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1. Density. y. Volume, Mass, m. Elemental Volume, Mass, m. C. x. z. 2. Fluid Shear. M. M’. P. P’. Force, Fx Velocity u. Fluid Element at time, t. Fluid Element at time, t+ t. y. y. x. y. N. O. 3. Viscosity.
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1. Density y Volume, Mass, m Elemental Volume, Mass, m C x z
2. Fluid Shear M M’ P P’ Force, Fx Velocity u Fluid Element at time, t Fluid Element at time, t+t y y x y N O
3. Viscosity In some sense measures fluidity of a fluid. Actually it is the resistance offered by a layer of fluid to the motion of an adjacent one. Consider the two-plate experiment. In case of a fluid in between them, we know that the upper plate moves with a speed U whereas the lower plate does not move. This sets up a velocity gradient in a direction normal to flow.
In general 4. Newtonian Fluids • For a Newtonian fluid ie., • mis called • absolute or dynamic viscosity. • Its dimensions are ML-1 T-1 Kinematic viscosity (n) is defined as ( m/r) . Its dimensions are M L-3 • Air and water are common examples
5. Non-Newtonian Fluids • Shear stressnotproportional to deformation rate • Toothpaste, paint are common examples Bingham Plastic Shear Stress, t pseudoplastic Dilatant Newtonian Deformation rate
6. Temperature Effect Values of viscosity m and kinematic viscosity n for various fluids are tabulated in handbooks and textbooks. For air viscosity may be calculated using the Sutherland formula, where T is in Kelvin and m is in kg/s m. It is observed that viscosity of a liquid decreases with temperature where as that of a gas increases with temperature. Find out why.
7. Velocity Field • Velocity at a point may be defined as the instantaneous • velocity of a fluid particle passing through that point. For asteadyflow the properties do not change with time - IfSis any property,
8. 1, 2, 3 Dimensional Flows One, Two, ThreeDimensional Flows -- One, Two, ThreeSpace Coordinates required to specify Velocity Field r R One Dimensional flow. u = u(r) u x umax Two Dimensional flow. u = u(x,y) y u=u(x,y) u=u(x,y) x
2R q Dh Dh q 9. Surface Tension It is the apparent interfacial stress that acts when a liquid has a density interface like liquid-gas, liquid-solid, liquid-liquid 2R q>90 0 q<90 0
10. Surface Shapes water water wax soap Wetting Non-wetting
12. Continuum Flow For most engineering applications we consider fluid to becontinuous. But we do know that matter consists of molecules. To be considered continuous a fluid must have a large number of molecules in a tiny place which is small compared to the body dimensions. Under ordinary conditions this is true. For eg., A cubic metre of Air at STP contains 2.5 x 10 25 molecules. Its mean free path is like 6.6 x 10-8 m.
13. Rarefied Flows At great heights from the sea level it is not possible to consider air to be continuous. The molecular mean free path may be of the same order of magnitude as the body dimensions. Eg., at an altitude of 130 km the mean free path of air is 10.2m. Then it becomes important to consider individual or groups of molecules. This leads to the discipline ofRarefied Gas Dynamics.
14. Bulk Modulus of Elasticity Compressibility of a fluid may be expressed in terms of Bulk Modulus of Elasticity. For airkis equal tog(adiabatic conditions) andp(isothermal) For water,k =2.2Gpa, meaning that when a pressure of0.1Mpaacts upon a cubic metre of water, the change in volume resultingis1/22000 m 3.
