A spring brake actuator for braking a wheel of a vehicle includes a housing defining a chamber, a push rod extending from the chamber such that pneumatic activation of the spring brake actuator causes the push rod to further extend out of the chamber to thereby activate braking of the wheel of the vehicle and such that pneumatic deactivation of the spring brake actuator causes the push rod to retract back into the chamber to thereby deactivate braking of the wheel of the vehicle, and a sensor assembly located in the chamber such that the housing limits movement of the sensor assembly in the chamber.

An electro-pneumatic brake system for an automotive vehicle, with a service brake arrangement and a park brake arrangement, comprising front and rear axle brake modules, each of front and rear axle brake module comprising an electrical control input and a pneumatic control input, a first bistable relay valve, possibly a second bistable relay valve to supply the trailer, first and second pressure control devices for generating first and second pressure, first and second service brake backup line, for supplying the pneumatic control input of the front and rear axle brake module, a swap arrangement configured to selectively connect the first pressure to the input of the first bistable relay valve or to the first service brake backup line, and connect the second pressure to the input of the second bistable relay valve or to the second service brake backup line.

An electro-pneumatic brake system for an automotive vehicle, with a service brake arrangement and a park brake arrangement, comprising front and rear axle brake modules, each of front and rear axle brake module comprising an electrical control input and a pneumatic control input, a first bistable relay valve, possibly a second bistable relay valve to supply the trailer, first and second pressure control devices for generating first and second pressure, first and second service brake backup line, for supplying the pneumatic control input of the front and rear axle brake module, a swap arrangement configured to selectively connect the first pressure to the input of the first bistable relay valve or to the first service brake backup line, and connect the second pressure to the input of the second bistable relay valve or to the second service brake backup line.

An electrically controllable pneumatic brake system has a front and a rear axle brake circuit, and a manually actuable brake signal transmitter which, upon actuation, outputs a first front brake control pressure and a first rear brake control pressure. A front axle brake pressure is produced based on a front axle braking demand pressure and a rear axle brake pressure is produced based on a rear braking demand pressure. A two-channel pressure modulator system is configured to receive a braking demand signal from an autonomous driving unit and, in response thereto, output the front and rear braking demand pressure, and is further configured to receive the first front and rear brake control pressure and, at least in an error situation, to output the front braking demand pressure depending on the first front brake control pressure and/or the rear braking demand pressure depending on the first rear brake control pressure.

An electrically controllable pneumatic brake system has a front and a rear axle brake circuit, and a manually actuable brake signal transmitter which, upon actuation, outputs a first front brake control pressure and a first rear brake control pressure. A front axle brake pressure is produced based on a front axle braking demand pressure and a rear axle brake pressure is produced based on a rear braking demand pressure. A two-channel pressure modulator system is configured to receive a braking demand signal from an autonomous driving unit and, in response thereto, output the front and rear braking demand pressure, and is further configured to receive the first front and rear brake control pressure and, at least in an error situation, to output the front braking demand pressure depending on the first front brake control pressure and/or the rear braking demand pressure depending on the first rear brake control pressure.

A braking system for a vehicle includes an indicator device provided to reliably indicate a state of a parking brake of the system, while being simple, convenient, and economical. The system includes a body that delimits a service brake pressure chamber and/or a parking brake pressure chamber, a parking brake movable relative to the body, an unlocking part for unlocking the parking brake connected to the parking brake pressure chamber and accessible from outside the body, and a parking brake indicator device. The indicator device is configured to receive a position of the unlocking part via a state pipe and an indicator of supply and/or the venting of the service brake pressure chamber and/or of the parking brake pressure chamber. This information is processed in to detect and indicate an engaged state or a disengaged state of the parking brake.

A vehicle braking system includes brakes, a body, a braking linkage, a service brake comprising a braking piston movable relative to the body to act on the braking linkage and delimiting a service brake pressure chamber to place the braking piston in a service braking position. A parking brake acts on the braking piston and has a working configuration and a resting configuration. The parking brake includes a blocking device movable relative to the body to act on the braking piston and having a first position and a second position in which the blocking device is configured to immobilize the braking piston in a service braking position. A control device is movable relative to the body and has a locking position to hold the blocking device in the second position. A service brake indicator device receives information representing supply and/or venting of the service brake pressure chamber.

Electric equipment for a vehicle with an electropneumatic service brake device, in which at least one pneumatic brake control pressure is immediately and directly controlled to the electromagnetic backup valve, which is still being closed by a current, of at least one pressure regulating module in response to an assistance brake request signal regardless of a defect of an electric service brake circuit. For a failure of the electric service brake circuit, the electromagnetic backup valve, which is then in the currentless state, of the at least one pressure regulating module is automatically opened, and the brake pressure is immediately formed in the pressure regulating module based on the at least one pneumatic brake control pressure already present in the pressure regulating module. Thus, the reaction time of a pneumatic redundancy of the electropneumatic service brake device in response to electric defects is reduced.

Electric equipment for a vehicle with an electropneumatic service brake device, in which at least one pneumatic brake control pressure is immediately and directly controlled to the electromagnetic backup valve, which is still being closed by a current, of at least one pressure regulating module in response to an assistance brake request signal regardless of a defect of an electric service brake circuit. For a failure of the electric service brake circuit, the electromagnetic backup valve, which is then in the currentless state, of the at least one pressure regulating module is automatically opened, and the brake pressure is immediately formed in the pressure regulating module based on the at least one pneumatic brake control pressure already present in the pressure regulating module. Thus, the reaction time of a pneumatic redundancy of the electropneumatic service brake device in response to electric defects is reduced.

A compressed air distribution system for a vehicle (e.g., rail vehicle) includes first and second reservoirs and first and second compressors. The first and second reservoirs are configured to contain respective compressed air to be supplied to first and second braking systems of the vehicle. The first braking system is configured to apply a first braking force to a first wheel set of the vehicle with the compressed air received from the first reservoir, and the second braking system is configured to apply a second braking force to a second wheel set with the compressed air received from the second reservoir. Each wheel set includes a respective axle and a respective one or more wheels coupled to the axle. The first and second compressors are configured to generate compressed air to be stored in the first and second reservoirs, respectively.