EP2856621A2

EP2856621A2 - Brush system for an electric motor

Info

Publication number: EP2856621A2
Application number: EP13728956.7A
Authority: EP
Inventors: Rainer Schoele; Frank Hartmann; Peter Stockmann
Original assignee: Brose Fahrzeugteile SE and Co KG
Current assignee: Brose Fahrzeugteile SE and Co KG
Priority date: 2012-05-26
Filing date: 2013-05-24
Publication date: 2015-04-08
Also published as: CN104335463B; WO2013178239A3; CN104350668A; WO2013178342A3; US9742247B2; BR112014029541A2; EP2856619A2; US20150076946A1; WO2013178342A2; CN104350668B; EP2856619B1; US9774231B2; BR112014029146A2; WO2013178239A2; CN104335463A; DE102012010483A1; US20150084479A1

Abstract

The invention relates to a brush system (8) for an electric motor (16), comprising a substantially semi-annular resistor housing (12) into which an electric flat resistor (38) is introduced, two resistor terminals (36) which protrude from the resistor housing (12) and can be coupled in an electrically conducting manner to a conductor path (32) of the electric motor (16), and a substantially semi-circular support plate (10) that includes two bus bars (34) to electroconductively couple the conductor path (32) to the terminals (36) and to two brush elements (22). The two terminals (36) are arranged on the same narrow side of the resistor housing (12).

Description

description

Brush system for an electric motor

The invention relates to a brush system for an electric motor, comprising a substantially semi-annular resistor housing with a flat electrical resistance introduced therein, with two resistor terminals protruding from the resistor housing, which are electrically conductively coupled to a conductor path of the electric motor, and with a substantially semicircular support plate with two Conductor rails for electrically conductive coupling of the conductor path to the terminals and with two brush elements connected to suppressor elements as sliding contacts for a commutator of the electric motor. The invention further relates to an electric motor with such a brush system.

Such an electric motor, in particular a so-called commutator motor, comprises a stator and a rotor arranged on a motor shaft, which is moved within the stator by an alternating magnetic field. The rotor carries a field or field winding and the motor shaft has rotorfestfest Kommutatorlamellen, which are coated by sliding contact in the form of brushes of a brush system. The brush system and the commutator bars interact during the rotation of the motor axis such that a polarity reversal (commutation) of the operating or motor current is achieved. This polarity reversal is necessary for the rotational movement of a DC electric motor. The brushes, which are usually designed as carbon brushes, are pressed by means of spring elements with spring force against the commutator concentric with the motor shaft. During operation of the electric motor, the direct current flows through the brushes and the commutator blades of the commutator into the field windings of the rotor.

In such an electric motor, a stepped speed control conventionally takes place by means of a resistance circuit. During operation, this resistance circuit heats up due to the DC current flowing through it. The resulting heat generation can lead to an over-

CONFIRMATION COPY heat of the electric motor, which can negatively affect its life.

WO 2005/078907 A1 discloses a brush system for an electromotive drive, in which brush system elements with brush elements and interference suppression elements are fastened on a carrier plate. On the support plate busbars are provided as conductor tracks for an electrical connection. The brush system has a flat resistor arranged in a semicircular resistor housing, wherein the resistor housing is made of a thermally conductive material and provided with air passage openings. Due to the integration of the resistor into the brush system and due to the design of the resistor housing with air passage openings, a suitable air-cooled brush system is provided for discharging or dissipating the heat generated during operation.

In the known brush system, in each case one connecting tab of the flat resistor is provided on a half-ring narrow side of the resistance housing, whereby an effective and space-saving cable routing of the conductor tracks and the positioning of the brush system elements on the base body are made disadvantageously difficult. This disadvantageously increases the manufacturing and assembly costs of such a brush system.

The invention is therefore based on the object of specifying a brush system of the type mentioned, which allows easy and inexpensive improved cable management and improved positioning of the brush system elements. Furthermore, an electric motor should be specified with such a brush system.

This object is achieved by the features of claim 1. Advantageous embodiments and further developments are the subject of the dependent claims. For this purpose, it is provided that both resistor terminals of the flat resistor are positioned at one, ie at the same narrow side of the resistor housing. This makes it advantageous and easy to arrange the busbars on one side of the support plate, whereby a higher flexibility in the positioning of the brush and interference suppression is possible, and a comparatively large, in particular maximum, potential separation between the associated poles is achieved.

