A pump assembly (1) includes a rotor axle (45), an impeller (12) fixed to the rotor axle (45), and a pump housing (11) accommodating the impeller (12). The pump housing (11) defines a first radial inner reference surface (71). A drive motor includes a stator (17) and a rotor (51) fixed to the rotor axle (45) for driving the impeller (12). A rotor can (57) accommodates the rotor (51) and includes a rotor can flange (63). A stator housing (13) accommodates the stator (17) and includes windings around a stator core (114). A first surface portion of the stator core (114) is overmolded with a first material (122) as an electrically insulating layer between the windings and the stator core (114). A second surface portion of the stator core (114) is overmolded with a second material (124) forming walls of the stator housing (13).

A pump assembly includes a rotor axle, an impeller and a pump housing defining a radial inner reference surface. A drive motor includes a stator accommodated in stator housing and a rotor accommodated in a rotor can. A radial bearing ring is in sliding contact with the rotor axle. A bearing retainer engages the radial bearing ring and centers it with respect to the radial inner reference surface. A neck ring is coupled to the pump housing and has a circumferential wall section. The impeller is located axially between the bearing retainer and the neck ring. The circumferential wall section at least partially extends into the impeller or the impeller at least partially extends into the circumferential wall section. The circumferential wall section includes a cylindrical radial outer surface and a cylindrical radial inner surface. The radial outer surface is eccentric with respect to the radial inner surface.

A pump assembly (1) includes a rotor axle (45) extending along a rotor axis (R), an impeller (12) fixed to the rotor axle (45), a pump housing (11) accommodating the impeller (12), and a drive motor including a stator (17) and a rotor (51). The rotor (51) is fixed to the rotor axle (45) for driving the impeller (12). A rotor can (57) accommodates the rotor (51). The rotor can (57) include a rotor can flange (63). A stator housing (13) accommodates the stator (17). The stator housing (13) is secured to the pump housing (11) by a bayonet ring (113). The bayonet ring (113) is resiliently spring-loaded for axially biasing the stator housing (13) towards the impeller (12) against the pump housing (11).

An electric fluid pump may include a pump housing and an electric motor arranged therein. A rotor of the electric motor may have a rotor shaft and may be mounted in a rotatable manner in a stator body, which may have a stator embedded at least regionally therein. The pump housing may be subdivided into a dry and a wet region containing the rotor. The rotor shaft may be mounted on a bottom side in the pump housing and may be connected in terms of drive to a pump impeller on a pump-impeller side, facing away from the bottom side, of the pump housing. The pump housing may have, on the pump-impeller side, an aperture out of which the rotor shaft may project. The pump housing may have an internal first bearing collar arranged around the aperture, wherein the dry region may be located radially around the first bearing collar, and wherein an outside diameter of the first bearing collar may be less than a maximum diameter of the rotor.

A pump assembly (1) includes a rotor axle (45), an impeller (12) fixed to the rotor axle, and a pump housing (11) accommodating the impeller and defining a radial inner reference surface (71). A drive motor includes a stator (17) and a rotor (51). The rotor is fixed to the rotor axle for driving the impeller. A rotor can (57) accommodates the rotor and includes a rotor can flange (63). A stator housing (13) accommodates the stator. A radial bearing ring (47) is in sliding contact with the rotor axle. A bearing retainer (41) engages the radial bearing ring and centers the radial bearing ring with respect to the radial inner reference surface. The rotor can flange has a radial distance to the pump housing. The rotor can includes a radial inner centering surface (65) centered by radially abutting against a radial outer centering surface (67) of the bearing retainer.

A thin type pump structure includes a pump housing, a rotor assembly, a stator assembly, a flow-guiding plate, and a closing member. The pump housing has a first side defining an open-topped pump chamber having a forward projected shaft and an opposite second side defining an open-bottomed annular recess at an area opposite to and around the pump chamber. The rotor assembly has a pivot hole and is received in the pump chamber with the pivot hole turnably around the shaft. The rotor assembly includes a blade wheel and a magnetic element located behind the blade wheel. The stator assembly is received in the annular recess to horizontally face toward the magnetic element, enabling mutual electromagnetic induction and magnetic field generation between the magnetic element and the stator assembly. The flow-guiding plate covers the pump chamber, and the closing member closes the pump housing from the first side thereof.

An electric liquid pump includes a casing having a central portion, rear cover and front cover, having an inlet and an outlet for the liquid. The central portion has first and second compartments, with the second compartment in fluid communication with the front cover interior. The pump includes an impeller and an electric motor, for operating the impeller, a stator housed in the first compartment, a rotor, coaxial with the stator, housed in the second compartment and an electronic card for supplying the stator at least partly housed in the rear cover. The central portion includes a plurality of walls delimiting a plurality of gaps in fluid communication with the second compartment and the front cover interior such that the liquid circulates in the gaps. The walls at least partly face the stator such that the liquid circulating in the corresponding gap removes heat from the stator.

An electric submersible pump (ESP) is described. The ESP includes a stator chamber, a stator within the stator chamber, a rotor, and an electrical connection. The stator chamber is configured to reside in a wellbore. The stator chamber is configured to attach to a tubing of a well. The stator chamber defines an inner bore having an inner bore wall that, when the stator chamber is attached to the tubing, is continuous with an inner wall of the tubing. The rotor is positioned within the inner bore of the stator chamber. The rotor includes an impeller. The rotor is configured to be retrievable from the well while the stator remains in the well. The stator is configured to drive the rotor to rotate the impeller and induce well fluid flow in response to receiving power through the electrical connection.

A pump device includes a casing, an impeller, a base, and a motor. The casing includes a pump chamber, and an inlet and an outlet. The impeller is accommodated in the pump chamber. The motor is connected to the casing for driving the impeller to rotate and includes a rotor chamber for receiving a rotor. The base is disposed between the impeller and the motor and includes an accommodating groove having an inlet port in communication with the rotor chamber to allow fluid in the pump chamber to enter into the rotor chamber. In the pump device, precipitation has been performed to fluid in the accommodating groove before the fluid enters into the rotor chamber, thus the impurity particles can be prevented from entering into the rotor chamber, thereby prolonging the service life of the pump device.

A de-blocking device for a hydraulic pump includes a can having a longitudinal axis and a conduit extending longitudinally along the longitudinal axis and having a first terminal aperture. The device further includes a bearing fixedly positioned in the conduit spaced from the first terminal aperture, and a plunger axially movably positioned in the conduit between the bearing and the first terminal aperture. A biasing element is positioned between the bearing and the plunger wherein the movement of the plunger toward the bearing compresses the biasing element.