A flow management and separation system for a wellbore having a horizontal section, vertical section and intermediate build section, a production tubing, and an annulus surrounding the production tubing, is combined with a primary vertical lift device disposed in the intermediate build section or a heel segment of the horizontal section. The fluid flow management system may be located adjacent to and downhole from the primary vertical lift device. The system includes an intake to an intake passage, to receive produced fluids from the reservoir; a wavebreaker for calming produced fluid flow; a fluidseeker having a rotatable inlet extension having a weighted keel and an internal bypass passage in fluid communication with the intake flow passage; and a separator for separating gas and liquid phases uphole from the fluidseeker.

A fuel system for a vehicle comprising a fuel tank having a fuel tank reservoir. A lift pump is outside of the fuel tank and includes an inlet, and first and second outlets, with the inlet being configured to receive fuel from the fuel tank. The lift pump is configured to output fluid from the first outlet at a first prescribed pressure. A venturi pump is located within the fuel reservoir and defines a venturi pump reservoir. The venturi pump includes a venturi jet including a drive inlet configured to be fluidly connectable to the first outlet of the lift pump to receive fluid therefrom. A suction inlet is configured to be placeable in fluid communication with the fuel tank reservoir and to draw fluid from the fuel tank reservoir into the venturi pump reservoir in response to fluid flowing through the venturi jet at the first prescribed pressure.

A pneumatic pump is provided, the pump comprising a first pressure vessel; a second pressure vessel; a first pneumatic assembly in flowable connection with the first pressure vessel, the first pneumatic assembly comprising a first pneumatic assembly valve; a second pneumatic assembly in flowable connection with the second pressure vessel, the second pneumatic assembly comprising a second pneumatic assembly valve; a first transfer assembly in flowable connection with the first pressure vessel, the first transfer assembly comprising one or more first transfer assembly valves; a second transfer assembly in flowable connection with the second pressure vessel, the second transfer assembly comprising one or more second transfer assembly valves; and a controller for controlling the first pneumatic assembly valve, the second pneumatic assembly valve, the one or more first transfer assembly valves, and the one or more second transfer assembly valves.

A pneumatic pump is provided, the pump comprising a first pressure vessel; a second pressure vessel; a first pneumatic assembly in flowable connection with the first pressure vessel, the first pneumatic assembly comprising a first pneumatic assembly valve; a second pneumatic assembly in flowable connection with the second pressure vessel, the second pneumatic assembly comprising a second pneumatic assembly valve; a first transfer assembly in flowable connection with the first pressure vessel, the first transfer assembly comprising one or more first transfer assembly valves; a second transfer assembly in flowable connection with the second pressure vessel, the second transfer assembly comprising one or more second transfer assembly valves; and a controller for controlling the first pneumatic assembly valve, the second pneumatic assembly valve, the one or more first transfer assembly valves, and the one or more second transfer assembly valves.

A bladeless fan comprising a ring-shaped chamber extending longitudinally and defining a suctioned air passage having a main-flow inlet and a main-flow outlet; a compressed-gas inlet adapted to receive compressed gas and to provide the compressed gas to the ring-shaped chamber; and a proximal row of channels radially distributed about the suctioned air passage. The channels provide a fluid connection for the compressed gas from the ring-shaped chamber to the suctioned air passage thereby generating a pressure differential along the suctioned air passage and forcing a flow of gas from the main-flow inlet to the main-flow outlet.

A bladeless fan comprising a ring-shaped chamber extending longitudinally and defining a suctioned air passage having a main-flow inlet and a main-flow outlet; a compressed-gas inlet adapted to receive compressed gas and to provide the compressed gas to the ring-shaped chamber; and a proximal row of channels radially distributed about the suctioned air passage. The channels provide a fluid connection for the compressed gas from the ring-shaped chamber to the suctioned air passage thereby generating a pressure differential along the suctioned air passage and forcing a flow of gas from the main-flow inlet to the main-flow outlet.

An ejector includes a shaft coupled to a passage formation member defining a refrigerant passage inside a body, and the shaft is slidably supported by a support member fixed to the body. A drive mechanism moves the shaft in an axial direction to change a passage sectional area of the refrigerant passage. The passage formation member is provided with a vibration suppressive member including a first mobile end that applies a load to enlarge the refrigerant passage and a second mobile end that applies a load to narrow the refrigerant passage. Both the first mobile end and the second mobile end are disposed on a same side of a slide region of the support member in the axial direction.

An ejector and a refrigeration system. The ejector includes: a high-pressure fluid passage, a flow valve for controlling a flow rate in the high-pressure fluid passage; a suction fluid passage; a mixing chamber, which includes a mixed fluid outlet; a thermal bulb disposed upstream of the flow valve, in the high-pressure fluid passage or outside the high-pressure fluid passage; and an elastic diaphragm disposed in the high-pressure fluid passage, wherein a closed cavity is on a first side of the diaphragm, and the high-pressure fluid passage is on a second side of the diaphragm; the thermal bulb in communication with the closed cavity, and the thermal bulb and the closed cavity are filled with fluid; and the diaphragm is associated with the flow valve so that an opening degree of the flow valve varies in response to a change in a pressure difference across two sides of the diaphragm.

A conveying device for a fuel cell system for conveying and/or recirculating a gaseous medium, in particular hydrogen, includes a recirculation fan, a jet pump that is driven by a motive stream of a gaseous medium that is under pressure, and a metering valve. The gaseous medium is supplied to the jet pump by the metering valve. The conveying device further includes an inlet fluidically connected to an anode outlet of the fuel cell and an outlet fluidically connected to an anode inlet of the fuel cell. The jet pump and the metering valve form a combined valve/jet-pump assembly. The components of the conveying device are positioned on a planar carrier element such that flow lines between and/or within the components extend only parallel to the planar carrier element. The planar carrier element is arranged between the fuel cell and the conveying device.

A jet pump comprising a jet nozzle for accelerating a propellant. The jet nozzle has a convergent inlet part and an outlet part connected to the convergent inlet part. The outlet comprises an inner wall diverging at an opening angle. The opening angle is designed such that a propellant flowing through the outlet part at subsonic speed is detached from the inner wall and a propellant flowing through the outlet part at supersonic speed is guided by the inner wall. An automatic, cost-effective and simple changeover of the jet pump to different pressure ratios is hence provided.