In an advantageous development, on the one hand the brush and suppression elements on the underside of the carrier plate and on the other hand the busbars are arranged on the upper side of the carrier plate. This ensures a particularly simple cable routing with simultaneously improved positioning of the brush system elements. Furthermore, this provides a simple and cost effective protection to avoid electrolytic reactions in terms of corrosion prevention realized and optimized the electromagnetic compatibility (EMC) in terms of radiation and radiation

In an advantageous further development form, the busbars of the two flat conductor connections of the resistor are expediently guided, for example, on the opposite motor side (upper side) to the supply connections (positive and negative poles) of the electric motor. The laying of the terminals of the flat resistor on the brush and suppressor opposite carrier plate side (bottom) allows avoiding corrosion due to chemical, such as electrolytic processes. For example, it is also conceivable to exchange the arrangement on the top and bottom.

The terminals of the flat conductor resistor are spaced from each other on the narrow side of the resistor housing and thus electrically isolated from each other. For this purpose, the terminals can also be electrically isolated from each other. Preferably, the terminals in particular about three millimeters apart from each other spatially (galvanically), whereby the risk of Short circuit between the terminals is advantageously and inexpensively reduced.

In an advantageous embodiment, the flat resistor has a meandering, substantially U-shaped course between the two terminals and extends substantially over the entire length of the resistor housing. In contrast to the prior art, in which the flat resistor extends essentially in an I-shaped manner from the first half-ring narrow side to the second, the flat resistor runs in two rows with an arc between the first and the second housing narrow side. As a result, the flat resistance path is approximately doubled, as a result of which the flat resistance can be made substantially flatter, for example, with the same resistance value. Thus, the thickness of the resistor housing is also advantageously reduced and the brush system can be carried out particularly space-saving.

Due to the meander-like and U-shaped configuration of the flat resistance curve, a particularly uniform heat convection is realized to the resistor housing, so that the heat generation is particularly effective, for example, in connection with air passage openings of the resistor housing, can be dissipated by the electric motor. This allows a particularly simple and cost-effective improvement of the engine cooling, which advantageously and simply increases the service life of the electric motor.

In a suitable embodiment, the resistor housing comprises two mutually arranged half-ring-shaped housing parts, in the space between the flat resistor is introduced. In a preferred embodiment, the resistor housing is sandwiched, wherein the semi-annular housing parts are preferably made of metal, and wherein the meandering laid flat resistor is electrically isolated from said metal half-rings.

In particular, this is in a suitable embodiment in the mounted state of the resistor housing between each semi-annular housing part and the flat conductor arranged an electrically non-conductive insulating layer. Preferably, the insulating layers are made of mica and thus on the one hand resistant to the high operating temperature of the flat resistor and on the other hand due to the high dielectric constant of mica particularly flat executable. As a result, an advantageous space-saving design of the resistor housing while avoiding an electrical short circuit is possible.

In an advantageous embodiment, the semi-annular housing parts are cup-shaped and have at least on their outer periphery, but suitably also on the inner circumference, tabs for assembling the resistor housing. The tabs are expediently bent inwardly or crimped in the assembled state. This advantageously allows a particularly simple and cost-effective production of the resistor housing.

In a suitable development, the semi-annular housing parts are made of a metal and thermally conductive coupled to a motor housing, for example to a pole pot, the electric motor. In an advantageous embodiment, the contact between the outer circumference of the brush system, ie the semi-annular housing parts and the motor housing, in "metal-on-metal" executed, which due to heat convection, the heat generation via the motor housing can be dissipated.Thus, the cooling of the electric motor improves, on the one hand increases the life and on the other hand a service life extension is achieved.

In a further advantageous embodiment, the resistance housing has a number of locking tabs for non-destructive clip attachment to the electric motor on the one hand and on the carrier plate on the other. As a result, the resistance housing is particularly easy to assemble or disassemble, whereby, for example, a maintenance or repair of the electric motor is advantageously simplified. With regard to an electric motor, the above object is achieved by the features of claim 10. Thereafter, the electric motor comprises a motor housing, which accommodates a stator and a rotor and a commutator ground by a current-carrying brush system according to the invention. In the preferred use of the brush system, for example, in an actuator or a radiator frame in a motor vehicle, the electric motor is therefore particularly suitable in view of a reliable and durable operation.

