An emergency brake valve system for a pneumatic brake system of a vehicle, in particular of a rail vehicle, includes a first valve and a second valve, wherein the first valve is configured to conduct an auxiliary pressure to, or isolate this from, the second valve, whereas the second valve is configured to provide either a static or a regulated pressure in a manner which is dependent on the auxiliary pressure. The first valve is configured in such a way that it isolates the prevailing auxiliary pressure from the second valve in regular operation, with the result that the second valve provides a regulated pressure, and that it conducts the prevailing auxiliary pressure to the second valve in emergency operation, with the result that the second valve provides a static pressure.

An electropneumatic brake system for a utility vehicle includes a front first brake cylinder and a front second brake cylinder on a front axle, the front first brake cylinder and the front second brake cylinder being configured to brake respective first and second front vehicle wheels. The system also includes a rear first brake cylinder and a rear second brake cylinder on a rear axle, the rear first brake cylinder and the rear second brake cylinder being configured to brake respective first and second rear vehicle wheels. The system additionally includes a central brake control device configured to output brake control signals for pneumatic pressurization of the front first and second brake cylinders and the rear first and second brake cylinders, and further includes two front wheel revolution rate sensors and two rear wheel revolution rate sensors configured to sense respective wheel revolution rates.

A brake valve for a compressed air brake system of a utility vehicle includes a compressed air input configured to connect to a system pressure, a compressed air output configured to connect a brake control line, and at least one sensor configured to determine a brake valve actuation travel of an actuating element of the brake valve with a working interconnection to the brake pedal. The brake valve further includes a characteristic curve memory storing two stored characteristic curves and/or dependences and at least one determination device. The brake valve is configured to output at least two useful sensor signals, a first of which represents a brake valve output pressure and a second of which represents a percentage actuation position of the actuating element. The at least one sensor is configured to generate an actuating signal depending on the brake valve actuation travel of the actuating element.

An electro-pneumatic central pressure control module having at least a single channel, and which is implemented as a component for an electro-pneumatic service brake of a vehicle, having at least one pressure control channel which is electrically controllable with regard to a brake pressure. Also described is an electronic control device of the pressure control module having a board carrying electrical and electronic components, at least one inertial sensor being arranged on or at the at least one board and being electrically conductively connected to at least several of the electrical and electronic components on the board, in which an arrangement/apparatus ensures a lower vibration load of the inertial sensor on the board.

An actuator module for a vehicle includes an actuator control device configured to output an actuator activation signal and at least one actuator configured to receive the actuator activation signal and perform, based on the actuator activation signal, an actuator operation. The actuator control device includes a driving dynamics sensor device configured to measure at least one driving dynamics measurement variable of the vehicle and to generate a driving dynamics measurement signal. The actuator control device also includes a signal compensation device configured to receive the driving dynamics measurement signal and an actuator information signal indicating the actuator operation of the actuator control device, to filter the driving dynamics measurement signal in a manner dependent on the actuator information signal, and to output a compensated driving dynamics measurement signal. The actuator, actuator control device, driving dynamics sensor device, and signal compensation device are provided in one structural unit.

An electro-pneumatic central pressure control module, having at least two channels, implemented as a structural unit for an electro-pneumatic service brake of a vehicle, having at least two pressure control channels which are electrically controllable with regard to a brake pressure. A central electronic brake control device has a board, carrying electrical and electronic components, in which routines at least for controlling the brake pressure and for controlling the driving dynamics are implemented in the electrical and electronic components. At least one inertial sensor is arranged on or at the at least one board and is electrically conductively connected to at least several of the electrical and electronic components on the board so that the output signals of the at least one inertial sensor are integrated into the at least several electrical and electronic components for carrying out the control of the driving dynamics.

An actuator module for a vehicle includes an actuator control device configured to output an actuator activation signal and at least one actuator configured to receive the actuator activation signal and perform, based on the actuator activation signal, an actuator operation. The actuator control device includes a driving dynamics sensor device configured to measure at least one driving dynamics measurement variable of the vehicle and to generate a driving dynamics measurement signal. The actuator control device also includes a signal compensation device configured to receive the driving dynamics measurement signal and an actuator information signal indicating the actuator operation of the actuator control device, to filter the driving dynamics measurement signal in a manner dependent on the actuator information signal, and to output a compensated driving dynamics measurement signal. The actuator, actuator control device, driving dynamics sensor device, and signal compensation device are provided in one structural unit.

A method of brake management in a heavy vehicle is provided, and includes, in response to determining that a request for emergency braking is imminent, increasing an air pressure of e.g., a service brake system of the vehicle and decreasing an air pressure of e.g., a parking brake system of the vehicle. The method further includes, in response to actually receiving the request for emergency braking of the vehicle, performing an emergency braking of the vehicle by compounding both the service and parking brake systems, including further increasing the air pressure of the service brake system and further decreasing the air pressure of the parking brake system. A corresponding brake system controller, brake system, heavy vehicle, computer program and computer program product are also provided.

The invention relates to electropneumatic equipment (1) of a vehicle comprising an electropneumatic parking brake device (2) having an electropneumatic parking brake control unit (EPB). According to the invention, the electropneumatic parking brake control unit (EPB) is supplied with electric energy by only two electric energy sources 52,54) which are independent of each other, a first electric energy source (52) and a second electric energy source (54).

A fail-safety valve unit is for a failure braking function of a pneumatic braking system for a vehicle. The fail-safety valve unit has a first and a second failure brake valve configured as monostable valves, and a main line which pneumatically connects a main port, which provides a first pressure, and a failure port. The first and second failure brake valves are connected pneumatically in series in the main line. The first and the second failure brake valves are controllable by different control units. The failure brake valves are open in an open position when not actuated such that the first pressure prevailing at the main port is provided as a failure brake pressure at the failure port such that, in a fault situation, in an electrical failure, and/or in a diagnostic situation, a failure braking operation is triggered via provision of the failure brake pressure at the failure port.