Transcript Slide 1
Unit 6 : Part 1
Fluids
Overview
Pressure and Pascal’s Principle
Buoyancy and Archimedes’ Principle
Fluid Dynamics and Bernoulli’s Equation
Fluids: Pressure and Pascal’s Principle
Pressure is defined as the force per unit area:
If the force is at an
angle to the
surface, the more
general form (blue
box) is used.
Fluids: Pressure and Pascal’s
Principle
Unit of pressure: the Pascal (Pa)
Density is defined as mass per unit volume:
Fluids: Pressure and Pascal’s
Principle
Fluids: Pressure and Pascal’s
Principle
The pressure in a
fluid increases with
depth, due to the
weight of fluid
above it.
Fluids: Pressure and Pascal’s
Principle
Pascal’s principle:
Pressure applied to an
enclosed fluid is transmitted
undiminished to every point
in the fluid and to the walls
of the container.
Fluids: Pressure and Pascal’s Principle
Hydraulic lifts and shock absorbers take
advantage of Pascal’s principle.
Fluids: Pressure and Pascal’s
Principle
Since the pressure is constant, a small force
acting over a small area can become a large
force acting over a large area.
Fluids: Pressure and Pascal’s
Principle
There are a number of methods used to
measure pressure.
Fluids: Pressure and Pascal’s
Principle
Absolute pressure is the total force per unit
area. We often measure the gauge pressure,
which is the excess over atmospheric pressure.
Atmospheric pressure historically was
measured using a mercury barometer.
Fluids: Pressure and Pascal’s
Principle
The pressure corresponding to 1 mm of
mercury is called the torr (in honor of
Torricelli).
Buoyancy and Archimedes’ Principle
A body immersed wholly or partially in a fluid
experiences a buoyant force equal in magnitude to the
weight of the volume of fluid that is displaced:
An object’s density will tell you whether it will
sink or float in a particular fluid.
Buoyancy and Archimedes’ Principle
The buoyant force on an object that is
completely submerged:
Buoyancy and Archimedes’ Principle
It is the average density that matters; a boat
made of steel can float because its interior is
mostly air.
An object’s density may be changed;
submarines fill tanks with water to submerge,
and with air to rise.
Buoyancy and Archimedes’ Principle
Specific gravity is the ratio of an object’s
density to that of water at 4°C.
Fluid Dynamics and Bernoulli’s Equation
In an ideal fluid, flow is
steady, irrotational,
nonviscous, and
incompressible.
Steady flow means that all the
particles of a fluid have the same
velocity as they pass a given
point.
Steady flow can be
described by streamlines.
Fluid Dynamics and Bernoulli’s
Equation
Irrotational flow means that a fluid element (a small
volume of the fluid) has no net angular velocity. This
condition eliminates the possibility of whirlpools and
eddy currents. (The flow is nonturbulent.)
In the previous figure, the paddle wheel does
not turn, showing that the flow at that point is
irrotational.
Fluid Dynamics and Bernoulli’s
Equation
Nonviscous flow means that viscosity is negligible.
Viscosity produces drag, and retards fluid flow.
Incompressible flow means that the fluid’s density is
constant. This is generally true for liquids, but not
for gases.
Fluid Dynamics and Bernoulli’s
Equation
Equation of continuity:
Fluid Dynamics and Bernoulli’s
Equation
If the density is constant,
Fluid Dynamics and Bernoulli’s
Equation
Bernoulli’s equation is a consequence of the
conservation of energy.
Fluid Dynamics and Bernoulli’s
Equation
One consequence of Bernoulli’s equation, that
the pressure is lower where the speed is higher,
can be counterintuitive.
Fluid Dynamics and Bernoulli’s
Equation
The flow rate from a tank with a hole is given by
Bernoulli’s equation; the pressure at open areas
is atmospheric pressure.
Review
Pressure is defined as force per unit area.
Pressure varies with depth in a fluid:
Review
Pressure in an enclosed fluid is transmitted
unchanged to every part of the fluid.
The buoyant force is equal to the weight of
displaced fluid.
An object will float if its average density is
less than that of the fluid; if it is greater,
the object will sink.
Review
Equation of continuity:
Flow rate equation:
Bernoulli’s law: