Transcript Slide 1

Chapter 9
Static Equilibrium; Elasticity
and Fracture
Equilibrium
• First Condition of Equilibrium
– The net external force must be zero
F  0
Fx  0 and Fy  0
• Second Condition of Equilibrium
– The net external torque must be zero
  0
Torque and Equilibrium, cont
• To ensure mechanical equilibrium, you
need to ensure rotational equilibrium as
well as translational
• The Second Condition of Equilibrium
states
– The net external torque must be zero
  0
9-1 The Conditions for Equilibrium
The first condition for
equilibrium is that the forces
along each coordinate axis
add to zero.
9-2 Solving Statics Problems
The previous technique may not fully solve all
statics problems, but it is a good starting point.
9.2 Rigid Objects in Equilibrium
Example 3 A Diving Board
A woman whose weight is 530 N is
poised at the right end of a diving board
with length 3.90 m. The board has
negligible weight and is supported by
a fulcrum 1.40 m away from the left
end.
Find the forces that the bolt and the
fulcrum exert on the board.
9.2 Rigid Objects in Equilibrium
  F 
2 2
WW  0
W W
F2 
2
F2

530 N 3.90 m 

 1480 N
1.40 m
9.2 Rigid Objects in Equilibrium
F
y
 F1  F2 W  0
 F1  1480N  530 N  0
F1  950 N
9-2 Solving Statics Problems
If there is a cable or cord in
the problem, it can support
forces only along its length.
Forces perpendicular to that
would cause it to bend.
9-1 The Conditions for Equilibrium
The second condition of equilibrium is that
there be no torque around any axis; the choice
of axis is arbitrary.
9-2 Solving Statics Problems
1. Choose one object at a time, and make a freebody diagram showing all the forces on it and
where they act.
2. Choose a coordinate system and resolve
forces into components.
3. Write equilibrium equations for the forces.
4. Choose any axis perpendicular to the plane of
the forces and write the torque equilibrium
equation. A clever choice here can simplify the
problem enormously.
5. Solve.
9-2 Solving Statics Problems
If a force in your solution comes out negative (as
FA will here), it just means that it’s in the opposite
direction from the one you chose. This is trivial to
fix, so don’t worry about getting all the signs of the
forces right before you start solving.
9-3 Applications to Muscles and Joints
These same principles can
be used to understand forces
within the body.
9-3 Applications to
Muscles and Joints
The angle at which this man’s
back is bent places an
enormous force on the disks
at the base of his spine, as
the lever arm for FM is so
small.
9-4 Stability and Balance
If the forces on an object are such that they
tend to return it to its equilibrium position, it is
said to be in stable equilibrium.
9-4 Stability and Balance
If, however, the forces tend to move it away from
its equilibrium point, it is said to be in unstable
equilibrium.
9-4 Stability and Balance
An object in stable equilibrium may become
unstable if it is tipped so that its center of gravity is
outside the pivot point. Of course, it will be stable
again once it lands!
9-4 Stability and Balance
People carrying heavy loads automatically
adjust their posture so their center of mass is
over their feet. This can lead to injury if the
contortion is too great.
9-5 Elasticity; Stress and Strain
Hooke’s law: the change in
length is proportional to the
applied force.
(9-3)
9-5 Elasticity; Stress and Strain
This proportionality holds until the force
reaches the proportional limit. Beyond that, the
object will still return to its original shape up to
the elastic limit. Beyond the elastic limit, the
material is permanently deformed, and it breaks
at the breaking point.
9-5 Elasticity; Stress and Strain
The change in length of a stretched object
depends not only on the applied force, but also
on its length and cross-sectional area, and the
material from which it is made.
The material factor is called Young’s modulus,
and it has been measured for many materials.
The Young’s modulus is then the stress divided
by the strain.
9-5 Elasticity; Stress and Strain
In tensile stress, forces
tend to stretch the
object.
9-5 Elasticity; Stress and Strain
Compressional stress is exactly the opposite of
tensional stress. These columns are under
compression.
9-5 Elasticity; Stress and Strain
Shear stress tends to deform an object:
9-6 Fracture
If the stress is too great, the object will
fracture. The ultimate strengths of materials
under tensile stress, compressional stress,
and shear stress have been measured.
When designing a
structure, it is a
good idea to keep
anticipated stresses
less than 1/3 to 1/10
of the ultimate
strength.
9-6 Fracture
A horizontal beam will be under both tensile and
compressive stress due to its own weight.
9-6 Fracture
What went wrong here?
These are the remains of an
elevated walkway in a
Kansas City hotel that
collapsed on a crowded
evening, killing more than
100 people.
9-6 Fracture
Here is the original design of
the walkway. The central
supports were to be 14 meters
long.
During installation, it was
decided that the long supports
were too difficult to install; the
walkways were installed this way
instead.
9-1 The Conditions for Equilibrium
An object with forces acting on it, but that is
not moving, is said to be in equilibrium.
9-6 Fracture
The change does not appear major until you
look at the forces on the bolts:
The net force on the pin in the
original design is mg, upwards.
When modified, the net force
on both pins together is still
mg, but the top pin has a force
of 2mg on it – enough to
cause it to fail.
9-7 Spanning a Space: Arches and Domes
The Romans developed
the semicircular arch
about 2000 years ago.
This allowed wider
spans to be built than
could be done with
stone or brick slabs.
9-7 Spanning a Space: Arches and Domes
The stones or bricks in a round arch are mainly
under compression, which tends to strengthen
the structure.
9-7 Spanning a Space: Arches and Domes
Unfortunately, the
horizontal forces
required for a
semicircular arch can
become quite large –
this is why many Gothic
cathedrals have “flying
buttresses” to keep
them from collapsing.
9-7 Spanning a Space: Arches and Domes
Pointed arches can be built that require
considerably less horizontal force.
9-7 Spanning a Space: Arches and Domes
A dome is similar to
an arch, but spans a
two-dimensional
space.
Summary of Chapter 9
• An object at rest is in equilibrium; the study
of such objects is called statics.
• In order for an object to be in equilibrium,
there must be no net force on it along any
coordinate, and there must be no net torque
around any axis.
• An object in static equilibrium can be either in
stable, unstable, or neutral equilibrium.
Summary of Chapter 9
• Materials can be under compression, tension,
or shear stress.
• If the force is too great, the material will exceed
its elastic limit; if the force continues to increase
the material will fracture.