2. Introduction
Introduction
Viscosity is a quantitative measure of a fluid’s resistance to
flow.
Dynamic (or Absolute) Viscosity:
The dynamic viscosity(η) of a fluid is a measure of the
resistance it offers to relative shearing motion.
η= F/ [A×(u/h)]
η= τ /(u/h) N-s/m²
Kinematic Viscosity :
It is defined as the ratio of absolute viscosity to the density
of fluid.
ν= η/ρ m²/s ; ρ= density of fluid
4. Viscosity Measurements
Viscosity Measurements
Rotational Viscometers
These viscometer give the value of the ‘dynamic viscosity’.
It is based on the principle that the fluid whose viscosity is
being measured is sheared between two surfaces.
In these viscometers one of the surfaces is stationary and the
other is rotated by an external drive and the fluid fills the
space in between.
The measurements are conducted by applying either a
constant torque and measuring the changes in the speed of
rotation or applying a constant speed and measuring the
changes in the torque.
There are two main types of these viscometers: rotating
cylinder and cone-on-plate viscometers
7. Effects of temperature
Effects of temperature
The viscosity of liquids decreases with increase the
temperature.
The viscosity of gases increases with the increase the
temperature.
8. Effects of temperature
Effects of temperature
The lubricant oil viscosity at a specific temperature can be
either calculated from the viscosity - temperature equation
or obtained from the viscosity-temperature ASTM chart.
Viscosity-Temperature Equations
10. Viscosity index
Viscosity index
An entirely empirical parameter which would accurately
describe the viscosity- temperature characteristics of the
oils.
The viscosity index is calculated by the following formula:
VI = (L - U)/ (L - H) * 10
where ,
VI is viscosity index
U is the kinematic viscosity
of oil of interest
L and H are the kinematic
viscosity of the reference oils
Fig . Shows the evaluation of viscosity index
11. Effects of pressure
Effects of pressure
Lubricants viscosity increases with pressure.
For most lubricants this effect is considerably largest
than the other effects when the pressure is significantly
above atmospheric.
The Barus equation :
13. Viscosity - shear relationship
Viscosity - shear relationship
For Newtonian fluids, shear stress linearly vary with the
shear rate as shown in Figure. Viscosity is constant for
this kind of fluid.
τ = η (u/h)
Non Newtonian fluid doesn’t
follow the linear relation
between viscosity and shear rate.
14. Viscosity – shear relationship
Viscosity – shear relationship
Pseudoplastic Behaviour
Pseudoplastic or shear thinning and is associated with the thinning of the fluid
as the shear rate increases.
Thixotropic Behaviour
Thixotropic or shear duration thinning, is associated with a loss of
consistency of the fluid as the duration of shear increases.
The opposite of this behavior is
known as inverse thixotropic.
15. Applications
Applications
Selection of lubricants for various purpose.
- we can choose an optimum range of viscosity for engine
oil.
- for high load and also for speed operation high viscous
lubricants is required.
In pumping operation
- for high viscous fluid high power will require.
- for low viscous fluid low power will require.
In making of blend fuel
- less viscous fuels easy to mix.
In the operation of coating and printing.
![Introduction
Introduction
Viscosity is a quantitative measure of a fluid’s resistance to
flow.
Dynamic (or Absolute) Viscosity:
The dynamic viscosity(η) of a fluid is a measure of the
resistance it offers to relative shearing motion.
η= F/ [A×(u/h)]
η= τ /(u/h) N-s/m²
Kinematic Viscosity :
It is defined as the ratio of absolute viscosity to the density
of fluid.
ν= η/ρ m²/s ; ρ= density of fluid](https://image.slidesharecdn.com/viscosity-250519041018-892673b4/85/viscosity-of-liquids-powerpoint-presentation-2-320.jpg)
