Title :
Dynamics of liquid meniscus bridge of intermittent contact slider
Author :
Matsuoka, Hiroshige ; Fukui, Shigehisa ; Morishita, Hiroshi
Author_Institution :
Dept. of Appl. Math. & Phys., Tottori Univ., Japan
fDate :
9/1/2002 12:00:00 AM
Abstract :
The dynamics of a liquid meniscus bridge between solid plane surfaces were analyzed assuming small vibrations of the spacing. The geometries of the meniscus considered in this study were the infinite-width meniscus and the finite meniscus ring. The time-dependent Reynolds equation was solved under a boundary condition considering the Laplace pressure, assuming that the contact angle of the liquid-solid interface remains zero and the mass of the liquid-in the meniscus is conserved, so that the boundary position moves parallel to the plane. By solving a linearized Reynolds equation under the assumption of small vibration, it was found that the pressure and the load carrying capacity has three terms, i.e. time-dependent squeeze term by the viscosity of the liquid, spring term by the dynamic Laplace pressure, and the static meniscus force term.
Keywords :
hard discs; lubrication; magnetic heads; mechanical contact; surface tension; viscosity; Laplace pressure; boundary condition; finite meniscus ring; head-disk interface; infinite-width meniscus; intermittent contact slider; linearized Reynolds equation; liquid meniscus bridge dynamics; liquid-solid interface contact angle; load carrying capacity; magnetic head flying height; meniscus liquid mass conservation; small spacing vibration; solid plane surfaces; spring term; static meniscus force term; time-dependent Reynolds equation; time-dependent squeeze term; Analytical models; Boundary conditions; Bridges; Disk recording; Geometry; Laplace equations; Magnetic heads; Solids; Springs; Viscosity;
Journal_Title :
Magnetics, IEEE Transactions on
DOI :
10.1109/TMAG.2002.802692
