DRIVE INCLUDING AN ELECTRIC MOTOR WITH A BRAKE ASSEMBLY

Abstract

A drive includes an electric motor with a brake assembly. The electric motor has a rotor rotatably mounted via a first bearing and a second bearing and has a housing part. The first bearing has an inner ring and an outer ring, and the inner ring is received on the rotor, e.g., placed thereover, e.g., is positioned against a step or pressed against a catch that is positioned against a step formed on the rotor. The brake assembly has a magnetic body, e.g., made of a ferromagnetic material. The outer ring is received in the magnetic body of the brake assembly, e.g., is positioned against a step.

Description

Claims

1-15. (canceled)

16. A drive, comprising: an electric motor including a rotor, rotatably mounted via a first bearing and a second bearing, and a housing part, the first bearing including an inner ring and an outer ring, the inner ring being arranged on the rotor; anda brake assembly including a magnetic body, the outer ring being arranged in the magnetic body.

17. The drive according to claim 16, wherein the inner ring is arranged against a step and/or pressed against a catch arranged against a step on the rotor, the magnetic body is formed of a ferromagnetic material, and the outer ring is arranged against a step.

18. The drive according to claim 16, wherein the second bearing and/or an outer ring of the second bearing is arranged in the housing part or in a flange part connected to the housing part and/or is arranged against a step, and an inner ring of the second bearing is arranged on the rotor and/or is arranged against a step.

19. The drive according to claim 16, wherein the magnetic body is arranged in a receiving part connected securely to the housing part or is arranged in the housing part, the magnetic body is arranged displaceable axially and is connected to a first torque support part, the first torque support part is connected to the receiving part and/or to the housing part.

20. The drive according to claim 19, wherein the magnetic body is arranged displaceable axially parallel to a direction of a rotational axis of the rotor, the magnetic body is connected to the first torque support part by second screws and/or by second screws spaced apart from one another regularly in a circumferential direction, and the first torque part is connected to the receiving part and/or to the housing part by first screws and/or first screws spaced apart from one another regularly in the circumferential direction.

21. The drive according to claim 19, wherein (a) the first torque support part is arranged as a bellows and/or a metal bellows, a region of the first torque support part contacting the receiving part is spaced apart axially from a region contacting the magnetic body and/or a region that is arranged at a smaller radial distance than the region contacting the receiving part, and/or (b) the first torque support part is arranged as a sheet part and/or a sheet metal part such that a region of the first torque support part contacting the receiving part is arranged at a same axial position as a region of the torque support part contacted by the magnetic body and/or that is arranged at a smaller radial distance than the region contacting the receiving part.

22. The drive according to claim 16, wherein an armature disk, with a catch, is arranged rotationally-fixed and axially displaceable.

23. The drive according to claim 22, wherein a spring element arranged between the catch and the armature disk and/or a spring plate connected to the catch by first connecting elements and/or rivets and connected to the armature disk by second connecting elements and/or rivets is adapted to generate a spring force oriented towards the catch and acting on the armature disk.

23. The drive according to claim 16, wherein (a) a coil is arranged in the magnetic body and/or arranged in a radial direction between an inner ring of the magnetic body and an outer ring of the magnetic body, and/or (b) a permanent magnet is arranged between the inner ring of the magnetic body and the outer ring of the magnetic body and/or is arranged in an axial direction between the inner ring of the magnetic body and the outer ring of the magnetic body.

24. The drive according to claim 16, wherein the outer ring of the first bearing is positioned against a step arranged on the magnetic body and/or on an inner ring of the magnetic body, and the inner ring of the first bearing is arranged against a step formed on a shaft.

25. The drive according to claim 23, wherein when the coil is energized, magnetic flux penetrating an armature disk is reduced and/or reduced in comparison to when the coil is not energized.

26. The drive according to claim 19, wherein an outer ring of the magnetic body is arranged displaceable axially in the receiving part.

27. The drive according to claim 16, wherein a rotor shaft of an angle sensor is connected rotationally-fixed to the rotor, and a housing of the angle sensor is connected to a first region of a torque support part, a second region of the torque support part being connected to an inner ring of the magnetic body.

28. The drive according to claim 27, wherein the second region is arranged at a greater radial distance than the first region and/or the second region is arranged radially further outward than the first region.

29. The drive according to claim 16, wherein a radial distance region covered by a first torque support part is spaced apart from a radial distance region covered by a second torque support part.

30. The drive according to claim 19, wherein the first torque support part includes an inner ring region, an outer ring region, and crosspieces that connect the inner ring region to the outer ring region and that are spaced apart from one another regularly in a circumferential direction, the inner ring region is arranged against an inner ring of the magnetic body and the outer ring region is arranged against the receiving part or the housing part, and a greatest circumferential angle value of a circumferential angle region covered by a specific crosspiece at a radial distance increases or decreases monotonically as radial distance increases, and a smallest circumferential angle value of the circumferential angle region increases or decreases monotonically as radial distance increases.

31. The drive according to claim 21, wherein the bellows is supported on the receiving part presses an inner ring of the magnetic body and/or a step arranged on the inner ring of the magnetic body toward the outer ring of the first bearing such that the inner ring of the first bearing presses a catch against a step formed on the rotor, and/or a spring element supported on the receiving part, the housing part, or a ring securely connected to the receiving part or the housing part presses an inner ring of the magnetic body and/or a step formed on the inner ring of the magnetic body toward the outer ring of the first bearing such that the inner ring of the first bearing presses the catch against the step formed on the rotor.

32. The drive according to claim 18, wherein an outer ring of the second bearing is arranged in an insulating part and/or an insulating part formed of fiberglass-reinforced plastic that is arranged in the housing part, and the flange part is arranged on a side of the insulating part facing away from the first bearing.

33. The drive according to claim 32, wherein the outer ring of the second bearing is arranged in the insulating part when the flange part and a gearbox have not yet been connected to the housing part, and the insulating part is arranged in a circumferential groove of the housing part.

34. The drive according to claim 33, wherein a first subregion of a region covered axially by an outer ring of the second bearing in an axial direction contacts the flange part and a second subregion of the region covered axially by the outer ring of the second bearing contacts the insulating part, the first subregion being spaced apart from or being adjacent to the second subregion.

35. The drive according to claim 34, wherein the first subregion does not overlap with the second subregion.