A motor having a fluid dynamic bearing generating a fluid dynamic pressure by forming an oil gap between a rotor and a stator such that oil is accommodated in the oil gap, and a first and second air dynamic bearing generating an air dynamic pressure by forming an air gap between the rotor and the stator such that air is introduced into the air gap. The fluid dynamic bearing generates a fluid dynamic pressure by forming an oil gap between an axial hole of a sleeve and a shaft such that oil is accommodated in the oil gap, and the first and second air dynamic bearings generate an air dynamic pressure by forming an air gap between an inner circumferential surface of a hub and an outer circumferential surface of the sleeve and between the inner circumferential surface of the hub and an upper plane surface of the sleeve, respectively.

Provided is a fluid dynamic bearing motor that can reduce vibration, oil deterioration, and power consumption by employing at least one pair of thrust bearings on upper and lower portions of a shaft. The fluid dynamic bearing motor includes: a housing to which a core with a coil wound around it, a sleeve having an axial hole at a central portion thereof, and a cover block supporting the sleeve are fixed; a shaft rotatably inserted into the axial hole to form an oil gap with the hole; a hub fixed to an upper end portion of the shaft and having a downwardly extending portion to an inner surface of which a magnet generating an electromagnetic force through an interaction with the core is attached; and circular thrust plates respectively fixed to upper and lower portions of the shaft, wherein receiving grooves are formed on an inner portion of the sleeve and accommodate the thrust plates to form fluid dynamic bearing surfaces. Since the fluid dynamic bearing motor employs the thrust fluid dynamic bearings on the upper and lower portions of the shaft, conical vibration of the shaft is prevented and heat generation and power consumption are reduced. Furthermore, since the fluid dynamic bearing motor employs the hydrodynamic pressure cover, oil leakage is prevented and an internal pressure of the fluid dynamic bearing is enhanced.

Provided is a fluid dynamic bearing motor including a housing fixing a core wound with a coil and a sleeve having a shaft hole at a center thereof, a shaft rotatably coupled to the shaft hole and forming an oil gap, a hub fixed to an upper end portion of the shaft and having a magnet attached to an inner circumferential surface of the hub and generating an electromagnetic force with the core, and a circular thrust plate coupled to an upper portion of the shaft and forming dynamic pressure in a thrust direction with the sleeve.