Embodiments of the invention will be explained in more detail with reference to a drawing. Show:

Fig. 1 in perspective an electric motor with a partially exposed

Motor housing and with a power connection and with a brush system,

2 perspectively the power connection and the brush system coupled thereto, comprising a carrier plate and a resistor housing,

3 the underside of the brush system in plan view,

4 perspective view of the resistor housing,

Fig. 5, the resistance housing in plan view, and

Fig. 6 is a sectional view of the resistor housing along the line

IV-IV according to FIG. 5.

Corresponding parts are provided in all figures with the same reference numerals.

1 shows an electromotive drive 2 with a motor housing 4 consisting of metal and with an electrical cable 6 for connection to a conductor path and with a brush system 8. The brush system 8 is substantially circular and becomes electrically conductive on the one hand by a semi-annular support plate 10 non-conductive material, in particular plastic, and on the other hand formed by a likewise semi-annular metallic resistance housing 12. The brush system 8 has a central recess 14 in which in the assembled state, an electric motor 16 is arranged. The brush system 8 is coupled in the assembled state with the motor housing 4. The cable 6 has a plug-in connection 18 to the drive 2 on the motor side and a plug-in connection 20 on the conductor path side.

In Figs. 2 and 3, the brush system 8 is shown in more detail. On the underside (FIG. 3) of the carrier plate 0 produced as an injection-molded part, two carbon brushes 22 are arranged as sliding contacts on the circumference of a rotor of the electric motor 16 (not shown). As shown on only one of the carbon brushes 22, these are together with a spring element in a brush holder 26. By the spring element, the respective carbon brush 22 is pressed under appropriate spring bias against a commutator 28, so that the respective carbon brush 22 at the commutator 28 and at its Contacting commutator blades contacting.

The carbon brushes 22 are each connected by means of a suppression choke (choke coil) 30 in a direction indicated by plus sign (+) and minus sign (-) current path 32. The current path 32 is connected via the commutator 28 and the rotor via the cable 6 to a vehicle battery of a vehicle or to its electrical system. The current path 32 is formed on the Bürstensystemoberseite the support plate 10 substantially by two parallel busbars 34 which are connected to terminal plates or the like designed as terminals 36 of a flat resistor 38 of the resistor housing 12 or directly on the flat resistor 38 are fixed. The flat resistor 38 is used for a stepped speed control of the electromotive drive 2.

The resistor housing 12 shown in FIGS. 4 to 6 receives the substantially U-shaped and meander-like flat resistor 38 shown in dashed lines in FIG. The terminal lugs or resistor terminals 36 of the plus and minus potential are galvanically isolated and spaced spatially arranged for this purpose. As shown in Fig. 6, the resistance case 12 is substantially sandwiched. An upper half-ring-shaped housing part 40a, a first mica layer 42a, the resistance meander 38, a second mica layer 42b and a lower semi-annular housing part 40b are crimped together by means of bending tabs 44 of the upper semi-annular housing part 40a. Through the mica layers 42a and 42b, the resistor 38 is on the one hand galvanically separated from the metallic housing parts 40a and 40b and on the other hand thermally conductive coupled thereto.

The carrier plate 10 and the resistor housing 12 of the brush system 6 are arranged in one plane. The support plate 10 is coupled on the one hand by means of the busbars 34 and the terminal lugs 36 on a narrow side of the housing of the resistor housing 12 and on the other hand by means of a latching connection 46 connected to the semi-annular housing part 40b. The resistor housing 12 has a number of circumferential latching tongues 48a for snapping or latching on corresponding recesses of the motor housing 4 and on the inner circumference two latching tongues 48b for connection to the electric motor 16. On the outer circumference a number of support tongues 50 for support / support on motor housing 4 is additionally arranged. Corresponding support structures are also arranged on the support plate 10, but not provided with reference numerals for better clarity.

