An emergency park brake system of an aircraft may include an electrical power interface, an electromechanical actuator, and a hydraulic brake valve. The electrical power interface may be configured to receive electrical power from a power source. The electromechanical actuator may be in selective power receiving communication with the electrical power interface and the electromechanical actuator may be mechanically coupled to and configured to selectively actuate the hydraulic brake valve. The electrical connection between the electromechanical actuator and the electrical power interface may be based on an emergency braking input.

A friction brake system comprises a first gear unit having a first member and a second member, the first gear unit is configured for converting a rotary motion of the first member into a braking motion of the second member, the first member is configured such that the rotary motion may be driven by an electric motor, the brake system further comprises a second gear unit having a spindle and nut for converting a rotary motion into a linear motion for pad wear compensation, the spindle is connectable to a brake pad, the second member of the first gear unit and the nut of the second gear unit are or may be mechanically coupled such that, during the braking motion, the second member of the first gear unit pushes against the nut of the second gear unit to press the brake pad against a friction surface.

An actuator assembly for a vehicle brake, in particular an electromechanical vehicle brake, is specified, having a brake caliper in which there is an intermediate space—for accommodating a brake rotor, a drive housing, in which a drive assembly of the actuator assembly is accommodated, wherein the drive housing is fixedly connected to the brake caliper, a linearly guided actuating slide for a brake pad, which can be moved optionally between a retracted position and an extended position via the drive assembly, and a frame part having an accommodation space, in which a transmission unit of the drive assembly is at least partially accommodated, wherein an electric motor is secured on the frame part, which electric motor is coupled in terms of drive to the actuating slide via the transmission unit and a spindle drive, and the frame part is secured on the drive housing.

A brake control unit (50) is provided comprising a primary control branch (510), a backup control branch (520), and mode control utilities (530), wherein the mode control utilities (530) are configured to select in accordance with integrity diagnostic indications an operational mode of the brake control unit from a plurality of potential operational modes comprising at least a normal operational mode and a degraded operational mode, wherein respectively the primary control branch (510) and the backup control branch (520) are configured to generate a brake motor drive signal (D.sub.10, D.sub.20) with their respective inverter being controlled by their respective control module in response to an external brake control signal (I.sub.B), wherein the primary control module (511) is configured to provide the integrity diagnostic indications in that it includes at least a first and a second mutually cooperating primary control component (511A, 511B) that are configured to diagnose (QA) each other's integrity status, and in that it is further configured to diagnose an integrity status of the backup control branch (520) by verifying a response signal (S.sub.R) of the backup control branch in response to a test signal (S.sub.T).

An actuating device for a disc brake may have a piston, and a first ramp-ball motion converter having a first ramp portion axially constrained and actuatable in rotation around and actuating axis. The device may also have a second ramp portion coupled to the piston and a plurality of rolling elements interposed in contact between ramp tracks formed by the first and second ramp portion. The device may also have a second screw and nut motion converter connected between the second ramp portion and the piston. The device may also have a torque limiter that implements a torsional connection of the first ramp portion with the second ramp portion. The torque limiter may also decouple the rotation of the first ramp portion with respect to the second ramp portion about the actuating axis when a predetermined limit torque is exceeded.

An electric brake system includes at least a pair of braking apparatuses each configured to advance a piston for pressing a frictional member against a rotational member rotatable together with a wheel and configured to press the frictional member against the rotational member with use of an electric mechanism according to a braking request signal and hold a pressing force of the frictional member. The electric brake system further includes a control apparatus configured to control the electric mechanism of each of the brake apparatuses and diagnose the failed state in which an abnormality has occurred in each of the brake apparatuses according to the braking request signal. The control apparatus is configured to, when any one of the brake apparatuses is diagnosed as being in the failed state, prohibit the electric mechanism of the one of the brake apparatuses from operating while the vehicle is running.

A system and method for operating a motor vehicle with an electric parking brake. The system includes a clutch sensor, generating a clutch sensor signal representing operation of a clutch of the motor vehicle. A gear selection sensor generates a sensor signal indicating a particular gear selection or position of a manual gearbox of the motor vehicle. Using these and if needed other various inputs, the system generates a deactivation signal for releasing the electric parking brake when a clutch operation is detected and the vehicle gearbox is positioned or has a gear selection other than a neutral position of the manual gearbox.

A system and method for operating a motor vehicle with an electric parking brake. The system includes a clutch sensor, generating a clutch sensor signal representing operation of a clutch of the motor vehicle. A gear selection sensor generates a sensor signal indicating a particular gear selection or position of a manual gearbox of the motor vehicle. Using these and if needed other various inputs, the system generates a deactivation signal for releasing the electric parking brake when a clutch operation is detected and the vehicle gearbox is positioned or has a gear selection other than a neutral position of the manual gearbox.

An actuator assembly for a vehicle brake is disclosed. The actuator assembly comprises, a carrier assembly, which comprises a first transmission plate and a second transmission plate, wherein the two transmission plates are connected to one another via a carrier component, are mounted in an actuator housing and carry a transmission unit. The first transmission plate has a fastening interface for an electric motor and is mounted in an elastically damped manner on the carrier component, and the second transmission plate is rigidly coupled to the carrier component.

A motor unit includes: a motor provided with a first chamber and including a shaft; a rotary member coupled to the shaft outside the first chamber; a housing provided with a second chamber accommodating the rotary member; and a guide member including a peripheral wall between the first chamber and the second chamber, the guide member being provided with a third chamber inside the peripheral wall, wherein the motor unit is provided with a fourth chamber which is outside the first chamber and is open to an inner surface of the second chamber and/or the third chamber, the inner surface of the third chamber includes a guide, and the guide extends farther away from a rotation axis as is closer to the fourth chamber.