SQUIRREL-CAGE ROTOR AND METHOD FOR PRODUCING A SQUIRREL-CAGE ROTOR

Information

  • Patent Application
  • 20190149027
  • Publication Number
    20190149027
  • Date Filed
    October 08, 2018
    6 years ago
  • Date Published
    May 16, 2019
    5 years ago
Abstract
The invention relates to a squirrel-cage rotor (1) having a shaft (2), a rotor plate stack (3) with rotor bars (4) arranged in the interior thereof, and cage rings (5), wherein at least one part of a cage ring (5) is comprised of a disk stack (7), which is constituted as a layered structure of disks (6) with cut-outs (63), through which the ends of the rotor bars (4) project out of the rotor plate stack (3). Adjoining disks (6) in the disk stack (7) are mutually spaced, and form a gap. The clearance between two adjoining disks (6), resulting from the gap, is constituted by moldings (61) which are arranged on the disks (6) wherein, in the gap (8), at least in the region of the moldings (61), a joint connection (9) is provided. The invention further relates to a method for producing a squirrel-cage rotor.
Description

The invention relates to a squirrel-cage rotor according to the introductory clause of claim 1, and to a method for producing a squirrel-cage rotor according to the introductory clause of claim 9.


Known squirrel-cage rotors comprise a rotor plate stack which incorporates slots, and rotor bars of a good electrically-conductive material which are inserted in the slots. The ends of the rotor bars project above the end faces of the rotor plate stack and are silver soldered or welded to compact cage rings. The ends of the rotor bars project into machined annular slots in the cage rings, which constitute the bed for the silver solder and are filled with the latter. For the prevention of any delamination of the rotor plate stack, and of any spurious oscillations, separate and compact clamping rings are press-fitted to the end face of the rotor plate stack. In order to further prevent any axial displacement of the rotor bars in the slots of the rotor plate stack, these are permanently mechanically attached to the rotor plate stack.


A squirrel-cage rotor with a rotor winding is known from document DE 34 21 537 A1. The rotor winding comprises electrically-conductive rotor bars, which are arranged in closed slots in a rotor plate stack, and project above the end faces thereof. The projecting ends are connected to good electrically-conductive cage rings in a conductive manner. The cage rings, correspondingly to the rotor plates, are configured as slotted plate stacks of a good electrically-conductive material and, as end face compression elements, are permanently connected over their entire surface to the rotor bars in their closed slots, in close proximity to the rotor plate stack, in a thermally-conductive manner. A particular feature is provided, in that the individual constituent electrically-conductive plates of the cage rings are of a greater thickness than the rotor plates, but are otherwise of the same size and shape as the latter. During the manufacture of a squirrel-cage rotor, the cage rings and the rotor plates are stacked together, the rotor bars are inserted at the end face thereof and thereafter, under the action of axial compression applied to the entire stack, the ends of the rotor bars are silver soldered to the cage rings.


A squirrel-cage rotor with cage rings for application in an asynchronous machine is further known from document DE 195 42 962 C1. The cage rings are comprised of copper plates, which are mutually spaced, and which form cooling ducts between the plate layers. Clearances between the copper plates are maintained by corresponding spacers. In the arrangement of the cage rings, the joint formed by solder extends in the axial direction of the squirrel-cage rotor, along the rotor bars, into the rotor plate stack, as a result of which end disks can be omitted.


The object of the invention is the further development of a squirrel-cage rotor, with respect to an improvement of the cage rings.


The invention is described with respect to a squirrel-cage rotor by the characteristics of claim 1, and with respect to a method for producing a squirrel-cage rotor by the characteristics of claim 9. The further dependent Claims relate to advantageous configurations and further developments of the invention.


The invention comprises a squirrel-cage rotor, having a shaft, a rotor plate stack with rotor bars arranged in the interior thereof, and cage rings, wherein at least one part of a cage ring is comprised of a disk stack, which is constituted as a layered structure of disks with cut-outs, through which the ends of the rotor bars project out of the rotor plate stack. According to the invention, adjoining disks in the disk stack are mutually spaced, and form a gap.


The clearance between two adjoining disks, resulting from the gap, is constituted by moldings which are arranged on the disks, wherein, in the gap, at least in the region of the moldings, a joint connection is provided. The squirrel-cage rotor is specifically intended for application in an asynchronous machine.


The invention proceeds from the consideration whereby, further to the joining process, the rotor plate stack, with the shaft and the cage rings, constitutes a compact squirrel-cage rotor component. Rotor bars are routed through the rotor plate stack and the cage rings, and are connected to the material of the cage rings in an electrically conductive manner. To this end, in relation to the rotor plate stack, the rotor bars are configured with an excess length, such that the latter project into cut-outs in the cage rings. The cage rings are positioned on the shaft, on both sides of the rotor plate stack. Each cage ring is itself comprised of a disk stack, which is constituted by a plurality of individual disks of identical diameter. The disks themselves, on the disk surface, incorporate cut-outs in an equal number to the rotor bars required for the constitution of a squirrel-cage rotor. These individual components, which are initially detachably arranged in relation to one another, must be connected to form a compact squirrel-cage rotor.


