Post on 18-Dec-2015
Motion in a Plane
Chapter 8
Centripetal Acceleration
• Centripetal Acceleration – acceleration that points towards the center of a circle.– Also called Radial Acceleration (aR)
vBall rolling in a straight line (inertia)
v Same ball, hooked to a string
aR
vaR aR = v2
r
If you are on a carousel at constant speed, are you experiencing acceleration?
If you twirl a yo-yo and let go of the string, what way will it fly?
Period and Frequency
Period (T)– Time required for one complete (360o) revolution– Measured in seconds
Frequency– Number of revolutions per second– Measured in rev/s or Hertz (Hz)
T = 1 f
Formulas
v = 2r v = r T
aR = v2 a = r
r
A 150-kg ball is twirled at the end of a 0.600 m string. It makes 2.00 revolutions per second. Find the period, velocity, and acceleration.
(0.500 s, 7.54 m/s, 94.8 m/s2)
The moon has a radius with the earth of about 384,000 km and a period of 27.3 days.
A.Calculate the acceleration of the moon toward the earth. (2.72 X 10-3 m/s2)
B.Calculate the previous answer in “g’s” (2.78 X 10-4 g)
Centripetal Force – the “center seeking” force that pulls an object in a circular path.– Yo-yo– Planets– Merry-go-round– Car rounding a curve
Centrifugal Force
A word about Centrifugal Force
• Doesn’t really exist.• “apparent outward
force”• Water in swinging cup
example Centripetal Force of string
Direction water wants to go
Centripetal Motion
F = maR = mv2
rA 0.150 kg yo-yo is attached to a 0.600 m string
and twirled at 2 revolutions per minute.a. Calculate the velocity in m/s ()b.Calculate the centripetal force in the string
(14.2 N)
Thor’s Hammer (mjolnir) has a mass of 10 kg and the handle and loop have a length of 50 cm. If he can swing the hammer at a speed of 3 m/s, what force is exerted on Thor’s hands?
(Ans: 180 N)
Can Thor swing his hammer so that it is perfectly parallel to the ground?
FR
What angle will the hammer take with the horizontal?
F R
mg
Let’s resolve the FR vector into it’s components:
FRx = FRsin
FRy = FRcos
Fy = 0 (the hammer is not rising or falling)
Fy = 0 = FRcos – mg
FRcos = mg
cos = mg/FR
= 57o
How about if he swings faster?
A father places a 20.0 kg child on a 5.00 kg wagon and twirls her in a circle with a 2.00 m rope of tension 100 N. How many rpms does the wagon make ()? (14 rpm)
A 0.150 kg ball is swung on a 1.10-m string in a vertical circle. What minimum speed must it have at the top of the circle to keep moving in a circle?
At the top of the circle, both the weight and the tension in the string contribute to the centripetal force
F = FT + mg
mg FT
F = FT + mg
FR = FT + mgmv2 = FT + mg r(tricky part: assume FT = 0, just as the cord
goes slack, but before the ball falls)mv2 = mg rv2 = grv = 3.28 m/s
Note: this equation is also the minumum velocity for orbit of a satellite
v = \/rg
What is the tension in the cord at the bottom of the arc if the ball moves at twice the minimum speed? (v = 6.56 m/s)
mg
FT
At the bottom of the circle, the weight opposes the centripetal force.
F = FT – mgmv2 = FT - mg rFT = mv2 + mg rFT = 7.34 N
Car Rounding a Turn
• Friction provides the centripetal force• Use the coefficient of static friction (s). The
wheels are turning, not sliding, across the surface
• Wheel lock = kinetic friction takes over. k is always less than s, so the car is much more likely to skid.
A 1000-kg car rounds a curve (r=50 m) at a speed of 14 m/s. Will the car skid if the road is dry and s=0.60?
Ffr = FR
mg
FNLet’s first solve for the Normal Force
FN = mg = (1000 kg)(9.8 m/s2)
FN = 9800 N
Fx = Ffr
FR = Ffr
mv2 = sFN
r(1000 kg)(14m/s)2 = (0.60)(9800 N) (50 m)3920 N < 5800 N
The car will make it. 3920 N are required, and the frcition provides 5800 N.
Will the car make it if it is icy and the s = 0.25
Fx = Ffr
FR = Ffr
mv2 = sFN
r(1000 kg)(14m/s)2 = (0.25)(9800 N) (50 m)3920 N > 2450 N
The car will not make it. 3920 N are required, and the friction only provides 2450 N.
What is the maximum speed a 1500 kg car can take a flat curve with a radius of 50 m (s = 0.80)
BANKED CURVES• Banked to reduce the reliance on friction• Part of the Normal Force now contributes
to the centripetal force
FR = Ffr + FNsin
(ideally, we bank the road so that no friction is required: Ffr = 0)
Banked Curves: Example 1A 1000-kg car rounds a 50 m radius turn at 14
m/s. What angle should the road be banked so that no friction is required?
mg
FN
FN = mgcos
Now we will simply work with the Normal Force to find the component that points to the center of the circle
mg
FN
First consider the y forces.
Fy = FNcos - mg
Since the car does not move up or down:
Fy = 0
0 = FNcos – mg
FNcos = mg
FN = mg/cos
FNcos
FNsin
mv2 = FNsin rmv2 = mgsin r cosv2 = gtan rv2 = gtanrv2 = tangr
tan = (14 m/s)2 = 0.40 (50 m)(9.8m/s2)
= 22o
Fred Flintstone places a 1.00 kg rock in a 1.00 m long sling. The vine breaks at a tension of 200 N.
a. Calculate the angle below the horizontal plane that the rock will take. (2.81o)
b.Calculate the maximum linear velocity the rock can twirl. (14.1 m/s)
c. Calculate the angular velocity in rpm’s. (135 rpm)
Circular Orbits• Orbits are freefall (not true weightlessness)• Orbital velocity must match the weight
mg = mv2
r g = v2 v = √ gr r
A satellite wishes to orbits at a height of 200 miles above the earth’s surface.
a. Calculate the height above the center of the earth if Rearth = 6.37 X 106 m. (6.69 X 106 m)
b.Calculate the orbital velocity. (8098 m/s)c. Calculate the period in minutes. (86.5 min)
Review of Angular KinematicsA motor spins a 2.0 kg block on an 80.0 cm arm at
200 rpm. The coefficient of kinetic friction is 0.60.a. Draw a free body diagram of the block.b. Calculate the tangential acceleration of the block
(due to friction). (-5.88 m/s2)c. Calculate the angular acceleration. (-7.35 rad/s2)d. Calculate the time until the block comes to a rest.
(2.8 s)e. Calculate the number of revolutions. (4.7 rev)