Environmental Engineering Reference
In-Depth Information
63. Ginder JM, Davis LC, Elie LD (1995) Rheology of magnetorheological fluids: models and
measurements. In: 5th International conference on ER fluids and MR suspensions, Singapore,
pp 504 - 514
64. Ginder JM, Davis LC, Elie LD (1996) Rheology of magnetorheological fluids: models and
measurements. Int J Mod Phys B 10(23 - 24):3293 - 3303
65. Genc S, Phul
é
PP (2002) Rheological properties of magnetorheological
fl
uids. Smart Mater
146
66. Charles E, See H (2009) Microstructural
Struct 11:140
-
investigations of the yielding behaviour of
32
67. Kittipoomwong D, Klingenberg DJ, Ulincy JC (2005) Dynamic yield stress enhancement in
bidispersion magnetorheological
bidisperse magnetorheological
fl
uids. Rheol Acta 48:19
-
uids. J Rheol 49:1521
68. Wereley NM, Chaudhuri A, Yoo JH et al (2006) Bidisperse magnetorheological
fl
fl
uids using
401
69. Ginder JM, Nichols ME, Elie LD et al (1999) Magnetorheological elastomers: properties and
applications. In: Wutttig M (ed) Proceedings of SPIE. Smart structures and materials, vol
3675. Smart Materials Technologies, Newport Beach, 12 July 1999
70. See H (2001) Mechanisms of magneto-and electro-rheology: recent progress and unresolved
issues. Appl Rheol 11(2):70 - 82
71. Brady JF, Bossis G (1988) Stokesian dynamics. Ann Rev Fluid Mech 20:111 - 157
72. Orihara H, Doi M, Ishibashi Y (1999) Two types of mechanism of electrorheological effect in
polymer blends. Int J Mod Phys B 13:1949 - 1955
73. Bonnecaze RT, Brady JF (1992) Yield stresses in electrorheological
Fe particle at nanometer and micron scale. J Intell Mater Syst Struct 17:393
-
fluids. J Rheol
115
74. Fang FF, Choi HJ, Jhon MS (2009) Magnetorheology of soft magnetic carbonyl iron
suspension with single-walled carbon nanotube additive and its yield stress scaling function.
Colloid Surf A 351:46
36:73
-
51
75. Hato MJ, Choi HJ, Sim HH et al (2011) Magnetic carbonyl iron suspension with organoclay
additive and its magnetorheological properties. Colloid Surf A 377:103
-
109
76. Hong CH, Liu YD, Choi HJ (2013) Carbonyl iron suspension with halloysite additive and its
magnetorheology. Appl Clay Sci 80:366
-
371
77. Cho MS, Choi HJ, Jhon MS (2005) Shear stress analysis of a semiconducting polymer based
electrorheological
-
11488
78. Choi HJMS, Cho JW, Kim CAMS et al (2001) A yield stress scaling function for
electrorheological fluids. Appl Phys Lett 78:3806
79. Gordanlnejad F, Fuchs A, Dogrour U et al (2004) A new generation of magneto-rheological
fluid dampers. Final progress report
80. Bell RC, Karli JO, Vavreck AN et al (2008) Magnetorheology of submicron diameter iron
microwires dispersed in silicone oil. Smart Mater Struct 17:015028
81. Cheng H, Yeung Y, Tong H (2008) Viscosity behavior of magnetic suspensions in fluid-
assisted nishing. Prog Nat Sci 18:91 - 96
82. Shulman ZP, Kordonskii VI, Zaltsgendler EA (1984) Structure and magnetic and rheological
characteristics of a ferrosuspension. Magnetohydrodynamics 20(3):223
fl
uid system. Polymer 46:11484
-
229
-
83. L
pez MT, Kuzhir P, Meunier AG et al (2010) Synthesis and magnetorheology of
suspensions of submicron-sized cobalt particles with tunable particle size. J Phys Condens
Matter 22:324106
84. Vereda F, Vicente J, Segovia-Gutierrez JP et al (2011) Average particle magnetization as an
experimental scaling parameter for the yield stress of dilute magnetorheological
ó
pez-L
ó
fl
uids. J Phys
D Appl Phys 44:425002
85. Vicente J, Vereda F, Segovia-Gutierrez JP et al
(2010) Effect of particle shape in
1343
86. Vicente J, Segovia-Gutierrez JP, Andablo-Reyes E et al (2009) Dynamic rheology of sphere-
and rod-based magnetorheological fluids. J Chem Phys 131:10
magnetorheology. J Rheol 54:1337
-
Search WWH ::




Custom Search