An electronic brake system and an operating method thereof are disclosed. Provided is an electronic brake system, according to the present embodiment, comprising: a first hydraulic pressure supply device for generating hydraulic pressure by means of an electric signal output in response to the displacement of a brake pedal; an oil pressure control unit including a first oil pressure circuit for controlling the hydraulic pressure of a first wheel cylinder and a second wheel cylinder, and a second oil pressure circuit for controlling the hydraulic pressure of a third wheel cylinder and a fourth wheel cylinder; and a second hydraulic pressure supply device which is connected between the first oil pressure circuit and the first and second wheel cylinders, and which generates hydraulic pressure by means of an electric signal if the first hydraulic pressure supply device and/or the oil pressure control unit malfunctions.

A method and system is provided for determining faults in a vehicle brake system. An electronic processor obtains a brake pedal signal from a brake pedal that indicates a driver intent to brake and obtains a vehicle braking response condition signal from a brake system feedback sensor. The electronic processor determines a fault state when (1) the brake pedal signal is indicative of no brake pedal movement and the vehicle braking response signal is indicative of a vehicle braking response occurring, or when (2) the brake pedal signal is indicative of brake pedal movement and the vehicle braking response condition signal is indicative of no occurrence of a vehicle braking response. The electronic processor controls an output of an audio or visual indication of a fault state and/or controls braking operation of the vehicle in response to the fault state.

A method and system is provided for determining faults in a vehicle brake system. An electronic processor obtains a brake pedal signal from a brake pedal that indicates a driver intent to brake and obtains a vehicle braking response condition signal from a brake system feedback sensor. The electronic processor determines a fault state when (1) the brake pedal signal is indicative of no brake pedal movement and the vehicle braking response signal is indicative of a vehicle braking response occurring, or when (2) the brake pedal signal is indicative of brake pedal movement and the vehicle braking response condition signal is indicative of no occurrence of a vehicle braking response. The electronic processor controls an output of an audio or visual indication of a fault state and/or controls braking operation of the vehicle in response to the fault state.

A vehicle braking device includes: an electric cylinder in which a piston driven by an electric motor slides in a cylinder to supply fluid; a hydraulic pressure output unit connected to the electric cylinder by way of a first liquid passage, the hydraulic pressure output unit pressurizing or depressurizing a hydraulic pressure in the first liquid passage and outputting the hydraulic pressure to a supply liquid passage connected to a first wheel cylinder; and a control unit that causes at least one of the electric cylinder and the hydraulic pressure output unit to generate the hydraulic pressure in the first wheel cylinder according to a relative position between the piston and the cylinder.

A vehicle braking device includes: an electric cylinder in which a piston driven by an electric motor slides in a cylinder to supply fluid; a hydraulic pressure output unit connected to the electric cylinder by way of a first liquid passage, the hydraulic pressure output unit pressurizing or depressurizing a hydraulic pressure in the first liquid passage and outputting the hydraulic pressure to a supply liquid passage connected to a first wheel cylinder; and a control unit that causes at least one of the electric cylinder and the hydraulic pressure output unit to generate the hydraulic pressure in the first wheel cylinder according to a relative position between the piston and the cylinder.

A vehicle brake pedal including a base and a pedal arm coupled to and rotatable relative to the base. A linear pedal resistance assembly extends between the base and the pedal arm and is adapted for exerting a resistance force against the pedal arm in response to the rotation of the pedal arm. A rotary pedal dampener assembly is associated with the base and adapted for exerting a dampening force against the pedal arm in response to the rotation of the pedal arm. A rotary pedal position sensor assembly is associated with the base and adapted for sensing the position of the pedal arm in response to the rotation of the pedal arm. In one embodiment, the linear pedal resistance assembly includes a housing with a plurality of springs adapted for compression in response to the rotation of the pedal arm and for exerting the resistance force against the pedal arm.

A vehicle brake pedal including a base and a pedal arm coupled to and rotatable relative to the base. A linear pedal resistance assembly extends between the base and the pedal arm and is adapted for exerting a resistance force against the pedal arm in response to the rotation of the pedal arm. A rotary pedal dampener assembly is associated with the base and adapted for exerting a dampening force against the pedal arm in response to the rotation of the pedal arm. A rotary pedal position sensor assembly is associated with the base and adapted for sensing the position of the pedal arm in response to the rotation of the pedal arm. In one embodiment, the linear pedal resistance assembly includes a housing with a plurality of springs adapted for compression in response to the rotation of the pedal arm and for exerting the resistance force against the pedal arm.

A wheel-braking system architecture for an aircraft is provided. The architecture includes a friction brake; an electromechanical actuator associated with a power module connected to a digital communication module by a first driver module; and a controller having both a power supply unit for powering the power module by delivering a power supply voltage (Vc) thereto, and also a control unit connected to the digital communication unit in order to transmit a digital control signal to the digital communication module. The control unit can be connected to the driver unit by an analog wired connection in order to transmit that to a first analog braking order from which the first driver module drives the power module to produce a degraded power supply current for the actuator.

A wheel-braking system architecture for an aircraft is provided. The architecture includes a friction brake; an electromechanical actuator associated with a power module connected to a digital communication module by a first driver module; and a controller having both a power supply unit for powering the power module by delivering a power supply voltage (Vc) thereto, and also a control unit connected to the digital communication unit in order to transmit a digital control signal to the digital communication module. The control unit can be connected to the driver unit by an analog wired connection in order to transmit that to a first analog braking order from which the first driver module drives the power module to produce a degraded power supply current for the actuator.

A locking knob for an air brake valve may include a push rod and a locking ring. The push rod may include a knob head at a first end of the push rod, first thread along an exterior surface of the push rod, and a cavity within the push rod exposed at a second end of the push rod opposite of the first end, the cavity configured to house an actuating arm of the valve that is held fixed to the push rod. The locking ring may include a channel that is configured to house the push rod, and second thread within the channel that is configured to mate with the first thread. Rotation of the locking ring restricts movement of the push rod and actuating arm.