The aim of the invention is to ensure a reliable lift of both brake pads of a floating-caliper brake (1) after releasing the brake. This is achieved in that a lifting part (20) is hinged to the brake caliper (2) at a hinge point (21), and the lifting part (20) is supported on the support structure (7) at a contact point (23) at least partly at releasing the floating-caliper brake (1), wherein a lift drive (22) is provided which rotates the lifting part (20) about the hinge point (21) such that a support for the lifting part (20) is produced on the contact point (23), whereby the hinge point (21) and the brake caliper (2) are moved.

A disc brake apparatus has a support member, slide members each having a guide pin and an anchor pin which are situated on an inner side and outer side of the support member, respectively, and a caliper which is held so that tangential force of an outer pad is transmitted to a claw portion and which is supported on the slide members. The caliper includes outer transmission surfaces which transmit braking torque generated in the outer pad to the anchor pins and inner transmission surfaces which transmit the braking force to the guide pins.

A disc brake and components thereof, in which a caliper or a carrier supporting such caliper and a connecting element being arranged on a wheel axle are in attachment with each other by inclined abutment surfaces.

A brake assembly for an electric motor includes: a magnetic body, a winding, a bolt, a housing part with a brake surface, an armature disk, a brake pad plate, a shaft, a spring part, and a first bushing. The housing part is connected to the magnetic body by the bolt, with a positive fit in at least the circumferential direction. The first bushing is accommodated in a second bushing. The spring part supported on the housing part presses the first bushing and/or the second bushing toward the magnetic body. The radial clearance range covered by the armature disk includes the radial clearance range covered by the second bushing, and the axial region covered by the armature disk includes the axial region covered by the second bushing.

A system is provided for suppressing undesired brake pad motion during brake application, and for installing and removing brake pads utilizing the inventive arrangements. The brake pads and a carrier mount having complementary surface features that retain the brake pad when the brake pad is in its installed position, and a brake pad biasing structure that biases the brake pad in the radially outward direction to bias the contact faces of the mount horn and the brake pad against one another to suppress brake pad kick and vibration and related wear and component fatigue. The radially-outward biasing force may be applied by a spring-loaded plunger located within a bore of a mount horn of the brake pad carrier against a radially-inner surface of a portion of the brake pad extending laterally over the mount horn.

A braking device for an in-wheel motor may include: a stator; a rotor configured to rotate when power is applied to the stator; a disk interlocked with the rotor; a bracket coupled to the stator and a knuckle; and a caliper mounted on the bracket, and configured to press the disk.

A disc brake rotor comprises a hub engagement member, an outer member, and a coupling arm. The hub engagement member is configured to engage with a hub assembly. The outer member is provided radially outwardly of the hub engagement member with respect to a rotational axis of the disc brake rotor. The coupling arm extends radially outwardly from the hub engagement member to the outer member. The coupling arm includes a first axial surface provided on a first axial side in an axial direction with respect to the rotational axis and a second axial surface provided on a second axial side reverse to the first axial side in the axial direction. At least one of the first axial surface and the second axial surface is non-parallel to a reference plane perpendicular to the rotational axis as viewed in a radial direction with respect to the rotational axis.

A disk brake includes a brake disk, a brake caliper, which fits over the brake disk, a brake support, a brake pad and an application device, which presses the brake pad against the brake disk when braking, wherein the brake pad rests in a U-shaped well and the two legs of the “U” serve to support the brake pad in the circumferential direction of the brake disk and the “base” of the “U” serves to support the brake pad radially toward the inside. The distance between the two legs of the “U” is shorter at the radially outer ends thereof than the distance at the radially inner ends thereof.

A pneumatically or electromechanically actuated disk brake includes a brake disk having a preferred direction of rotation in forward travel, a brake carrier extending around the brake disk, a brake caliper extending around the brake disk, a fastening-side brake pad with a friction material, an application device having a pressure-exerting device on one side of the brake disk, and a rim-side brake pad with friction material. A fastening-side line of gravity, in the rest state of the brake, is arranged with a predetermined first offset with respect to a central axis in the direction of the entry side of the brake disk in the preferred direction of rotation. A rim-side line of gravity is arranged either with a predetermined second offset with respect to the central axis, the second offset being unequal to the first offset, or with a third offset with respect to the central axis.

A wheel suspension (1) for a wheel (23) of a vehicle, in particular the rear wheel of a utility vehicle, driven by an electric or pneumatic motor (2), having a swing arm (3) which is mounted pivotably around a pivot axis (7) on the vehicle in a first region (4) and is supported on the vehicle in a second region (8), wherein a third region (10) of the swing arm (3) carries a part of the motor (2) which is rotationally fixed in relation to the swing arm (3) in order to transmit a torque to the wheel using a rotating part of the motor (2).