A fan assembly includes a radial blower unit configured to exhaust air radially from an inlet axis of the radial blower unit. The fan assembly also includes baffles each partially surrounding the radial blower unit. The baffles are rotatable between an open position and a closed position around respective pivot axes, and the baffles have respective centers of mass aligned with the respective pivot axes.

Particular embodiments described herein provide for an electronic device that can be configured to include a fan where the fan blades are decoupled from the center shaft. The fan can include a center shaft, a motor coil support, motor coils coupled to the motor coil support, a rotator coupled to the center shaft, and fan blades coupled to the rotator, where rotation of the fan blades is decoupled from the center shaft by the rotator. A blade support can be coupled to the rotator, where the blade support couples the fan blades to the rotator and magnets can be coupled to the blade support. In an example, the rotator can include an inner, an outer race, and bearings.

A flow guiding device for use on a fan assembly with a motor-operated radial impeller rotating about an axis of rotation. The guiding device has an outer housing and an inner diffuser. A flow duct is formed between the outer housing and inner diffuser. The flow duct extends along an axial flow direction. The outer housing forms a receiving space for the integral holding of the radial impeller. The impeller borders, in the axial direction, on the inner diffuser. The impeller, during operation, takes in a flow axially and blows it out radially into the flow duct. The flow duct is adapted to deflect the flow from a radial direction into an axial direction.

A compressor 100 includes: a rotor 10 having a rotary shaft 11 rotating around an axis A, and an impeller 12 provided integrally with the rotary shaft 11; a casing 5 having a casing main body 51 which surrounds the rotor 10 and forms an annular inlet flow path F1 surrounding the axis A at a front stage of the impeller 12, and an inlet nozzle 52 which introduces a fluid into the inlet flow path F1 from an outer side in a radial direction Dr; an external pipe 2 connected to the inlet nozzle 52 to introduce the fluid from the outside to the inlet nozzle 52; and a cleaning liquid supply part 4 which is configured to supply a cleaning liquid from a plurality of locations in a circumferential direction of the external pipe 2 to an interior of the external pipe 2.

A compressor 100 includes: a rotor 10 having a rotary shaft 11 rotating around an axis A, and an impeller 12 provided integrally with the rotary shaft 11; a casing 5 having a casing main body 51 which surrounds the rotor 10 and forms an annular inlet flow path F1 surrounding the axis A at a front stage of the impeller 12, and an inlet nozzle 52 which introduces a fluid into the inlet flow path F1 from an outer side in a radial direction Dr; an external pipe 2 connected to the inlet nozzle 52 to introduce the fluid from the outside to the inlet nozzle 52; and a cleaning liquid supply part 4 which is configured to supply a cleaning liquid from a plurality of locations in a circumferential direction of the external pipe 2 to an interior of the external pipe 2.

A heat-dissipation fan includes a rotary assembly and a plurality of rotary cylinders mounted on an outer surface of the rotary assembly to serve as cylindrical fan blades of the heat-dissipation fan. The rotary assembly includes a plurality of first electrical conducting units and a second electrical conducting unit. The rotary cylinders move along with the rotary assembly when the latter rotates and are correspondingly electrically connected to the first electrical conducting units to be rotatable about their respective centerlines.

A heat-dissipation fan includes a rotary assembly and a plurality of rotary cylinders mounted on an outer surface of the rotary assembly to serve as cylindrical fan blades of the heat-dissipation fan. The rotary assembly includes a plurality of first electrical conducting units and a second electrical conducting unit. The rotary cylinders move along with the rotary assembly when the latter rotates and are correspondingly electrically connected to the first electrical conducting units to be rotatable about their respective centerlines.

An impeller wheel for fans has a bottom disc, a cover disc, and three-dimensionally shaped blades connected to the bottom disc and the cover disc. The bottom disc, cover disc, and the blades form a one-piece part. The blades have a leading edge and a trailing edge, wherein the leading edge and the trailing edge each have a median diameter. In a projection onto a cylinder that is coaxial with a rotation axis of the impeller wheel and has a diameter matching a median diameter of the trailing edge or of the leading edge, a first extension of the trailing edge and/or the leading edge is positioned at a first angle and a second extension of the trailing edge and/or the leading edge is positioned at a second angle relative to a line parallel to the rotation axis. At least one of the first and second angles is different from 0.

An impeller wheel for fans has a bottom disc, a cover disc, and three-dimensionally shaped blades connected to the bottom disc and the cover disc. The bottom disc, cover disc, and the blades form a one-piece part. The blades have a leading edge and a trailing edge, wherein the leading edge and the trailing edge each have a median diameter. In a projection onto a cylinder that is coaxial with a rotation axis of the impeller wheel and has a diameter matching a median diameter of the trailing edge or of the leading edge, a first extension of the trailing edge and/or the leading edge is positioned at a first angle and a second extension of the trailing edge and/or the leading edge is positioned at a second angle relative to a line parallel to the rotation axis. At least one of the first and second angles is different from 0.

There is a method for controlling a centrifugal compressor (22) having an inlet (24), an outlet (26), an impeller (54) mounted for rotation about an impeller axis (502), a motor (52) coupled to the impeller to drive the impeller about the impeller axis (502), and a variable inlet guide vane (56) array (55) controllable for movement between a relatively closed first condition and a relatively open second condition. A lift value is determined (304). An allowable guide vane condition based upon the lift value is determined (306). The guide vane array is closed (308) to the determined allowable guide vane condition. The impeller is accelerated (312) to an operational speed.