A method and an ejection device are provided for discharging contaminants out of a seal chamber of a rotating-fluid machine driving a main flow of contaminated fluid. The ejection device incorporates an obstacle for arresting a portion of the flow in the seal chamber to stagnation pressure, whereby a zone of fluid at stagnation pressure is created. A discharge passage is disposed in the seal chamber adjacent to a region of concentration of contaminants and in the zone of stagnation pressure created by the obstacle, whereby contaminants are pumped out via the discharge passage into the main driven flow. The discharge passage is disposed upstream of the obstacle and provides fluid communication between the seal chamber and a process side of the machine. The method and the ejection device are operative with a machine driving fluid in clockwise direction, in counterclockwise direction, and in both clockwise and counterclockwise direction.

A submersible well pump assembly has a motor that rotates a drive shaft within the pump. The pump has a number of pump stages, each stage having a diffuser and an impeller. A bushing is fixed for non-rotation within the diffuser. A thrust runner sleeve mounted to the drive shaft has an outer diameter surface in sliding rotating engagement with an inner diameter surface of the bushing. At least one seal ring is mounted to the sleeve in sealing engagement with the drive shaft to block the entry of well fluid particulates between the sleeve and the drive shaft.

A protector for an electric submersible pump includes a plurality of chambers, with adjacent or consecutive pairs of chambers coupled, e.g., fluidly coupled, via a series or parallel body. The body defines two separate hydraulic circuits, which allows for the inclusion of a shaft seal, even when the body couples consecutive chambers in a parallel configuration or couples to a thrust bearing chamber. The shaft tube circuit can include a compensator and/or a relief valve.

The approach presented here concerns a pump for delivering a fluid. The pump comprises an impeller, a drive device with a shaft, a shaft housing and a sealing device. The impeller is shaped to deliver the fluid. The drive device with the shaft is designed to drive the impeller. The shaft housing is shaped to receive the shaft and/or the drive device. The sealing device comprises at least one casing sealing element and/or an impeller sealing element which is received between the drive device and the impeller and which is designed to prevent fluid from entering the drive device and/or the shaft casing during operation of the pump.

A process fluid lubricated pump includes a housing with an inlet to receive the fluid, and an outlet to discharge the fluid, a shaft extending from a drive end to a non-drive end and rotatable about an axial direction, the drive end of the shaft arranged outside the housing, a hydraulic unit including impellers mounted on the shaft, a collection chamber to collect leaking process fluid, the collection chamber comprising an exit, through which the shaft passes, and an exit to discharge the process fluid, and a throttle device arranged between the hydraulic unit and the collection chamber, the throttle device comprising a stationary throttle part having first and second axial faces delimiting the stationary throttle part, the first axial face facing the collection chamber, and the throttle device including a throttle gap surrounding the shaft and extending from the first axial face to the second axial face.

Disclosed are an oil circuit, an oil supply method for lubricating wheel-end electric drive axles, and a dual-circuit oil pump. The oil pump has a motor, first and second pumps with a common rotor shaft driven by the motor, and a seal mounted on the rotor shaft and configured to sealingly isolate the first pump from the second pump. The oil circuit design includes an oil pump, first and second oil filters, and first and second heat exchangers. From first and second housings each receiving a first and second wheel-end electric drive axle, respectively, a lubricating oil flows into a respective oil filter, flows into the oil pump after being filtered, is then pumped into the respective heat exchanger and cooled, and finally flows back into the respective housing.

An electrical submersible pump assembly includes a production pump, a motor containing a motor lubricant, and a seal section coupled between the motor and the pump. A drive shaft extends through the seal section, the drive shaft being rotated by the motor for driving the production pump. A mechanical face seal in the seal section seals around the shaft. A circulation pump is mounted to the shaft above the face seal for rotation therewith. An inlet passage leads from an exterior of the seal section to the circulation pump to deliver well fluid to the circulation pump. An outlet passage leads from the circulation pump to the exterior of the seal section to discharge well fluid exterior of the seal section. The rotating component of the face seal is located in the outlet passage.

The Invention provides a spiral flow constant pressure pump, comprising a pump body, a pump casing and an impeller; the pressure drop between the end face of pump rear cover and the rear end face of impeller auxiliary blade is used for providing wash water to sealing device; a hole is opened in the high pressure area of the end face of pump rear cover; the position of the hole for entering the seal cavity is close to the sealing device, leading expectant high pressure water into the seal cavity; a hole is opened in the low pressure area of the end face of pump rear cover; the position of the hole for exiting the seal cavity is far away from the sealing device; the expectant high pressure water that enters the seal cavity will flow back to low pressure area through the drainage hole along flow direction after washing the sealing device; the pump recycles a part of energy, improves the hydraulic efficiency, decreases the turbulent loss and takes way the gas might exist in the seal cavity; the extended orifice sleeve reduces the damage to the pressure drop of the auxiliary blade caused by the high pressure water leaked from seal cavity and thus ensures the balance effect of the auxiliary blade.

A throat bushing for use in a seal chamber or stuffing box of rotary fluid equipment is provided. The throat bushing includes a first face; a second face; an outer annular surface spanning between the first second faces and dimensioned to be received within a bore of the seal chamber or stuffing box; and an inner annular surface defining an inner bore extending from the first face to the second face, the inner bore dimensioned to receive a rotary shaft and permit rotation of the shaft therein. The throat bushing further includes at least one arced groove traversing the inner annular surface from the first face to the second, the arced groove being open to the inner bore along its length and defining a substantially semi-helical path leading from an opening of the arced groove on the first face to an exit of the arced groove on the second face.

A coolant pump is provided that includes a pump housing that receives a pump shaft for driving a pump member for a liquid medium in a medium chamber. The pump shaft is arranged at least in sections in the medium chamber and is rotatable mounted by means of an anti-friction bearing. The anti-friction bearing has a plurality of rolling bodies which are arranged in a rolling body chamber. The rolling body chamber and the medium chamber are fluidly connected, such that the anti-friction bearing device is lubricated and/or can be lubricated with the medium from the medium chamber.