A fluid dynamic-pressure bearing set for a fan includes a casing having a hollow inner space; a seat integrally formed with the casing; the seat including a lower plate, and a hollow cylinder extended from the lower plate of the seat; a friction sheet being installed on the lower plate of the seat; a bearing being installed around an inner periphery of the cylinder; a motor coil installed around an outer periphery of the cylinder; a rotary shaft installed in an axial center of the bearing; and a fan blade set installed at an upper portion of the rotary shaft; and wherein a recess is formed on the lower plate of the seat and does not penetrate the bottom of the seat; and the recess is positioned between the friction sheet and an inner wall of the seat.

A fan motor includes a housing, a stator assembly disposed inside the housing, a rotor assembly rotatably disposed inside the stator assembly, an impeller configured to generate a flow of air in the housing based on receiving power from the rotor assembly, a first housing cover disposed at one side of the housing, a first bearing disposed in the first housing cover, a second housing cover disposed at another side of the housing and configured to guide the air along an axial direction of the impeller, a second bearing disposed in the second housing cover, and a vane disposed at a lower portion of the second housing cover and configured to guide the air in the second housing cover. The impeller is a diagonal flow impeller, and the second housing cover is arranged along the axial direction.

A motor includes a bearing having a rolling member disposed between an inner ring and an outer ring, a spring connected to the outer ring, and a pusher connected to the spring and configured to move to a first position spaced apart from the inner ring by the spring. The pusher is further configured to move to a second position at which friction with the inner ring is caused by a pressure of air. The inner ring is spaced apart from the rotating shaft by a gap between the inner ring and the rotating shaft when the pusher is at the second position.

A compressor includes a low pressure stage having a low pressure cylinder, a high pressure stage having a high pressure cylinder, a low pressure piston guided in an axially movable manner in the low pressure cylinder, a high pressure piston guided in an axially movable manner in the high pressure cylinder, a piston rod rigidly connecting the low pressure piston and the high pressure piston, and a sliding block guide. The sliding block guide includes a recess arranged in the piston rod and further includes two substantially parallel sliding block tracks. One of the sliding block tracks has an arc-shaped indentation in a central portion. The sliding block tracks are constructed and such that a movement of the low pressure piston and of the high pressure piston follows a piston stroke curve that deviates from a regular sinusoidal stroke curve.

A vapor pump for an automotive application includes a housing group with a pump housing having a pump chamber, an inlet opening and an outlet opening, and a motor housing having a motor chamber; a rotor shaft made from an electrically conductive material; a pumping wheel made of an electrically conductive plastic material arranged in the pump chamber and mounted on the rotor shaft to rotate therewith to pump the fuel vapor from the inlet opening to the outlet opening; a drive motor arranged in the motor chamber which includes a motor stator, a motor rotor and a motor control unit; a contact plug which electrically connects the motor control unit; and an electrically conductive bearing arrangement which is connected with the contact plug via a conductor. The motor rotor is connected with the rotor shaft to rotate therewith. The electrically conductive bearing arrangement rotatably supports the rotor shaft.

A heat dissipation device including frame, fan rotating assembly, stator assembly, decorative plate and at least two magnetic components. Frame includes base and barrel connected to base. Fan rotating assembly includes hub and a plurality of blades connected to hub. Fan rotating assembly is rotatably disposed on frame via first bearing fan rotating assembly. Stator assembly is disposed on barrel. Hub covers stator assembly. Decorative plate has decorative design and central pillar connected to decorative plate and extending from decorative plate. Central pillar is connected to hub via second bearing. At least two magnetic components are respectively disposed on decorative plate and stator assembly. One of the at least two magnetic components disposed on decorative plate and another one of the at least two magnetic components disposed on stator assembly are attracted to each other so that decorative plate is stationary while fan rotating assembly rotates.

According to the present invention, foreign substances, such as external dust and the like, can be prevented from being introduced into a lubricating fluid inside a bearing, so that the extension of the durability life of a motor or fan motor can be expected and once the assembly of a rotor assembly is completed, an impeller and a stator assembly can be assembled even in a non-clean room environment, thereby reducing cost and time in an assembly process, and because a sealing protrusion can block external foreign substances in a state in which the sealing protrusion is located radially inside a sleeve than the outer diameter of the sleeve, the design of a stator core can be made more freely, and it can be applied in even a case where the inner diameter of the stator core is small and the thickness of the stator core is large.

A ceiling fan assembly including a non-rotating motor shaft with an upper and lower bearing stop, a stator mounted to the non-rotating motor shaft, a rotor surrounding the stator, a motor housing having an upper bearing seat spaced above the upper bearing stop and a lower bearing seat spaced below the lower bearing stop, an upper bearing seated within the upper bearing seat, a lower bearing seated within the lower bearing seat, and a downrod coupling provided on the non-rotating shaft. When the ceiling fan assembly is suspended from a structure with the downrod coupling, the weight of the rotor presses the upper bearing against the upper bearing stop such that the weight of the rotor is transferred through the upper bearing to the non-rotating shaft.

A fluid dynamic-pressure bearing set for a fan includes a casing having a hollow inner space; a seat integrally formed with the casing; the seat including a lower plate, and a hollow cylinder extended from the lower plate of the seat; a friction sheet being installed on the lower plate of the seat; a bearing being installed around an inner periphery of the cylinder; a motor coil installed around an outer periphery of the cylinder; a rotary shaft installed in an axial center of the bearing; and a fan blade set installed at an upper portion of the rotary shaft; and wherein a recess is formed on the lower plate of the seat and does not penetrate the bottom of the seat; and the recess is positioned between the friction sheet and an inner wall of the seat.

A thin fan includes a frame and a driving device. The driving device includes a stator structure and a rotor structure corresponding to the stator structure. The stator structure includes a stator magnetic pole group and a base body The rotor structure includes a rotor shell, a magnetic structure and an impeller connected to the rotor shell. The rotor shell includes a top plate, an outer sidewall, an oil seal and a protruding structure. A center of the rotor shell is formed with a cylindrical shaft. The rotor shell and the shaft are a single component manufactured by processing a single material workpiece. The stator magnetic pole group magnetically drives the magnetic structure as well as the rotor shell to rotate. Wherein an inner surface of the rotor shell facing the stator structure and corresponding to the base body is formed with an oil repellent layer.