A valve cartridge for a magnet valve has a capsule, an armature movable within the capsule, a valve insert, and a valve body. One end of the valve insert inserted into the capsule, and a valve seat of the valve body inserted into a second end of the valve insert. The armature moves a plunger within the valve insert. The plunger has a base body and a closing body. A closing element of the closing body sealingly plunges into the valve seat. The base body includes an equalization groove, which enables volume equalization between a sealing region and an armature chamber. The plunger has a closed cylindrical outer contour on the end thereof facing the armature, which forms a radial guide of the plunger in the valve insert, and an axial recess, which overlaps with the equalization groove and is connected to the armature chamber via a radial recess.

A solenoid valve includes a magnet assembly, a valve cartridge having a pole core, a valve sleeve connected to the pole core, an armature, a valve body, and at least one spring tongue. The armature is guided in an axially movable manner within the valve sleeve and is coupled to a closing element. The magnet assembly generates a magnetic field via energization of a coil winding. The magnetic field is configured to move the armature counter to a force of a restoring spring. The valve body is positioned within the valve sleeve. A main valve seat of the valve body forms a main valve with the closing element that sets a fluid flow between at least one first fluid opening and at least one second fluid opening. The spring tongue is arranged on the valve sleeve and forms a positively locking connection between the valve sleeve and the valve body.

A solenoid valve includes a magnet assembly, a valve cartridge having a pole core, a valve sleeve connected to the pole core, an armature, and a valve body. The armature is guided in an axially movable manner within the valve sleeve and is coupled to a closing element. The magnet assembly generates a magnetic field via energizing a coil winding. The magnetic field moves the armature counter to a force of a spring. The valve body is positioned within the valve sleeve. A valve seat of the valve body forms a main valve with the closing element that sets a fluid flow between at least one first fluid opening and at least one second fluid opening. A positive connection between the valve sleeve and the valve body is formed to prevent movement of the valve body introduced into the valve sleeve counter to a direction of introduction.

A movable core includes an iron core formed into a plate having a substantially rectangular section, and a valve support portion continuous with the iron core. The valve support portion includes a pair of support arms. The pair of support arms are arranged side by side in a width direction of the movable core to be parallel to each other and seamlessly integrated with the iron core. A surface of the movable core on one side in a thickness direction and a surface of the movable core on the other side are single flat surfaces parallel to each other and extending continuously from the iron core to the pair of support arms. A valve disk is supported between the pair of support arms.

The disclosure relates to an apparatus and a method for driving a solenoid valve. The apparatus comprises a PWM apparatus, an evaluation and control unit, and a current measuring apparatus The evaluation and control unit is configured to: in a test operation, generate and emit test PWM signals having test duty ratios, the test PWM signals inducing test currents through a magnet assembly of the solenoid valve that are below a response threshold that triggers a switching process of the solenoid valve; derive presently prevailing ambient conditions of the test operation from the test PWM signals and the induced test currents; and in a normal operation generate and emit a PWM signal based on the presently prevailing ambient conditions of the test operation, the PWM signal inducing a current that is above the response threshold and switches the solenoid valve.

An integrated solenoid valve and a brake system using the same are disclosed. The integrated solenoid valve includes an armature, an elastic member, a magnet core, an orifice unit, a filter member, a lip seal, a bidirectional passage, and a unidirectional passage. The armature is disposed in a sleeve, moves upward and downward in an axial direction, and opens or closes an orifice of a seat disposed at a lower side thereof. The elastic member provides elastic force to the armature in a closing direction of the orifice. The magnet core provides drive force to the armature in a direction opposite to that of the elastic member. The orifice unit is coupled to a lower side of the seat, and includes not only a hollow hole communicating with the orifice of the seat but also a passage hole. The filter member prevents inflow of foreign materials. The lip seal is inserted between the orifice unit and the filter member, and includes an inclined protrusion. The bidirectional passage is opened or closed by the armature moving up and down. The unidirectional passage is formed to pass through the passage hole and an outer surface of the inclined protrusion.

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.

An electronic control brake system for a vehicle, comprising: a pressure sensor connected to an electronic control device for electrically controlling a brake hydraulic pressure and sensing the brake hydraulic pressure generated in a master cylinder, the electronic control device includes a PCB separated from the pressure sensor, and an elastic connecting body of a conductive material provided on the PCB, the pressure sensor includes a sensor housing, a sensing portion provided inside the sensor housing for sensing the brake hydraulic pressure, and a lead portion of inelastic and conductive material and having a first end electrically connected to the sensing portion while passing through the sensor housing and a second end exposed to the outside and electrically connected to the electronic control device.

A solenoid valve for brake system includes a valve housing installed in a modulator block, and having an oil flow path; a valve seat installed in the inside of the valve housing, and forming an orifice; an armature configured to move up and down by a magnet core in the valve housing, and to open or close the orifice; a sleeve coupled with the valve housing, and accommodating the armature therein; a restoring spring configured to provide an elastic restoring force to the armature to close the orifice normally; and a damper member interposed between the magnet core and the armature.

A solenoid valve for a brake system to control a flow rate of a flow path connecting a first port with a second port includes: an armature disposed inside a sleeve and configured to vertically move in an axial direction together with a plunger to open or close an orifice of a seat; an elastic member providing an elastic force to the armature; a magnetic core configured to accommodate the seat therein and provide a driving force in a direction opposite to the elastic member; an outer filter coupled to a lower side of the seat; an inlet filter coupled to a lower side of the outlet filter; and a lip seal interposed between the outlet filter and the inlet filter and including an inclined protrusion to allow a unidirectional flow of a fluid, wherein the solenoid valve has a flow path opened or closed by vertical movement of the armature and a unidirectional flow path via the lip seal.