A plunger sleeve for use in an artificial lift system for the production of hydrocarbons which includes an elongate body having an upper end, a lower end, and a central opening through the elongate body. The lower end includes a structural section forming at least a portion of the outer surface of the elongate body and a polymeric section forming at least a portion of an inner surface of the elongate body. At least a portion of the inner surface of the elongate body formed by the polymeric section within the lower end is configured to sealingly conform with a portion of an outer surface of a wellbore sealing device. An artificial lift system including the plunger sleeve and a method of proving artificial lift using the plunger sleeve is described.

An improved ball valve on a pump system comprising a ball valve having a ball, a first end arranged for operatively engaging the pump system, a first axial port on the first end sufficiently narrow to prevent the passage of the ball, a ball-seat disposed on the first end with a plurality of ports annularly disposed around the ball and extending through the ball-seat, a second axial port on a second end sufficiently narrow to prevent the passage of the ball, and the second end of the ball valve arranged for connecting to the pump system. The improved ball valve further comprising a ball seat without a first axial port. The improved ball valve further comprising a plurality of ports extending outwardly from the first axial port and extending through the ball-seat.

The invention relates to a ball valve (1) for a pipe system for conveying liquid or gaseous media, comprising a housing (3), which has a ball plug (4) and seat rings (5, 6). A hydraulic system (7), which is independent of the pressure of the liquid or gaseous medium flowing through the pipe system, is provided for changing the contact pressure of at least one of the seat rings (5, 6) against the ball plug (4).

A sealing structure of plunger pump, comprising a pump body, a feed chamber, an oil, a suited plunger; wherein the plunger includes a one-way valve and a discharge hole; the feed chamber includes a mounting step having a first sealing ring, a second sealing ring; an inner wall of the first sealing ring has a plurality of first sealing pipes distributed uniformly in longitudinal direction; an infusion step having an annular mounting groove; the mounting groove is embedded with a suited spring leaf; an inner wall of the second sealing ring includes a plurality of sealing toothed rings. The sealing structure of the plunger pump can ensure the sealing effect of the sealing ring when the sealing ring is worn out, and can ensure the service life of the sealing ring to the utmost extent.

A discharge valve for a hydraulic pump of a hydraulic unit defines a valve port, and includes a valve body and a receiving element. The valve body is configured to seal off the valve port. The receiving element adjoins the valve port, and defines a cavity configured to receive the valve body. The cavity has a longitudinal axis and an inner wall with a radially outwardly oriented pocket configured to receive the valve body.

An electromagnetic pump (100). The electromagnetic pump (100) comprises a conduit (101) comprising an inlet (103) and an outlet (105). A first magnetic field generating unit (109) is provided for generating a first magnetic field having a first component with a first direction in the conduit. A second magnetic field generating unit (111) is provided for generating a second magnetic field having a second component with a second direction in the conduit (101), the second direction being substantially opposite to the first direction. A piston member (113) is disposed within the conduit, the piston member (113) being movable within the conduit (101) under the influence of the first and/or second magnetic fields to pump fluid received from the inlet (103) of the conduit (101) to the outlet (105) of the conduit (101).

A protection mechanism for a lubricant reservoir is mounted within a valve protection chamber disposed on an actuator. The protection mechanism includes a valve actuating plate and an elastic member biasing the valve actuating plate upwards. The actuator is pushed upwards by a rising level of lubricant as the lubricant reservoir is filled. When the reservoir is full, the actuator causes the valve actuating plate to contact a valve stem. The valve actuating plate pushes the valve stem up to shut off a flow of lubricant to the reservoir through the shut off valve. During an overfill event the actuator shifts upward due to the rising level of the lubricant in the reservoir. As the actuator shifts upward, the elastic member compresses such that valve actuating plate remains static relative to the lubricant reservoir as actuator rises.

According to the embodiment of the present disclosure, it provides a method of manufacturing a piston of a pump for brake system, the piston fabricated using a piercing process by press forming to have an inlet path communicating with a suction port through which oil is introduced.

There is provided an airless paint spray pump wherein the pump is a double acting piston pump having an inlet communicating with a source of paint, a motor for driving the pump, a pressure controller for controlling the pressure of the pressurized paint delivered by the pump, and a filter for filtering the paint delivered by the pump. The pump includes features which increase the accessibility of the components thereof, prevent the incorrect installation of the seal packings in the pump cylinder, and allow the assembly of the piston in the pump cylinder properly aligned with the cylinder so as not to damage the seal packings therein.

The present disclosure relates to a downhole pump designed to include a sand separation unit. In one implementation, the downhole pump comprises a barrel having a first valve for controlling fluid flow into the barrel. The first valve includes an interior cavity with a first surface. The downhole pump further includes a plunger housed within the interior cavity of the barrel. The plunger comprises a wiper-plunger having a first circumference to which one or more resilient seals are coupled. The one or more resilient seals seal a first boundary between the first circumference of the wiper- plunger and a first portion of the first surface associated with the barrel. The plunger further comprises a sand separation unit coupled to the wiper-plunger at a first side. The sand separation unit forms a balancing chamber that minimizes a pressure differential across the one or more resilient seals. The sand separation unit uses centrifugal force to separate particulate matter from fluid during a first motion of the wiper-plunger relative to the first portion of the first surface associated with the barrel. The plunger further comprises a plunger-assembly coupled to the sand separation unit at a second side. The plunger-assembly has a second valve that controls fluid flow into the plunger-assembly via a third side from the interior cavity of the barrel. Additionally, the plunger includes a second boundary between a second circumference of the plunger-assembly and a second portion of the first surface associated with the barrel. The second boundary is fillable by slippage fluid within the barrel to create a fluid seal at the second boundary.