ELECTRIC MACHINE HAVING AN ELECTRIC SLIDING CONTACT

Abstract

Electric machine (10), in particular for adjusting movable parts in a motor vehicle, having a stator housing (22) which accommodates a stator (12) and a rotor (14), wherein the rotor (14) has a rotor shaft (16), and the stator housing (22) has an axial opening (24) through which the rotor shaft (16) projects out of the stator housing (22), wherein an electrically conductive shielding plate (29) is arranged transverse to the rotor shaft (16) and substantially covers the entire opening (24), and an electrically conductive sliding contact (77), which is electrically conductively connected to the shielding plate (29), is formed on the rotor shaft (16).

Description

Claims

1. An electric machine (10) having a stator housing (22), which accommodates a stator (12) and a rotor (14), wherein the rotor (14) comprises a rotor shaft (16), and the stator housing (22) comprises an axial opening (24), through which the rotor shaft (16) projects out of the stator housing (22), wherein an electrically conductive shielding plate (29) is arranged transversely to the rotor shaft (16) and substantially covers the entire opening (24), and an electrically conductive sliding contact (77) is formed on the rotor shaft (16) and is electrically conductively connected to the shielding plate (29).

2. The electric machine (10) according to claim 1, wherein on the periphery of the opening (24), a flange (28) is formed, which radially overlaps the shielding plate (29), and the shielding plate (29) conductively abuts, on its outer perimeter (31), axially on the flange (28) of the stator housing (22) in order to form a ground contact, wherein axially opposite the stator housing (22), a transmission housing (60) is arranged with a mating flange (61), which axially clamps the shielding plate (29) to the stator housing (22).

3. The electric machine (10) according to claim 1, wherein the sliding contact (77) is formed by an electrically conductive nonwoven material (76) or fabric that radially abuts on the rotor shaft (16).

4. The electric machine (10) according to claim 1, wherein the sliding contact (77) is formed by an electrically conductive metal braiding (75), which radially abuts on the rotor shaft (16) on the periphery thereof.

5. The electric machine (10) according to claim 1, wherein the sliding contact (77) is formed by at least one electrically conductive sheet metal tongue (81), which radially abuts on a periphery of the rotor shaft (16).

6. The electric machine (10) according to claim 1, wherein the sliding contact (77) is formed by an electrically conductive wire spring (78), which radially abuts on a periphery of the rotor shaft (16).

7. The electric machine (10) according to claim 6, wherein the wire spring (78) is formed as a polygonal chain (73) or as a corrugated ring (74), which extends substantially over the entire periphery of the rotor shaft (16).

8. The electric machine (10) according to claim 1, wherein a bearing shield (56) made of plastic is arranged axially spaced apart from the shielding plate (29) and mounts a central bearing receptacle (57) for a bearing component (58), which is formed as a cylinder bearing or spherical bearing.

9. The electric machine (10) according to claim 8, wherein axially between the bearing component (58) and the shielding plate (29), a separately manufactured, electrically conductive adapter element (82) is arranged and is electrically conductively connected to the shielding plate (29), and the adapter element (82) electromagnetically shields a central aperture (32) in the shielding plate (29).

10. The electric machine (10) according to claim 9, wherein the sliding contact (77) is arranged directly on the bearing component (58) or directly on the adapter element (82) or directly on the shielding plate (29).

11. The electric machine (10) according to claim 9, wherein the adapter element (82) comprises a cuboid cavity that conductively abuts with an axially open end face (106) on the shielding plate (29), and the entire adapter element (82) is formed from an electrically conductive nonwoven material (76) or fabric, or the adapter element (82) is lined on its inner side with the electrically conductive nonwoven material (76) or fabric.

12. The electric machine (10) according to claim 9, wherein the adapter element (82) is clamped to the bearing shield (56), and the adapter element (82) is electrically conductively connected to the bearing component (58).

13. The electric machine (10) according to claim 8, wherein a brush holder plate (55) comprising electric brushes (20) is connected to the bearing shield (56), wherein clip or clamping elements (98) project axially through the central aperture (32) of the shielding plate (29) and press the adapter element (82) radially against holding elements (108) of the bearing shield (56).

14. The electric machine (10) according to claim 13, wherein the shielding plate (29) is formed as part of an electronic circuit board (PCB) (30), which is populated with at least one anti-interference element (44) and/or electric contact elements (50) for the brushes (20), wherein the electronic circuit board (30) comprises four conductor layers (35, 36), of which two axially inner conductor layers (36) are formed over their entire surface of conductive material.

15. The electric machine (10) according to claim 2, wherein on a top side (42), facing away from the flange (28), of the shielding plate (29), over a periphery of a central aperture (32) in the shielding plate (29), the shielding plate (29) comprises an axial ground contact region (80), on which an adapter element (82) electrically conductively abuts with axial spring elements (87).

16. The electric machine (10) according to claim 3, wherein the sliding contact (77) is formed by an electrically conductive nonwoven material (76) or fabric that radially abuts an entire periphery of the rotor shaft (16).

17. The electric machine (10) according to claim 8, wherein the bearing shield (56) is in the transmission housing (60).

18. The electric machine (10) according to claim 14, wherein the conductor layers (35, 36) are electrically connected to one another by several axial vias (38).

19. The electric machine (10) according to claim 4, wherein the electrically conductive metal braiding (75) is a strand.