Title :
Core-Shell Structured Polystyrene Coated Carbonyl Iron Microspheres and their Magnetorheology
Author :
Xuemei Quan ; Weihuan Chuah ; Yongsok Seo ; Hyoung Jin Choi
Author_Institution :
Dept. of Polymer Sci. & Eng., Inha Univ., Incheon, South Korea
Abstract :
Soft magnetic carbonyl iron (CI) microparticle, possessing high magnetic saturation with less magnetic hysteresis, was mostly applied as an active material in magnetorheological (MR) fluids. However, pure CI suspension is known to have poor dispersion stability in the MR fluid system. To overcome this problem, we fabricated polystyrene (PS)-coated CI particles through a simple coating method of dispersion polymerization. Surface morphology of synthesized PS coated CI was observed using scanning electron microscopy. Performance of this MR fluid dispersed in silicone oil, including shear stress and shear viscosity, was measured using a rotational parallel disk rheometer in a steady shear flow and suspension stability was examined by a Turbiscan apparatus. The PS-coated CI suspension was found to improve settling of the CI particles without much deterioration of MR performance.
Keywords :
coatings; iron; magnetic hysteresis; magnetic particles; magnetorheology; polymer films; polymerisation; scanning electron microscopy; shear strength; soft magnetic materials; surface morphology; suspensions; viscosity; Turbiscan apparatus; active materials; coating method; core-shell structured polystyrene coated carbonyl iron microspheres; dispersion polymerization; dispersion stability; magnetic hysteresis; magnetic saturation; magnetorheological fluids; polystyrene-coated carbonyl iron particle fabrication; rotational parallel disk rheometer; scanning electron microscopy; shear stress; shear viscosity; silicone oil; soft magnetic carbonyl iron microparticle; steady shear flow; surface morphology; Iron; Magnetic hysteresis; Magnetomechanical effects; Saturation magnetization; Soft magnetic materials; Stress; Suspensions; Carbonyl iron (CI); magnetorheological (MR) fluid; polystyrene (PS); yield stress;
Journal_Title :
Magnetics, IEEE Transactions on
DOI :
10.1109/TMAG.2013.2278291
