WO2007115613A1

WO2007115613A1 - Brush holder for contact brushes of a commutator machine

Info

Publication number: WO2007115613A1
Application number: PCT/EP2007/001881
Authority: WO
Inventors: Helmut Sesselmann
Original assignee: Brose Fahrzeugteile Gmbh & Co. Kg, Coburg
Priority date: 2006-04-07
Filing date: 2007-03-01
Publication date: 2007-10-18
Also published as: DE202006005903U1

Abstract

The invention relates to a brush holder for contact brushes of a commutator machine with spring elements which have brush shoes connected to the contact brushes, carry the contact-brush current, and prestress the contact brushes in the direction of the commutator of the commutator machine. The invention provides for the spring elements (5, 5') to be connected to bimetallic elements (6, 6') which carry the contact-brush current, or to be in the form of bimetallic elements which are designed such that the spring force of the spring elements (5, 5'), which decreases on heating of the spring elements (5, 5') without bimetallic elements (6, 6') or on heating of the spring elements (5, 5'), which are not in the form of bimetallic elements, and by means of which spring force the contact brushes (3, 3') are pressed against the commutator (2), is at least partially compensated.

Description

Brush holder for contact brushes of a commutator machine

description

The invention relates to brush holders for contact brushes of a commutator machine according to the preamble of claims 1 and 9.

Brush holders are known for holding and guiding contact brushes of a commutator machine which consist of a carrier frame adapted to the contact brushes, in which the contact brushes are inserted, are displaceably arranged in the longitudinal direction of the frame-shaped support frame for readjustment and by means of a rear side of the contact brushes facing away from the commutator adjacent spring biased toward the commutator and fed with the armature current. A simpler and less expensive solution for a brush holder consists of spring elements, in particular leaf springs, which provide by shaping and Eigenfederverhalten for the required bias of the contact brushes and supply the contact brushes the power.

WO 03/032 468 A1 discloses a brush holder system for an electric drive device, which has a brush holder plate with a central opening for mounting would take a collector and arranged on the brush holder plate and each having a brush, the brush current leading leaf springs, which bias the brushes in the direction of the collector. The leaf springs are formed U-shaped in the side view, wherein the free end of the one leg is the directly or via a Bürsten tenaufnahme arranged on the leaf spring brush and the other end of the leaf spring perpendicular to the brush holder plate inserted into this.

With increasing load and associated increased power consumption of the commutator, the temperature of the current-carrying parts of the brush holder, in particular of the brush shoes bearing sections of the leaf springs increases. However, as the temperature of the required due to the required electrical conductivity and because of the necessary elasticity of a suitable metal or a metal alloy such as copper or bronze beryllium leaf springs decreases their spring constant, so that the force decreases, with the contact brushes of the leaf springs against the commutator be pressed. Under heavy load on the commutator machine, temperatures of up to 300 ^° C. occur on the leaf springs in the area of the brush shoes, which soften the material, for example in the case of leaf springs and brush shoes made of copper or bronze beryllium with brushes embedded or riveted on the brush shoes with embedded silver particles with irreversible change in shape and thus significantly reduced spring force leads.

As a result of the decreasing contact pressure, the contact resistance from the contact brushes to the commutator of the commutator increases according to a hyperbolic function, resulting in a further increase in temperature of the brush shoes and leaf springs, so that wear due to this reinforcing effect, the contact brushes with increased burnout prematurely and must be replaced costly.

The object of the present invention is to provide brush holders for contact brushes of a commutator machine of the type mentioned above, which press the contact brushes against the commutator with at least minimum contact pressure, independently of the load on the commutator machine, thus preventing premature wear of the carbon brushes or the entire brush holder system ,

This object is achieved by the features of claim 1. The solution according to the invention provides brush holders for contact brushes of a commutator machine which, irrespective of the load on the commutator machine, press the contact brushes against the commutator with a minimally required, but preferably with an optimum contact pressure and thus prevent premature wear of the carbon brushes or the entire brush holder system.

The caused by the bimetallic, increasing with increasing load of the commutator machine shape change of the bimetallic compensates the declining spring force of the spring elements at a compound of the spring elements with the contact brush current bimetallic leading at least partially or counteracts a decrease in the contact force, when the spring elements are designed as bimetallic elements , It is basically not necessary that the decreasing with increasing load of the commutator spring force of the combined bimetallic / spring elements or bimetallic elements is fully compensated, but at least partially offset by the change in shape of the bimetal and thus a premature wear of the contact brushes is counteracted.

