University Physics with Modern Physics Fifteenth Edition Chapter 12 : Fluid Mechanics PDF

Summary

This document is a chapter from a university physics textbook focusing on fluid mechanics. The chapter covers topics such as density, pressure, and different types of flow in fluids. It includes illustrative examples, diagrams, and information on key figures and concepts in fluid dynamics.

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University Physics with Modern Physics
Fifteenth Edition

Chapter 12
Fluid Mechanics

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Learning Outcomes
In this chapter, you’ll learn…
the meaning of the density and pressure of a fluid, and how
they are measured.
how to calculate the buoyant force that a fluid exerts on an
object immersed in it.
how to use Bernoulli’s equation to relate pressure and flow
speed at different points in certain types of flow.
the significance of laminar versus turbulent fluid flow, and
how the speed of flow in a tube depends on the tube’s size.
how viscous flow and turbulent flow differ from ideal flow.
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Introduction
A colorful tail-spot wrasse is
about 10 cm long and can float
in the ocean with little effort.
A manta ray is more than 5 m
across and must “flap” its fins
continuously to keep from
sinking.
The differences have to do with
fluid mechanics.
We begin with fluids at rest and
then move on to the more
complex field of fluid dynamics.

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Density (1 of 2)
An important property of any material, fluid or solid, is
its density, defined as its mass per unit volume.
A homogeneous material such as ice or iron has the
same density throughout.
For a homogeneous material,

The SI unit of density is the kilogram per cubic meter
(1 kg/m3 ).

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Density (2 of 2)
Here are two objects with different masses and
different volumes, but the same density.

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Densities of Some Common
Substances
Material Density(kilograms
kg/m per3cubic meter
)
Air (1 atm, 20 1.20 ✕ 100
degrees Celsius)
Ice 0.92 10 3
0.92 times 10 cubed

Water 1.00 times 10 cubed
1.00 10 3

Blood 1.06 times 10 cubed
1.06 10 3

Aluminum 2.7 times 10 cubed
2.7 10 3

Lead 11.3 times 10 cubed
11.3 10 3

Gold 19.3 times 10 cubed
19.3 10 3

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Pressure in a Fluid
A fluid exerts a force perpendicular to any surface in
contact with it, such as a container wall or an object
immersed in the fluid.
Consider a small surface of area dA within a fluid at
rest, centered on a point in the fluid.
We define the pressure p at that point as:

The SI unit of pressure is the pascal, where
1 pascal 1 Pa = 1 N/m2.
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Pressure
Here are the forces
acting on a small
surface within a fluid
at rest.

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Pressure Is a Scalar Quantity

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Pressure at Depth in a Fluid (1 of 2)
The pressure at a depth h in a fluid is greater than the
pressure p0 at the surface:

Video Tutor Solution: Example 12.4

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Pressure at Depth in a Fluid (2 of 2)
Each fluid column has the
same height, no matter what
its shape.

Video Tutor Demonstration: Wa
ter Level in Pascal’s Vases

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Pascal’s law
Pressure applied to an
enclosed fluid is
transmitted undiminished
to every portion of the fluid
and the walls of the
containing vessel:
F1 F2
p 
A1 A2

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Absolute Pressure and Gauge
Pressure
When we say that the pressure in a car tire is “32 psi”
(2.2 × 105 Pa), we mean that it is greater than
atmospheric pressure by this amount.
The total pressure in the tire is greater by patm.
The excess pressure above atmospheric pressure is
usually called gauge pressure.
The total pressure is called absolute pressure.
If the pressure is less than atmospheric, as in a partial
vacuum, the gauge pressure is negative.

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Pressure Gauges
This Bourdon-type pressure gauge is connected to a
high-pressure gas line.
The gauge pressure shown is just over 5 bars
(1 bar = 105 Pa).

