A hydraulic braking system for a vehicle includes a master brake cylinder, a hydraulic unit and a plurality of wheel brakes, the hydraulic unit including at least one brake circuit for brake pressure modulation in the wheel brakes. A bistable solenoid valve is associated with at least one wheel brake, which valve is looped into the corresponding fluid channel, immediately upstream of the associated wheel brake, and in a de-energized open position enables brake pressure modulation in the associated wheel brake, and in a de-energized closed position seals a current brake pressure in the associated wheel brake, wherein a hydraulic force brought about by the sealed-in brake pressure acts in a seat-opening manner in the corresponding bistable solenoid valve.

An electronic control device is configured to control at least one electromagnetic valve mounted on a vehicle. The electronic control device includes a regenerative current detector configured to detect a regenerative current circulating through the at least one electromagnetic valve immediately after power supply to the at least one electromagnetic valve is stopped. The electronic control device further includes a regenerative current singularity detector configured to detect a regenerative current singularity that is a singularity in a temporal change of the regenerative current. The electronic control device further includes a regenerative current failure detector configured to detect a stuck failure of the at least one electromagnetic valve based on a detection result of the regenerative current singularity detector.

A braking system for a vehicle including front and rear wheels having wheel brakes includes a fluid displacement mechanism for supplying brake fluid to at least one of the wheel brakes. The fluid displacement mechanism includes a piston having a first position prior to braking and a second position for applying braking. A fluid accumulator is in fluid communication with the fluid displacement mechanism and stores brake fluid. A valve is in fluid communication with the fluid displacement mechanism and the accumulator and is configured to be closed while the piston moves from the second position towards the first position to prevent depletion of the accumulator.

A hydraulic braking system for a vehicle includes a master brake cylinder, a hydraulic unit and a plurality of wheel brakes, the hydraulic unit including at least one brake circuit for brake pressure modulation in the wheel brakes. A bistable solenoid valve is associated with at least one wheel brake, which valve is looped into the corresponding fluid channel, immediately upstream of the associated wheel brake, and in a de-energized open position enables brake pressure modulation in the associated wheel brake, and in a de-energized closed position seals a current brake pressure in the associated wheel brake, wherein a hydraulic force brought about by the sealed-in brake pressure acts in a seat-opening manner in the corresponding bistable solenoid valve.

A simulator valve and an electronic brake system using the same are disclosed. The electronic brake system includes a master cylinder provided with at least one cylinder chamber having a volume changeable according to operation of a pedal, a pedal simulator connected to the cylinder chamber, configured to provide reaction force corresponding to a pedal effort of the pedal, a hydraulic-pressure supply device configured to provide hydraulic pressure to at least one wheel cylinder, an electronic control unit (ECU) configured to operate the hydraulic-pressure supply device, and a simulator valve provided in a flow passage through which the master cylinder is connected to the pedal simulator, and provided with a unidirectional flow passage that allows fluid to flow from the pedal simulator to the cylinder chamber and a bidirectional flow passage that is electronically opened or closed.

A power-operated hydraulic brake system for a wheeled vehicle includes a main brake line; a brake valve configured to input a target brake pressure into the main brake line, the brake vale configured to be actuated via a brake pedal; a plurality of wheel brake lines branching off from the brake valve, each of which leads to an actuating unit of a wheel brake; and a valve assembly of an ABS control system. The valve assembly includes an inlet valve arranged between the main brake line and one of the wheel brake lines, and an outlet valve arranged between the relevant wheel brake line and an unpressurized return line. The inlet valve and the outlet valve are pressure-controlled 2/2-way switching valves with correspondingly large switching cross sections, and the inlet valve and the outlet valve are each assigned at least one pilot valve designed as a solenoid switching valve.

Disclosed is a solenoid valve for a brake system. The solenoid valve comprises an armature disposed inside a sleeve to open and close an orifice formed in a seat by moving up and down along an axial direction together with a plunger; an elastic member for providing an elastic force to the armature; a magnet core accommodating the seat therein and providing a driving force to the armature in a direction opposite to the elastic force of the elastic member; a seal stopper coupled to a lower side of the magnet core so as to communicate with the orifice and having a slot on an outer circumferential surface thereof to allow the flow of a fluid through the slot; an outlet filter forming an outer flow passage with the seal stopper; an inlet filter coupled to a lower side of the seal stopper; a lip seal fitted between the seal stopper and the inlet filter and having an inclined protruding portion to allow only one-way flow of the fluid; an orifice flow passage opened and closed by the up and down movement of the armature; and a one-way flow passage formed to include a mesh portion of the outlet filter, a gap formed between a modulator block and the lip seal due to a deformation of the lip seal, and a mesh portion of the inlet filter, wherein the inlet filter includes a protruding portion inclined outwardly so as to have a chamber therein, and the lip seal is provided so that the inside thereof can be inserted into the chamber.

A braking control module includes a housing with at least one fluid line disposed within the housing. First and second inlet ports are each in communication with the fluid line or electronic input. Additionally, a linear actuator is in fluidic communication with the fluid line for controlling pressure in the at least one fluid line. A processor controls operation of the linear actuator. The braking control module further includes at least one outlet port in fluidic communication with the fluid line and connectable to a brake. The braking system also includes a tandem, single or electronic master cylinder having a first bore defining a first volume and an optional second bore defining a second volume. First and second pistons are connectable to a brake pedal and in connection with the first inlet port and the second inlet port, respectively, or in electronic communication with the EBS unit.

A solenoid valve comprises first, second, and third ports. The solenoid valve further comprises an armature movable between a first position in which fluid flow from the second port to the third port is blocked and fluid flow from the first port to the third port is unblocked and a second position in which fluid flow from the second port to the third port is unblocked and fluid flow from the first port to the third port is blocked. The fluid flow in the second position is blocked until fluid pressure at the first port exceeds fluid pressure at the third port by a predetermined amount to thereby provide check valve functionality. The check valve functionality is integral to the armature. The solenoid valve also comprises an energizeable solenoid that, when energized, moves the armature from the first position to the second position.

A valve device, in particular solenoid valve device, having at least one throughflow region (12), having at least one valve seat (14) and having an actuating unit (16) which has at least one valve body (18), at least an actuating element (20) provided for transmitting an actuation force to the valve body (18), and at least one first ventilation opening (24) arranged outside a fluid contact region (22) of the actuating element (20). The actuating unit (16) has at least one second ventilation opening (26, 28) arranged outside the fluid contact region (22) of the actuating element (20).