator of a dynamoelectric machine, comprising: a stator segment as set forth in claim 4, wherein when viewed in a peripheral direction, the stator segment is mechanically connected to a joint plate of an adjacent stator segment.

7. The stator of claim 6, wherein a plurality of said stator segment are connected together by the joint plates and by a sub-structure which extends over the stator segments.

8. A stator of a dynamoelectric machine, comprising: a stator segment as set forth in claim 5, wherein when viewed in a peripheral direction, the stator segment is mechanically connected to a joint plate of an adjacent stator segment.

9. The stator of claim 8, wherein a plurality of said stator segment are connected together by the joint plates and by a sub-structure which extends over the stator segments.

10. An external rotor generator or external rotor motor, comprising: a stator as set forth in claim 6; and a rotor interacting with the stator and including permanent magnets.

11. An external rotor generator or external rotor motor, comprising: a stator as set forth in claim 8; and a rotor interacting with the stator and including permanent magnets.

12. A wind turbine, comprising an external rotor generator as set forth in claim 10.

13. A wind turbine, comprising an external rotor generator as set forth in claim 11.

14. A process for the manufacture of a stator segment, comprising: providing a support structure as set forth in claim 1, with the joint plates, ribs and pressure plates being connected to one another on a longitudinal face of the ribs by the element with polygonal cut-outs; arranging a pre-packaged laminated core on the support structure on a side of the ribs facing away from the element; and inserting a winding system into grooves in the laminated core.

15. The process of claim 14, wherein the element is a mesh sheet.

16. The process of claim 14, wherein the winding system is a coil winding system.

17. A process for the manufacture of a stator, comprising: assembling individual stator segments as set forth in claim 4 by connecting the stator segments together by their joint plates and/or by a sub-structure extending over the stator segments; and establishing an electrical connection with a winding system for individual coils of the stator segments and with a converter.

18. A process for the manufacture of a stator, comprising: assembling individual stator segments as set forth in claim 5 by connecting the stator segments together by their joint plates and/or by a sub-structure extending over the stator segments; and establishing an electrical connection with a winding system for individual coils of the stator segments and with a converter.

Description

BRIEF DESCRIPTION OF THE DRAWING

(1) The invention and further advantageous embodiments thereof will now be described in greater detail by reference to outline visualizations of exemplary embodiments; in the figures:

(2) FIG. 1 shows a perspective representation of a support structure,

(3) FIG. 2 shows a perspective representation of a further support structure,

(4) FIG. 3 shows a cross-section of a stator segment without windings,

(5) FIG. 4 shows a further representation of a stator segment.

(6) FIG. 5 shows a support structure with a single-piece laminated core,

(7) FIG. 6 shows a support structure with an offset mesh sheet,

(8) FIG. 7 shows an outline longitudinal section through an external rotor generator of a directly driven wind turbine.

(9) FIG. 1 shows a support structure 17 which, in the further manufacturing process, forms the basis of a stator segment 13 of a stator 12 of a directly driven external rotor generator of a wind turbine.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

(10) This support structure 17 is curved and has joint plates 5 which, in the installed state of the stator segments 13, establish a mechanical contact with further stator segments 13 directly adjacent in the peripheral direction. The support structure 17 has a concave part 23 and a convex part 24. There are pressure plates 1 on the end faces of the support structure 17, preferably with holes 8 through which cooling air can be conducted in or out to cool the laminated core 9 of the stator 12 during the operation of the wind turbine.

(11) In another embodiment the pressure plates 1 are closed, i.e. they do not have holes 8. Consequently the support structure 17 is more or less open only at the top and bottom. When viewed in a tangential plane the support structure 17 is therefore closed.

(12) Flanges 6 of the pressure plate 1 are provided radially further inside on the concave side of the support structure 17, which flanges allow a connection to further fastening devices e.g. of a bearing unit 16 of the directly driven wind turbine.

(13) Bar elements, bars or ribs 3 extend essentially radially between the pressure plates 1 and are connected to a mesh sheet 4 in a firmly bonded manner, in particular by means of welding. In this case the gap in the webs 7 of the mesh sheet 4 extending between the pressure plates 1, in other words the mesh size, then corresponds to the gap in the ribs 3. Here the webs 7 are at least twice as wide as the bar elements or ribs 3 at their connection point to the ribs 3. With varying thicknesses of the bars 3 and/or webs 7, this prerequisite is especially important in order to ensure a firmly bonded connection of the web 7 and rib 3.