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Blood Pressure
Blood-pressure readings, such as 130/80, give the maximum and
minimum gauge pressures in the arteries, measured in “mm Hg” or
“torr.”
Blood pressure varies with vertical position within the body.
The standard reference point is the upper arm, level with the heart.

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Archimedes's Principle: Proof Step 1

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Archimedes's Principle: Proof Step 2

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Archimedes's Principle
An object immersed in water seems to weigh less than when it is
in air.
When the object is less dense than the fluid, it floats.
The human body usually floats in water, and a helium-filled
balloon floats in air.
These are examples of buoyancy, a phenomenon described by
Archimedes’s principle:
‒ When an object is completely or partially immersed in a
fluid, the fluid exerts an upward force on the object
equal to the weight of the fluid displaced by the object.
Video Tutor Demonstration: Weighing Weights in Water

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Surface Tension (1 of 2)
The surface of the water acts like a membrane under
tension, allowing this water strider to “walk on water.”

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Surface Tension (2 of 2)
A molecule at the surface of a
liquid is attracted into the bulk
liquid, which tends to reduce
the liquid’s surface area.

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Fluid Flow (1 of 2)
The path of an individual particle in a moving fluid is called a
flow line.
In steady flow, the overall flow pattern does not change with
time, so every element passing through a given point follows
the same flow line.
In steady flow no fluid can cross the side walls of a given flow
tube.

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Fluid Flow (2 of 2)
In laminar flow, adjacent layers of
fluid slide smoothly past each
other and the flow is steady.
At sufficiently high flow rates, the
flow can become turbulent.
In turbulent flow there is no
steady-state pattern; the flow
pattern changes continuously.

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The Continuity Equation (1 of 2)
The figure at the right shows
a flow tube with changing
cross-sectional area.
The continuity equation for
an incompressible fluid is A1v1
= A2v2.
The volume flow rate is
dV
 Av.
dt

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The Continuity Equation (2 of 2)
The continuity equation
helps explain the shape of
a stream of honey poured
from a spoon.

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Bernoulli's Equation
Bernoulli’s equation is:
1 1
p1  pgy1  pv12  p2  pgy 2  pv 2 2
2 2
It is due to the fact that the work
done on a unit volume of fluid by
the surrounding fluid is equal to
the sum of the changes in kinetic
and potential energies per unit
volume that occur during the flow.
Video Tutor Solution: Example
12.7
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Why Healthy Giraffes Have High
Blood Pressure
Bernoulli’s equation suggests
that as blood flows upward at
roughly constant speed v from
the heart to the brain, the
pressure p will drop as the
blood’s height y increases.
For blood to reach the brain
with the required minimal
pressure, the giraffe’s
maximum (systolic) blood
pressure must be 280 mm Hg!

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The Venturi Meter
The pressure is less at point 2 because the fluid flow
speed is greater.

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Lift on an Airplane Wing (1 of 2)
Bernoulli’s principle helps to explain how airplanes fly.

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Lift on an Airplane Wing (2 of 2)
Computer simulation of air parcels flowing around a
wing, showing that air moves much faster over the top
than over the bottom.

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Viscosity (1 of 2)
Viscosity is internal
friction in a fluid.
Due to viscosity, the
speed is zero at the
pipe walls (to which
the fluid clings) and is
greatest at the center
of the pipe.

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Viscosity (2 of 2)
Lava is an example of a viscous fluid.
The viscosity decreases with increasing temperature:
The hotter the lava, the more easily it can flow.

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Turbulence
At low flow speeds, the flow of a fluid of a given viscosity is
laminar.
When a critical speed is exceeded, however, the flow pattern
becomes turbulent.

Video Tutor Solution: Example 12.11
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Listening for Turbulent Flow
Normal blood flow in the human
aorta is laminar, but a small
disturbance such as a heart
pathology can cause the flow to
become turbulent.
Turbulence makes noise, which
is why listening to blood flow
with a stethoscope is a useful
diagnostic technique.

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