The valve includes a casing arrangeable so the fluid in the passage flows over an outer side. The valve includes a piston axially slidably positionable within the casing, and the axial position regulates the fluid pressure in the poppet valve passage downstream, an annular clearance between the piston and casing. The valve includes a dynamic seal between the piston and casing to seal the annular clearance end. The valve includes a piston chamber located on the dynamic seal opposing side of the annular clearance so a leakage flow may cross the dynamic seal between the annular clearance and piston chamber. The fluid pressure in the piston chamber varies the axial position within the casing. A diversion path formed in the casing diverts fluid for the leakage flow into the annular clearance from the fluid flow in the passage, the diversion path having filter to filter debris from the diverted fluid.

A homogenization device having an inlet valve, a flow-through chamber and a discharge valve. A baffle element reciprocatingly moves between an upstream portion and a downstream portion of the flow-through chamber. When the baffle element moves downstream, the inlet valve opens and liquid is admitted into the upstream portion. When the baffle element moves upstream, the inlet valve closes, the liquid in the upstream portion is pressurized and forced to flow downstream through a gap or local constriction between the outer perimeter of the baffle element and the inner surface of the chamber, causing cavitation bubbles to form and collapse.

A need exists for a tank regulator that can reduce a pressure of more than about 4,300 psi to a much lower pressure. The present disclosure describes a piston regulator that allows for pressure to be reduced from an inlet pressure of about 5,000 psi or more to outlet pressure of about 2,000 psi or less. The regulator includes intermediate chambers to provide step-down pressures along the piston. The internal chambers enable to hold pressure differentials between the high-pressure inlet and the low-pressure outlet. The pressure in the intermediate chambers is maintained by a pressure-limiting valve to control the pressure differentials across piston seals. These seals allow the piston to actuate while maintaining a seal between the various pressure chambers.

Provided is a valve assembly system including a flowbody including a channel formed at an inner surface thereof, a butterfly plate disposed within the channel and rotatably mounted within the flowbody. The system also includes a pair of dual-sided pistons that receive differential pressure at an input side and an output side of the valve assembly system. A spring is controlled for biasing against at least one of the dual-sided pistons based on the differential pressure, and to rotate the butterfly plate to regulate the differential pressure and the valve assembly system to a predetermined output pressure.

Apparatus for regulating gas pressure suitable for use in systems and/or networks for transport and/or distribution of gas, the apparatus configured to be connected upstream with an inlet duct for the gas and downstream with an outlet duct, and includes: a main regulator including: an inlet area fluidically connectable with the inlet, an outlet area fluidically connectable with the outlet, a shutter which acts between the inlet area and the outlet area, means configured to push the shutter towards a closed position, a motorization chamber in which a movable element is housed, a pilot regulator including: an inlet which is fluidically connected with a first sub-chamber, to thus allow the passage of gas from the first sub-chamber towards an inlet of the pilot regulator, an outlet which is fluidically connected to said second sub-chamber, and at least one pilot valve.

Blocking device for pressurized gas pipelines includes: a blocking valve, which includes: a connection body; a movable shutter; a stem carrying the shutter; a fluid-dynamic actuator, configured to translate the stem; thrust means to bring the shutter from an operating position of opening to an operating position of complete closure; a control system for controlled actuation of the fluid-dynamic actuator, having a by-pass group for equalizing upstream pressures in an upstream chamber and downstream pressures in a downstream chamber, and a pressure reducer group interconnected with the bypass group, the pressure reducer group configured to receive a motorization fluid at a supply pressure as input, and to supply the fluid-dynamic actuator with a motorization pressure through a motorization line, the control system having a pressure differential selector that detects a signal of the upstream pressure and a signal of the supply pressure.

A device for controlling the flow of a fluid through a conduit from an upstream side of the device to a downstream side of the device. The device includes an upstream valve casing defining an inlet, a downstream valve casing defining an outlet aperture, and a valve core secured between the upstream valve casing and the downstream valve casing. The upstream valve casing, the downstream valve casing and the valve core are formed as discrete parts. The valve core includes a housing defining a control volume. The valve member is mounted on the housing and positioned on the upstream side of the outlet aperture, the valve member being arranged to move reciprocally to selectively open and close the outlet aperture, thereby controlling flow of the fluid through the outlet aperture.

A pilot valve arrangement including a first and second pilot valve parts. The second pilot valve part including a second pilot valve body including a compartment, a low pressure fluid inlet for receiving fluid from the first pilot valve part, and a high pressure fluid inlet, and a fluid outlet for receiving fluid from the low pressure and high pressure inlets via said compartment and providing fluid to a piloted valve. In a first state, the second pilot valve of the pilot valve arrangement provides for a first fluid flow path within the compartment to enable the low pressure fluid inlet to be in fluid communication with the fluid outlet via the first fluid flow path. In a second state, a second fluid flow path within the compartment to enable the high pressure fluid inlet to be in fluid communication with the fluid outlet via the second fluid flow path.

A pressure reduction valve includes: a housing; an inlet and an outlet provided in the housing; a piston movable in the housing; a rod extending from the piston toward the inlet; a rod sliding part where the rod slides in the housing; a valve element provided in the rod; a valve seat to be seated with the valve element; a valve chamber formed around the valve element downstream the valve seat; a pressure control chamber provided between the piston and the housing downstream of the piston to communicate with the outlet; a passage formed in the rod and the piston; a spring to urge the piston and the rod to separate the valve element from the valve seat; and a sealing member provided in the rod sliding part. A wear ring is provided upstream of the seal member to narrow a clearance between the rod sliding part and the housing.

The present invention relates to pressure stabilizing mechanism and to a hydraulic pump including the pressure stabilizing mechanism. The pressure stabilizing mechanism comprises a frame, a piston and a first and second seals. The frame defines a piston chamber, a lower-pressure circuit and a higher-pressure inlet. The piston chamber has a first section of smaller circumference and a second section of larger circumference. The first section of the piston chamber connects the lower-pressure circuit and the higher-pressure inlet. The lower-pressure circuit further connects with the second section of the piston chamber. The lower-pressure circuit receives a fluid at a lower pressure and the higher-pressure inlet receives the fluid at a higher pressure. The piston is slidably movable in the piston chamber between an open position and a closed position. The piston slidably moves between the closed and open position upon relative variation between the lower-pressure fluid and larger surface in the second chamber with respect to the higher-pressure fluid and smaller surface in the first chamber of the piston chamber.