Numerical analysis of electrorheological effect

Satoru Yamamoto; Takaaki Matsuoka; Hideroh Takahashi; Toshio Kurauchi

doi:10.1122/1.550415

Numerical analysis of electrorheological effect

Satoru Yamamoto, Takaaki Matsuoka, Hideroh Takahashi, Toshio Kurauchi

Research output: Contribution to journal › Article › peer-review

Abstract

The electrorheological effect found for the suspensions was numerically analyzed by three- and two-dimensional molecular-dynamics-like simulations. The shear stress in a uniform shear flow field was calculated from results obtained by the simulations. The calculation suggested that the increase in the apparent viscosity of the suspension might be attributed to the clustering of the dispersing spherical particles between a pair of electrodes under the influence of the applied electric field. The electrorheological effect calculated for the three-dimensional model was comparable to that computed for the two-dimensional model. Both three- and two-dimensional simulations predict that the electrorheological fluid behaves as a Bingham fluid.

Original language	English
Number of pages	1
Journal	Journal of Rheology
Volume	37
Issue number	3
DOIs	https://doi.org/10.1122/1.550415
Publication status	Published - May 1993
Externally published	Yes

All Science Journal Classification (ASJC) codes

Materials Science(all)
Condensed Matter Physics
Mechanics of Materials
Mechanical Engineering

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10.1122/1.550415

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title = "Numerical analysis of electrorheological effect",

abstract = "The electrorheological effect found for the suspensions was numerically analyzed by three- and two-dimensional molecular-dynamics-like simulations. The shear stress in a uniform shear flow field was calculated from results obtained by the simulations. The calculation suggested that the increase in the apparent viscosity of the suspension might be attributed to the clustering of the dispersing spherical particles between a pair of electrodes under the influence of the applied electric field. The electrorheological effect calculated for the three-dimensional model was comparable to that computed for the two-dimensional model. Both three- and two-dimensional simulations predict that the electrorheological fluid behaves as a Bingham fluid.",

author = "Satoru Yamamoto and Takaaki Matsuoka and Hideroh Takahashi and Toshio Kurauchi",

year = "1993",

month = may,

doi = "10.1122/1.550415",

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AU - Yamamoto, Satoru

AU - Matsuoka, Takaaki

AU - Takahashi, Hideroh

AU - Kurauchi, Toshio

PY - 1993/5

Y1 - 1993/5

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AB - The electrorheological effect found for the suspensions was numerically analyzed by three- and two-dimensional molecular-dynamics-like simulations. The shear stress in a uniform shear flow field was calculated from results obtained by the simulations. The calculation suggested that the increase in the apparent viscosity of the suspension might be attributed to the clustering of the dispersing spherical particles between a pair of electrodes under the influence of the applied electric field. The electrorheological effect calculated for the three-dimensional model was comparable to that computed for the two-dimensional model. Both three- and two-dimensional simulations predict that the electrorheological fluid behaves as a Bingham fluid.

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Numerical analysis of electrorheological effect

Abstract

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