SK399492A3 - A commutator for electrical devices and method of its production - Google Patents

Description

Technical field

BACKGROUND OF THE INVENTION The present invention relates to a commutator for electrical machines with external metal slats, which are spaced apart from one another by stiffening rings, pre-assembled into a lamella body and together with a hub for fastening to the machine shaft anchored in the press insulating material. a ring provided with recesses adjacent to spacers which are formed of an insulating material surrounding the reinforcing rings to hold the metal plates at a predetermined distance from each other,

BACKGROUND OF THE INVENTION

DE-PS 11 55 528 already discloses such a commutator for electrical machines and a method for its manufacture, wherein in this commutator the individual lamellas are arranged annularly on two reinforcing rings arranged on the fronts into the lamella body by inserting the reinforcing rings into the respective front recesses on the lamellae before the lamella body mounted on the mandrel is inserted into the mold, the mandrel is removed and the lamella body, together with the hub arranged concentrically thereto, is anchored in the insulating molding material. In order to arrange the slats at a predetermined distance, spacers are provided on the insulating material surrounding the reinforcing ring, which are laterally supported by the slats. The disadvantage of this commutator is that the lamella body must be held together by special precautions prior to the hub pressing and that the reinforcing rings must be held by special fixing supports against axial pushing out of the lamella recess when the insulating molding material is pressed.

SUMMARY OF THE INVENTION It is an object of the present invention to retain the lamella body before and during compression by the simplest possible measures and to prevent the reinforcing rings from being pressed out by the molding material.

SUMMARY OF THE INVENTION

This task is accomplished by a commutator for electrical machines with external metal slats, which are spaced from each other by means of reinforcing rings pre-assembled into a lamellar body and together with a hub for fastening to the machine shaft anchored in the press insulation material, the metal slats being a ring provided with recesses adjacent to the spacing ribs which are formed of an insulating material surrounding the reinforcing rings to hold the metal slats at a predetermined distance from each other, according to the invention which is based on the spacing ribs on at least an axial portion of the insulating material surrounding the stiffening rings and the lamella recess portions, radially adjacent portions, axially cooperating means are provided which secure the stiffening rings in the lamella recesses against axial displacement.

with said latch

According to a preferred embodiment of the invention, between the spacing ribs on the insulating mass of the reinforcing ring there are formed snap-in protrusions, pointing axially outwards, which snap into corresponding projections in the recesses of the slats.

For the pre-assembly of the lamella body, it is further advantageous if the side of the reinforcement ring opposite the latching projection has a distance from the lamella recess which roughly corresponds to the height of the latching projection so that the reinforcing rings can be easily inserted into the lamella recess.

The reliable holding of the pre-assembled lamella body together is advantageous in that the latching means are arranged on the radially outer side of the reinforcing rings and the recesses of the slats.

The commutator according to the invention has the advantage that the latching means formed on the reinforcing rings and the lamella recesses both hold the lamella body together prior to being pressed by the insulating material and prevent the reinforcing rings from being pushed out of the recesses of the commutator lamellae during compression.

The object of the present invention further provides a method of manufacturing a commutator in which an annular body of annular metal lamellae is guided and spaced apart from each other, together with a concentrically arranged hub, anchored in a molding composition according to the invention. The principle is that the metal lamellas are first annularly arranged in the holding fixture on a larger external diameter, then the reinforcing rings on the side of the recess of the lamellas lying on the smaller diameter are inserted into these recesses and subsequently the metal lamellas are pressed radially inwards so that The latch body engages the latching means on the reinforcement ring and the recess.

An advantage of the method of manufacture of the commutator according to the invention is that by snapping the slats over the reinforcing rings, the automatic assembly of the lamella body is carried out, thereby enabling the transport of the preformed lamella body for proper pressing.

BRIEF DESCRIPTION OF THE DRAWINGS

BRIEF DESCRIPTION OF THE DRAWINGS The invention will now be described in more detail with reference to the accompanying drawing, in which: FIG. 1 shows a preformed lamella body, FIG. 2 shows the lamella and the reinforcement ring before engaging, FIG. 3 shows a commutator molded with an insulating material, and FIG. 4 shows, in a larger scale, a rust in the region of the latch engagement and the reinforcement ring on the finished commutator.

DETAILED DESCRIPTION OF THE INVENTION

For manufacturing the commutator 10 for the electrical machines shown in FIG. 3, first the individual pressed and embossed media plates 11 of FIG. 1 and 2 are arranged in a ring, in which the media plates 11 have a certain distance from each other. The recesses 13, which are visible in FIG. 2, in which one reinforcing ring 14 is inserted from the front side of the copper strips 11. In the circumferential area, the recess 13 abuts the medial spacing zebra 15, which are formed of 16 surrounding the three side reinforcing rings.

14, so that FIG. 1, the media plates 11 are held at a predetermined distance from each other.

slats 11 for insulating materials

In FIG. 2 it can be seen that the reinforcing rings 14, made of metal, preferably steel, are first surrounded by a free insulating material 16 on their radial inner side 14a. Furthermore, it can be seen that between the spacer ribs 15 shown in FIG. 1, snap-in protrusions 17 are formed on the insulating material 16 of the reinforcing rings 14 on the radially outer side of the reinforcing rings 14, facing axially outwards, and that the recesses 13 of the median lamellae 11 are pressed on the radially outer side of the reinforcing rings 11. FIG. 2 it can be seen that the recesses 13 of the copper plates 11 are in the radial direction by the height of the latching lugs 17 on the reinforcing rings 14 farther than the radial thickness of the reinforcing rings 14, including the insulating material 16 surrounding them.

