An actuator for a compressor element, the actuator comprising an electrical motor with a motor casing which defines a motor chamber in which a motor rotor is positioned rotatably with the help of one or more motor bearings in relation to a motor stator, whereby the motor stator is built of laminations around which windings are attached and whereby the motor rotor is built of a shaft with laminations, whereby the actuator is further equipped with a cooling circuit for a coolant, wherein the coolant is water, the motor bearings are water-lubricated, the shaft on the motor rotor is made from stainless steel, the windings are embedded in an epoxy resin and a composite sleeve is applied around each of the laminations on the motor rotor and on the motor stator.

The present invention can provide a motor including a shaft, a yoke coupled to the shaft, a stator disposed between the shaft and the yoke, a first magnet and a second magnet which are disposed on the yoke, and a circuit board on which a first Hall sensor disposed to correspond to the first magnet and a second Hall sensor disposed to correspond to the second magnet are disposed, wherein the yoke includes a body and a flange extending from the body, the flange includes a first groove, the first magnet is disposed on an inner circumferential surface of the body, the second magnet is disposed in the first groove, and a second groove having an open portion in a direction opposite to the first groove is disposed between the body and the flange.

A stepping motor has a relationship between an outer diameter of a rotor and an outer diameter of a bearing made of magnetic material that can be adjusted appropriately so as to impart magnetic attractive force to the bearing, the stepping motor including a rotor 400 made of a permanent magnet, a stator including multiple pole teeth 223, 243, 323 and 343 extending in an axial direction of the rotor 400 arranged at an outer circumferential side of the rotor 400, a bearing 250 rotatably supporting one end portion in the axial direction of the rotor 400, and a bearing 260 rotatably supporting the other end portion in the axial direction of the rotor 400. Magnetic permeability of the bearing 260 is greater than that of the bearing 250, the rotor 400 includes multiple magnetic poles on an outer circumferential surface along a circumferential direction of the rotor 400, and an outer diameter D.sub.R of the rotor 400, an outer diameter D.sub.B of a portion of the bearing 260 which is facing the rotor 400, and a pitch P of the multiple magnetic poles of the rotor 400 are set to satisfy the following relationship of formula 1
(D.sub.R−P)=<D.sub.B=<D.sub.R  (Formula 1).

Systems and methods for producing fluids from a subterranean well include an electrical submersible pump assembly with a motor-pump unit. The motor-pump unit has a motor housing and a stator is located within the motor housing. The stator has a stator body with an interior cavity. A rotor assembly is located within the interior cavity of the stator. The rotor assembly includes a rotor shaft extending along the central axis of the stator, a rotor member, and an intermediate rotor bearing assembly. The rotor member and the intermediate rotor bearing assembly circumscribe the rotor shaft. An impeller is mounted on the rotor shaft and located within the interior cavity of the stator. A liner with a polygonal cross section is located along an interior surface of the interior cavity. The liner is secured to the motor housing and seals the stator body from a wellbore fluid.

Provided is a slide bearing (bearing sleeve (8)), comprising an oxidized green compact in which particles (11) of metal powder are bonded to each other by an oxide film (12) formed on surfaces of the particles (11). The oxidized green compact has a bearing surface (A, B) configured to slide, through intermediation of a lubricating film, relative to a mating member (shaft member (2)) to be supported. The bearing surface (A, B) has a large number of opening portions (13a), and the large number of opening portions (13a) and inner pores (13b) are interrupted in communication therebetween by the oxide film (12).

An engine-and-electric-machine assembly, including an engine (8) and an electric machine (9). The crankshaft (7) of the engine has an extension section (7-3) that extends to the exterior of the engine, and the rotor (3) of the electric machine is mounted to the extension section. The present disclosure improves the integration level of the engine-and-electric-machine assembly, and reduces the weight and volume of the engine-and-electric-machine assembly. A vehicle driving device including the engine-and-electric-machine assembly is also disclosed.

An electrical machine has a stator with a stator body supporting an electrical stator and a rotor. The rotor is supported by bearing including a radial bearing section forming a radial gas bearing and an axial bearing section forming an axial gas bearing, the stator side parts of these bearing sections being a stator side radial bearing part and a stator side axial bearing part that are rigidly connected to one another and together form a stator bearing structure. The stator side radial bearing part is a bushing, and is radially surrounded by a cooling body. The bushing is connected to the cooling body by an elastic support comprising a thermally conducting filler.

The present invention belongs to the technical field of washing machines, and particularly relates to a three-phase drainage motor for a washing machine. The three-phase drainage motor includes a stator, a rotor and an upper cover, wherein the rotor is sealed inside the stator through the upper cover; the stator includes an iron core, a coil bobbin, a three-phase coil and a plastic package portion, wherein the iron core includes a hub, an inner ring and teeth, the teeth radially connecting the hub to the inner ring, the inner ring being of a nine-section arc structure, the coil bobbin covers the teeth, the three-phase coil is wound around the coil bobbin, the plastic package portion is wrapped around the coil bobbin, the three-phase coil and the iron core to form a spigot, a rotor cavity and a rotary shaft cavity, the spigot is located above the rotor cavity, the rotary shaft cavity is at a bottom of the rotor cavity, the plastic package portion includes a housing, a wall surface of the rotor cavity and a wall surface of the rotary shaft cavity, and the housing, the wall surface of the rotor cavity and the wall surface of the rotary shaft cavity are molded through integral injection. The wall surface of the rotor cavity of the three-phase drainage motor for the washing machine provided by the present invention not only reduces an air gap of the motor to improve the motor efficiency, and meanwhile, prevents the noise problem caused by rust of nine sections of arc surfaces of the inner ring of the iron core.

A control device may include an electric motor having a stator and a rotor with a driveshaft, an output shaft, a transmission having a worm drive with a worm and a worm wheel, and a drive axis of the drive shaft extending inclined to an output axis of the output shaft. The worm may be arranged non-rotatably and may mesh with the worm wheel, which may be rotatably arranged on the output shaft and non-rotatably connected to a first gear wheel, which may be rotatably arranged on the output shaft and may mesh with a second gear wheel, which may be rotatable about an intermediate axis extending parallel to the output axis and may be non-rotatably connected to a third gear wheel, which may be rotatable about the intermediate axis and may mesh with a fourth gear wheel, which may be non-rotatably arranged on the output shaft.

A fan includes a fan frame, a stator fixedly mounted in the fan frame, and a rotor fixedly mounted in the fan frame. The rotor includes an impeller. The impeller includes a main body and a number of blades equally spaced around a periphery of the main body. The main body includes a top portion and a side portion. The top portion has an annular shape. The side portion has a cylindrical shape and extends from a peripheral edge of the top portion. A number of heat dissipating portions protrudes from an inner side of the top portion. The heat dissipating portions are arranged at intervals.