A fan assembly comprising a plurality of nested components comprising a first stator; a first rotor that is radially spaced from the first stator, wherein the first rotor is magnetically driven by the first stator, the first rotor includes a second stator whereby the second stator rotates with the first rotor; a second rotor that is radially spaced from the second stator, wherein the second rotor is magnetically driven by the second stator; and, a fan blade drivenly connected to the second rotor.

A fluid pump assembly is provided. The pump has a pair of units magnetically coupled to each other. The first unit contains a drive motor and a magnetic assembly. The second unit contains a magnetic assembly and a blade of a propeller/impeller for imparting movement to a fluid. As the first unit is activated by the drive motor, a magnetic flux is created which in turn rotates the magnetic assembly in the second unit, driving the blade.

Technologies are generally described for end-suction pumps that are adapted for a dual inlet impeller. Example end suction pumps includes a body casing with a pump housing, a single inlet, a single outlet, and a magnetically coupled drive to effectuate drive to the impeller in the body casing. Fluid flows to one side of the impeller (e.g., a right-eye side) via a primary flow path from an impeller inlet of the body casing, and also to another side of the impeller (e.g., a left-side eye) via a secondary flow path through a stationary shaft with a semi-hollow hydraulic passageway therein.

A dual-impeller driving device and a liquid-cooling heat dissipation device with the dual-impeller driving device are provided. The dual-impeller driving device includes a double-sided circuit board, a first stator, a first magnetic element, a first impeller, a second stator, a second magnetic element, a second impeller and a shaft. The first stator is located beside a first active surface of the double-sided circuit board. The first magnetic element is located near the first stator. The first impeller is combined with the first magnetic element. The second stator is located beside a second active surface of the double-sided circuit board. The second magnetic element is located near the second stator. The second impeller is combined with the second magnetic element. The shaft is penetrated through the double-sided circuit board. The first impeller and the second impeller are rotated about the shaft.

The present invention relates to a magnetic gear comprising a first magnetic rotor with a first shaft; and a second magnetic rotor with a second shaft; a support structure, with a first end shield and a second end shield connected by a stat or support element. A first bearing attached to the first end shield supports the first shaft and a second bearing supports the second shaft. The first and second magnetic rotors are displaced in axial direction from each other in an axial gap; and the first shaft and shaft are approximately aligned in opposite axial directions; and a plurality of magnetic flux conductors encircles the first and second magnetic rotors, thereby conducting magnetic flux from the first magnetic rotor to the second magnetic rotor. The magnetic gear comprises a dividing wall arranged in the axial gap between the first magnetic rotor and the magnetic second rotor, to separate a first chamber from a second chamber.

A magnetic coupling includes an inner rotor (11) and an outer rotor (9) which at least partly surrounds the inner rotor (11). These rotors (11, 9) each are formed of magnetic material (18) and are coupled to one another by way of magnetic forces. The inner rotor (11) and/or the outer rotor (9) contain powdery, magnetizable material (18). The powdery, magnetizable material (18) is magnetized at a side lying opposite the other rotor at several locations distributed over the periphery.

A fluid pump assembly is provided. The pump has a pair of units magnetically coupled to each other. The first unit contains a drive motor and a magnetic assembly. The second unit contains a magnetic assembly and a blade of a propeller/impeller for imparting movement to a fluid. As the first unit is activated by the drive motor, a magnetic flux is created which in turn rotates the magnetic assembly in the second unit, driving the blade.

Extracorporeal circuit devices can be used for on-pump open-heart surgery to support surgical procedures such as coronary artery bypass grafting. In some cases, a centrifugal pump is used as part of an extracorporeal circuit. Centrifugal pump heads are described herein that induce flow on two sides of an impeller plate, and that can be conveniently mechanically assembled.

Disclosed are a water pump and an aquarium equipment that includes the water pump. The water pump includes a stator, a rotor assembly, an impeller, and a power generation induction module. The stator includes a U-shaped iron core and a coil winding wound around the U-shaped iron core. The coil winding is connected to an external power source. The rotor assembly includes a rotating shaft and a permanent magnet rotor. The impeller is connected to the rotating shaft or to the permanent magnet rotor. The power generation induction module is spaced apart from the rotor assembly. The rotor assembly and the power generation induction module are both disposed within a range of a magnetic field at an opening of the U-shaped iron core. The power generation induction module is electrically connected to an electric equipment.

A ventricle assist device comprising a device body with a housing having an inlet and an outlet. A centrifugal pump is disposed in a portion of the housing. The inlet is adapted to allow a flow of blood into the device body housing and an outlet adapted to allow the flow of blood from the device body housing. The flow of blood from the device body housing is primarily directed into the left ventricle, and the inlet and the outlet are positionable in a ventricle.