An electromagnetic valve includes a mover that is able to move in a predetermined direction. The mover includes a valve body part including a valve body base part and an annular elastic body. The valve body base part includes a large diameter part and a small diameter part connected via a step difference. The annular elastic body includes a first contact surface, a second contact surface in contact with a step difference surface in the step difference, and a sealing projecting part that is able to come into contact with a peripheral edge part of an opening part of a first flow path in the predetermined direction. The sealing projecting part surrounds the opening part when seen in the predetermined direction. The sealing projecting part, the second contact surface, and the step difference surface are at least partially superimposed on each other when seen in the predetermined direction.

An electromagnetic valve includes a mover that is able to move in a predetermined direction. The mover includes a valve body part including a valve body base part and an annular elastic body. The valve body base part includes a large diameter part and a small diameter part connected via a step difference. The annular elastic body includes a first contact surface, a second contact surface in contact with a step difference surface in the step difference, and a sealing projecting part that is able to come into contact with a peripheral edge part of an opening part of a first flow path in the predetermined direction. The sealing projecting part surrounds the opening part when seen in the predetermined direction. The sealing projecting part, the second contact surface, and the step difference surface are at least partially superimposed on each other when seen in the predetermined direction.

A valve assembly, comprising a first fluid port, a second fluid port, a valve seat comprising an inner valve seat and an outer valve seat, and a moveable plunger, being moveable between a closed position and an open position arranged to simultaneously seal the inner valve seat and the outer valve seat when in the closed position. A first fluid pathway passes via the inner valve seat, and a second fluid pathway passes via the outer valve seat between the first and second fluid ports when the movable plunger is in the open position. At least one fluid flow path is provided through the body of the moveable plunger. The cross-sectional area of the flow path through the moveable plunger is at least half of the cylindrical cross-sectional area of the gap between the plunger and the respective inner or outer valve seat.

A valve assembly, comprising a first fluid port, a second fluid port, a valve seat comprising an inner valve seat and an outer valve seat, and a moveable plunger, being moveable between a closed position and an open position arranged to simultaneously seal the inner valve seat and the outer valve seat when in the closed position. A first fluid pathway passes via the inner valve seat, and a second fluid pathway passes via the outer valve seat between the first and second fluid ports when the movable plunger is in the open position. At least one fluid flow path is provided through the body of the moveable plunger. The cross-sectional area of the flow path through the moveable plunger is at least half of the cylindrical cross-sectional area of the gap between the plunger and the respective inner or outer valve seat.

Provided are a piston valve core structure with a combination of a rigid ring surface and a flexible base surface, and a method thereof. The structure includes a piston valve core, a flexible base surface, a rigid ring surface and a connecting member; a bottom surface of the piston valve core is planar; a top surface of the flexible base surface fits to the piston valve core, and a bottom surface thereof is a ellipsoidal convex surface; the rigid ring surface is a ring body with a stepped cross-section, and is coaxially arranged under the flexible base surface; a protruding height of the flexible base surface is greater than that of the rigid ring surface; the connecting member is configured to connect respective structures. The piston valve core structure can overcome unbalanced moment on the valve core, has a simple structure, and can be widely promoted and applied.

A pressure relief valve assembly includes a carrier, a valve, and a baffle. The carrier includes a first end and a second end. The first end defines a first opening. The second end defines a second opening. The carrier defines a flow passage extending from the first opening to the second opening. The valve is supported by the carrier and is operable in an open position and a closed position. In the open position, the valve permits a flow of fluid through the first opening. In the closed position, the valve inhibits the flow of fluid through the first opening. The baffle is disposed in the flow passage. The baffle and the carrier collectively define a flowpath extending through the flow passage.

A pressure relief valve assembly includes a carrier, a valve, and a baffle. The carrier includes a first end and a second end. The first end defines a first opening. The second end defines a second opening. The carrier defines a flow passage extending from the first opening to the second opening. The valve is supported by the carrier and is operable in an open position and a closed position. In the open position, the valve permits a flow of fluid through the first opening. In the closed position, the valve inhibits the flow of fluid through the first opening. The baffle is disposed in the flow passage. The baffle and the carrier collectively define a flowpath extending through the flow passage.

A Y-globe valve assembly includes a valve body having a neck portion defining a chamber with a circumferential wall and an integrated pressure relief passageway formed in the circumferential wall and communicating between the chamber and a flow passageway downstream of a valve port. A valve includes a core having an outer surface spaced radially inwardly from the circumferential wall of the valve body so as to define an annular space therebetween. The pressure relief passageway is in fluid communication between the annular space and the flow passageway upstream of the valve port when the valve is in at least the open position.

A Y-globe valve assembly includes a valve body having a neck portion defining a chamber with a circumferential wall and an integrated pressure relief passageway formed in the circumferential wall and communicating between the chamber and a flow passageway downstream of a valve port. A valve includes a core having an outer surface spaced radially inwardly from the circumferential wall of the valve body so as to define an annular space therebetween. The pressure relief passageway is in fluid communication between the annular space and the flow passageway upstream of the valve port when the valve is in at least the open position.

A buffer valve is installed on a pneumatic diaphragm valve. An inner flow channel of the buffer valve includes an inner micro gas hole, an inner chamber, an outer gas hole, and a floating ball. The buffer valve has functions with a high-filling action, a shielding action, a releasing action, a shielding time Δt, and an adjusting mechanism. When inflatable, the floating ball will not block the inner micro hole to be quickly filled with high-pressure gas. when gas discharge, the floating ball will move to the outer gas hole with the gas flow and produce the shielding action to reduce the discharge rate to reduce the vibration and slow down the approach speed of the diaphragm to reduce the impact against the valve seat. When the pressure of the gas decreases, the floating ball is separated from the outer gas hole by the releasing action to accelerate the discharge.