If the spring elements and bimetallic elements have different spring rates, additional vibrations occurring during operation are damped.

The different spring rates of the interconnected and layered leaf springs behaving bimetallic and spring elements cause additional vibration damping of the entire brush holder system. By this additional effect, in addition to an improved noise behavior and an unwanted lifting of connected to the bimetallic / spring elements or bimetallic contact brushes are prevented by the commutator due to natural oscillations, which in turn would lead to increased wear of the contact brushes and deteriorated electrical properties.

In the first embodiment of the invention spring elements are provided, which are connected to the contact brush current leading bimetal elements, when heated, the force with which the contact brushes are pressed against the commutator, at least equal to the decreasing by the heating of the spring elements spring force. In the second embodiment, the spring elements are formed over at least part of their length as bimetallic spring elements, when heated, the force with which the contact brushes are pressed against the commutator, at least equal to the decreasing by the heating of the spring elements spring force.

In both embodiments of the invention, a temperature-induced decrease in the spring force of the spring elements is thus at least partially compensated, but preferably approximately balanced or even overcompensated especially at high load of the commutator, so that premature wear of the carbon brushes and occurring due to the decreasing spring force reinforcing effect by increasing the Transition resistance of the carbon brushes to the commutator avoided with decreasing spring force and thus the duration of the operational readiness of the commutator is significantly increased.

Bimetallic or bimetallic spring elements are understood to mean metal strips of two layers of different material, which are connected to one another in a materially positive or form-fitting manner and whose coefficients of linear expansion are different, so that they expand when heated by different distances, resulting in the material or positive connection of the metal strips leads to a bending of the bimetallic elements or bimetallic spring elements.

Preferably, in the first embodiment of the invention, the bimetallic elements of two non-positively or positively interconnected metal strips, of which the inner metal strip of a metal or metallic compound having a first coefficient of linear expansion and the outer metal strip of a metal or a metallic compound with a second Linear expansion coefficient is greater than the first coefficient of linear expansion by such a measure that the force with which the contact brushes are pressed against the commutator is equal to or slightly greater than the decreasing by the heating of the spring elements spring force.

By this design of the bimetallic elements, the decreasing at elevated temperature of the brush holder spring force of the spring elements is compensated by a compensating force which compensates for the loss of spring force of the spring elements at least partially by a bending of the bimetallic elements. With appropriate material Selection of the metal strip, a stronger bending of the bimetallic elements are caused, so that the adjusting force even overcompensated - without bimetal - declining spring force of the spring elements.

The bimetallic elements extend at least over a part of the length of the spring elements and are preferably on one side transmitting force to the spring elements, so that the mobility of the bimetallic elements is not limited when bending due to their heating and a deflection of the spring elements is ensured in the direction of the commutator.

A force-transmitting system of the bimetallic elements on the outer sides of the spring elements facing away from the commutator is achieved in a preferred embodiment in that the bimetallic elements are inserted into first socket slots of a base of the brush holder and the spring elements in second socket slots, which are arranged between the first socket slots ,

In order to maintain the mobility of the bimetallic elements when bent as a result of their heating, to ensure a uniform, non-positive engagement of the bimetallic elements on the spring elements and to avoid pressing the bimetallic elements into the outsides of the spring elements, the ends of the bimetallic elements facing away from the base are bent and transmit the Adjusting force on the bent ends on the outer sides of the spring elements.

The transfer of the force exerted by the bimetallic elements due to their heating compensation force on the spring elements can be optimized in that the ends of the bimetallic elements abut against each other curved portions of the spring elements, which connect to the connection of the spring elements with the socket slots.

The curvature of the spring elements essentially serves to ensure a large contact surface of the contact brushes on the commutator even with changed orientation of the spring elements.

In a first possible variant of the second embodiment of the invention, the bimetallic spring elements consist of two positively or non-positively connected, resilient metal strip made of a metal or a metallic compound having different coefficients of linear expansion, wherein the coefficient of linear expansion of the outer metal strip is greater than the coefficient of linear expansion of the inner metal strip by such a degree that the compensation force resulting from the bending of the bimetallic spring element caused thereby results the heating of the resilient bimetallic spring elements decreasing spring force compensated at least partially.

