A ball-screw drive for an actuator assembly of a vehicle brake is disclosed, comprising a rotatably mounted recirculating ball screw on which a screw nut which is closed on one side is mounted, at least one thread being formed on the circumferential surface of the recirculating ball screw, in which thread a plurality of balls are guided in such a way that a rotation of the recirculating ball screw brings about an axial displacement of the screw nut along an axis of rotation of the recirculating ball screw. A ball return system is integrated in the recirculating ball screw. Furthermore, an actuator assembly comprising a ball-screw drive and a method for producing a ball-screw drive are indicated.

A drum brake apparatus includes: a housing; a main braking unit disposed on a first portion of the housing, and the main braking unit configured to be, during main braking, driven by a hydraulic pressure and pressing a shoe; a parking braking unit disposed on a second portion of the housing, the parking braking unit configured to be, during parking braking, driven by an electromotive force of an actuator and pressing the shoe; a first locking member configured to couple the housing to one surface of a back plate; and a second locking member configured to couple the actuator to the housing on another surface side of the back plate.

A motor vehicle brake, in particular a motor vehicle brake which can be activated in a combined fashion both hydraulically and electromechanically, having an actuator assembly comprising a housing, an actuator element which can be moved relative to the housing in order to move a brake lining hydraulically or electromechanically, a motor-operated drive, a movement mechanism arranged between the motor-operated drive and the movable actuator element, a gear arrangement assigned to the movement mechanism, and a separate self-locking device which is designed to block the movement mechanism when necessary and is integrated into the motor-operated drive.

A floating caliper (2) for a disc brake comprises a first half-caliper (10), which houses a reaction piston (50), a second half-caliper (12), which houses an action piston (90) and locking means for locking the action piston (90) in a preset parking position. The reaction piston (50) is elastically yielding when the braking action acting on it exceeds a preset parking action threshold which corresponds to said parking position wherein the locking means lock the action piston (90).

A brake cylinder device having a parking spring brake mechanism, provided with a clutch mechanism configured so as to transmit or block urging force of a piston to or from a brake force transmitting unit; a latch member for restricting displacement of the brake force transmitting unit relative to the piston by engaging with the clutch mechanism, and allowing displacement of the brake force transmitting unit relative to the piston by disengaging from the clutch mechanism; a latch lock member for engaging at an inclined part with a protruding part of the latch member; and a rotation-preventing part for preventing the latch lock member from rotating.

An electromechanical brake system includes a brake actuator having a power transmission for transmitting an actuating force to a brake pad, the power transmission including a rotatable shaft. A coupler with a locking element can be controlled so that the locking element is engaged with the rotatable shaft and blocks its rotation or so that the locking element is disengaged from the rotatable shaft so that the rotatable shaft can be rotated. The brake actuator has an interface configured to be connected to the locking element and to engage or disengage the locking element from the rotatable shaft.

The vehicle control apparatus comprises one or more processors, one or more storage media storing a program to be executed by the one or more processors. The program includes one or more instructions. The one or more instructions cause the one or more processors to perform a brake control process in which, after a stroke of a predetermined amount or more is made to a brake pedal by a brake booster to apply brake fluid pressure to the brake mechanism to make the brake fluid pressure in a pressurized state in response to input of a predetermined signal corresponding to detection of theft of the vehicle, the stroke of the brake pedal by the brake booster is cancelled while a first valve disposed in a brake fluid pressure circuit is kept at a closed state to keep the pressurized state of the brake fluid pressure applied to the brake mechanism.

A bistable electromagnetic actuator includes a housing extending along an exertion axis of the actuator, two excitation coils arranged inside the housing and having at least one winding around the exertion axis for generating a magnetic control flux, a core that can be moved along the exertion axis and immobilized in two end positions depending on the magnetic flux generated by the coils, an actuating member coupled to the core to form a movable assembly, and a manual control device comprising a drive shaft mounted such that it can rotate about a first axis orthogonal to the exertion axis.

The drive shaft has at least one tooth engaging with at least one first raised part translationally connected to the actuating member such that rotation of the drive shaft generates translational movement of the movable assembly.

An electromechanical brake integrates a function of a parking brake by adding a simple structure to an existing electromechanical brake. In particular, the electromechanical brake includes a parking braking releasing structure configured to automatically release parking braking after a parking brake operates. In addition, the electromechanical brake is implemented to perform and release parking braking by using a drive unit which may operate in a single direction instead of using a drive unit which may operate in two directions.

An assembly that includes a parking brake system including two or more spindle/nut devices. The two or more spindle/nut devices include a high efficiency device and a low efficiency device. The high efficiency device is in communication with a first end of a brake pad, and the low efficiency device in communication with a second end of the brake pad. The high efficiency device moves the first end of the brake pad against a braking surface, and the low efficiency device moves the second end of the brake pad against the braking surface. After one or both of the ends of the brake pad are moved against the braking surface and a clamping force is created, the low efficiency device locks and prevents movement of the high efficiency device so that the clamping force is maintained.