Variable conductance gas distribution systems, reactors and systems including the variable conductance gas distribution systems, and methods of using the variable conductance gas distribution systems, reactors, and systems are disclosed. The variable conductance gas distribution systems allow rapid manipulation of gas-flow conductance through the gas distribution system.

Variable conductance gas distribution systems, reactors and systems including the variable conductance gas distribution systems, and methods of using the variable conductance gas distribution systems, reactors, and systems are disclosed. The variable conductance gas distribution systems allow rapid manipulation of gas-flow conductance through the gas distribution system.

A piston for dual-directional hand inflator comprises a main body (1) having an internal hole (11) and an external hole (12). A plurality of spacers (17) are disposed between the top surface and the bottom surface of the main body (1) and divide a space into a gas-intake guide chamber (3) and a gas-exhaust guide chamber (5). The gas-intake guide chamber (3) communicates with the internal hole (11), and the gas-exhaust guide chamber (5) communicates with the external hole (12). A first cover plate (6) is disposed at an end of the gas-intake guide chamber to seal the gas-intake guide chamber. A second cover plate (7) is disposed at an end of the gas-exhaust guide chamber to seal the gas-exhaust guide chamber. There is only two cover plate to be adhered and fixed. The assembly is more convenient and the leakage probability is reduced.

A fluid pump apparatus for an artificial lift system has a barrel, a standing valve positioned at a lower end of the barrel, a plunger reciprocatingly mounted within the barrel, and a traveling valve positioned in an interior of the plunger so as to control fluid flow through the plunger. The barrel has an opening at a top thereof and an opening at a lower end thereof. The standing valve is movable between an open position and a closed position. The plunger has a first aperture at an upper portion of the plunger and a second aperture extending through a wall of the plunger so as to open to a channel extending longitudinally through the plunger. The traveling valve has a head portion of the body extending downwardly from the head portion. The body is slidably movable within an interior of the plunger. The body has a fluid-passing channel therein that opens to an exterior of the body.

Provided are apparatus and systems having a poppet valve assembly and swing adsorption separation techniques related thereto. A poppet valve includes a valve body, a plurality of static valves fixedly secured to the valve body and a single dynamic poppet valve having a plurality of openings. The plurality of static valves align and mate with the plurality of openings. The single dynamic poppet valve reciprocates to selectively open and close the plurality of static valves.

Systems, methods, and devices are disclosed, including a compressor having a piston and a valve assembly. In some embodiments, the valve assembly includes a check valve having a valve member, a magnet coupled to the valve member, and an electrical conductor near the magnet. The check valve may be configured to change state in response to a change in fluid pressure. The compressor may also have an electric device coupled to the electrical conductor.

An autolift-resistant piston assembly is provided for an air compressor. The piston assembly comprises an unloader piston having an interior chamber. The piston assembly further comprises a first coil spring for biasing the unloader piston to a loaded position when the piston assembly is installed in the air compressor. The piston assembly also comprises an inner member disposed in the interior chamber of the unloader piston and including (i) a body portion, and (ii) a tapered end portion extending from the body portion and facing an unloader air passage of the air compressor when the piston assembly is installed in the air compressor.

A reciprocating compressor having: a suction valve; a discharge valve; and a working chamber; wherein the suction valve is configured to provide fluid communication between a suction channel and the working chamber and the discharge valve is configured to provide fluid communication between the working chamber and a discharge channel; wherein the suction valve has at least one non-self-actuated valve and the discharge valve has at least one self-actuated check valve.

An improved inlet valve system for a cylinder chamber of a reciprocating compressor and a method for utilizing a high pressure gas source to control an inlet valve system for a cylinder chamber of a reciprocating compressor is disclosed. The inlet valve system may include an unloader, a valve assembly including a cylindrical valve body circumferentially disposed about a central axis of the inlet valve system, and a control valve actuator including a control valve body. The valve assembly may include a plurality of inlet valve elements disposed respectively in valve element ports fluidly connected to a control valve passage. A high pressure gas source is utilized to hold open and close the inlet valve elements via the control valve passage in order to control the capacity of the reciprocating compressor.

The present invention relates to a check valve unit (1, 100, 200, 300, 400) having a shaft bearing body (10, 110, 210, 310, 410) with an at least substantially cylindrical mounting portion (11) extending along an axial direction (A) and an axially extending valve shaft (20, 120) mounted therein. The latter is displaceable along the axial direction (A). The check valve unit (1, 100, 200, 300, 400) further includes a valve head (25, 125) with a sealing surface (33, 133), wherein the valve head (25, 125) is disposed on a distal end (21) of the valve shaft (20, 120) in the axial direction (A), the distal end (21) facing away from the mounting portion (11). Further, a damping reservoir (50) is provided inside the shaft bearing body (10, 110, 210, 310, 410). A volume of the damping reservoir (50) is changed by axial movement of the valve shaft (20, 120). In order to obtain a well-defined times for opening and closing under given conditions and to make the check valve unit (1, 100, 200, 300, 400) less prone to making noise, at least two channels (46a, 46b) are provided in parallel, each of them constituting a fluid connection between the damping reservoir (50) and an outside (70). The damping reservoir (50) is, apart from the channels (46a, 46b), at least substantially enclosed. Each channel (46a, 46b) has a length being at least ten times a hydraulic diameter of the respective channel (46a, 46b).