A disk brake includes a brake mechanism configured to apply a braking force by advancing a piston in a cylinder portion based on driving of an electric motor to thus press inner and outer brake pads against a disk rotor, and an elastic member configured to bias the inner and outer brake pads in an axial direction of the disk rotor and in a direction away from the disk rotor. A biasing force of the elastic member is greater than sliding resistance of the piston on the cylinder portion. Due to this configuration, the disk brake can effectively prevent or reduce the drags of the inner and outer brake pads.

A helical connection mechanism for an electromechanical brake piston is configured to be mounted in the piston, including a sleeve and a drive member cooperating by a helical connection of longitudinal axis (AX), and a locking structure for rotationally locking the sleeve relative to the piston about the longitudinal axis (AX) and for axially holding the mechanism. The locking structure includes a plate attached to the sleeve and extending orthogonally to the longitudinal axis (AX), at least three axial extensions cooperating with an axial wall of the piston and at least one radial shape cooperating with the axial wall of the piston.

An electromechanical brake device has a rotation-translation converter of short construction for moving a brake piston in an electromechanically operable wheel brake of a motor vehicle, and to a motor vehicle having an electromechanical brake device of this type. The electromechanical brake device comprises a caliper housing defining an actuator receptacle, an actuator unit having a piston movable in a linear manner relative to the caliper housing, wherein at least a portion of the actuator unit is arranged within the actuator receptacle, a drive unit to generate a drive torque which can be transmitted to the actuator unit, a rotation-translation converter of the actuator to axially shift the piston based on the drive torque; and at least one first rotation prevention device for securing against relative rotation between the piston and the actuator receptacle.

A method for ascertaining a motor constant of an electric machine, in particular an actuator assembly. At least one excitation signal having at least one direct current component and one alternating current component is specified. The machine is controlled using the excitation signal. At least one actual value of a motor current of the machine and one actual value of a rotation rate of a rotor shaft of the machine are ascertained in each case. The motor constant is ascertained as a function of the excitation signal and the actual values.

A brake actuator is disclosed for an electromechanical vehicle brake, comprising an electric motor for actuating the vehicle brake, a blocking assembly for selectively rotationally blocking an output shaft of the electric motor for the purposes of implementing a parking brake function. The blocking assembly comprises a blocking module, which is mounted so as to be movable linearly between an arresting position and a release position, and a drive for moving the blocking module. The brake actuator further includes an electronic detection device for detecting the arresting position and/or the release position of the blocking module. Also specified is a method for operating a brake actuator.

An electromechanical drive includes a motor, a rotational part rotatable by the motor about a rotational axis, and a braking device that can be actuated between a braking position and a released position, the braking device having a brake disc that rotates with the rotational part and a braking element that can be adjusted in the axial direction and acts on the brake disc in the braking position. The brake disc has an inner area, a friction surface area extending annularly around the rotational axis with a first friction surface formed on a first side of the brake disc, and an intermediate area extending between the friction surface area and the inner area around the rotational axis. A first mating surface is formed on the braking element, which mating surface faces the first friction surface and interacts with the first friction surface in the braking position.

An electric actuator includes a forwardly and reversely rotatable electric motor, a motion conversion mechanism configured to convert rotation of the electric motor into reciprocating linear motion of a screw shaft, an actuator case containing the electric motor and the motion conversion mechanism, and a boot covering a portion of the screw shaft that extends out of the actuator case. A vent is formed on the actuator case. The vent is configured to ventilate a sealingly closed space in the actuator case and the boot. A breathable waterproof member is provided on the vent and a cover member is also provided on the vent. The breathable waterproof member is configured to block entry and exit of water while permitting entry and exit of air. The cover member is configured to cover the vent so as to allow ventilation with outer air.

Provided in a device for activating a wheel brake of a vehicle, having a tensioning installation which has a spindle drive, are two electric motors, the first electric motor by way of a first gear mechanism acting bi-directionally on the spindle drive. In order for the position of the tensioning installation, once attained, to be fixed in a parking brake, a second electric motor by way of a second gear mechanism, which has a self-locking worm gear mechanism and by way of at least one releasable coupling that acts uni-directionally in the activating direction, is coupled to the spindle drive. The coupling is composed of a cam on an output shaft of the first gear mechanism, and a pin on an output element of the worm gear mechanism. Since the cam cannot be reversed beyond the pin, a latching position of the tensioning installation is defined in this way.

The releases of an electromechanical parking brake are controlled by measuring the change in the intensity (I) of the electrical current provided to the control motor, or a function derived from this intensity, and by extending the release of the brake only for a determined duration (t) after stabilization of this intensity, in order not to unnecessarily increase the idle travel of the brake actuator nor to extend the duration of the control. The determined duration (t) also depends on the temperature and on the hydraulic pressure in the brake.

The disclosure relates to an electromechanical brake for a motor vehicle. The electromechanical brake comprises an actuating piston which is set up to be moved translationally in a direction of a piston axis in order to actuate at least one brake shoe. The electromechanical brake also comprises a brake carrier having a gas-containing piston chamber in which the actuating piston is received such that it can be moved translationally in a direction of the piston axis. Furthermore, the electromechanical brake comprises an electric motor for driving the actuating piston. In the case of the electromechanical brake, a venting device is provided, which is set up to vent the piston chamber with respect to an exterior. The disclosure also relates to a disc brake, to a brake system, and to a motor vehicle.