A fluid pump includes a fluid pump inlet and a fluid pump outlet. A motor includes an armature and a stator such that the armature rotates about an axis. A pump section includes a pump section having a pumping element coupled to the armature such that rotation of the armature rotates the pumping element such that the pumping element pumps fluid from the fluid inlet to a pump section outlet of the pump section. A fluid passage within the fluid pump provides fluid communication from the pump section outlet to the fluid pump outlet such that the armature in part defines the fluid passage. The armature includes blades arranged in a polar array centered about the axis such that each of the blades extends in a helix about the axis and such that the blades define chambers. The chambers are in constant fluid communication with the pump section outlet.

A combined pump and motor has a stator mounted for non-rotation in a housing. The stator has windings that create an electromagnetic field in the stator cavity when powered. An upper diffuser and a lower diffuser are mounted for non-rotation in the stator cavity. Annular clearances exist between the upper diffuser and the inner diameter of the stator and between the lower diffuser and the inner diameter of the stator. An impeller between the lower diffuser and the upper diffuser has an array of magnets circumferentially mounted around the impeller that impart rotation to the impeller in response to the electromagnetic field in the stator cavity. The array of magnets has at least one end portion extending into one of the upper and lower diffuser annular clearances.

Embodiments of pumps are disclosed along with systems and methods relating thereto. In an embodiment, the pump includes a casing assembly that includes a central axis, an upstream connector that is configured to engage with a first connector on a fluid line, and a downstream connector that is configured to engage with a second connector on the fluid line. In addition, the pump includes an impeller rotatably disposed within the casing assembly. Further, the pump includes a driver assembly coupled to the casing assembly and annularly disposed about the impeller. The driver assembly is configured to rotate the impeller about the central axis.

The present invention is a system and method for pumping a fluid using a high-speed, fluid evacuating pump in which the pump is operated by a battery powered hand drill, wherein a first embodiment of a pump design includes a cylindrical draw tube with the intake placed at the bottom and an outlet disposed near the top, a gear assembly attached to the top of the pump to achieve proper impeller speeds required to reach the targeted fluid pumping volume, a driveshaft connected to the gear assembly to drive the impeller placed near the intake of the pump, seals and other components placed inside the pump to support the driveshaft, to direct flow, and to increase outlet pressure, and to keep fluid and particulate matter out of the driveshaft support bearings and a filtering mesh having a large amount of screen area attached to the inlet portion of the pump, thereby blocking larger debris from entering the pump and causing damage to the internal components.

A combined well pump and motor includes a housing having an axis, an upstream end and a downstream end. Diffusers are mounted for non-rotation in the housing, each of the diffusers having diffuser passages. An impeller is mounted between each of the diffusers for rotation relative to the impellers. Each of the impellers has impeller vanes defining impeller passages. The impeller has an exterior outer wall extending circumferentially around the impeller vanes, closing outer sides of each of the impeller passages. An array of magnets is mounted to each of the impellers. The magnets are spaced circumferentially apart from each other around the axis at a different radial distance from the axis than the impeller vanes. A stator is mounted in the housing. The stator has windings for interacting with the magnets to impart rotation to the impellers.

A pump in which an electric motor which is connected to a rotor provided with at least one pump vane is integrated into a pump casing. The electric motor is a ring motor surrounding at least a portion of a fluid flow path through the pump. A stator is arranged internally in an intermediate section of the pump casing and surrounds the rotor. The rotor, which is supported in the pump casing, is cylinder-shaped and forms an intermediate portion of the fluid flow path, and the at least one pump vane is attached internally in the rotor.

A top side-less pump system for managing multiphase fluid includes a pump subsystem having a suction and a discharge. A first gas liquid extraction unit has a multiphase fluid inlet and a liquid outlet. The liquid outlet is coupled to the suction for providing a liquid rich fluid to the bearing lubrications. An ejector is coupled to a gas outlet of the main gas liquid extraction unit to receive a gas rich fluid. A second gas liquid extraction unit is coupled to an outlet of the ejector. A water based lubrication liquid unit is coupled to the inlets of the pump and, after being energized at higher to pressure, injected into the bearings through built in lubrication and cooling passages.

A fluid processing machine that includes a stator capable of generating an electromagnetic field and a first rotor section having at least one impeller and at least one permanent magnet. The stator is configured to electromagnetically engage with the first rotor section so as to rotate the first rotor section about a central axis in a first rotational direction. Further rotor sections can also be included that are induced to rotate in the first rotational direction. Other rotator sections with impellers and permanent magnets can also be included that are driven in a second, contra-rotating, direction by a second stator. Several of the fluid processing machine can be distributed within a surface system or subsea system that transports produced fluid from wells to a surface facility.

A pump includes an armature, a rotor assembly, a liquid path connector and a member. The armature includes a ferromagnetic core, a winding and a through passageway. The rotor assembly is disposed in the passageway and includes an impeller to rotate to pump liquid through the passageway. The liquid path connector is connected to the armature to communicate the liquid with the passageway. The member contacts an outer surface of the armature and contacts an outer surface of the liquid path connector to transfer thermal energy from the armature to the liquid path connector.

A pump includes an armature, a rotor assembly, a liquid path connector and a member. The armature includes a ferromagnetic core, a winding and a through passageway. The rotor assembly is disposed in the passageway and includes an impeller to rotate to pump liquid through the passageway. The liquid path connector is connected to the armature to communicate the liquid with the passageway. The member contacts an outer surface of the armature and contacts an outer surface of the liquid path connector to transfer thermal energy from the armature to the liquid path connector.