In a second possible variant of the second embodiment of the invention, the bimetallic spring elements consist of the brush shoes bearing leaf springs and positively or positively connected thereto, resilient bimetallic strip, which are non-positively or positively connected to each other, wherein the bimetallic strip connected to the leaf springs are composed of an inner metal strip having a first coefficient of linear expansion and an outer metal strip having a second coefficient of linear expansion, which is greater than the first coefficient of linear expansion by such a degree that the compensation force resulting from the bending of the bimetallic strip, when heated the Brush shoes bearing leaf springs and the elastic bimetallic strip - without bimetallic elements - decreasing spring force at least partially compensated.

In this variant of the second embodiment of the invention, the elastic metal strips and the leaf springs are riveted together, welded or cold-welded, wherein during cold welding the bare metal strips are rolled under pressure on each other, so that in the contact zone by cold welding an insoluble compound arises.

Also in the second embodiment of the invention, the bimetallic spring elements or the leaf springs connected to the bimetallic spring elements are preferably inserted into slots in a base of the brush holder and connected to a current leading to the contact brush current electrical line.

The bimetallic spring elements likewise have sections adjoining the connection with the base slot, which are curved relative to one another, so that a large-area contact brush contact with the commutator is ensured even when the orientation of the bimetallic spring elements is changed. In the figures of the drawing three embodiments of the invention are shown, which show essential features of the invention and are intended to illustrate the idea underlying the invention. Show it:

Figure 1 is a perspective view of the rotor of a commutator with a commutator and connected to a circuit board brush holder with spring elements and on the outer sides of the spring elements adjacent bimetallic elements.

Fig. 2 is a perspective view of the rotor of a commutator with a commutator and connected to a circuit board brush holders formed over part of their length as bimetallic spring elements and spring elements

Fig. 3 is a perspective view as in Fig. 2 with over its entire length designed as a bimetallic spring elements spring elements.

In Fig. 1 in a schematic perspective view of the rotor or armature 1 of a commutator, which is connected to a commutator segments having commutator or collector 2, and connected to a circuit board 9 brush holder 4, 4 'shown. The brush holder 4, 4 'have connected to the circuit board 9 sockets 8, 8 "and contain two diametrically arranged, applied to the commutator segments or -Stegen the commutator 2 contact brushes 3, 3' and the contact brushes 3, 3 ¹ in not spring elements 5, 5 'which are shown in more detail and which are designed as leaf springs and which press the contact brushes 3, 3' with a spring force determined by their spring constant to the commutator segments of the commutator 2. The spring elements 5, 5 'are arranged in first slots 81, 81'. the base 8, 8 'plugged in and connected via an electrical line or an electrically conductive pad 10, 10' to the output of a control circuit arranged on the circuit board 9 and lead the contact brushes 3, 3 'the contact brush or armature current.

As the load on the commutator machine increases, the armature current supplied via the contact brushes 3, 3 "to the commutator 2 of the armature 1 increases, which due to the e- Lektrischen resistance of the contact brushes 3, 3 'and the spring elements 5, 5' to a temperature increase, in particular in the region of the contact brushes 3, 3 'receiving brush shoes of the spring elements 5, 5' leads. Since with increasing temperature of the spring elements 5, 5 ', the spring constant of the spring elements 5, 5 ¹ decreases, and the contact pressure decreases, with which the contact brushes 3, 3' are pressed against the commutator 2, which in turn leads to a disproportionate increase in the contact resistance of the contact brushes 3, 3 'leads to the commutator 2. With increasing contact resistance but also increases the heating of the contact brushes 3, 3 ¹ and the spring elements 5, 5 ', so that the spring constant of the spring elements 5, 5' further decreases. This reinforcing effect means that with minimal contact pressure of the contact brushes 3, 3 'on the commutator 2, the power of the commutator machine is drastically reduced and the burnup of the contact brushes 3, 3' with the result of a drastic reduction in the life of the contact brushes 3, 3 "is amplified ,

Another problem is that the spring elements 5, 5 ', which are usually made of copper beryllium or bronze beryllium, change their lattice structure above a temperature predetermined by the material, with the result that the spring constant of the spring elements 5, 5' after an inadmissibly high heating of the Spring elements 5, 5 'is irreversibly reduced and thus an insufficient contact pressure of the contact brushes 3, 3' is given to the commutator 2 even at low load of the commutator.

