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Physics 207: Lecture 21, Pg 1
Chapter 15, Fluids & ElasticityThis is an actual photo of an iceberg, taken by a rig manager for Global Marine Drilling in St. Johns, Newfoundland. The water was calm and the sun was almost directly overhead so that the diver
Physics 207: Lecture 21, Pg 2
Lecture 21Goals:Goals:
• Chapter 15Chapter 15 Understand pressure in liquids and gases Use Archimedes’ principle to understand buoyancy Understand the equation of continuity Use an ideal-fluid model to study fluid flow. Investigate the elastic deformation of solids and liquids
• AssignmentAssignment HW10, Due Wednesday, Apr. 14th Thursday: Read all of Chapter 16
Physics 207: Lecture 21, Pg 3
Fluids
At ordinary temperature, matter exists in one of three states Solid - has a shape and forms a
surface Liquid - has no shape but forms a
surface Gas - has no shape and forms no
surface What do we mean by “fluids”?
Fluids are “substances that flow”…. “substances that take the shape of the container”
Atoms and molecules are free to move.
No long range correlation between positions.
Physics 207: Lecture 21, Pg 4
Fluids
An intrinsic parameter of a fluid Density
V
m
units :kg/m3 = 10-3 g/cm3
(water) = 1.000 x 103 kg/m3 = 1.000 g/cm3
(ice) = 0.917 x 103 kg/m3 = 0.917 g/cm3
(air) = 1.29 kg/m3 = 1.29 x 10-3 g/cm3
(Hg) = 13.6 x103 kg/m3 = 13.6 g/cm3
(W or Au) = 19.3 x103 kg/m3 = 19.3 g/cm3
Physics 207: Lecture 21, Pg 5
Fluids
nF ˆAp
A
Any force exerted by a fluid is perpendicular to a surface of contact, and is proportional to the area of that surface.
Force (a vector) in a fluid can be expressed in terms of pressure (a scalar) as:
A F
p Another parameter: Pressure
n̂
Physics 207: Lecture 21, Pg 6
What is the SI unit of pressure?
A. PascalB. AtmosphereC. BernoulliD. YoungE. p.s.i.
Units : 1 N/m2 = 1 Pa (Pascal)1 bar = 105 Pa1 mbar = 102 Pa1 torr = 133.3 Pa
1 atm = 1.013 x105 Pa = 1013 mbar
= 760 Torr = 14.7 lb/ in2 (=PSI)
Physics 207: Lecture 21, Pg 7
When the pressure is small, relative to the bulk modulus of the fluid, we can treat the density as constant independent of pressure:
incompressible fluid
For an incompressible fluid, the density is the same everywhere, but the pressure is NOT!
p(y) = p0 - y g Gauge pressure (subtract p0) pGauge = p(y) - p0
Pressure vs. DepthIncompressible Fluids (liquids)
y1 y2
Ap
1
p2
F1
F2
mg
0p
F2 = F1+ m g = F1+ VgF2 /A = F1/A + Vg/Ap2 = p1 - g y
Physics 207: Lecture 21, Pg 8
Pressure vs. Depth
For a uniform fluid in an open container pressure same at a given depth independent of the container
p(y)
y
Fluid level is the same everywhere in a connected container, assuming no surface forces
Physics 207: Lecture 21, Pg 9
Pressure Measurements: Barometer Invented by Torricelli A long closed tube is filled with mercury
and inverted in a dish of mercury
The closed end is nearly a vacuum
Measures atmospheric pressure as
1 atm = 0.760 m (of Hg)
Physics 207: Lecture 21, Pg 10
Exercise Pressure
What happens with two fluids??
Consider a U tube containing liquids of density 1 and 2
as shown:
Compare the densities of the liquids:
(A) 1 < 2 (B) 1 = 2 (C) 1 > 2
1
2
dI
Physics 207: Lecture 21, Pg 11
Exercise Pressure
What happens with two fluids??
