A powder jet pump that is effective for creating a smoothly flowing gas stream with well dispersed particles.

A powder jet pump that is effective for creating a smoothly flowing gas stream with well dispersed particles.

A vacuum cup assembly has a vacuum device with a vacuum passageway and a venturi. A vacuum cup is configured to engage an object. The venturi generates an at least partial vacuum at the vacuum cup when the vacuum cup is engaged with an object. The vacuum cup seals against the object when the venturi device generates the at least partial vacuum. A noise reducing device is at a discharge of the venturi. The noise reducing device has a housing defining a chamber, a plurality of spaced exit openings and a movable cap. Air discharged at the venturi is diverted in the chamber and flows out through the exit openings. The movable cap covers the exit opening to override the vacuum to enable the vacuum cup to be positioned or repositioned on the object.

A vacuum cup assembly has a vacuum device with a vacuum passageway and a venturi. A vacuum cup is configured to engage an object. The venturi generates an at least partial vacuum at the vacuum cup when the vacuum cup is engaged with an object. The vacuum cup seals against the object when the venturi device generates the at least partial vacuum. A noise reducing device is at a discharge of the venturi. The noise reducing device has a housing defining a chamber, a plurality of spaced exit openings and a movable cap. Air discharged at the venturi is diverted in the chamber and flows out through the exit openings. The movable cap covers the exit opening to override the vacuum to enable the vacuum cup to be positioned or repositioned on the object.

A three-port turbo purge module, including a housing having a cavity, and two check valves. During a first mode of operation, the first check valve is open and the second check valve is closed by vacuum pressure generated in an intake manifold, such that purge vapor flows from an inlet port into the cavity, through the first check valve, and into a first port. During a second mode of operation, where the intake manifold is operating under positive pressure, the first check valve is closed such that pressurized air flowing into the first port is accelerated through a venturi device disposed in the cavity, and the second check valve is open such that purge vapor flows from the inlet port into the cavity, through the venturi device and mixes with the high-velocity air, through the second check valve into the second port.

A multifunctional air extraction boosting pump includes an upper cover, two positioning rings mounted in the upper cover, a control valve mounted in the upper cover, an air inlet pipe connected with the upper cover, and a container connected with the upper cover. One of the positioning rings is initially mounted in the upper cover. Then, the control valve is mounted in the upper cover. Then, the other one of the positioning rings is mounted in the upper cover. Then, the air inlet pipe is mounted on the upper cover. Thus, the air extraction boosting pump is assembled easily and conveniently.

A multifunctional air extraction boosting pump includes an upper cover, two positioning rings mounted in the upper cover, a control valve mounted in the upper cover, an air inlet pipe connected with the upper cover, and a container connected with the upper cover. One of the positioning rings is initially mounted in the upper cover. Then, the control valve is mounted in the upper cover. Then, the other one of the positioning rings is mounted in the upper cover. Then, the air inlet pipe is mounted on the upper cover. Thus, the air extraction boosting pump is assembled easily and conveniently.

An aspirator system for inflating an inflatable evacuation device includes an aspirator body having a plurality of flapper doors configured to open to allow intake of atmospheric gas. The aspirator system also includes an aspirator barrel connecting the aspirator body to the inflatable evacuation device, having connected inflation chambers wrapping around a circumference of the aspirator barrel and arranged along a length of the aspirator barrel, and being configured to provide an aspirator barrel chamber for guiding the atmospheric gas to the inflatable evacuation device when the aspirator barrel is inflated. The aspirator system also includes a showerhead nozzle connected to the connected inflation chambers, configured to direct high-pressure gas to inflate the aspirator barrel and compel intake of atmospheric gas through the plurality of flapper doors, to inflate the inflatable evacuation device.

An aspirator system for inflating an inflatable evacuation device includes an aspirator body having a plurality of flapper doors configured to open to allow intake of atmospheric gas. The aspirator system also includes an aspirator barrel connecting the aspirator body to the inflatable evacuation device, having connected inflation chambers wrapping around a circumference of the aspirator barrel and arranged along a length of the aspirator barrel, and being configured to provide an aspirator barrel chamber for guiding the atmospheric gas to the inflatable evacuation device when the aspirator barrel is inflated. The aspirator system also includes a showerhead nozzle connected to the connected inflation chambers, configured to direct high-pressure gas to inflate the aspirator barrel and compel intake of atmospheric gas through the plurality of flapper doors, to inflate the inflatable evacuation device.

The invention relates to a metering valve (1) for controlling a gaseous medium, particularly hydrogen, comprising a valve housing (2), wherein an interior space (3) is formed in said valve housing (2). A movable closing element (10) is arranged in the interior space (3) along a longindinal axis (40) of the metering valve (1), and said element interacts with a valve seat (19) in order to open or close off an opening cross-section of an inflow region (28) into a through channel (18). Furthermore, the metering valve (1) comprisies a nozzle (15) in which the through channel (18) is formed and on which at least one sealing element (54) is arranged, wherein the sealing element (54) is designed to seal a gap (56) in an opening in which said nozzle (15) is received.