Rotor and method for adjusting a rotor

Abstract

In rotors for electric motors, it is usual to fix the commutator on the rotor shaft by means of a press fit. In the process, damage undesirably occurs to the surface of the rotor shaft.

Description

PRIOR ART

[0001] The invention is based on a rotor and a method for producing a rotor as generically defined by the preamble to claim 1 and to claim 4, respectively. A rotor is already known (German Patent DE 37 28 000 C2), in which the rotor core is covered by an end disk on each face end that, on its face toward the rotor core and toward the rotor shaft has flow conduits, into which a winding impregnating agent can be introduced that after curing has taken place serves as an additionally effective stabilizing agent.

ADVANTAGES OF THE INVENTION

[0002] The rotor according to the invention and the method according to the invention for producing a rotor, as defined by the bodies of claims 1 and 4, respectively, has the advantage that a fixation of the commutator is possible in a simple way by means of the insulating agent (epoxy-based coating powder) applied to the rotor shaft and the rotor core. For that purpose, the inner bore of the commutator can be manufactured with a clearance fit or transition fit relative to the rotor shaft, and as a result on assembly the commutator can be slipped, fitting smoothly onto the rotor shaft, and both damage to the surface of the rotor shaft and internal stresses in the commutator are avoided, because the usual embodiment of the inner bore of the commutator with a press fit relative to the rotor shaft in the prior art has the danger of scratching the surface of the rotor shaft. The insulating layer applied moreover increases the axial retention forces of the rotor core, as a rule built up from lamination sheets, on the rotor shaft; that is, the rotor core is additionally mechanically held by the insulating layer.

[0003] By means of the provisions recited in the dependent claims, advantageous refinements of and improvements to the rotor disclosed in claim 1 and the method disclosed in claim 4 are possible. It is advantageous to embody the at least one recess of the commutator as a conical face that tapers from the connecting end face toward the inner bore, which makes easier penetration of the plasticized epoxy between the inner bore of the commutator and the rotor shaft possible, which leads to an improvement in the fixation of the commutator on the rotor shaft.

[0004] It is also advantageous to cover the rotor winding and the connecting wires, leading from the rotor winding to the commutator and joined to the commutator, with a second sintered epoxy layer, which not only protects against damage and aggressive media, but also effects an additional fixation of the rotor winding, which in turn prevents vibration-caused breakage.

DRAWING

[0005] One exemplary embodiment of the invention is shown in simplified form in the drawing and described in further detail in the ensuing description. FIG. 1 shows a rotor with an epoxy layer; FIG. 2 shows a rotor with a commutator slipped onto the rotor shaft; FIG. 3 shows a commutator in longitudinal section, taken along the line III-III in FIG. 4; FIG. 4 shows a commutator of FIG. 3 in side view; and FIG. 5 shows a rotor with a second epoxy layer.

DESCRIPTION OF THE EXEMPLARY EMBODIMENT

[0006] FIG. 1 shows a rotor for an electric motor, having a longitudinal axis 1, a rotor shaft 2 extending coaxially with it, and a rotor core 3 slipped with a press fit coaxially onto the rotor shaft 2. The rotor core 3 is a package of individual laminated sheets in a known manner, and has a plurality of winding slots 6, extending parallel to the longitudinal axis 1, which as shown in FIG. 2 extend from a first end face 8, toward a commutator 7, to a second end face 9 of the rotor core 3, remote from the commutator 7. The winding slots 6, the first end face 8, and the second end face 9 of the rotor core 3, and a first portion 12 of the rotor shaft 2 located between the rotor core 3 and the commutator 7, as well as a second portion 13 of the rotor shaft 2, remote from the commutator 7 and adjoining the rotor core 3, are covered with a centered epoxy layer 14. For that purpose, the rotor, without the commutator, is covered with masks in the regions of the rotor shaft 2 and rotor core 3 that are not to be provided with an epoxy layer 14, and the thus-equipped rotor is introduced into coating system 17, indicated by dashed lines, in which electrostatically charged epoxy powder in a fluidized powder bed is deposited on those regions of the rotor shaft 2 and rotor core 3 that are not covered by masks, so that the portions 12 and 13 of the rotor shaft 2, along with the first end face 8, the second end face 9 and the winding slots 6 of the rotor core 3, are covered with a layer of epoxy powder. The outer jacket of the rotor core 3 is covered as well. This powder layer on the outer jacket of the rotor core is removed in an ensuing operation by means of blowing, suction or stripping, so that the outer jacket is powder-free. After that, the temperature in the coating system 17 is increased until such time as the epoxy powder has heated up to its plasticizing and curing temperature, which is at approximately 240° C., and at which the epoxy powder becomes a viscous mass. In this state, the commutator 7 is slipped by means of a sliding tool 19, represented by dot-dashed lines, onto the rotor shaft 2 that rests near its second portion 13 on a retaining stop 18, in such a way that the viscous epoxy layer 14 present on the first portion 12 of the rotor shaft 2 partly curves radially outward in the manner of a bead 22 on a connecting end face 23 of the commutator 7 and penetrates an annular gap formed between the circumference of the rotor shaft 2 and the wall of an inner bore 24 (see FIGS. 3 and 4). Once the epoxy has cured and the rotor has cooled down, the commutator 7 is fixed in the axial direction and secured against rotation solely by the epoxy 14 on the rotor shaft 2. As shown in FIGS. 3 and 4, the commutator 7 has a commutator core 27 made of a duroplastic, which us surrounded by a metal conductor sleeve 28, made particularly from copper. The inner bore 24, which has a clearance or transition fit relative to the circumference of the rotor shaft 2, extends in the commutator core 27.