In particular, the reinforcing effect in reducing the contact pressure of the contact brushes 3, 3 ¹ on the commutator 2 and an irreversible change in the material structure of the spring elements 5, 5 'with the result of too low contact pressure of the contact brushes 3, 3' on the commutator 2 against act, the spring elements 5, 5 'with bimetallic elements 6, 6' are connected, which are connected via a conductive connection to the output of the control circuit for driving the commutator and accordingly lead the armature or contact brush current, they by their electrically conductive system the spring elements 5, 5 'and forward them on the brush shoes to the contact brushes 3, 3'.

The bimetallic elements 6, 6 'consist in a manner known per se of metal strips with two layers of different material, which are connected cohesively or positively to one another. The two metal layers have different lengths coefficients of expansion, so that they expand when heated by different distances. As a result of the cohesive or positive connection of the two metal layers by riveting, welding or cold welding leads the different length expansion of the two metals to a bending of the bimetallic element in the direction of the metal layer, which has the lower coefficient of linear expansion, that is, which expands less when heated.

In order to exploit this effect for at least partial compensation or overcompensation of the spring constants of the spring elements 5, 5 'decreasing with heating of the spring elements 5, 5', the bimetallic elements 6, 6 ^{1 are} frictionally connected to the spring elements 5, 5 'in such a way in that they rest either on a part of the length of the spring elements 5, 5 'or on the entire length of the spring elements 5, 5' on the spring elements 5, 5 'and due to the application of the armature or contact brush current when heated in the Bending direction, which leads to an increase of the contact pressure of the contact brushes 3, 3 'on the commutator 2.

In the embodiment according to FIG. 1, the bimetallic elements 6, 6 'which extend over only a part of the spring elements 5, 5' rest on the outside of the spring elements 5, 5 'and are composed of two metal layers of different coefficients of linear expansion in such a way that they to bend when heated in the direction of the spring elements 5, 5 '. The bimetal elements 6, 6 'are inserted into second slots 82, 82' of the base 8, 8 'and connected via an electrical line or a conductive pad to the output of the control circuit for driving the commutator, so that they with the anchor or Contact brush current are applied and bend with increasing armature or contact brush current in the direction of the spring elements 5, 5 '. As a result, the spring elements 5, 5 'and, accordingly, the contact brushes 3, 3' bearing portions of the spring elements 5, 5 'in the direction of the commutator 2 to increase the contact pressure of the contact brushes 3, 3' pressed to the commutator 2.

The non-positive connection of the bimetal 6, 6 'with the spring elements 5, 5' via bent or angled ends 61, 61 'of the bimetallic elements 6, 6'. As a result of this form of non-positive connection of the bimetallic elements 6, 6 'with the spring elements 5, 5', a planar system for transmitting the armature or contact brush current from the bimetal elements 6, 6 'to the spring elements 5, 5' is produced. acts and at the same time created the prerequisite for a compensation of movement when the bimetallic 6, 6 'when heated to the spring elements 5, 5 "bend while a longitudinal displacement of the bimetallic 6, 6' to the spring elements 5, 5 '.

In order to achieve a uniform contact surface of the contact brushes 3, 3 'on the commutator 2 under the action of the spring force of the spring elements 5, 5 ¹ or by the bimetallic 6, 6' effected adjusting force, the spring elements 5, 5 'to each other arched sections 51, 51 'on. Preferably, the force transmitting ends 61, 61 'of the bimetallic elements 6, 6' bear against the curved sections 51, 51 'of the spring elements 5, 5', preferably in the region of their closest approach, so that the bending of the bimetallic elements 6, 6 ' when they are heated to a uniform pressing of the contact surfaces of the contact brushes 3, 3 'on the commutator 2 and thus to a targeted partial compensation, compensation or overcompensation of decreasing upon heating spring constant of the spring elements 5, 5' leads.

Depending on the length or design of the spring elements 5, 5 ', the material composition of the bimetallic 6, 6' and the power of the commutator, the length of the bimetal 6, 6 'and the contact surface of the bimetal 6, 6' on the spring elements 5, 5th 'be varied. Thus, for example, in an alternative embodiment, the bimetallic 6, 6 'to the ends of the spring elements 5, 5' or to the brush shoe-carrying portions of the spring elements 5, 5 'are extended and the transmission of the armature or contact brush current directly in the area the brush shoes of the spring elements 5, 5 'or distributed over a plurality of contact portions over the length of the spring elements 5, 5'.

