General Physics (PHY 2130) - Wayne State Universityapetrov/PHY2130/Lectures2130/...Calculating the...
Transcript of General Physics (PHY 2130) - Wayne State Universityapetrov/PHY2130/Lectures2130/...Calculating the...
Lecture 20
General Physics (PHY 2130)
http://www.physics.wayne.edu/~apetrov/PHY2130/
• Rotational dynamics
equilibrium 2nd Newton’s Law for rotational motion rolling
• Exam II review
Lightning Review
Last lecture: 1. Momentum:
momentum conservation collisions in one and two dimensions
Review Problem: An engineer wishes to design a curved exit ramp for a toll road in such a way that a car will not have to rely on friction to round the curve without skidding. She does so by banking the road in such a way that the force causing the centripetal acceleration will be supplied by the component of the normal force toward the center of the circular path. A highway curve has a radius of 825 m. At what angle should the road be banked so that a car traveling at 26.8 m/s has no tendency to skid sideways on the road? (Hint: No tendency to skid means the frictional force is zero.)
Review Problem An engineer wishes to design a curved exit ramp for a toll road in such a way that a car will not have to rely on friction to round the curve without skidding. She does so by banking the road in such a way that the force causing the centripetal acceleration will be supplied by the component of the normal force toward the center of the circular path. A highway curve has a radius of 825 m. At what angle should the road be banked so that a car traveling at 26.8 m/s has no tendency to skid sideways on the road? (Hint: No tendency to skid means the frictional force is zero.)
θ
Take the car’s motion to be into the page. Draw FBD and apply Newton’s Second Law:
x
y
N
w
θ ( )
( ) 0cos 2
sin 12
=−=
===
∑
∑wNF
rvmmaNF
y
rx
θ
θ
Rewrite (1) and (2): 3( ) N sinθ =m v2
r4( ) N cosθ =mg
Divide (3) by (4): ( )
( )( )°=
===
1.5
089.0m 825m/s 8.9
m/s 8.26tan 2
22
θ
θgrv
Net Torque • The net torque is the sum of all the torques produced by
all the forces
• Remember to account for the direction of the tendency for rotation • Counterclockwise torques are positive • Clockwise torques are negative
Example 1:
Given: weights: w1= 500 N
w2 = 800 N lever arms: d1=4 m d2=2 m Find: Στ = ?
1. Draw all applicable forces
(500 )(4 ) ( )(800 )(2 )2000 1600400
N m N mN m N mN m
τ = + −
= + ⋅ − ⋅
= + ⋅
∑
2. Consider CCW rotation to be positive
500 N 800 N
4 m 2 m
Rotation would be CCW
N
Determine the net torque:
Example 2:
Given: weights: w1= 500 N
w2 = 800 N lever arms: d1=4 m Στ = 0 Find: d2 = ?
1. Draw all applicable forces and moment arms
2
2 2
(800 )(2 )
(500 )( )800 2 [ ] 500 [ ] 0 3.2
RHS
LHS
N m
N d mN m d N m d m
τ
τ
=−
=
− ⋅ ⋅ + ⋅ ⋅ = ⇒ =
∑∑
500 N 800 N
2 m d2 m
According to our understanding of torque there would be no rotation and no motion!
N’ y
What does it say about acceleration and force?
Thus, according to 2nd Newton’s law ΣF=0 and a=0! NNNNNFi
1300'0)800(')500(
=
=−++−=∑
Torque and Equilibrium • First Condition of Equilibrium
• The net external force must be zero
• This is a necessary, but not sufficient, condition to ensure that an object is in complete mechanical equilibrium
• This is a statement of translational equilibrium • Second Condition of Equilibrium
• The net external torque must be zero
• This is a statement of rotational equilibrium
ΣF= 0
ΣFx = 0 and ΣFy = 0
0=Στ
Axis of Rotation
• So far we have chosen obvious axis of rotation • If the object is in equilibrium, it does not matter where you put the axis of rotation for calculating the net torque • The location of the axis of rotation is completely arbitrary • Often the nature of the problem will suggest a
convenient location for the axis • When solving a problem, you must specify an axis of
rotation • Once you have chosen an axis, you must maintain that choice
consistently throughout the problem
Center of Gravity (center of mass)
• The force of gravity acting on an object must be considered
• In finding the torque produced by the force of gravity, all of the weight of the object can be considered to be concentrated at one point
Calculating the Center of Gravity
1. The object is divided up into a large number of very small particles of weight (mg)
2. Each particle will have a set of coordinates indicating its location (x,y)
3. The torque produced by each particle about the axis of rotation is equal to its weight times its lever arm
4. We wish to locate the point of application of the single force , whose magnitude is equal to the weight of the object, and whose effect on the rotation is the same as all the individual particles.
• This point is called the center of gravity of the object
Coordinates of the Center of Gravity
• The coordinates of the center of gravity can be found from the sum of the torques acting on the individual particles being set equal to the torque produced by the weight of the object
• The center of gravity of a homogenous, symmetric body must lie on the axis of symmetry.
