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Rheologica Acta
Published in: Rheologica Acta 1/2009

01-01-2009 | Original Contribution

Microstructural investigations of the yielding behaviour of bidisperse magnetorheological fluids

Authors: Charles Ekwebelam, Howard See

Published in: Rheologica Acta | Issue 1/2009

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Abstract

Particle level simulations were used to investigate the effects of size bidispersity and particle size ratios on the static and yielding behaviour of magnetorheological fluids (MRF). The MRF were treated as linearly magnetisable, neutrally buoyant particles dispersed in a viscous carrier liquid. In the quiescent mode (static structures), the bidisperse suspensions were found to have a higher tendency to form straight chains than the monodisperse suspensions; this is consistent with previous findings. Under steady shearing, the bidisperse suspensions exhibited higher stress enhancement than the monodisperse systems. The stress enhancement in bidisperse suspensions is likely to be due to the population and orientation of interacting large particles in the bidisperse suspensions.
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Literature
Ahn KH, Klingenberg DJ (1994) Relaxation of polydisperse electrorheological suspensions. J Rheol 38:713–741CrossRef
Allen MP, Tildesley DJ (1987) Computer simulation of liquids. Oxford University Press, Oxford
Block H, Kelly JP (1988) Electrorheology. J Phys D Appl Phys 21:1661–1677CrossRef
Bossis G, Volkova O, Lacis S, Meunier A (2002) Magnetorheology: fluids, structures and rheology. Lecture notes in physics. Springer, Berlin, pp 202–230
Doi M, Edwards SF (1986) The theory of polymer dynamics. Oxford University Press, Oxford
Kittipoomwong D, Klingenberg DJ, Ulicny JC (2002) Simulation of bidisperse magnetorheological fluids. Int J Mod Phys B 16:2732–2738CrossRef
Kittipoomwong D, Klingenberg DJ, Ulicny JC (2005) Dynamic yield stress enhancement in bidisperse magnetorheological fluids. J Rheol 49:1521–1538CrossRef
Klingenberg DJ, van Swol F, Zukoski CF (1989) Dynamic simulation of electrorheological suspensions. J Chem Phys 94:7888–7895CrossRef
Klingenberg DJ, van Swol F, Zukoski CF (1991) The small shear rate response of electrorheological suspensions. I. Simulation in the point-dipole limit. J Chem Phys 94:6160–6169CrossRef
Martin EJ (2000) Thermal chain model of electrorheology and magnetorheology. Phys Rev E 63:011406–1–011406–9
Mori Y, Tsunamoto T, Nakayama H (1998) Computer simulation of electrorheological fluids in the binary system of particle size. In: Nakano M, Koyama K (eds) Proceedings of the 6th international conference on electro-rheological fluids, magneto-rheological suspensions and the applications, Yonezawa, Japan, 22–25 July 1997. World Scientific, Singapore, pp 180–185
Pappas Y, Klingenberg DJ (2006) Simulations of magnetorheological suspensions in Poiseuille flow. Rheol Acta 45:621–629CrossRef
Parthasarathy M, Klingenberg DJ (1996) Electrorheology: mechanisms and models. Mater Sci Eng R 17:57–103CrossRef
Rankin PJ, Ginder JM, Klingenberg DJ (1998) Electro- and magneto-rheology. Curr Opin Coll Inter Sci 3:373–381CrossRef
See H (1999) Advances in modelling the mechanisms and rheology of electrorheological fluids. Korea-Australia Rheol J 11:169–195
See H (2004) Advances in electro-rheological fluids: materials, modeling and applications. J Ind Eng Chem 10:1132–1145
See H, Kawai A, Ikazaki F (2002) The effect of mixing particles of different size on the electrorheological response under steady shear flow. Rheol Acta 41:55–60CrossRef
Sevick EM, Monson PA, Ottino JM (1988) Monte Carlo calculations of cluster statistics in continuum models of composite morphology. J Chem Phys 88:1189–1206CrossRef
Sim HG, Ahn KH, Lee SJ (2003) Three dimensional dynamics simulation of electrorheological fluids under large amplitude oscillatory shear flow. J Rheol 47(4):879–895CrossRef
Tan Z, Zou X, Zhang W, Jin Z (1999) Influences of the size and dielectric properties of particles on electrorheological response. Phys Rev E 59(3):3177–3181CrossRef
Trendler AM, Böse H (2004) Influence of particle size on the rheological properties of magnetorheological suspensions. In: Lu K, Shen R, Liu J (eds) Proceedings of the 9th international conference of electrorheological fluids and magnetorheological suspensions. Beijing, China World Scientific, Singapore, pp 433–438
Wereley NM, Chaudhuri A, Yoo JH, John S, Kotha S, Suggs A, Radhakrishnan R, Love J, Sudarshan TS (2006) Bidisperse magnetorheological fluids using Fe particles at nanometer and micron scale. J Int Mat Syst Struct 17:393–401CrossRef
Wu CW, Conrad H (1998) Influence of mixed particle size on electrorheological response. J Appl Phys 83(7):3880–3884CrossRef
Metadata
Title
Microstructural investigations of the yielding behaviour of bidisperse magnetorheological fluids
Authors
Charles Ekwebelam
Howard See
Publication date
01-01-2009
Publisher
Springer-Verlag
Published in
Rheologica Acta / Issue 1/2009
Print ISSN: 0035-4511
Electronic ISSN: 1435-1528
DOI
https://doi.org/10.1007/s00397-008-0297-9

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