The arrangements shown schematically in perspective in FIGS. 2 and 3 relate to alternative embodiments for compensation or overcompensation of the spring constants of the spring elements 5, 5 'decreasing with heating of the spring elements 5, 5'. In these embodiments, the spring elements 5, 5 'at least over part of their length as bimetallic spring elements 7, 7' are formed, the contact pressure of the contact brushes 3, 3 'to the commutator 2 of the commutator above with increasing heating due to increasing load on the commutator a minimum or constant value or even increase overcompensation. In the embodiment according to FIG. 2, the spring elements 5, 5 'are formed over only part of their length as bimetal spring elements 7, T, into a slot 80, 80' of the base 8, 8 'connected to the circuit board, the brush holder 4, 4 'inserted and connected via an electrically conductive connection to the output of the control circuit of the commutator. The bimetallic spring elements 7, T formed portions of the spring elements 5, 5 'extend as shown in FIG. 2, approximately to the region of the smallest distance to achieve a uniform contact pressure of the contact bus surfaces on the commutator 2 curved spring elements 5, 5'.

In the embodiment according to FIG. 3, the spring elements are designed over their entire length as bimetallic spring elements 7, T with unchanged shaping.

The bimetal spring elements 7, 7 'can be assembled in different ways. In a first embodiment, the bimetallic spring elements 7, T consist of metal strips with two metal layers of different material, which are connected to one another in a material- or form-fitting manner. In this case, the metal layers adjacent to the commutator 2 have a lower coefficient of linear expansion than the metal layers facing the outside of the contact brushes 4, 4 ', so that when the bimetallic spring elements 7, 7' rise due to increasing armature or contact brush current, they are firmly connected to one another by riveting, Welding or cold welding connected metal layers or strips of the bimetallic spring elements 7, T strive to bend in the direction of the commutator 2 and thereby due to the contact brushes 3, 3 'on the commutator 2, the contact pressure of the contact brushes 3, 3' on Kom - Increase mutator 2.

In an alternative embodiment, bimetallic spring elements 7, T composed of metal strips with two metal layers of different material are connected partially or continuously with positive, non-positive or cohesive force with spring elements 5, 5 ', so that three metal layers are provided in cross-section. When heated, the current-carrying bimetallic spring elements 7, 7 'and the spring elements 5, 5' connected to them bend in the direction of the commutator 2 and thus maintain the contact pressure of the contact brushes 3, 3 'on the commutator 2 above a predetermined minimum value or approximately constant or increase this slightly with increasing warming for at least partial compensation or overcompensation of the decreasing spring constants of the bimetallic spring elements 7, T and spring elements 5, 5 '.

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LIST OF REFERENCE NUMBERS

1 rotor or armature of a commutator machine

2 commutator

3, 3 ¹ contact brushes

4, 4 "brush holder

5, 5 'spring elements

6, 6 'bimetallic elements

7, T bimetallic spring elements

8, 8 'brush holder base

9 circuit board

10, 10 'electrical line or an electrically conductive coating

51, 51 'curved portions of the spring elements

61, 61 'angled ends of the bimetallic elements

80, 80 'slots

81, 81 'first slots

82, 82 'second slots

Claims

claims

1. Brush holder for contact brushes of a commutator machine with spring elements, which have brush shoes connected to the contact brushes, guide the contact brush current and bias the contact brushes in the direction of the commutator of the commutator machine,

characterized,

the spring elements (5, 5 ¹ ) are connected to the bimetal elements (6, 6 ') which carry the contact brush current, or are designed as bimetallic elements (7, 7') which are dimensioned such that when the spring elements (5, 5 ') are heated without bimetallic elements (6, 6 ') or upon heating of the spring elements (5, 5') which are not formed as bimetal elements (7, 7 '), decreasing spring force of the spring elements

(5, 5 '), with which the contact brushes (3, 3') are pressed against the commutator (2) is at least partially compensated.

2. Brush holder according to claim 1, characterized in that the bimetallic elements (6, 6 '; 7, 7') when heating the spring elements (5, 5 ') without bimetallic elements (6, 6') or when heated not as bimetal elements (7, 7 ') formed spring elements (5, 5') decreasing spring force of the spring elements (5, 5 '), with which the contact brushes (3, 3') are pressed against the commutator (2), over-compensate.