[0007] Beginning at the connecting end face 23, the commutator 7 has a recess 29, which extends toward the inner bore in the direction of the longitudinal axis and which is shown in FIG. 3 as a conical face 29 tapering toward the inner bore 24. However, the recess 29 may also be embodied as a longitudinal groove leading to the inner bore 24. The recess, for instance in the form of the conical face 29 that tapers toward the inner bore 24, makes easy, uniform penetration of the viscous epoxy into the annular gap formed between the rotor shaft 2 and the inner bore 24 possible. For better fixation of the commutator 7 in the direction of rotation, indentations 32 in the commutator core 27 are provided on the connecting end face 23 of the commutator 7, which for instance begin at the recess 29 and extend as far as the circumference of the commutator core 27. The cross section of the indentations 32 may be rectangular, triangular, semicircular, or the like. The bead 22 of epoxy 14 radially covers the indentations 32 and digs into them. Commutator slots 33 extending in the direction of the longitudinal axis sever the conductor sleeve 28 to form individual segments 34, electrically insulated from one another, that each have a respective connecting hook 35 toward the connecting end face 23. One connecting wire 37 of the rotor winding 38 shown in FIG. 5 is electrically connected to each connecting hook 35 by clamping. Once the rotor winding 38 has been inserted into the winding slots 6 of the rotor core 3 and the connecting wires 37 have been connected to the connecting hooks 35 of the commutator 7, the rotor is reintroduced into the coating system 17 and recoated electrostatically with epoxy powder on the rotor winding 38 and the connecting wires 37, and then heated to the plasticizing and curing temperature, as a result of which a second epoxy layer 39 is sintered on that covers the rotor winding 38 and the connecting wires 37 and thus fixes them; this improves both the resistance to jarring and the protection against aggressive media. Naturally, the second epoxy layer 39 in the process is also deposited on the first portion 12 of the rotor shaft 2 and on both the connecting end face 23 and the connecting hooks 35 of the commutator 7.

Claims

1. A rotor for an electric motor, having a rotor shaft, having a rotor core, and having a commutator, which are disposed coaxially to a longitudinal axis, wherein the rotor core has winding slots with at least one rotor winding disposed therein and a first end face oriented toward the commutator and a second end face remote from the commutator, and the rotor shaft has a first portion located between the rotor core and the commutator and a second portion beginning at the second end face of the rotor core and remote from the commutator, and the commutator has both a connecting end face oriented toward the rotor core and an inner bore coaxial with the longitudinal axis, characterized in that the winding slots (6), the first end face (8), and the second end face (9) of the rotor core (3), as well as the first portion (12) and the second portion (13) of the rotor shaft (2), are covered with a first sintered epoxy layer (14), and the commutator (7) has at least one indentation (32) on its connecting end face (23) and, beginning at the connecting end face (23), at least one recess (29) extending toward the inner bore (24) in the direction of the longitudinal axis (1), and the first sintered epoxy layer (14), for fixation of the commutator (7), engages the at least one indentation (32) and the at least one recess (29).

2. The rotor according to

claim 1, characterized in that the at least one recess of the commutator (7) is embodied as a conical face (29) that tapers from the connecting end face (23) toward the inner bore (24).

3. The rotor according to

claim 1 or

2, characterized in that the rotor winding (38) and the connecting wires (37), leading from the rotor winding (38) to the commutator (7) and joined to the commutator, are covered with a second sintered epoxy layer (39).

4. A method for producing a rotor for an electric motor, which coaxially to a rotor axis has a rotor shaft, a rotor core, and a commutator, wherein the rotor core has winding slots for at least one rotor winding that can be disposed therein and a first end face, toward the commutator, and a second end face, remote from the commutator, and the rotor shaft has a first portion located between the rotor core and the commutator and a second portion beginning at the second end face of the rotor core and remote from the commutator, and the commutator has a connecting end face toward the rotor core and an inner bore coaxial with the longitudinal axis, characterized in that after the rotor core (3) is press-fitted onto the rotor shaft (2), the first portion (12) and the second portion (13) of the rotor shaft (2) as well as the first end face (8), the second end face (9), and the winding slots (6) of the rotor core (3) are electrostatically coated with epoxy powder (14), after which the epoxy powder (14) is heated to its plasticizing and curing temperature, and after that the commutator (7) is slipped to its terminal position onto the rotor shaft (2), wherein some of the plasticized epoxy (14) is shifted from the first portion (12) and deposited on the connecting end face (23) and penetrates the inner bore (24).

5. The method according to

claim 4, characterized in that after the at least one rotor winding (38) is introduced into the winding slots (6) of the rotor core (3), the rotor winding (38), the connecting wires (37) leading from the rotor winding (38) to the commutator (7) and connected to the commutator, and the connecting end face (23) of the commutator (7) are electrostatically coated with epoxy powder (39), and after that the epoxy powder (39) is heated to its plasticizing and curing temperature.