Consider a U tube containing liquids of density 1 and 2 as shown:
At the red arrow the pressure must be the same on either side. 1 x = 2 (d1+ y)
Compare the densities of the liquids:
(A) 1 < 2 (B) 1 = 2 (C) 1 > 2
1
2dI
y
Physics 207: Lecture 21, Pg 12
Archimedes’ Principle: A Eureka Moment
Suppose we weigh an object in air (1) and in water (2).
How do these weights compare?
W2?W1
W1 < W2 W1 = W2W1 > W2
Buoyant force is equal to the weight of the fluid displaced
Physics 207: Lecture 21, Pg 14
Archimedes’ Principle
Suppose we weigh an object in air (1) and in water (2).
How do these weights compare?
W2?W1
W1 < W2 W1 = W2W1 > W2
Why?
Since the pressure at the bottom of the object is greater than that at the top of the object, the water exerts a net upward force, the buoyant force, on the object.
Physics 207: Lecture 21, Pg 15
Sink or Float?
The buoyant force is equal to the weight of the liquid that is displaced.
If the buoyant force is larger than the weight of the object, it will float; otherwise it will sink.
F mgB
y
We can calculate how much of a floating object will be submerged in the liquid:
Object is in equilibrium mgFB
objectobjectliquidliquid VgVg
liquid
object
object
liquid
V
V
Physics 207: Lecture 21, Pg 16
Bar Trick
piece of rockon top of ice
What happens to the water level when the ice melts?
A. It rises B. It stays the same C. It drops
Expt. 1 Expt. 2
Physics 207: Lecture 21, Pg 17
Exercise
V1 = V2 = V3 = V4 = V5
m1 < m2 < m3 < m4 < m5
What is the final position of each block?
Physics 207: Lecture 21, Pg 18
Exercise
V1 = V2 = V3 = V4 = V5
m1 < m2 < m3 < m4 < m5
What is the final position of each block?
Not this But this
Physics 207: Lecture 21, Pg 24
Pascal’s Principle So far we have discovered (using Newton’s Laws):
Pressure depends on depth: p = - g y Pascal’s Principle addresses how a change in pressure is
transmitted through a fluid.
Any change in the pressure applied to an enclosed fluid is transmitted to every portion of the fluid and to the walls of the containing vessel.
Physics 207: Lecture 21, Pg 25
Pascal’s Principle in action: Hydraulics, a force amplifier
Consider the system shown: A downward force F1 is applied
to the piston of area A1.
This force is transmitted through the liquid to create an upward force F2.
Pascal’s Principle says that increased pressure from F1 (F1/A1) is transmitted throughout the liquid.
F F
1
2
d
2d
1
A A21
F2 > F1 with conservation of energy
P1 = P2
F1 / A1 = F2 / A2
A2 / A1 = F2 / F1
Physics 207: Lecture 21, Pg 27
Fluids in Motion
To describe fluid motion, we need something that describes flow: Velocity v
There are different kinds of fluid flow of varying complexity non-steady / steady compressible / incompressible rotational / irrotational viscous / ideal
Physics 207: Lecture 21, Pg 28
Types of Fluid Flow Laminar flow
Each particle of the fluid follows a smooth path
The paths of the different particles never cross each other
The path taken by the particles is called a streamline
Turbulent flow An irregular flow
characterized by small whirlpool like regions
Turbulent flow occurs when the particles go above some critical speed
Physics 207: Lecture 21, Pg 29
Types of Fluid Flow Laminar flow
Each particle of the fluid follows a smooth path
The paths of the different particles never cross each other
The path taken by the particles is called a streamline
Turbulent flow An irregular flow
characterized by small whirlpool like regions
Turbulent flow occurs when the particles go above some critical speed
Physics 207: Lecture 21, Pg 30
Lecture 21
• Question to ponder: Does heavy water (DQuestion to ponder: Does heavy water (D22O) ice sink O) ice sink or float?or float?
• AssignmentAssignment HW10, due Wednesday, Apr. 14th Thursday: Read all of Chapter 16