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Title: Goals:


1
Lecture 21
  • Goals
  • Discussion conditions for static equilibrium
  • Use Free Body Diagrams prior to problem solving
  • Introduce Youngs, Shear and Bulk modulus

Exam 3 Wednesday, April, 18th 715-845 PM
2
Statics
Equilibrium is established when
In 3D this implies SIX expressions (x, y z)
3
Three force and three torque expressions
4
Free Body Diagram Rules
  • For forces zero acceleration reflects the motion
    of the center of mass
  • For torques the position of the force vector
    matters
  • We are free to choose the axis of rotation
    (usually one that simplifies the algebra)

5
Statics Using Torque
  • Now consider a plank of mass M suspended by two
    strings as shown.
  • We want to find the tension in each string

6
Statics Using Torque
  • Now consider a plank of mass M suspended by two
    strings as shown.
  • We want to find the tension in each string

7
Statics Using Torque
  • Now consider a plank of mass M suspended by two
    strings as shown.
  • Using a different torque position

8
Another Example See-saw
60 kg
30 kg
30 kg
  • Two children (60 kg and 30 kg) sit on a 3.0 m
    long uniform horizontal teeter-totter of mass 30
    kg. The larger child is 1.0 m from the pivot
    point while the smaller child is trying to figure
    out where to sit so that the teeter-totter
    remains motionless.
  • Position of the small boy?

9
Example Soln.
30 kg
d
  • Draw a Free Body diagram (assume g 10 m/s2)
  • 0 300 d 300 x 0.5 N x 0 600 x 1.0
  • 0 2d 1 4
  • d 1.5 m from pivot point

10
Exercise Statics
  • A 1.0 kg ball is hung at the end of a uniform rod
    exactly 1.0 m long. The system balances at a
    point on the rod 0.25m from the end holding the
    mass.
  • What is the mass of the rod?

(a) 0.5 kg (b) 1 kg (c) 2 kg

1m
1kg
11
The classic ladder problem
  • A uniform ladder of length L and mass m is
    propped up against a frictionless wall. There is
    friction with the ground with static coefficient
    m. The angle the ladder makes with the ground
    is q.
  • What is the minimum value of m to keep the latter
    from slipping?

12
The classic ladder problem
  • A uniform ladder of length L and mass m is
    propped up against a frictionless wall. There is
    friction with the ground with static coefficient
    m. If the angle the ladder makes with the
    ground is q.
  • What is the minimum value of m that keeps the
    ladder from slipping?

13
Example Statics
  • A box is placed on a ramp in the configurations
    shown below. Friction prevents it from sliding.
    The center of mass of the box is indicated by a
    white dot in each case.
  • In which case(s) does the box tip over ?

(a) all (b) 2 3 (c) 3 only

14
A stable equilibrium
  • Potential energy with tipping (left and right)
  • x-axis corresponds to the x-position of the
    center-of mass

15
Balancing Acts
  • So, where is the center of mass for this
    construction?
  • Between the arrows!

16
Example problem
  • The board in the picture has an average length of
    1.4 m, mass 2.0 kg and width 0.14 m. The angle
    of the board is 45. The bottle is 1.5 m long, a
    center of mass 2/5 of the way from the bottom and
    is mounted 1/5 of way from the end. If the
    sketch represents the physics of the problem.
  • What are the minimum and maximum masses of the
    bottle that will allow this system to remain in
    balance?

-0.1 m
-0.8 m
0.0 m
-0.5 m
0.1 m
0.4 m
17
Example problem
  • What are the minimum and maximum masses of the
    bottle that will allow this system to remain in
    balance?
  • X center of mass,
  • x, -0.1 m lt x lt 0.1 m

2.0 kg
18
Example problem
  • What are the minimum and maximum masses of the
    bottle that will allow this system to remain in
    balance?
  • Check torque condition (g 10 m/s2)
  • x, -0.1 m lt x lt 0.1 m

2.0 kg
19
Real Physical Objects
  • Representations of matter
  • Particles No size, no shape ? can only
    translate along a path
  • Extended objects are collections of point-like
    particles
  • They have size and shape so, to better reflect
    their motion, we introduce the center of mass
  • Rigid objects Translation Rotation
  • Deformable objects
  • Regular solids
  • Shape/size changes under stress (applied
    forces)
  • Reversible and irreversible deformation
  • Liquids
  • They do not have fixed shape
  • Size (aka volume) will change under stress

20
For Thursday
  • All of chapter 12

21
Some definitions
  • Elastic properties of solids
  • Youngs modulus measures the resistance of a
    solid to a change in its length.
  • Bulk modulus measures the resistance of
    solids or liquids to changes in their volume.

elasticity in length
volume elasticity
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