A hydraulic assembly of a traction control system of a hydraulic vehicle brake system includes a hydraulic block, a motor block, and a control device. The hydraulic block includes at least one electric hydraulic valve and at least one electric hydraulic pump arranged therein. The motor block includes an electric motor arranged therein. The electric motor is configured to drive the at least one hydraulic pump. The control device is configured to control the at least one hydraulic valve, the at least one hydraulic pump, and the electric motor. The control device has two structurally separate control units, which include a first control unit with signal components and a second control unit with power components.

A method for influencing the kinematic behavior of a vehicle, in particular a rail vehicle with at least one friction brake system, wherein a brake effect is generated by pressing at least one first and second friction elements against each other, where to achieve advantageous method conditions, temperatures of at least the first friction element are calculated from at least speed, brake pressure, external temperature of the vehicle and absolute times, and heat conduction through the first friction element and a speed-dependent cooling process of the first friction element are taken into consideration during the calculation, and where the kinematic behavior of the vehicle is influenced based on the calculation such that expensive fitting of the friction brake system with sensors for measuring friction element temperatures can be advantageously omitted, and the thermal state of the friction brake system can still be estimated with a high degree of precision.

A hydraulic vehicle brake includes a housing and first and second brake pistons at least partially located within the housing. The brake pistons are configured to cooperatively press a common friction pad against a rotor of the vehicle brake. Each of the pistons is a hollow piston including a substantially solid piston bottom. A clamp beam laterally spans the piston bottoms of the first and second pistons within the housing. The clamp beam is configured to selectively apply longitudinally directed clamping force upon the pistons. A spindle is selectively driven for rotational motion by an electric motor. The spindle is interposed laterally between the first and second brake pistons within the housing. The spindle is configured to reciprocate the clamp beam longitudinally within the housing responsive to a direction of the rotational motion.

A hydraulic vehicle brake includes a housing and first and second brake pistons at least partially located within the housing. The brake pistons are configured to cooperatively press a common friction pad against a rotor of the vehicle brake. Each of the pistons is a hollow piston including a substantially solid piston bottom. A clamp beam laterally spans the piston bottoms of the first and second pistons within the housing. The clamp beam is configured to selectively apply longitudinally directed clamping force upon the pistons. A spindle is selectively driven for rotational motion by an electric motor. The spindle is interposed laterally between the first and second brake pistons within the housing. The spindle is configured to reciprocate the clamp beam longitudinally within the housing responsive to a direction of the rotational motion.

A method for operating an electromechanical braking system for a transportation vehicle having a brake pedal, a brake master cylinder, and an electromechanical brake booster. The electromechanical brake booster includes an actuator motor for increasing or decreasing the pedal force on the brake master cylinder to boost or reduce the braking power accordingly. A change in the boosting force of the electromechanical brake booster is limited to avoid uncontrolled changes of the brake boosting.

Disclosed is a railway braking system including a service brake supplied by a first source, a parking brake having a device for immobilizing the service brake and a mobile control device for mobile control of the immobilizing device, and a command and control unit configured to receive information indicative of a value of the first source, process information indicative of a parking brake setpoint so as to actuate the control device, and determine a value of a second source according to the setpoint and to the information indicative of a value of the first source, so as to supply a pressure chamber of the service brake.

An emergency braking control circuit based on coupler coupling detection includes a coupler status detection circuit and a coupler status relay that are connected in series with a train power loop. A normally open contact of the coupler status relay is connected to an emergency braking train line in a cross-parallel manner. When a coupler is coupled normally, inductive proximity sensors located at a knuckle and a central pivot are closed to drive the coupler status relay, and the normally open contact of the coupler status relay is connected in a cross-parallel manner to ensure that a corresponding node of the emergency braking loop is closed. In case of abnormal coupling or accidental uncoupling of couplers, the inductive proximity sensors of the couplers of two adjacent cars are disconnected simultaneously, the coupler status relays of the two cars are powered off, and emergency braking is applied.

A Vehicle Corner Module (VCM) based brake system, which includes a brake actuator, adapted to regulate the rotation rate of the wheel assembled to the VCM, a fluid-based brake power source, fluidly connected to the brake actuator and adapted to provide pressurized brake fluid for operating the brake actuator, and a brake-control-circuit, functionally associated with the brake actuator and with the brake power source, and adapted to provide functional inputs to the brake actuator based on a target rotation rate profile desired for a wheel mounted on the VCM. All mechanical components of the VCM-based brake system are disposed within the VCM. The VCM-based brake system and the vehicle platform are not in fluid communication with each other.

A braking system for a vehicle, including: at least one pressure regulating module to set a setpoint brake pressure for at least one brake cylinder of a vehicle wheel; at least one wheel speed sensor to detect the wheel slip of the one vehicle wheel; at least one pressure control valve, assigned to the brake cylinder of a wheel, to control the brake pressure applied at the brake cylinder depending on the wheel slip; and a central processing unit to control the at least one pressure regulating module and the at least one pressure control valve at least starting from a brake signal and the detected data of the at least one wheel speed sensor, which has a direct connection to the central processing unit to transmit data detected by the wheel speed sensor.

A parking brake apparatus for a vehicle includes a parking brake controller controlling a parking brake system and arranged to obtain one or more input signals indicative of one or more actions from one or more vehicle systems other than the parking braking system. The parking brake controller is also arranged to provide one or more control signals to be applied to components of the parking brake system to apply parking brakes based upon an adaptive time delay to prevent a vehicle rollaway when the one or more input signals are indicative of the one or more actions meeting respective one or more predetermined conditions.