A brake system for motor vehicles has a master brake cylinder having at least a first and a second master brake cylinder piston, arranged one behind the other and bound a first and second pressure space. Wheel brakes are connected to each a brake circuit. The first master brake cylinder piston is connected to a brake pedal via a pressure rod. An atmospheric pressure medium storage tank is assigned to the pressure spaces at, per brake circuit, an electrically controllable pressure source with a suction connection and a pressure connection. The pressure connection connected to the wheel brakes. The suction connection connected to the master brake cylinder via a normally closed valve, and, per brake circuit, a normally open valve via which the master brake cylinder is connected to the wheel brakes. Per brake circuit, the suction connection is connected to the pressure medium storage tank via a first valve.

A braking system for vehicles having at least one manual and/or automatic actuation device operatively connected to a processing and control unit to transmit thereto a request for a braking action by a user. The system may also have at least one first electro-hydraulic actuator device operatively connected to a first and second hydraulic supply circuit of a respective first and second braking device. The first electro-hydraulic actuator device may be actuated by the processing and control unit depending on the request for a braking action.

A vehicle braking device includes: a stroke simulator for generating a hydraulic pressure corresponding to a brake operation in a hydraulic chamber, the stroke simulator having a cylinder part and a piston part for sliding through the inside of the cylinder part in conjunction with a brake operation of a brake pedal; a booster mechanism having an input part directly pressed by the piston part or pressed by a spring interposed between the input part and the piston part in conjunction with the sliding of the piston part, and thereby moved in sliding fashion through the inside of the cylinder, and a hydraulic pressure generating part for generating a first hydraulic pressure corresponding to the movement of the input part based on the hydraulic pressure of an accumulator; and a wheel cylinder for applying a braking force to a vehicle wheel on the basis of the first hydraulic pressure.

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 pedal simulator includes a pedal housing, a pedal unit rotatably mounted to the pedal housing, and a simulator unit mounted in the pedal housing and configured to compress a plurality of rods connected to the pedal unit by pressing the pedal unit.

Disclosed herein an electronic brake system includes a hydraulic pressure supply device including a first pressure chamber and a second pressure chamber partitioned by a hydraulic piston, and a hydraulic control unit, wherein the hydraulic control unit comprises a first hydraulic flow path connecting the first pressure chamber and one of the first and second hydraulic circuits, a second hydraulic flow path branched from the first hydraulic flow path to connect to the other one of the first and second hydraulic circuits, a third hydraulic flow path branched from the first hydraulic flow path on upstream side of a branch point of the second hydraulic flow path to connect the second pressure chamber, and a fourth hydraulic flow path branched from the first hydraulic flow path on upstream side of a branch point of the third hydraulic flow path to connect the third hydraulic flow path.

A brake-force simulator for a motor vehicle includes a piston operatively connectible to an operable brake pedal that is guided in an axially displaceable manner in a cylinder; and at least one elastomer spring element situated in the cylinder, which acts with a spring force counter to the movement of the piston in one direction.

A brake apparatus improved in mountability on a vehicle is provided. The apparatus includes a master cylinder 4 that generates hydraulic brake pressure by a driver's brake operation, and a stroke simulator 5 that creates an artificial operation reaction force of a brake operation member when the brake fluid flown out of the master cylinder 4 enters the stroke simulator 5. The master cylinder 4 and the stroke simulator 5 are integrally arranged to overlap each other in a perpendicular direction (as viewed from the perpendicular direction) when installed in the vehicle.

A pedal travel simulator for a hydraulic vehicle power braking system with a cup-shaped cylinder cover in which a piston spring is accommodated, which is held by an orifice disk as a stop for a piston of the pedal travel simulator in the cylinder cover. Recesses are provided in an outer edge of the orifice disk, through which the piston is able to displace brake fluid on its rear side out of a cylinder of the pedal travel simulator through a circumferential groove into a return.

A hydraulic brake device includes (a) a master fluid passage for supplying a working fluid from a master cylinder to a wheel brake, (b) a master shut-off valve provided in the master fluid passage, (c) a return fluid passage, (d) a return passage opening valve provided in the return fluid passage, (e) an electromagnetic control valve provided in the return fluid passage and configured to control a flow of the working fluid or to allow a flow of the working fluid without controlling, and (f) a stroke simulator having first and second fluid chambers defined by a partition member, the first fluid chamber being connected to the master fluid passage between the master shut-off valve and the master cylinder, the second fluid chamber being connected to the return fluid passage on one on opposite sides of the return passage opening valve that is nearer to the wheel brake.