A method for controlling an electromagnetic brake (1) having a coil carrier (2), a solenoid (5), an armature disc (7), and at least one further force-exerting element. The internal and external poles (3, 4) of the coil carrier each have a front surface with a varying gradient that fits, in a complementary fashion, the front surfaces of the respective internal and external poles (8, 9) of the armature disc. The brake has an air gap (11) which varies in size and forms a stroke region (21). When excitation occurs, the solenoid generates a magnetic force, and the force-exerting element generates an opposing force, wherein the ratio of the solenoid's magnetic force and the opposing force varies at least once between greater than and smaller than one during the movement of the armature disc in the stroke region owing to the variation of the excitation of the solenoid.

A self-energizing brake caliper comprises a caliper bracket fixed to a vehicle frame, a first caliper arm rotatably connected to the caliper bracket, a second caliper arm rotatably connected to the caliper bracket, an inboard brake pad, and an outboard brake pad. The first caliper arm is rotatably connected to the outboard brake pad at a first position and is configured to press against the outboard brake pad at the first position by receiving the power of an actuator at the second position which is inboard side. The second caliper arm is rotatably connected to the inboard brake pad at a third position and is configured to press against the inboard brake pad at the third position by receiving the power of an actuator at the fourth position which is inboard side.

A self-energizing brake caliper comprises a caliper bracket fixed to a vehicle frame, a first caliper arm rotatably connected to the caliper bracket, a second caliper arm rotatably connected to the caliper bracket, an inboard brake pad, and an outboard brake pad. The first caliper arm is rotatably connected to the outboard brake pad at a first position and is configured to press against the outboard brake pad at the first position by receiving the power of an actuator at the second position which is inboard side. The second caliper arm is rotatably connected to the inboard brake pad at a third position and is configured to press against the inboard brake pad at the third position by receiving the power of an actuator at the fourth position which is inboard side.

The description relates to devices that include hinged portions and controlling rotation of the hinged portions with smart clutch control. One example can include powering a motor to cause clutch portions to engage in a first instance. The example can also include monitoring an operational parameter during the powering. The method can further include, based at least in part upon the monitoring, adjusting power to cause the clutch portions to engage in a second instance with a force that is different than the first instance.

The description relates to devices that include hinged portions and controlling rotation of the hinged portions with smart clutch control. One example can include powering a motor to cause clutch portions to engage in a first instance. The example can also include monitoring an operational parameter during the powering. The method can further include, based at least in part upon the monitoring, adjusting power to cause the clutch portions to engage in a second instance with a force that is different than the first instance.

The invention relates to a disc brake, comprising a brake carrier, a brake caliper, brake shoes, and an actuating piston. The brake carrier has at least one mounting point for mounting on a vehicle. The actuating piston is displaceably accommodated on the brake caliper and is actuatable for carrying out a service brake function of the disc brake. At least one further actuating piston is provided, which in the direction of its longitudinal axis is displaceably accommodated on the brake caliper. For carrying out the service brake function, the at least two actuating pistons are actuatable, and for carrying out a parking brake function, one of the actuating pistons is actuatable. The invention further relates to a disc brake system and a parking brake system.

A method for controlling an electromagnetic brake (1) having a coil carrier (2), a solenoid (5), an armature disc (7), and at least one further force-exerting element. The internal and external poles (3, 4) of the coil carrier each have a front surface with a varying gradient that fits, in a complementary fashion, the front surfaces of the respective internal and external poles (8, 9) of the armature disc. The brake has an air gap (11) which varies in size and forms a stroke region (21). When excitation occurs, the solenoid generates a magnetic force, and the force-exerting element generates an opposing force, wherein the ratio of the solenoid's magnetic force and the opposing force varies at least once between greater than and smaller than one during the movement of the armature disc in the stroke region owing to the variation of the excitation of the solenoid.

An integrated torque limiter/no-back device for use in an actuator with an input shaft, an output, and a gear reduction. The device includes an input ramp, an output ramp coupled to the gear reduction, a combined ramp disposed between the input ramp and the output ramp, a first plurality of balls arranged between the input ramp and the combined ramp, a second plurality of balls arranged between the combined ramp and the output ramp, a pin, and a brake. The pin extends from the input ramp to the combined ramp and coupled to the input shaft. The combined ramp, the output ramp, and the second plurality of balls therebetween are configured to operate as a torque limiter by causing the combined ramp and the output ramp to separate and the output ramp to engage the brake when the torque from the input shaft exceeds a torque threshold.

An integrated torque limiter/no-back device for use in an actuator with an input shaft, an output, and a gear reduction. The device includes an input ramp, an output ramp coupled to the gear reduction, a combined ramp disposed between the input ramp and the output ramp, a first plurality of balls arranged between the input ramp and the combined ramp, a second plurality of balls arranged between the combined ramp and the output ramp, a pin, and a brake. The pin extends from the input ramp to the combined ramp and coupled to the input shaft. The combined ramp, the output ramp, and the second plurality of balls therebetween are configured to operate as a torque limiter by causing the combined ramp and the output ramp to separate and the output ramp to engage the brake when the torque from the input shaft exceeds a torque threshold.

A disk brake piston system having a piston having a metallic outer wall surrounding a central axis, the outer wall being of a material and a thickness which that could be formed by deep drawing; a metallic front wall closing one end of the outer wall, the front wall including a curved area extending toward an interior of the piston, the front wall being of a material and having a thickness that could be formed by deep drawing; and a sleeve positioned at least partially within the piston and configured to interface with an interior side surface of the outer wall such that the sleeve and the piston are restrained from rotating relative to one another around an axis parallel to the central axis, the sleeve comprising a flat or curved internal surface, having a non-circular cross-section, wherein the sleeve comprises a polymeric material.