A pump for pumping a multiphase fluid includes a housing and a rotor with an outer surface. A plurality of inducer vanes are attached to the rotor hub, each having a leading edge and a trailing edge where the leading edge of one inducer vane overlaps the trailing edge of an adjacent inducer vane by a first overlap angle. A plurality of impeller vanes are also attached to the hub. The impeller vanes each have a leading edge and a trailing edge where the leading edge of one impeller vane overlaps the trailing edge of an adjacent impeller vane by a second overlap angle larger than the first overlap angle. The pump includes a rotor flow channel extending between the hub outer surface and the housing inner surface. The rotor flow channel has an inlet area and an outlet area, whereby the outlet area is smaller than the inlet area.

Propeller pump for pumping liquid, including: an axially extending tubular pump housing having an inner surface, an axially extending pump core having an envelope surface, at least one axial portion of the pump core enclosed in the pump housing. The pump core includes a propeller having a hub and at least one blade, and at least one guide vane that includes an upstream leading edge and a downstream trailing edge, and that in the circumferential direction includes a pressure side and a suction side. The guide vane extends between the inner surface of the pump housing and the envelope surface of the pump core. At the leading edge of the guide vane a connection angle between the suction side of the guide vane and the envelope surface of the pump core is larger than 90 degrees.

A centrifugal fluid machine includes an impeller (4) that has a front shroud (41) arranged on one side in an axial direction, a rear shroud (42) arranged on the other side in the axial direction, and a plurality of blades (43) provided side by side in a circumferential direction between the front shroud and the rear shroud and is rotatably supported within a casing (2); a suction passage (2A) that allows a fluid to be sucked therethrough in the axial direction toward the impeller with the rotation of the impeller; a discharge passage (2B) that allows a fluid delivered under pressure by the impeller with the rotation of the impeller to be discharged in a direction intersecting the axial direction of the impeller; and a first flow path (5A) that communicates with the discharge passage, leads to the suction passage through a gap between the casing and the rear shroud, and an opening (5Aa) that opens toward the downstream side of the suction passage in a suction direction of a fluid. The opening area of the opening is set so that the ejection speed (Vs) of a fluid ejected from the opening to the suction passage is matched with the suction speed (V) of a fluid sucked into the suction passage.

A subsea fluid pressure-increasing machine includes an elongated member that is rotatable about a longitudinal axis. The machine also may include a plurality of impellers each having a leading edge, a trailing edge, a suction side, and a chord line defined by a line between the leading and trailing edges. Each impeller is fixedly mounted to the member such that a chord angle defined by an angle between the chord line and the rotation direction is less than or equal to a stall angle at which a maximum force is exerted on a fluid in a direction primarily parallel to the longitudinal axis when the member is rotated in the rotation direction. At least some of the impellers comprise one or more features that effectively reduce a pressure peak or specific loading of the suction side such that the axial length of the impeller is configured to be reduced without exceeding a desired specific load.

A cleaning system used for vehicles and capable of suppressing vibrations and reducing noise is disclosed. The cleaning system includes a cleaning liquid tank provided with an upward liquid outlet and a limiting plate opposite the liquid outlet; an engagement slot is provided in the limiting plate; a sealing hole is provided in the center of a sealing ring, and the sealing ring is fixed to the liquid outlet; a liquid intake nozzle is arranged at one end of a cleaning pump and inserted into the sealing hole of the sealing ring; an end face of the cleaning pump abuts against a surface of the sealing ring to axially position the cleaning pump; an elastic positioning sleeve is fixed to an elastic positioning member and a plurality of vibration suppression holes are provided at intervals in the elastic positioning sleeve.

A cleaning system used for vehicles and capable of suppressing vibrations and reducing noise is disclosed. The cleaning system includes a cleaning liquid tank provided with an upward liquid outlet and a limiting plate opposite the liquid outlet; an engagement slot is provided in the limiting plate; a sealing hole is provided in the center of a sealing ring, and the sealing ring is fixed to the liquid outlet; a liquid intake nozzle is arranged at one end of a cleaning pump and inserted into the sealing hole of the sealing ring; an end face of the cleaning pump abuts against a surface of the sealing ring to axially position the cleaning pump; an elastic positioning sleeve is fixed to an elastic positioning member and a plurality of vibration suppression holes are provided at intervals in the elastic positioning sleeve.