• Often, the center of gravity of such an object is the geometric center of the object.
i
iicg
i
iicg m
ymyandmxmx
Σ
Σ=
Σ
Σ=
Example:
Given: masses: m1= 5.00 kg
m2 = 2.00 kg m3 = 4.00 kg
lever arms: d1=0.500 m d2=1.00 m
Find: Center of gravity
Find center of gravity of the following system:
mkg
mkgmkgmkgmmmxmxmxm
mxm
xi
iicg
136.00.11
)00.1(00.4)0(00.2)500.0(00.5321
332211
=
++−=
++
++==
∑∑
Experimentally Determining the Center of Gravity • The wrench is hung freely from two
different pivots • The intersection of the lines
indicates the center of gravity • A rigid object can be balanced by a
single force equal in magnitude to its weight as long as the force is acting upward through the object’s center of gravity
Equilibrium, once again
• A zero net torque does not mean the absence of rotational motion • An object that rotates at uniform angular velocity can be under the
influence of a zero net torque • This is analogous to the translational situation where a zero net force
does not mean the object is not in motion
More on Free Body Diagrams
• Isolate the object to be analyzed
• Draw the free body diagram for that object • Include all the external
forces acting on the object
Suppose that you placed a 10 m ladder (which weights 100 N) against the wall at the angle of 30°. What are the forces acting on it and when would it be in equilibrium?
Example
Example:
Given: weights: w1= 100 N length: l=10 m angle: α=30° Στ = 0 Find: f = ? n=? P=?
1. Draw all applicable forces
NP
PN
PLLmg
6.86211866.0
211000
030sin30cos2
=
⋅⋅−⋅⋅=
=−=∑ τ
Torques: Forces:
NnmgnF
NfPfF
y
x
100
06.860
=
=−=
=
=−=
∑
∑
α
2. Choose axis of rotation at bottom corner (τ of f and n are 0!)
Note: f = µs n, so 866.01006.86
===NN
nf
sµ
mg
Torque and Angular Acceleration
• When a rigid object is subject to a net torque (≠0), it undergoes an angular acceleration
• The angular acceleration is directly proportional to the net torque • The relationship is analogous
to ∑F = ma • Newton’s Second Law
Torque and Angular Acceleration
( )
so,:onacceleratitangential
bymultiply,
αra
rmarFrmaF
t
tt
tt
=
=
=
α2mrrFt =
torque τ dependent upon object and axis of rotation. Called moment of inertia I. Units: kg m2
2iirmI Σ≡
ατ I=The angular acceleration is inversely proportional to the analogy of the mass in a rotating system
Newton’s Second Law for a Rotating Object
• The angular acceleration is directly proportional to the net torque • The angular acceleration is inversely proportional to the moment of
inertia of the object
• There is a major difference between moment of inertia and mass: the moment of inertia depends on the quantity of matter and its distribution in the rigid object.
• The moment of inertia also depends upon the location of the axis of rotation
ατ I=Σ
Example:
Consider a flywheel (cylinder pulley) of mass M=5 kg and radius R=0.2 m and weight of 9.8 N hanging from rope wrapped around flywheel. What are forces acting on flywheel and weight? Find acceleration of the weight.
mg
Example:
Given: masses: M = 5 kg weight: w = 9.8 N radius: R=0.2 m Find: Forces=?
1. Draw all applicable forces
IRT
IRT⋅
=
⋅=⋅=
α
ατ
Forces: Torques:
!TneedmaTmgF =−=∑
Tangential acceleration at the edge of flywheel (a=at):
( )( ) ttt
t
akgammkga
ITRRa
5.22.0
10.0RIT
or
aor
2
2
2
2
t
=⋅
==
==α
N
T
T
Mg
mg
( )
( )28.2
5.38.9
5.2
5.2
smkgN
kgmmga
maakgmgmaTmgF
t
==+
=
=−
=−=∑
22 10.021 mkgMRI ⋅==
Note on problem solving:
• The same basic techniques that were used in linear motion can be applied to rotational motion. • Analogies: F becomes , m becomes I and a becomes , v
becomes ω and x becomes θ
• Techniques for conservation of energy are the same as for linear systems, as long as you include the rotational kinetic energy
• Problems involving angular momentum are essentially the same technique as those with linear momentum • The moment of inertia may change, leading to a change in
angular momentum
τ α
Review before Exam 2
Useful tips:
1. Do and understand all the homework problems. 2. Review and understand all the problems done in class. 3. Review and understand all the problems done in the textbook
(chapters 4-7). 4. Come to office hours if you have questions!!!
Review problem
The launching mechanism of a toy gun consists of a spring of unknown spring constant, as shown in Figure 1. If the spring is compressed a distance of 0.120 m and the gun fired vertically as shown, the gun can launch a 20.0-g projectile from rest to a maximum height of 20.0 m above the starting point of the projectile. Neglecting all resistive forces, determine (a) the spring constant and (b) the speed of the projectile as it moves through the equilibrium position of the spring (where x = 0), as shown in Figure 1.