An electric brake device is disclosed. The electric brake device includes a reservoir configured to store brake oil; a reaction force cylinder fluidically communicating with the reservoir and configured to change a pedal effort and a pressure of the brake oil in operative connection with a movement of a pedal; a wheel brake mechanism configured to restrain rotation of wheels of a vehicle in connection with the operation of the reaction force cylinder; and a pedal effort adjustment stopper configured to adjust a change in magnitude of the pedal effort according to the movement of the pedal, the pedal effort adjustment stopper comprising a coupling body mounted on at least one side of the reaction force cylinder and one or more pedal effort adjusters connected to the coupling body and movable in a longitudinal direction of the reaction force cylinder.

A pedal simulator connected to a master cylinder to provide brake pedal response to a driver. The pedal simulator includes first and second reaction force members with an adjustable gap to change brake pedal feeling. A component of the pedal simulator includes a deformable portion that is used to adjust the gap to achieve a desired brake pedal response.

A braking system for a motor vehicle comprises a first and second electrically controllable pressure source for providing a brake pressure for actuating the wheel brakes. An electrically controllable pressure modulation device sets brake pressures that are individual to each of the wheel brakes, said device having electrically actuatable inlet valves and outlet valves for each wheel brake. The second pressure source comprises a motor-pump unit and at least one low-pressure accumulator. The low-pressure accumulator is connected to an output connection of at least one outlet valve. A first and a second energy supply unit for the braking system are independent from one another. The first energy supply unit supplies the first pressure source with energy. The second energy supply unit supplies the second pressure source with energy. The pressure modulation device is supplied with energy by the first energy supply unit and by the second energy supply unit.

An actuator assembly for an integrated dynamic brake apparatus according to an embodiment of the present invention includes a hollow motor having a stator and a rotor spaced apart from an inner circumferential surface of the stator; a block having one side coupled to one side of the motor and in which chamber that accommodates fluid is formed; a gear unit having one side coupled and fixed to the rotor to convert rotational movement of the rotor to linear movement; a piston configured to receive the converted linear movement from the gear unit to linearly reciprocate; and an electronic control unit coupled to the other side of the block and comprising a motor position sensor configured to detect a position of the motor.

A pedal simulator is disclosed. The pedal simulator is connected to a master cylinder, receives hydraulic pressure corresponding to a pedal effort of a driver of a vehicle, and provides pedal feel to the driver. The pedal simulator includes a simulator block, an upper part of which includes an oil port connected to the master cylinder, configured to include a bore communicating with the oil port, and a reaction force portion provided in the bore, configured to be pressurized by oil introduced through the oil port during braking of the vehicle, and provide reaction force. An upper end of a reaction force piston of the reaction force portion that moves back to an original position thereof during release of the braking is provided with a buffering member formed of rubber by which the simulator block is not in contact with the upper end of the reaction force piston.

A brake system for a vehicle is provided to independently adjust a braking pressure of each wheel. The system includes a hydraulic pressure brake driven by two actuators and a sub-cylinder and valve configurations that are disposed in the peripheral flow path thereof to eliminate the pressure unbalance generated in the hydraulic pressure brake.

Disclosed herein is an electronic brake system and a method for controlling the same are disclosed. The electronic brake system includes a master cylinder for discharging oil according to displacement of a brake pedal, a pedal displacement sensor sensing brake pedal displacement, a simulation apparatus providing pedal pressure responsive to the sensed pedal displacement, a hydraulic pressure supply unit for generating hydraulic pressure using a motor that operates based on the sensed pedal displacement, a hydraulic circuit for supplying the hydraulic pressure generated from the hydraulic pressure supply unit to the caliper, a cut valve positioned between the master cylinder and the hydraulic circuit for transmitting or blocking the hydraulic pressure discharged from the master cylinder, and a controller for blocking at least one of the cut valve and braking control with a target pressure according to a pressure in the simulation apparatus when the simulation apparatus fails.

A braking apparatus for a vehicle and a method for controlling the same. The braking apparatus includes a master cylinder configured to form braking pressure based on an input to a brake pedal and transmit the braking pressure to a wheel brake side, a motor configured to control the pressure transmitted to the wheel brake side by moving a piston included in the master cylinder, and a controller configured to control the motor. The controller determines whether the piston reaches an end point of travel, based on a rate of change in a position of the piston and a current of the motor, and sets a displacement of the piston as a maximum displacement when it is determined that the piston has reached the end point and position initialization for the piston has been completed.

A brake system includes a reservoir and a master cylinder operable to provide a brake signal responsive to actuation of a brake pedal connected thereto. A power transmission unit is configured for selectively providing pressurized hydraulic fluid for actuating at least one of the pair of front wheel brakes and the pair of rear wheel brakes in a normal non-failure braking mode. A plurality of iso/dump valve arrangements are each hydraulically interposed between the power transmission unit and a corresponding one of the wheel brakes. A plurality of two-position three-way valves are each hydraulically connected with the master cylinder, the power transmission unit, and at least a selected wheel brake of the pair of front wheel brakes. The three-way valves selectively control hydraulic fluid flow from a chosen one of the master cylinder and the power transmission unit to the corresponding one of the front wheel brakes.

A brake system includes a reservoir and a master cylinder operable to provide a brake signal responsive to actuation of a brake pedal connected thereto. A power transmission unit is configured for selectively providing pressurized hydraulic fluid for actuating at least one of the pair of front wheel brakes and the pair of rear wheel brakes in a normal non-failure braking mode. A iso/dump valve arrangement is hydraulically interposed between the power transmission unit and a corresponding one of the wheel brakes. A fluid separator is hydraulically interposed between a selected one of the pair of front wheel brakes and a corresponding iso/dump valve arrangement. A normally open base brake iso valve is energized closed during normal non-failure braking mode. The base brake iso valve is open to place the master cylinder into fluid communication with at least one of the fluid separators during manual push-through braking mode.