Provided are an electronic brake system and a method of operating the same, capable of performing a normal operation mode and an abnormal operation mode by including an integrated master cylinder configured to discharge a pressurizing medium according to a displacement of a brake pedal while providing a driver with a pedal fee, a liquid pressure supply device configured to generate a liquid pressure by operating a hydraulic piston according to an electrical being output on the basis of the displacement of the brake pedal, and a hydraulic control unit configured to a liquid pressure of a pressurizing medium to be supplied to each wheel cylinder.

A support element for positioning a first element, in particular a cover, on a second element, in particular a housing, includes an annular disk-shaped base body that can be positioned on a support rod fastened on the second element, the base body having on a first end face a support surface for making supporting contact with the first element, where the support element has, on the first end face, a plastically deformable projection forming the support surface.

An actuation system includes a power drive unit that drives a plurality of drive shafts that each has a first end individually connected to the power drive unit. The power drive unit includes a geartrain including a plurality of individual gears that are offset relative to each other along the gearbox, and a motor-driven rotation of one of the plurality of individual gears drives rotation of the other individual gears, and each of the plurality of individual gears rotates to drive rotation of a respective one of the plurality of drive shafts. A plurality of torque brakes is mounted to the gearbox, the torque brakes being mechanically coupled to respective individual gears and drive shafts. When the torque being passed through is above a predetermined threshold value, a locking of one of the torque brakes stops rotation of all gears simultaneously to maintain positional symmetry in the actuation system.

A brake system and a method for controlling a brake system. The brake system may include a first module having a first pressure supply unit with an electromotive drive, an optional second pressure supply unit and a first control device for controlling the first pressure supply unit; a second module having a third pressure supply unit, isolation valves and brake-pressure-adjusting valves, and a second control device for controlling the brake-pressure-adjusting valves; and a detection unit for detecting a first case of error. The brake system is designed such that, in the first case of error, in order to provide an ABS function and/or a yaw torque intervention, it implements a (wheel-specific and/or selective) adjustment of the pressures in the wheel brakes by actuating at least one of the brake-pressure-adjusting valves of the second module and/or the isolation valves of the second module and the first pressure supply unit.

An electromechanical brake pressure generator for a hydraulic brake system of a vehicle. The electromechanical brake pressure generator includes a screw drive system for converting a drive-side rotary movement into a translation movement to generate brake pressure. The screw drive system includes a spindle which is rotatable via an electric motor, a spindle nut, which interacts with a thread of the spindle so that the spindle nut is axially displaceable by a rotation of the spindle, and a drive wheel, which is situated coaxially on the spindle in a torsionally fixed manner and via which the spindle is connected to the electric motor. The drive wheel is developed from at least two different materials. A first material forms at least a wheel hub of the drive wheel. A second material forms at least a drive ring enclosing the wheel hub. The first material has greater strength than the second material.

A detection method for an electromechanical brake booster. The method includes: ascertaining, while both a driver braking force is transferred to an input element and a motor force is transferred to a support element so that a coupling element of the electromechanical brake booster which is provided downstream from the input element and the support element is also displaced at least using the motor force, whether an open intermediate gap, when the input element is present in its starting position, is closed when the coupling element is present in its starting position, and establishing an actual variable with respect to a coupling element path of the coupling element out of its coupling element starting position and/or a coupling element velocity of the coupling element in the case of an open intermediate gap using a first formula, and in the case of a closed intermediate gap using a second formula.

A method for operating a brake system, which comprises hydraulically actuatable wheel brakes with brake linings; a brake fluid reservoir; a master brake cylinder; a pressure supply device with a pressure piston that can be moved into a pressure chamber; an integrated parking brake, wherein, in a normal operating mode, brake pressure is actively built up in the wheel brakes by means of the pressure supply device, and wherein, in a parking operating mode, the integrated applies the brake linings of at least two wheel brakes, and wherein, when the integrated parking brake is released, the application of the linings is withdrawn again, wherein after the integrated parking brake has been released, the brake fluid volume displaced by the integrated parking brake is taken into consideration for the subsequent operation in the normal operating mode.

A hydraulic block for a hydraulic power unit of a hydraulic, slipped-controlled power vehicle braking system. A power piston of an electromechanical power brake pressure generator in a power cylinder borehole of the hydraulic block is guided radially in the power cylinder borehole with the aid of a guide bushing.

An actuating unit for a brake booster of a vehicle is disclosed, the actuating unit having a housing and a force transmission module which is received displaceably in the housing. The force transmission module has a first force transmission element, a second force transmission element which is couplable or coupled to the first force transmission element so as to transmit force, a spring device which is couplable or coupled to the second force transmission element so as to transmit force and an actuating element which is couplable or coupled to the first force transmission element. The spring device is configured to exert a spring force on the first and/or second force transmission element such that the first and/or second force transmission element is able to be held at least temporarily in a predetermined initial position. The first and/or second force transmission element is adjustable from the initial position counter to the spring force of the spring device by an adjustment path by a force exerted and/or transmitted onto the first force transmission element. The force transmission module is configured to decouple the first force transmission element from the spring device after a defined adjustment path, as well as a brake booster, vehicle brake system and subassembly therefor.

An electromechanical brake booster for a vehicle brake system is disclosed. The electromechanical brake booster has an actuating element which is couplable to an electric motor via a transmission, a housing in which the actuating element is displaceably received, and at least one sliding element which is arranged between the housing and the actuating element. A vehicle brake system, subassembly therefor and sliding element is also disclosed.