A transmission module for a hybrid drive vehicle configured to be interposed between an internal combustion engine and a transmission of the vehicle has a tray-like support structure configured to be secured to the engine and defines a housing for a clutch to be interposed between a crankshaft of the internal combustion engine and the module. An actuator controls the clutch. The actuator includes an annular chamber provided in the support structure and opens toward the housing, and an annular piston housed in the annular chamber is axially sliding but angularly fixed. A thrust member is coupled in a rotationally free manner to the annular piston, coaxial thereto and operable to cooperate with a control member of the clutch under the thrust of the piston.

A piston for the actuation of a brake pad, the piston comprising a body having a base end, a pad end and a side wall formed therebetween, an axis X extending from the base end to the pad end, the pad end having a cap contact surface at a non-zero angle relative to the axis of the body; a cap movably secured to the body at the pad end, the cap being arranged over the cap contact surface and having a pad contact face and an opposite body contact face; and a resilient member arranged between the body and the cap; wherein, on application of a braking force, the cap is arranged in an initial position where the cap contact surface of the body is spaced apart from the body contact face of the cap, whereby the cap is moveable transversely relative to the axis of the body into an intermediate position; and wherein the cap is moveable axially relative to the body from the intermediate position into a final position where the cap contact surface contacts the body contact face such that movement of the cap transversely relative to the axis of the body is restrained in the final position.

A multi-piston disengagement system for a vehicle braking device includes an annular housing formed from a main housing and a housing cover, and a plurality of hydraulic actuation assemblies. The annular housing includes a main axis defining an axial direction, a plurality of housing portions, a plurality of pressure chambers, and a flow channel fluidically connecting the plurality of pressure chambers. Each one of the plurality of pressure chambers is arranged in a respective one of the plurality of housing portions and arranged to be filled with a fluid. Each one of the plurality of hydraulic actuation assemblies includes a piston arranged in a respective one of the plurality of pressure chambers and axially movable therein. The piston is arranged to displace in an actuation stroke for introducing an actuation force into the vehicle braking device when a hydraulic pressure is applied to the fluid.

A method and a system for monitoring wear of a braking frictional pad of a motor vehicle, the motor vehicle including a brake device acting on a vehicle wheel, the brake device including a braking frictional pad that is non-rotatable relative to the vehicle wheel and is linearly movable parallel to a rotational axis of the vehicle wheel; a brake piston configured to drive the braking frictional pad; and an electric parking brake or an electric mechanical brake, the electric parking brake or the electric mechanical brake having a drive motor and a piston driving part driven by the drive motor to be linearly movable, the piston driving part being configured to, when the motor vehicle is braking, drive the brake piston to contact the braking frictional pad and in turn drive the braking frictional pad to move.

According to at least one aspect, the present disclosure provides a piston pump comprising: a piston unit configured to reciprocate by driving of a motor cam; a sleeve unit disposed to surround at least a part of the piston unit and having a space in which brake oil is stored; and a check valve unit facing the sleeve unit and discharging the brake oil to an outside of the sleeve unit when a pressure of the brake oil increases, wherein the piston unit includes a first piston having a first end in contact with the motor cam and reciprocating, a second piston having a first end coupled to a second end of the first piston and configured to press the brake oil, and a spring cap coupled to a second end of the second piston and disposed to accommodate an inlet spring therein.

A device disclosed herein is used with an electric submersible pump (ESP) assembly disposed on tubing in a well. A housing of the device connects between tubing and pump. A shaft in the housing can rotate in response to imparted rotation associated with the pump and permanent magnet (PM) motor. A piston in the housing can move longitudinally relative to the shaft in response to a pressure differential across the piston. A clutch on the piston can engage and disengage with a distal end of the shaft in response to the piston's movement of the piston. Additionally or alternatively, a key on the piston can engage and disengage with a pocket on the shaft. The engagement of the clutch and/or key can prevent imparted rotation associated with the pump and the PM motor.

In the case of a hydraulic vehicle brake, having a brake caliper (12), having a brake piston (16), having a receiving bore (14) for the brake piston (16), and having a brake piston seal (32) that acts between the brake caliper (12) and the brake piston (16), the brake piston seal (32) is designed as a composite part, with a composite of a base component (34) and a reinforcement insert (36). The reinforcement insert (36) provides the brake piston seal (32) with a degree of elasticity in an axial direction, whereby, after the brake piston (16) has been displaced in the direction of brake pads (22), the brake piston seal (32) displaces the brake piston (16) in the opposite direction.

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.