Fluid Mechanics PDF

Summary

These are lecture notes for a course on fluid mechanics. Topics covered include states of matter, fluid properties (density and pressure), hydrostatic pressure, Bernoulli's equation, and applications. The presenter is Ranjini Rajammal from Manipal University College Malaysia.

Full Transcript

CHAPTER 4
Fluid Mechanics
Dr. Ranjini Rajammal
 Chapter Outline:
Pressure and its application
Archimedes’s Principle
Pascal’s Principle
Bernoulli’s Principle
States of Matter

Before we begin to understand the nature of a fluid
we must understand the basic nature of all states
of matter:
The 3 primary states of matter:
① solid - definite shape and volume.
② liquid -takes the shape of its container yet has
a definite volume.
③ gas - takes the shape and volume of its
container.
What is a Fluid?
By definition, a fluid is any material that is unable
to withstand a shear stress. Unlike an elastic solid
which responds to a shear stress with a
recoverable deformation, a fluid responds with an
irrecoverable flow.
Examples of fluids include gases and liquids.
Why fluids are useful in
physics?
Typically, liquids are considered to be incompressible.
That is once you place a liquid in a sealed container you
can DO WORK on the FLUID as if it were a rigid object.
The PRESSURE you apply is transmitted throughout the
liquid and over the entire length of the fluid itself.
Fluid Properties - Density

The mass density  of any substance is the
mass of the substance divided by the volume
it occupies:

m unit: kg/m3
 mass can be found as m = V
V and weight as mg = Vg

The density of water is 1000kg/m3
Fluid Properties - Pressure

Any fluid can exert a force perpendicular to its surface on
the walls of its container. This force is described in terms
of the pressure it exerts, or force per unit area:

Other units of pressure:

N/m2 = Pascal
psi (pounds per square inch)
atmosphere

The same force applied over a smaller area results in greater
pressure – think of poking a balloon with your finger and then
with a needle.
Problem Example
A waterbed is 2.0 m on a side and 30.0 cm deep.
a) Find its weight if the density of water is 1000 kg/m3.
b) Find the pressure the waterbed exerts on the floor.
Assume that the entire lower surface of the bed makes
contact with the floor.
Atmospheric Pressure
Atmospheric pressure is due to the weight of the
atmosphere above us.

N
1 2 = 1 Pascal (Pa)
m
 Fluid Properties - Hydrostatic Pressure

If a Fluid (such as a liquid) is at REST, the pressure it
exerts is called HYDROSTATIC PRESSURE
Two important points
A fluid will exert a pressure in all directions
A fluid will exert a pressure perpendicular to any
surface it compacts

Notice that the arrows on TOP of the objects are smaller than at
the BOTTOM. This is because pressure is greatly affected by the
DEPTH of the object. Since the bottom of each object is deeper
than the top the pressure is greater at the bottom.
Pressure vs. Depth
Fatm
Suppose we had an object
submerged in water with the top
part touching the atmosphere. If
we were to draw an FBD for this
object we would have three
forces
1. The weight of the object
Fwater mg 2. The force of the atmosphere
pressing down
3. The force of the water
pressing up
Fwater= Fatm + mg
Pressure vs. Depth
Fatm
But now suppose the
“object” is just a cylindrical
container holding water.
This water also has weight
and the same equation
applies.

Fwater mg Finally, make the container
imaginary. The water is still
there and its weight. This
weight is that affects the
pressure below it.
Fwater= Fatm + mg
Pressure vs. Depth
But pressure is force per unit area. So express the force
of the fluids in terms of pressure.
F
P Fwater  Fatm  mg
A
PA  Po A  mg Note: The initial
pressure in this
m
  m  V case is atmospheric
V pressure, which is a
PA  Po A  Vg CONSTANT.

V  Ah Po = 1 x 105 N/m2
PA  Po A  Ahg
P  Po  gh
A closer look at Pressure vs. Depth

P  Po  gh
Depth below surface

ABSOLUTE PRESSURE
Initial Pressure – May or The weight of the
May NOT be atmospheric volume of fluid.
pressure

P  gh
Gauge Pressure = CHANGE in pressure or the
DIFFERENCE in the initial and absolute pressure
Example

Calculate the absolute pressure at an ocean depth of 1000 m.
Assume that the density of water is 1000 kg/m3 and that
Po= 1.01 x 105 Pa (N/m2)..
Pascal’s Principle
“states that when pressure is applied to an enclosed
fluid, the pressure is transmitted equally to every point
in the fluid and to every point on the walls of the
container.”
If you take a liquid and place it in a system that is
CLOSED (plumbing or a car’s brake line), the
PRESSURE is the same everywhere in the system.

The fact that the pressure is the same in a closed system
has MANY applications.

This is called PASCAL’S PRINCIPLE
Pascal’s Principle
Another Example - Brakes
In the case of a car's brake pads, a
small initial force applied by you on
the brake pedal is transferred via a
brake line, which has a small
cylindrical area. The brake fluid then
enters a chamber with more AREA
allowing a LARGE FORCE to be
applied on the brake shoes, which in
turn slow the car down.

P1  P2
Fbrake pedal Fbrake pad / shoe

Abrake pedal Abrake pad / shoe
Another Example –
Hydraulic Lift
In a car lift in a service station, compressed air exerts a force on
a small piston of circular cross section having a radius of 5.0 cm.
This pressure is transmitted by an incompressible liquid to a
second piston of radius 15 cm.
What force must the compressed air exert in order to lift a car
weighing 13300 N?
P1  P2
F1 F2

A1 A2
A1
F1  F2
A2
 0.052
F1  13300
 0.152

F1  1478 N
Buoyancy
When an object is immersed in a fluid, such as a liquid, it is buoyed
UPWARD by a force called the BUOYANT FORCE.
When the object is placed in fluid
is DISPLACES a certain amount
of fluid. If the object is completely
submerged, the VOLUME of the
OBJECT is EQUAL to the
VOLUME of FLUID it displaces.
Archimedes' Principle
" An object is buoyed up by a force equal to
the weight of the fluid displaced."

In the figure, we see that the
difference between the
weight in AIR and the weight
in WATER is 3 lbs. This is
the buoyant force that acts
upward to cancel out part of
the force. If you were to
weight the water displaced it
also would weigh 3 lbs.
Archimedes' Principle

Buoyant Force Weight (Force) of
displaced fluid

FB = (mg)Fluid m = r V
FB = ( r Vg)Fluid Weight (Force) in
terms of density of
the fluid.
Vobject = VFluid
Problem Example
A bargain hunter purchases a "gold" crown at a flea market. After she
gets home, she hangs it from a scale and finds its weight in air to be
7.84 N. She then weighs the crown while it is immersed in water (density
of water is 1000 kg/m3) and now the scale reads 6.86 N. Is the crown
made of pure gold if the density of gold is 19.3 x 103 kg/m3?
Fobject (air ) - Fobject (water ) = Fbuoyant
7.84 - 6.86 = FB = 0.98 N NO! This is NOT gold as 8000