An electrically actuated valve is provided. The electrically actuated valve includes a valve housing comprising a valve chamber and a first and second port in fluidic communication with the valve chamber. The electrically actuated valve further comprises a valve sealing component including a cap sealing section adjacent to an opening in the valve housing and a valve seat arranged within the valve chamber between the first port and the second port and a plunger configured to couple to a solenoid piston and including a proximal seal configured to selectively sealingly interface with the valve seat.

The present disclosure provides a heat exchanger system for a servovalve, comprising a base comprising a supply port in fluid communication with a return port, a first passage for fluid connection to a source of cooling fluid, and a second passage in fluid communication with the return port. The system further comprises one or more pipes located over a surface of the base, the one or more pipes fluidly connected between the first passage and the second passage, such that in use cooling fluid may flow from the first passage to the second passage via the network of pipes.

The solenoid valve (10) has a poppet valve (41) which is operated to move between a position to close a port and a position to open the port. A fixed iron core (50) having a supporting leg (52) and a driving leg (51) is installed in a valve housing (11), and a movable iron core (60) which drives the poppet valve (41) is disposed between a valve driving member (42) and the fixed iron core (50). An arcuate sliding contact surface (61) is provided on one end portion of the movable iron core (60), and a sliding-abutting surface (62) which abuts on the sliding contact surface (61) is provided on a leading end portion of the supporting leg (52). When a coil (56) is de-energized, the sliding-contacting surface (61) is pressed onto the sliding-abutting surface (62) by a flat spring (70), with an abutting portion of the valve driving member (42) serving as a fulcrum of a tensile force applied to the movable iron core (60).

A solenoid valve (10) has a valve housing (11); one end portion of the valve housing (11) is provided with a flow passage portion (16) having ports and a valve element housing hole to store a poppet valve (41), and the other end portion of the valve housing (11) is opened. Parts, such as a fixed iron core (50) having a supporting leg (52) and a driving leg (51), and a movable iron core (60) which drives the poppet valve (41) is inserted from an opening end (17) on the other end portion of the valve housing (11). All parts to be inserted into the valve housing (11) are inserted from one direction.

A solenoid valve (10) has a U-shaped fixed iron core (50) with a driving leg (51), a supporting leg (52), and a yoke portion (53) integrally formed. One end portion of a movable iron core (60) which drives a poppet valve (41) abuts on the supporting leg (52), and the other end portion of the movable iron core (60) abuts on the driving leg (51). A sealing member (81) is disposed between and a valve housing (11) and a fixed flange (58) of a bobbin (54) attached to the fixed iron core (50). A sealing member (83) is disposed between an abutting flange (57) of the bobbin (54) and the yoke portion (53).

An example system includes a valve assembly having: (i) a plurality of ports including an inlet port, an outlet port, and a vent port, (ii) a solenoid coil having a cavity therein, (iii) an armature slidably accommodated in the cavity of the solenoid coil, (iv) a magnet fixedly disposed within the solenoid coil, wherein the magnet applies a magnetic force on the armature in a distal direction, and (v) a spring applying a biasing force on the armature in a proximal direction; and a controller sending a signal having a particular polarity to the solenoid coil such that the signal is applied to the solenoid coil for a particular period of time, and resending the signal periodically every particular time interval.

The present invention relates to a valve assembly, comprising a valve chamber, accesses to the valve chamber, the accesses including a first access and a second access, and a movable sealing body assembly comprising at least one sealing portion, wherein at least a portion of the sealing body assembly is magnetic, and wherein at least a portion of the sealing body assembly comprising the at least one sealing portion is located within the valve chamber. Further, the valve assembly comprises at least one sealing surface, wherein each of the at least one sealing surface is configured to complement one of the at least one sealing portion, and wherein each sealing surface comprises an orifice fluidly connected to one of the accesses. The valve assembly further comprises a force unit configured to exert a magnetic force on the magnetic portion of the movable sealing body assembly and is configured to assume at least two configurations, wherein in a first configuration, the first access is sealed, and wherein in a second configuration, the first access is fluidly connected to the second access. Further, the present invention relates to a pump system, as well as a use and manufacturing method of a valve assembly according got the present invention.

A diagnostic method for diagnosing a malfunction of a solenoid valve includes: a) storing reference features of a solenoid current waveform, b) detecting features of the solenoid current waveform during operation of the solenoid valve, c) comparing the reference features with the detected features, d) comparing the pressure value of fluid entering the solenoid valve inlet orifice with a predetermined range of pressure values in the event of deviation between the value of the detected features and the value of the reference features, e) adjusting the pressure value and repeating steps b) and c) in the case of deviation of the pressure value with respect to the pressure value range, and f) generating an alarm signal due to malfunction of the solenoid valve in the event of a deviation between the value of the detected features and the value of the reference and fluid pressure features within the pressure value range.

A nozzle of or for a servo valve comprises a nozzle element having a fluid outlet at a first axial end and a tubular body extending from the first end to an opposed, second axial end. The nozzle further comprises a plug element mounted in and closing the second axial end of the tubular body, thereby defining an internal cavity within the tubular body. One or more openings are formed through the tubular body to fluidly communicate with the internal cavity. A filter may be mounted across the internal cavity at a position axially intermediate the openings and the fluid outlet.

A solenoid valve device for a pressure-compensated solenoid valve, in particular a pressure-compensating solenoid valve device, has a magnet part including at least one magnetic coil winding and preferably at least one magnetic core arranged at least partially in an interior of the magnetic coil winding, and has a valve part including at least one tappet unit, which is at least configured to control at least one flow-through path through the solenoid valve and which is at least configured to interact with a magnetic field generated within the magnet part, at least for a generation of at least one movement of the tappet unit, wherein the magnet part and the valve part form separable, independently functional modules which are in particular free of shared functional components, such as a shared magnet armature.