3. brush holder according to claim 1 or 2, characterized in that the spring elements (5, 5 ') and bimetallic elements (6, 6', 7, 7 ') have different spring rates.

4. brush holder according to at least one of the preceding claims, characterized in that the bimetallic elements (6, 6 ') consist of two force or form-fitting interconnected metal strips, of which the inner Metal strip of a metal or a metallic compound having a first coefficient of linear expansion and the outer metal strip of a metal or a metallic compound with a second coefficient of linear expansion, which is greater than the first coefficient of linear expansion by such a degree that the force with which Contact brushes (3, 3 ') to the

Commutator (2) are pressed, the at least partially compensated or overcompensated by the heating of the spring elements (5, 5 ') without bimetallic elements (6, 6') decreasing spring force.

5. brush holder according to at least one of the preceding claims, characterized in that the bimetallic elements (6, 6 ') extend over at least part of the length of the spring elements (5, 5') and transmitting force to the spring elements (5, 5 ') issue.

6. brush holder according to at least one of the preceding claims, characterized in that the bimetallic elements (6, 6 ') on one side against the spring elements (5, 5').

7. brush holder according to claim 6, characterized in that the bimetallic elements (6, 6 ¹ ) force applied to the commutator (2) facing away from the outer sides of the spring elements (5, 5 ').

8. brush holder according to at least one of the preceding claims, characterized in that the bimetallic elements (6, 6 ') in first base slots (81, 81') of a base (8, 8 ') of the brush holder (4, 4') and the spring elements (5,5 ') in second socket slots (82, 82') of the base (8, 8 ') are inserted, which are arranged between the first base slots (81, 81').

9. brush holder according to at least one of the preceding claims, characterized in that the said base (8, 8 ') facing away from the end portions (61, 61') the bimetallic elements (6, 6 ') are bent outwardly and with the end portions (61, 61') frictionally rest against the outer sides of the spring elements (5, 5 ').

10. brush holder according to claim 9, characterized in that the ends (61, 61 ') of the bimetallic elements (6, 6') at mutually arched portions (51, 51 ') of the spring elements (5, 5') rest, which adjoins connect the connection of the spring elements (5, 5 ') to the socket slots (82, 82').

11. brush holder according to claim 1, characterized in that the bimetallic spring elements (7, 7 ') consists of two non-positively or positively connected to each other, resilient metal strips, of which the inner metal strip of a metal or a metallic compound with a first Längenausdeh - The coefficient of friction and the outer metal strip consists of a metal or a metallic compound having a second coefficient of linear expansion, which is greater than the first coefficient of linear expansion by such that the bending of the bimetallic spring elements (7, 7 ') resulting force, with in that the contact brushes (3, 3 ') are pressed against the commutator (2), which by heating the spring elements (5, 5') without bimetallic spring elements (7,

7 ') decreasing spring force at least partially compensated or overcompensated.

12. brush holder according to claim 11, characterized in that the bimetal spring elements (7, 7 ') of the brush shoes (3, 3') bearing leaf springs and positively or positively connected with these, resilient bimetallic strip exist, the non-positive or positive connected to each other, wherein the metal strip connected to the leaf springs of a metal or a metallic compound having a first coefficient of linear expansion and the outer

Metal strip of a metal or a metallic compound with a second coefficient of linear expansion, which is greater than the first coefficient of linear expansion by such a degree that the compensation force resulting from the bending of the bimetallic strip, the heating of the brush shoe-bearing leaf springs and the resilient bimetallic strip decreasing spring force at least partially compensated or overcompensated.

13. brush holder according to claim 1 1 or 12, characterized in that the bimetallic strip of the bimetal spring elements (7, 7 ') and the leaf springs riveted together, welded or cold-welded.

14. Brush holder according to at least one of the preceding claims 11 to 13, characterized in that the bimetallic spring elements (7, 7 ') or the leaf springs connected to the bimetal spring elements (7, 7') inserted into slots of a base of the brush holder and are connected to a contact brush current leading electrical line.

15. Brush holder according to at least one of the preceding claims 11 to 14, characterized in that the bimetallic spring elements (7, 7 ') to the connection with the base slot subsequent sections which are curved to each other.

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