In order to form the preformed lamella body 20 shown in FIG. 1, which is easily transportable, the media plates 11 are first placed in the retaining device 19 annular to a larger outer diameter. Thereafter, the reinforcing rings 14 on the end faces in the axial direction along the side 13a lying on the smaller radius are inserted into the recesses 13 of the copper plates 11 shown in FIG. 2. Subsequent with copper slats. 11 pushes radially inwards by reducing the diameter of the vane ring by radial compression. As a result, the latching means on the reinforcing rings 14 and the recesses 13 of the copper plates 11 are now locked in such a way that, as can be seen in FIG. The snap-in lugs 17 on the insulating material 16 of the reinforcing rings 14 snap into the respective recesses 18 in the recesses 13 of the copper plates 11. In the preformed lamella body 20, the reinforcing rings 14 in the recesses 13 of the copper plates 11 are now secured against axial displacement.

The lamella body 20 is now transported, without special additional measures, for example on automatic conveyor belts and the like, to a crimping place with an insulating material, where it is inserted concentrically with the lamella body 20 into a mold (not shown) into which it is inserted. 21 on a mandrel (not shown). Thereafter, in the mold, all of the interstices between the copper plates 11 of the stiffening rings 14 and the hub 21 are filled with a press insulating material 22, liquid at the correspondingly higher temperatures, which is then allowed to harden. In this case, both the copper plates 11 and the reinforcing rings 14 and the hub 21 are anchored in a snap-fit arrangement in the press insulation material 22.

In FIG. 3 shows a commutator removed from the press mold, which only needs to be turned on the outer periphery of the copper plates 11 to form a sliding surface for the cooperating carbon brushes of an electric machine (not shown). Alternatively, flat notches are also cut between the media plates 11.

In FIG. 4 it can be seen that on the preformed and then compressed lamella body 22, the inner side 14a of the reinforcing rings has a recess 13 relative to the inner side 13a of the copper plates 11, approximately equal to the latching height of the latching lugs 17 with the recesses 18. shown in FIG. 4, this gap 23 is filled with this insulating material 22. so that the metal reinforcement ring 14 is also insulated on its lower inner side 14a against the copper plates 11.

The invention is not limited to the illustrated embodiment. For example, the reinforcing rings 14 may also be wound from steel wires or may be made of glass fiber reinforced plastic, which itself is an insulator against the copper plates 11. When using reinforcing rings 14 of carbon fiber reinforced plastic, due to the negative coefficients of elongation of the carbon fibers, aligned into the ring, the advantage is that the reinforcing force increases with increasing temperature. Therefore, under the thermal load, a radial bias is created in the reinforcing rings to help hold the media plates 11 together.

In addition, it is possible to make a snap connection on the inner side of the reinforcement rings 14 and to cut out 13 of the copper plates 11. In this case, the copper plates 11 of the commutator 10 for snap connection with the reinforcement rings 14 would be pushed radially outwards. Instead, however, it is also possible to only snap radially outwardly to the heel portion 14b for engaging the laths 11 with the reinforcing rings 14 if the insulating ring 14 is sufficiently insulated against the laths 11. Finally, it is also possible to arrange snap-in lugs 17 on the copper plates 11 and in the insulating material 16 of the reinforcing rings 14 corresponding to the recess 18. Irrespective of the snap-fit arrangement, this solution is not limited to the use of copper plates, since other materials can also be used as long as they provide sufficient mechanical strength and lossless current conduction.

Claims (6)

PATENT CLAIMS 1. Commutator for electric machines with external metal slats, which are spaced from one another by means of reinforcing rings pre-assembled into a lamella body and together with a hub for fastening on the machine shaft anchored in a press insulating material, the metal slats for receiving the reinforcing rings provided with recesses adjacent to the spacers which are formed of an insulating material surrounding the reinforcing rings to hold the metal plates at a predetermined distance from each other, characterized in that between the spacers (15) on at least an axial portion of the insulating the masses (16) surrounding the stiffening rings (14) and on the portion of the recesses (13) of the slats (11) radially adjacent to said portion are formed axially cooperating latching means (17, 18), which stiffening rings (14) in the recesses (13). ) of the slats (11) secure against axial displacement. Commutator according to claim 1, characterized in that between the spacers (15) on the insulating material (16) of the reinforcement ring (14) there are formed locking projections (17) which extend axially outwardly and which extend into corresponding recesses (18). ) in the recesses (13) of the slats (11). Commutator according to claim 2, characterized in that the side of the stiffening ring (14) opposite the latching projection (17) has a distance (23) to the recess (13) of the slat (11) corresponding approximately to the latching height of the latching projections (17). ) with recesses (18). Commutator according to claim 3, characterized in that the reinforcing rings (14) are made of carbon fiber reinforced plastic. Commutator according to claim 3, characterized in that the latching means (17, 18) are arranged on the radially outer side of the reinforcing rings (14) and the recesses (13) of the slats (11). Method for producing a commutator according to one of Claims 1 to 5, in which the lamella body of the annular metal lamellae is guided and arranged at a distance from each other, together with the concentrically arranged hub, anchored in the molding compound characterized in that the metal slats (11) are first arranged in a holding fixture (19) on a larger outer diameter, then the reinforcement rings (14) on the side (13a) of the slats (13) lying on the a smaller diameter, is inserted into these recesses (13) and then the metal slats (11) are pressed radially inwards so that, to form the preformed lamella body (20), the latching means (17, 18) snap onto each other on the reinforcement ring (14) and recess (13).