The joining process proceeds from the shell surface of each cage ring. Where the geometry of a disk is considered as a cylinder, the shell surface is the end-facing envelope or circumferential surface, i.e. the outermost region of the surface in the radial viewing direction. The base or top surfaces of the cylinder are then the surfaces which are perpendicular to its axis of rotation. By means of the moldings which are configured on the disks, the adjoining disks arranged in a disk stack are spaced from one another, as a result of which a respective gap is constituted. In the respective gap, at least in the region of the moldings, a joint connection is provided. The joint connection, specifically originating from the shell surface, can extend radially inwards only as far as the moldings, and can enclose the latter. However, the joint connection can also occupy the entire respective gap between two disks. By means of the joining material, the rotor bars are connected to the disks of a cage ring in an electrically conductive manner. The moldings configured on the disks, from a radial viewpoint, lie within the cut-outs which are provided for the rotor bars.


The solution according to the invention provides a particular advantage, in that the individual disks are produced from a strip material, in a cost-effective manner, by punching and embossing. By means of the moldings, a defined joint gap can be set between the disks, and between the rotor bars. A clearance defined by the moldings for the first disk on the rotor plate stack can be employed as a residual gap for cooling purposes.


In a preferred configuration of the invention, the joint connection can be a soldered connection. Originating from the shell surface, the solder can be separately introduced into a gap, by means of thermal treatment. By this arrangement, a strictly demarcated, yet adequate joining region is constituted, at least in the outer region in the vicinity of the shell surface of a cage ring. By means of soldered connection, this joining region provides adequate mechanical strength for the entire assembly. Satisfactory electrical contact between the rotor bars and the cage rings is likewise established.


Advantageously, the moldings can be configured to a step-wise design. The moldings comprise a given contact surface which, in the cage ring, engages in contact with the adjoining disk. Specifically, rectangular step shapes consequently deliver adequate stability, and provide an accurately-defined gap width.


In a further preferred configuration of the invention, indentations can be configured on the reverse side of the moldings. The indentations are specifically configured such that at least a given proportion by volume of appropriate moldings on an adjoining disk can engage in said indentations in a precisely fitted manner. In a disk stack of a cage ring, this provides a degree of mutual meshing between the individual disks.


Advantageously, the indentations can be configured to a step-wise design. The step geometry can be configured here such that a rectangular step shape interlocks with a molding in a precisely fitted manner.


In a further advantageous configuration of the invention, the moldings on one disk can, in part, engage with the indentations in an adjoining disk. By means of partial engagement, recesses for the formation of a joint connection and additional voids can be constituted in the immediate vicinity of the moldings on a disk, which are filled with a joining material. By this arrangement, an additional material bond, and thus an improved joint connection, is provided between the individual disks.


In an advantageous form of embodiment of the invention, the moldings on one disk can engage with the undercut indentations in an adjoining disk. Appropriate moldings can engage with the undercut indentations under the action of a degree of tension and thus provide additional solidarity between adjoining disks.


In a preferred form of embodiment of the invention, the volume of a respective indentation can be only partially occupied by a molding which engages with said indentation, as a result of which solder from the joint connection fills the residual volume of the indentation which is accessible via the gap. Accordingly, in comparison with exclusively flat disks, the overall proportion of the joint surface is enlarged, and the mutual connection of two disks is thus improved.


A further aspect of the invention comprises a method for producing a squirrel-cage rotor according to the invention by the following sequential steps:

    • Provision of a sheet metal blank for a disk,
    • Punching of cut-outs for the rotor bars,
    • Embossing of moldings or indentations in the disk,
    • Installation of the disks in a disk stack of a cage ring,
    • Arrangement of the cage rings on a rotor disk stack, together with rotor bars and a shaft,
    • Formation of a joint connection by the introduction of solder into the respective gap configured between adjoining disks, at least in the region of the moldings.





Further exemplary embodiments of the invention are described in greater detail with reference to the figures.


In the figures:



FIG. 1 shows a schematic longitudinal section of a squirrel-cage rotor,



FIG. 2 shows a detailed section of FIG. 1, in region A of the cage rings,



FIG. 3 shows a schematic representation of the process for the punching of cut-outs in a disk, and



FIG. 4 shows a schematic representation of the process for the embossing of moldings in a disk.





In all the figures, mutually corresponding parts are identified by the same reference numbers.



FIG. 1 shows a schematic longitudinal section of a squirrel-cage rotor 1. In this state, the rotor plate stack 3 is positioned on the shaft 2, in combination with two cage rings 5, which enclose the rotor plate stack 3 on the end faces thereof. A plurality of rotor bars 4 are arranged in the interior of the plate stack 3 and the cage rings 5. The bar ends of the rotor bars 4 project into cut-outs 63 in the cage rings 5, and terminate flush to the respective outermost disk 6 in the disk stack 7. As a result of the moldings 61 configured in the disks 6, adjoining disks 6 in the disk stack 7 are mutually spaced.


