This document discusses several key properties of fluids: viscosity, surface tension, and capillary action. Viscosity is a fluid's resistance to flow and depends on internal friction. Surface tension is a contractive tendency that allows fluids to resist external forces. Capillary action describes a fluid's ability to flow in narrow spaces without external assistance and against gravity, such as liquid rising in a thin tube. The document provides examples of applications for each property, like lubrication using viscosity and water striders walking on water using surface tension. Formulas for calculating these properties are also presented.
2. CONTENTS:-
PROPERTIES OF FLUID
VISCOSITY
APPLICATION OFVISCOSITY
SURFACETENSION
APPLICATION OF SURFACETENSION
CAPILLARY ACTION
APPLICATION OF CAPILLARYACTION
CONCLUSION
3. PROPERTIES OF FLUIDS:-
Matter exists in two states- the solid state and
the fluid state.This classification of matter is
based on the spacing between different
molecules of matter as well as on the behavior of
matter when subjected to stresses. Because
molecules in solid state are spaced very closely,
solids possess compactness and rigidity of form.
The molecules in fluid can move more freely
within the fluid mass and therefore the fluids do
not possess any rigidity of form.
4. THE PROPERTIES OF FLUIDS ARE:-
VISCOSITY
SURFACETENSION
COMPRESSIBILITY
6. Viscosity is a measure of a fluid's
resistance to flow. It describes the internal
friction of a moving fluid. A fluid with large
viscosity resists motion because its molecular
makeup gives it a lot of internal friction. A
fluid with low viscosity flows easily because
its molecular makeup results in very little
friction when it is in motion. Gases also have
viscosity, although it is a little harder to
notice it in ordinary circumstances.
7.
8. APPLICATION OF VISCOSITY :-
1. Transparent and storing facilities for fluids ie,
pipes, tanks
2. Bitumen used for road construction.
3. Designing of the sewer line or any other pipe
flow viscosity play an important role in finding
out its flow behaviour.
4. Drilling for oil and gas requires sensitive
viscosity.
5. To maintain the performance of machine and
automobiles by determining thickness of
lubricating oil or motor oil.
9. TO MAINTAIN THE PERFORMANCE
OF MACHINE AND AUTOMOBILES:-
Oil viscosity needs to suit the right ambient temperatures. If
it’s too thick when the engine is cold, it won’t move around the
engine. And if it becomes too thin when the engine is hot, it won’t
give the right protection to the engine parts.Optimising an oil’s
viscosity, or thickness, helps maximise energy efficiency while
avoiding component wear. Viscosity modifiers increase the viscosity
of your oil at high temperature but have little effect on low-
temperature viscosity. These enable your oil to flow properly when
cold and also to remain thick enough to protect your engine
components at high temperatures.
Lower-viscosity grades of oil such as Shell Helix Ultra, make it
easier for your engine to start from cold because they present less
resistance to moving parts and hence take less power from your
engine.This also means that you get enhanced fuel economy.
10. TYPES OF VISCOMETER :-
Laboratory viscometers for fluid
U-tube
Falling sphere
Falling PistonViscometers
Falling SphereViscometers
11. U-TUBE MANOMETER
Pressure measuring devices using liquid
columns in vertical or inclined tubes are called
manometers. One of the most common is the
water filled u-tube manometer used to
measure pressure difference in pitot or
orifices located in the airflow in air handling
or ventilation system.
pd = γ h
= ρ g h
where
pd = pressure
γ = specific weight of the fluid in the tube (kN/m3, lb/ft3 )
ρ = density (kg/m3, lb/ft3)
g = acceleration of gravity (9.81 m/s2, 32.174 ft/s2)
h = liquid height (m, ft)
12. SURFACE TENSION
Surface tension is a contractive tendency
of the surface of a fluid that allows it to resist
an external force. Surface tension is an
important property that markebly influences
the ecosystems.
13. Whenever a fluid is left to itself, the fluid
tends to attend the minimum surface area
possible. The reason behind this is that while
a molecule inside the fluid is pulled in each
and every direction by the adjacent
molecules in the surface of the fluid , the case
is different. the adhesive forces causes
downward pull on the molecule due to
cohesent. So the molecule on the surface
tends to move down but it is repelled by the
molecules below it.
14. FORMULA USED TO CALCULATE SURFACE TENSION :-
Where,
Where, γ = surface tension
θ = contact angle
ρ = density
g = acceleration due to gravity
r = radius of tube
15. The magnitude of repulsive forces per
unit length is called surface tension or
coefficient of surface tension.
σ = F/L
16. APPLICATION OF SURFACE TENSION :-
A water strider can walk on water.
Some tent are made impermeable of the
rain but they are not really impermeable, but
if water is placed on it then the water doesn’t
pass through the fine small pores of the tent
cover. But as you touch the cover while water
is on it, you break surface tension and water
passes through.
17.
18. CAPILLARY ACTION :-
Capillary action is the ability of a fluid to flow in
narrow spaces without the assistance of, and in
opposition to, external forces like gravity.
19. A common apparatus used to demonstrate
the first phenomenon is the capillary tube. When
the lower end of a vertical glass tube is placed in
a fluid, such as water a concave meniscus forms.
Adhesion occurs between the fluid and the solid
inner wall pulling the fluid column up until there
is a sufficient mass of fluid for gravitational
forces to overcome these intermolecular forces.
The contact length between the top of the fluid
column and the tube is proportional to the
diameter of the tube, while the weight of the
fluid column is proportional to the square of
tube’s diameter. So, a narrow tube will draw a
fluid column higher than a wider tube will.
20. APPLICATION OF CAPILLARY ACTION :-
Capillary action is found in thermometer
where fluid used in it automatically rises
when comes in contact with higher
temperature or falls down with lower ones.
Capillary action can be performed to transfer
fluid from one vessel to another on its own.
Capillary action can be experienced in the half
dipped cloth as well as on lantern.
21. CAPILLARY ACTION ON LANTERN :-
Capillary action works by drawing the
kerosene/oil out of the fount to the tip of the
wick where the flame heats the oil to a gas
and ignites it.
When one end of the cloth kept in
contact with the oil and another at the top to
burn, the oil rises upward with the help of the
cloth. Due to the capillary action, the oil
simply travels to the top and ignites