In order to ensure a high rate of dissipation of the heat generated during operation at the flat resistance (resistance meander) 38, the resistance housing 12 has a number of ventilation holes 52 for aeration or air cooling of the housing 12. In the figures, only one vent hole 52 is designated in each case by way of example. The semi-annular housing parts 40a and 40b are designed as stamping plates, preferably made of aluminum, wherein the ventilation holes 52 are formed by punched holes. Depending on the field of application, the number or dimensions of the ventilation holes 52 can be adapted, so that a sufficiently high ventilation of the drive 2 can always be achieved. To further improve the heat dissipation, the resistor housing 12 is thermally coupled to the motor housing 4, so that the Heat in the interior of the resistor housing 12 through the motor housing 4 to the outside can be discharged.

The brush system 8 for an electric motor 16 thus comprises according to the invention a substantially semi-annular resistor housing 12 with electrical flat resistor 38 inserted therein, two resistor terminals 36 protruding from the resistor housing 12 and arranged on the same housing narrow side of the resistor housing 12, and a substantially semicircular carrier plate 10 with two bus bars 34 for electrically conductive coupling of the conductor path 32 with the terminals 36 and with the brush elements 22nd

The invention is not limited to the embodiments described above. On the contrary, other variants of the invention can be derived therefrom by the person skilled in the art without departing from the subject matter of the invention. In particular, furthermore, all individual features described in connection with the various exemplary embodiments can also be combined with one another in other ways, without departing from the subject matter of the invention.

LIST OF REFERENCE NUMBERS

2 drive

4 motor housing

6 cables

8 brush system

10 carrier plate

12 resistor housing

14 recess

16 electric motor

18 plug connection

20 plug connection

22 carbon brush

26 brush quiver

28 commutator,

30 suppression choke

32 current path

34 busbar

36 connecting lug

38 flat resistor

40a, 40b housing part

42a, 42b mica layer

44 folding bag

46 locking connection

48a, 48b snap tongues

50 support tongues

52 ventilation hole

Claims

claims

1. brush system (8) for an electric motor (16),

- With a substantially semi-annular resistor housing (12) having a flat electrical resistance (38) incorporated therein,

- With two of the resistor housing (12) protruding resistor terminals (36) which are electrically conductively coupled to a conductor path (32) of the electric motor (16), and

- having a substantially semicircular support plate (10) with two busbars (34) for electrically conductive coupling of the conductor path (32) with the resistor terminals (36) and with two with Entstörelementen (30) connected brush elements (22) as sliding contacts for a commutator ( 28) of the electric motor (16),

characterized,

the resistor terminals (36) are positioned on the same narrow side of the housing of the resistor housing (12).

2. brush system (8) according to claim 1,

characterized,

on the one hand, the brush elements (22) and the Entstörelmente (30) on the underside of the carrier plate (10) and on the other hand the busbars (34) and the resistor terminals (36) on the upper side of the carrier plate (10) are arranged.

3. brush system (8) according to claim 1 or 2,

characterized,

the flat resistor (38) extends substantially the entire length of the resistor housing (12).

4. brush system (8) according to one of claims 1 to 3,

characterized,

the flat resistor (38) has a meander-like profile between the two resistance terminals (36).

5. brush system (8) according to one of claims 1 to 4,

characterized,

in that the resistance housing (12) comprises two half-ring-shaped housing parts (40a, 40b) arranged on top of each other, in the intermediate space of which the flat resistor (38) is arranged.

6. brush system (8) according to one of claims 1 to 5,

characterized,

that in the assembled state in each case an electrically non-conductive insulating layer (42a, 42b) between the resistor housing (12), in particular its halbbringförmigem housing part (40a, 40b), and the flat conductor (38) is arranged.

7. brush system (8) according to claim 5 or 6,

characterized,

the half-ring-shaped housing parts (40a, 40b) are cup-shaped and have circumferentially arranged tabs (44) which are bent inwardly or crimped in the assembled state.

8. Electric motor (16) with a motor housing (4) and with a brush system (8) according to one of claims 1 to 7.

9. Electric motor (16) according to claim 8,

characterized,

the half-ring-shaped housing parts (40a, 40b) are made of a metal and are thermally coupled to a motor housing (4).

10. Electric motor (16) according to claim 8 or 9, characterized,

in that the resistance housing (12) has a number of latching lugs (48a, 48b, 50) for nondestructive fastening to the motor housing (4) and / or to the carrier plate (10).