In this case, a disk stack 7 is comprised of four disks 6 which, from the shell surface outwards, which constitutes the end face of the respective disks 6, are connected over the outer circumference thereof by means of soldered connections 9. The soldered connections 9 extend radially inwards in the direction of the shaft 2. In the configuration represented, the soldered connections 9, viewed radially, extend fully to the interior, and enclose the moldings 61. In the case represented, as a result of the presence of a given residual gap, the material of the soldered connections 9 also penetrates axially between the cut-outs 63 and the rotor bars 4.



FIG. 2 shows a detailed section of FIG. 1, in region A of the cage rings. The disk stack 7 of a cage ring 5 is constituted by a plurality of individual disks 6 of equal diameter. Each disk 6 incorporates moldings 61 by means of which, upon the stacking of the disks 6 to form a disk stack 7, a gap 8 is constituted between adjoining disks 6. By way of a joint connection 9, solder is introduced into the respective gap 8. The moldings 61 are formed by a punching process, wherein corresponding indentations 62 are configured on the reverse side of the moldings 61. The moldings 61 and the indentations 62 are configured to a step-wise design, such that they fit together in pairs. In this manner, the moldings 61 on one disk 6, to a certain extent, engage with the indentations 62 in an adjoining disk 6. The volume of a respective indentation 62 is only partially occupied by a molding 61 which engages with said indentation. By this arrangement, solder from the joint connection 9 can penetrate the residual volume 81 of the indentation 62 which is accessible via the gap 8. The cage ring 5 encloses the shaft in an annular manner and, as a compact component, is connected to the rotor bars 4 in a good electrically conductive manner.



FIG. 3 represents one of the first process steps, whereby cut-outs 63 for the rotor bars and central cut-outs 64 for the shaft are punched out of a sheet metal blank to form a disk 6. The size of the central cut-outs 64 can be selected such that an annular disk 6 is constituted, the diameter of which can also be significantly larger than the shaft diameter.



FIG. 4 shows a further process step, whereby moldings 61 and indentations 62 are embossed into a disk 6. The embossing tool generates a multi-stepped profile in the indentations 62. The stepping of the indentations 62 is executed such that the latter interlock with the moldings 61 on an adjacently arranged disk 6, upon the connection thereof.


LIST OF REFERENCE SYMBOLS


1 Squirrel-cage rotor



2 Shaft



3 Rotor plate stack



4 Rotor bar



5 Cage ring



6 Disk



61 Moldings



62 Indentations



63 Cut-out for rotor bar



64 Central cut-out



7 Disk stack



8 Gap



81 Residual volume



9 Joint connection, soldered connection


A Detailed image section

Claims
  • 1. Squirrel-cage rotor (1), specifically for an asynchronous machine, having a shaft (2), a rotor plate stack (3) with rotor bars (4) arranged in the interior thereof, and cage rings (5), wherein at least one part of a cage ring (5) is comprised of a disk stack (7), which is constituted as a layered structure of disks (6) with cut-outs (63), through which the ends of the rotor bars (4) project out of the rotor plate stack (3), characterized in that adjoining disks (6) in the disk stack (7) are mutually spaced, and form a gap (8),the clearance between two adjoining disks (6), resulting from the gap (8), is constituted by moldings (61) which are arranged on the disks (6), andin the gap (8), at least in the region of the moldings (61), a joint connection (9) is provided.
  • 2. Squirrel-cage rotor according to claim 1, characterized in that the joint connection (9) is a soldered connection.
  • 3. Squirrel-cage rotor according to claim 1, characterized in that the moldings (61) are configured to a step-wise design.
  • 4. Squirrel-cage rotor according to claim 1, characterized in that indentations (62) are configured on the reverse side of the moldings (61).
  • 5. Squirrel-cage rotor according to claim 4, characterized in that the indentations (62) are configured to a step-wise design.
  • 6. Squirrel-cage rotor according to claim 4, characterized in that the moldings (61) on one disk (6), in part, engage with the indentations (62) in an adjoining disk (6).
  • 7. Squirrel-cage rotor according to claim 6, characterized in that the moldings (61) on one disk (6) engage with the undercut indentations (62) in an adjoining disk (6).
  • 8. Squirrel-cage rotor according to claim 6, characterized in that the volume of a respective indentation (62) is only partially occupied by a molding (61) which engages with said indentation (62), as a result of which solder from the joint connection (9) fills the residual volume (81) of the indentation (62) which is accessible via the gap (8).
  • 9. Method for producing a squirrel-cage rotor according to claim 1, characterized by the following sequential steps: Provision of a sheet metal blank for a disk (6),Punching of cut-outs (63, 64) for the rotor bars (4) and the shaft (2),Embossing of moldings (61) or indentations (62) in the disk (6),Installation of the disks (6) in a disk stack (7) of a cage ring (5),Arrangement of the cage rings (5) on a rotor disk stack (3), together with rotor bars (4) and a shaft (2),Formation of a joint connection (9) by the introduction of solder into the respective gap (8) configured between adjoining disks (6), at least in the region of the moldings (61).
Priority Claims (1)
Number Date Country Kind
10 2017 010 685.1 Nov 2017 DE national