This results in the lowering of the viscosity with increasing shear rate. The flow itself can rearrange the spatial order of the particles, so that the random arrangement at low shear rates can become ordered into strings and layers of particles at high shear rates. At higher concentrations, hydrodynamic and physical interactions between suspended particles increases the resistance even further. The deviation of the flow lines caused by the presence of particles of the dispersed phase increases the resistance, i.e., the viscosity. The viscosity of non-Newtonian liquids usually arises from the presence of at least one dispersed phase in a liquid. This is a useful approximation for the flow rate curve over the shear rate range of measurement only and this in fact was the first-ever non-Newtonian law to be expounded. This would be the stress that has to be exceeded before flow begins. From the linear plot 3a, we see that for a number of liquids it looks as if the stress extrapolates to a yield stress. In Figure 3a, the data is plotted linearly as shear stress against shear rate, and transformed in Figure 3b to viscosity versus shear rate plotted on logarithmic axes: from 3b, we can identify which part of the universal curve we are on. If a standard laboratory viscometer is employed, with a shear rate range of typically 1−1000 s −1, then different types of behavior might be seen, as shown in Figure 3. Depending on the range of shear rates available in Viscosity Measurement different parts of the curve will be accessed for different liquids. The absolute position of this curve on the viscosity and shear rate axes depends on the particular non-Newtonian liquid being investigated, as does the slope of the power-law region, as well as the possible upturn at high shear rate. At low enough shear rates, the viscosity is constant, thereafter decreasing through what is called the power-law region, to eventually flatten out a higher shear rates, often to become constant again, but sometimes rising. The (almost) universal behavior of all such liquids is shown in Figure 2. The most important variation of viscosity for non-Newtonian liquids is with shear rate. Its dependence is such that at the normal pressures found in heat and mass transfer operations, it can usually be neglected. The viscosity of liquids almost always increases with pressure, with water being the sole exception. Around room temperature, the viscosity of water decreases by 3% per degree Celcius oils by about 5%, and bitumen by 15% or more. The temperature dependence of the viscosity of Newtonian liquids is such that the viscosity decreases with temperature, and in general, the higher the viscosity, the greater the rate of decrease with temperature. (Prior to the introduction of the SI system, the cgs unit relevant to low viscosity liquids was the centipoise, which is identical to the mPas.) A form of viscosity often referred to is the kinematic viscosity, ν m 2s −1 which is the quantity we have defined above divided by the density of the fluid, ρ, i.e., ν = η/η. The units of shear stress are Pascals (Pa), shear rate reciprocal seconds (s −1), and so the unit of viscosity is the Pascal-seconds (Pas or Pa.s), with mPas being the more usual unit used for low viscosity fluids. The ratio of these two quantities is the viscosity hence η = σ/ The shear rate (sometimes called the strain rate or velocity gradient), which is the proper measure of the rate of deformation in the fluid undergoing shear flow. In shear flow-where we imagine the flow as hypothetical layers of fluid flowing over each other-we define the relevant parameters as (see Figure 1) σ the shear stress (force per unit area) at the boundary of the fluid to produce the flow, and Quantitatively, viscosity is defined as the stress in a particular ideal flow-field divided by the rate of deformation of the flow. Viscosity can depend on the type of flow (shear and/or extensional), its duration and rate, as well as the prevailing temperature and pressure. Viscosity is that property of a fluid which is the measure of its resistance to flow (i.e.
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