Electrorhelogical Fluids, Second International Conference ProceedingsJ. David Carlson, A.F. Sprecher, Hans Conrad |
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Page 4
... magnitude [ 8 ] . There are other approaches to explaining the effect , for example , the osmotic or Stangroom water glue theory [ 9 ] , and the Peterzhik theory [ 10 ] , which explains the electrorheological behaviour of the fluids by ...
... magnitude [ 8 ] . There are other approaches to explaining the effect , for example , the osmotic or Stangroom water glue theory [ 9 ] , and the Peterzhik theory [ 10 ] , which explains the electrorheological behaviour of the fluids by ...
Page 208
... magnitude of the charge transported by an activated silica gel sphere is close to that of the charge transported by the conductor particle of the same size , and proportional to the field intensity and squared particle radius ( Figure 2 ) ...
... magnitude of the charge transported by an activated silica gel sphere is close to that of the charge transported by the conductor particle of the same size , and proportional to the field intensity and squared particle radius ( Figure 2 ) ...
Page 309
... magnitude of the electric field across the ER material between the electrodes controls the amount of force , F , required to move the electrode at a constant speed , S. This relationship can be quantified using the equation : F = Fo + ...
... magnitude of the electric field across the ER material between the electrodes controls the amount of force , F , required to move the electrode at a constant speed , S. This relationship can be quantified using the equation : F = Fo + ...
Contents
Introduction | 3 |
Orientation of Particle Chains in AC Electric Fields | 14 |
Dynamic Simulation of a Suspension of Dielectric Particles Forming | 27 |
Copyright | |
22 other sections not shown
Common terms and phrases
active applied electric field base liquid beam behavior Bingham brake carrier fluid characteristics concentration conductivity current density curve cylinder damper damping decrease dependence developed device dielectric constant dipole dispersed phase displacement dynamic effect EG shear stress electric field strength electrode Electrorheological Fluids electrostatic Electroviscous engine mount Equation ER fluid ER-fluid experimental fibrils flow rate force fraction frequency function geometry high voltage hydraulic hydrodynamic hysteresis increase interactions interparticle kV/mm load lubrication m/min magnetic magnitude material measured mechanical modulus observed parameters particle chains Phys piston plates polarization pressure drop problem properties radius range ratio relative response rheological rotation rotor sensor shear modulus shear rate shear stress shown in Figure silica silica gel silicone oil simulation speed spheres starch static yield strain structure surface suspension temperature torque valve velocity viscoelastic viscometer viscosity volume yield stress zeolite zero