S. J. Park scite author profile

S. J. Park

3Publications

7Citation Statements Received

20Citation Statements Given

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Hanyang University

Publications

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Investigation of the electromechanical variables of the spindle motor and the actuator of a HDD due to positioning and free fall

Jang

Park

Kim³

et al. 2006

Microsyst Technol

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This research investigates the electromechanical variables of a spindle motor and an actuator of an operating hard disk drive (HDD) due to the positioning and the free-fall of a HDD. Magnetic fields of a brushless DC motor and a voice coil motor are determined by the time-stepping finite element equation of the Maxwell equation and the driving circuit equation. The pressure of the fluid dynamic bearings (FDBs) is determined by solving the finite element equation of the Reynolds equation to calculate the reaction force and the friction torque. Dynamic equations of the rotating disk-spindle, actuator, and stationary bodies of a HDD are derived from the Newton-Euler's equation. The speed control of the rotating disk-spindle and the servo control of the actuator are included to describe the head positioning between the rotating disk and the head. The simulation is performed to investigate the electromechanical variables of the spindle motor and the actuator due to the positioning and the free-fall of a HDD. This research shows that the positioning and the free-fall of a HDD change the electromechanical variables of the spindle motor and the actuator of an operating HDD, and that monitoring their electromechanical variables may identify the positioning and the free-fall of a HDD without using extra sensors.

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Damage in graphite tiles irradiated with helium plasmas

Kim

Lee

Ohn

et al. 2012

Journal of the Korean Physical Society

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Transformation of Helically Structured Nanofibers into Linearly Oriented Nanofibers

et al. 2005

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Helical structures have been fabricated from a solution of poly(2-acrylamido-2-methyl-1propane sulfonic acid) (PAMPS) in water and ethanol by the whipping instability of a jet in a conventional electrospinning system. The simple modification of the electrospinning system involved introducing two parallel subelectrodes, which enabled the transformation of helical nanofibers into linearly oriented nanofibers due to the tensional forces caused by the modified electric field. This means that the tensional forces caused by the modified electric field had an important effect on linearizing the helical structures. Therefore, a technique using modified electric fields can play a significant role as an intermediary between helical structures and onedimensional linear structures. EXPERIMENTAL DETAILSMater. Res. Soc. Symp. Proc. Vol. 888

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S. J. Park

Investigation of the electromechanical variables of the spindle motor and the actuator of a HDD due to positioning and free fall

Damage in graphite tiles irradiated with helium plasmas

Transformation of Helically Structured Nanofibers into Linearly Oriented Nanofibers

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