II. Properties of Fluids
Contents 1. Definition of Fluids 2. Continuum Hypothesis 3. Density and Compressibility 4. Viscosity 5. Surface Tension 6. Vaporization 7. Forces Acting on Fluids
1. Definition of Fluids
Definition of Fluids A fluid is a substance that deforms continuously when subjected to a shear stress, no matter how small that the shear stress may be Flows
SolidFluid
Fixed Plate Fluid
Definition of Fluids A fluid is a substance that cannot support any shear stress in static state
Fluids Liquids (water) Gases (air) Classification of Fluids
Liquids and Gases Liquid has definite volume; gas has no definite volume.
2. Continuum Hypothesis
The Sensitive Volume The minimal volume in which the number of fluid molecule is big enough so that the average of any physical quantity over this volume is essentially independent of the volume itself
Physical quantity Sensitive volume Micro effect Macro effect
The Sensitive Volume FACT: There are 2.7 molecules in 1 mm 3 air of 0 C at 1 atm The sensitive volume is usually very small (infinitesimally small) from a macroscopic view
Fluid Particle A mass of fluid that has a spatial dimension equivalent to the sensitive volume
Mathematical point of view: Fluid particle = Moving point with no size with no orientation
Continuum Hypothesis At any point in a fluid we can find a fluid particle which occupies that point The fluid is a continuum formed by fluid particles
3. Density and Compressibility
Density
Density Density is the mass per unit volume Unit: kg / m 3
Specific Weight Unit: N / m 3
Specific Volume Specific Volume is the volume occupied by a unit mass of fluid
Compressibility of Fluid (Bulk modulus)
Compressibility of Water
Incompressible Fluid
The bulk modulus of liquid is usually very large, or the compressibility of liquid is usually very small Water can be assumed as incompressible fluid in hydraulics
Incompressible Fluid A fluid can be assumed to be incompressible if the variation of density within the flow is not large Air can be assumed as incompressible fluid when velocity is much smaller than the speed of sound
4. Viscosity
Viscosity EXPERIMENT A measurement on stickiness of fluids
Viscosity A measurement on the ability of a fluid to resist shearing
Fixed Plate Moving Plate
Measured Results The flow is nearly parallel The fluid near the lower plate does not move The fluid near the upper plate moves with the plate The velocity distribution in y direction is linear
Viscosity Viscosity Shear stress Rate of strain
Viscosity Coefficient of Viscosity Absolute Viscosity Dynamic Viscosity Unit of : N s / m 2
Dynamic Viscosity of Fluids
Viscosity is a function of temperature
Newtonian and Non-Newtonian Fluid
Inviscid Fluid ( ) The viscosity of water is very small and may be omitted depends on the problem of interest Water can be assumed as inviscid fluid in many situations
Kinematic Viscosity Unit of : m 2 / s
Kinematic Viscosity of Fluids
Problem A journal bearing consists of a shaft and a sleeve as shown in the following figure. The clearance space is filled with oil. The sleeve is fixed. The shaft turns at a known speed. Calculate the rate of heat generation at the bearing. Diameter of shaft: d (m) Diameter of sleeve: d (m) Length of sleeve: l (m) Viscosity of oil: (N s/m 2 ) Speed of shaft: n (rpm) Shaft Sleeve Oil
Solution Angular velocity of the shaft: Shear stress on the surface of the shaft: Torque to keep rotation of the shaft: Heat generation rate (= Power):
5. Surface Tension
Capillary Rise
Surface Tension = Surface tension per unit length Unit of : N / m
6. Vaporization
ICE WATERVAPOR
Vapor Pressure p Water Vapor
Vapor Pressure
6. Forces Acting on Fluids
Two Types of Forces Body force Body force Forces acting on fluid mass, e.g. gravity force Surface force Surface force Contact force acting on fluid surface
Description of Body Force (Force per unit mass) In case of gravity,
Description of Surface Force (Force per unit area = Stress) Normal stress Shear Stress
END OF CHAPTER II