(14) The bars or ribs 3 preferably extend on or adjacent to the webs 7 in order in principle to enable spot or linear welding of ribs 3 and webs 7 of the mesh sheet 4 to these webs 7.

(15) FIG. 2 shows a perspective representation of a further, similar variant of the support structure 17 wherein the joint sheets 5 have fastening holes 18 in order to be connected mechanically to further joint sheets 5 of adjacent stator segments 13. The pressure plate 1 likewise exhibits holes 8 that are rounded in this case Between the webs 7 extending axially, in other words the webs 7 following the curvature in the peripheral direction, sections of the material of the mesh sheet 4 have a slight thinning 21, in order to enable the mesh sheet 4 to be bent slightly to form the curvature. This is advantageous especially in the case of thicker mesh sheets 4, the thickness of which approximately corresponds to that of, or which are even thicker than, the pressure plates.

(16) FIG. 3 shows, in a cross-section of a stator segment, the arrangement of the laminated core 9 on the bar-shaped elements or ribs 3 and between the pressure plates 1, as well as the fastening of the ribs 3 onto the axially-extending webs 7 of the mesh sheet 4. The arrangement of the flange 6 of the pressure plate 1 can also be seen, with which the stator segments 13 can be fastened to further fastening elements of a bearing unit 16 or sub-structure 22 (in each case not shown).

(17) The mesh sheet 4 has an open mesh 25 in at least one corner in order to be able to compensate better for the forces occurring during welding operations, for example.

(18) FIG. 4 shows a further perspective representation of a stator segment 13 without the winding system, wherein the axially layered laminated core 9 is fastened, positioned and packaged by means of the pressure plate 1 as well as pressure fingers 2. In this representation the laminated core 9 is constructed by axially lining up partial laminated cores 11. Spacing apart these partial laminated cores 11 produces cooling vents 10 between the partial laminated cores 11, which enable cooling of the stator segment 13 and consequently the stator during the operation of the generator or motor. The spacing is achieved by means of intermediate elements extending radially that are inserted while packaging the laminated core 9.

(19) Alternatively, the axially layered laminated core 9 of the stator segment 13 can also be fastened, positioned and packaged by means of the pressure plate 1 and by bonding the first and last layers of the laminated core 9 using bonding varnish so that pressure fingers 2 then need not necessarily be present. In each case three up to approx. 20 layers are then provided with bonding varnish. In certain variants this can simplify the manufacture of a stator segment 13.

(20) FIG. 5 shows a further perspective representation of a stator segment 13 without the winding system, wherein the axially layered laminated core 9 is fastened, positioned and packaged by means of the pressure plate 1 as well as pressure fingers 2. In this representation the laminated core 9 is designed as a single-layer laminated core 9 having no spacers extending radially that form cooling vents 10 between the partial laminated cores 11.

(21) FIG. 6 shows a perspective representation of the support structure 17 in which the ribs 3 run “over” the meshes of the mesh sheet 4. In other words, the ribs 3 that extend from one side of the laminated core 9, i.e. from one pressure plate 1 to the other pressure plate 1, only have contact points with the mesh sheet 4 at the webs extending tangentially. Accordingly, a connection between the ribs 3 and the mesh sheet 4, in particular the webs extending tangentially, is only created here. The connection is preferably a welded connection.

(22) In the variants presented here, the welded connections are preferably realized as spot or linear welds.

(23) In one possible variant, the thickness of the almost cuboidal bars or bar elements or ribs, but also of the mesh sheet, is in this case approximately twice as thick as the pressure plates 1 or joint plates 5.

(24) In a further possible variant, the thickness of the almost cuboidal bars or bar elements or ribs 3, but also of the mesh sheet 4, is approximately the same as the thickness of pressure plates 1 or joint plates 5.

(25) These “thickness variants” depend inter alia on the possible mechanical stresses expected during the operation of the wind turbine.

(26) FIG. 7 shows in an outline longitudinal section the arrangement of the stator 12 on a bearing unit 16. This representation also shows the rotor 20 as an external rotor of the generator having permanent magnets 26 pointing toward the air gap 27 of the dynamoelectric machine. The single-layer or double-layer winding system 14 shown here in outline form can be realized in this case using form-wound coils of equal or unequal coil pitch. Likewise, corded windings as well as lap windings may also be used, Preferably each stator segment 13 is supplied with its complete winding system 14 and connected electrically to a stator 12 on the construction site.

(27) A construction of this type is suitable not only for wind turbine generators; the support structure 17 is also suitable as the basis for large motors in drives, e.g. in extractive industry.