A braking system, in particular for a motor vehicle, including a braking force device having a brake booster for boosting a braking force and a brake pressure supply device for providing brake pressure with the aid of a brake medium, a braking device which may be acted on by pressure by the brake medium with the aid of the brake pressure supply device, and at least one sensor which is designed to detect a distance differential of a displacement means for the displacement of a volume of the brake medium of the braking force device. The braking force device is designed to ascertain the volume of brake medium to be displaced on the basis of the detected distance differential.

A system for determining brake wear based on hydraulic fluid volume may comprise a brake actuator and a fluid supply line fluidly coupled to the brake actuator. The brake actuator may include a brake ram configured to translate in response to changes in fluid pressure in the brake actuator. A piston may be fluidly coupled between a first portion of the fluid supply line and a second portion of the fluid supply line. The piston may include a cylinder and a ram configured to translate within the cylinder. A first sensor may be operably coupled to the piston.

There is provided a booster of a braking force 1 which drives a master cylinder by boosting an operation force of a brake pedal 100 in accordance with a movement amount of an input member 4 that reciprocates by an operation of the brake pedal 100, including: the input member 4 of which one end is linked to the brake pedal 100, which is inserted and fitted to the inside of a control housing 3 installed in a housing 2, and which is provided to be freely relatively slidable in an axial direction; and damping members 22, 31, and 32 which are provided at a part at which the input member 4 and the housing 2 abut against each other, or at a position which can be linked or abut against a part of the input member 4, in which, when the input member 4 moves to return when releasing an operation of the brake pedal 100, when the input member 4 abuts against the housing 2, the damping members 22, 31, and 32 perform an impact absorbing and damping action.

There is provided a booster of a braking force 1 which drives a master cylinder by boosting an operation force of a brake pedal 100 in accordance with a movement amount of an input member 4 that reciprocates by an operation of the brake pedal 100, including: the input member 4 of which one end is linked to the brake pedal 100, which is inserted and fitted to the inside of a control housing 3 installed in a housing 2, and which is provided to be freely relatively slidable in an axial direction; and damping members 22, 31, and 32 which are provided at a part at which the input member 4 and the housing 2 abut against each other, or at a position which can be linked or abut against a part of the input member 4, in which, when the input member 4 moves to return when releasing an operation of the brake pedal 100, when the input member 4 abuts against the housing 2, the damping members 22, 31, and 32 perform an impact absorbing and damping action.

There is provided a booster of a braking force 1 which drives a master cylinder by boosting an operation force of a brake pedal 100 in accordance with a movement amount of an input member 4 that reciprocates by an operation of the brake pedal 100, including: the input member 4 of which one end is linked to the brake pedal 100, which is inserted and fitted to the inside of a control housing 3 installed in a housing 2, and which is provided to be freely relatively slidable in an axial direction; and damping members 22, 31, and 32 which are provided at a part at which the input member 4 and the housing 2 abut against each other, or at a position which can be linked or abut against a part of the input member 4, in which, when the input member 4 moves to return when releasing an operation of the brake pedal 100, when the input member 4 abuts against the housing 2, the damping members 22, 31, and 32 perform an impact absorbing and damping action.

A rod boot (24) seals a rod opening (20), through which a piston rod of a piston of a pneumatic actuator is guided from a retained position to an extended position. The rod boot is connected to the rod opening (20) and the piston rod (18). A mantle (30) of the rod boot (24) has a first section (34) and a second section (36) opposite from the first section (34). The first section (34) is connected to the rod opening (20) and the second section (36) is connected to a mounting section (38) of the piston rod (18). The second section (36) is inverted inwardly (40) relative to the first section (34), and the longitudinal dimensions of the first section (34) and second section (36) vary relative to each other as a function of a relative position of the first section (34) to the second section (36).

A rod boot (24) seals a rod opening (20), through which a piston rod of a piston of a pneumatic actuator is guided from a retained position to an extended position. The rod boot is connected to the rod opening (20) and the piston rod (18). A mantle (30) of the rod boot (24) has a first section (34) and a second section (36) opposite from the first section (34). The first section (34) is connected to the rod opening (20) and the second section (36) is connected to a mounting section (38) of the piston rod (18). The second section (36) is inverted inwardly (40) relative to the first section (34), and the longitudinal dimensions of the first section (34) and second section (36) vary relative to each other as a function of a relative position of the first section (34) to the second section (36).

Provided is a master cylinder apparatus with a reduced size enabled by simplifying the fluid passageway configuration. A master cylinder apparatus which includes a base member containing a fluid passageway for brake fluid and to which an operation of a brake operator is inputted is provided with: a master cylinder installed on the base member to generate a fluid pressure based on an input produced by operating the brake operator; and at least two solenoid valves attached to one side of the base member to open or close the fluid passageway. The two solenoid valves are disposed symmetrically with respect to a central axis along the axial direction of the master cylinder as viewed from a direction perpendicular to the one side of the base member.

A device for controlling a deceleration system of a vehicle includes an input port configured to receive a fluidic main deceleration request, and an output port configured to supply an electric deceleration demand to the deceleration system. The device is configured to generate the electric deceleration demand according to the fluidic main deceleration request. A deceleration system, a vehicle, a method and a computer product are also disclosed.

There is set out an actuator subassembly (10) for a vehicle brake, having a linearly displaceable, unilaterally open brake piston (20) which is used to apply a brake liner to a brake rotor, having a brake calliper unit (12), in which a receptacle (22) having a running face (24) for the brake piston (20) is provided, and having a rotation prevention member which has at least one axially extending groove (38) in the running face (24) and at least one rotation prevention element (32) and by means of which the brake piston (20) is guided in the brake calliper unit (12) in a rotationally secure manner when the rotation prevention element (32) is received in the groove (38). The rotation prevention member is constructed in such a manner that the brake piston (20) can be inserted in the receptacle in an axial direction during assembly of the actuator subassembly (10) together with the rotation prevention element (32) so that the rotation prevention element (32) is located in the groove (38) in a rotationally secure manner. Furthermore, a method for producing an actuator subassembly (10) is set out.