2.4 Understanding Momentum
Transcript of 2.4 Understanding Momentum
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Chapter 2 Forces and Motion
2.4 Understanding Momentum
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2.4 Understanding Momentum
• http://www.youtube.com/watch?v=T9lehHxv-C8
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2.4 Understanding Momentum
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2.4 Understanding Momentum
• Every moving object has momentum.• Momentum can be thought as the
tendency of an object to keep on moving with the same speed in the same direction.
• Momentum and inertia are quite connected. (momentum only found in moving object)
• Momentum often indicates the difficulty a moving object has in stopping. A fast-moving car has more momentum than a slower one of the same mass.
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2.4 Understanding MomentumDifference between
INERTIA and MOMENTUM Inertia it is the tendency of body to resist
any change in its motion. Eg: A body at rest will be at rest until a force has been applied ........... mass is measure of inertia
Momentum product of mass and velocity, so for deciding momentum velocity also plays a role. Eg: It is easier to stop a cycle rather than a massive car ......... it has the same tendency as inertia
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2.4 Understanding Momentum• If an object is moving in a straight
line, we say that it has linear momentum.
• The amount of linear momentum of the object depends on its mass and velocity.
We define linear momentum as the product of mass and velocity:Momentum = mass x velocity
p = mvWhere m = mass and v =
velocity
kg m s-1
orN s
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2.4 Understanding Momentum
• Momentum is a vector quantity, the direction of the momentum is the same as the direction of the velocity.
Momentum = mass x velocityp = mv
Where m = mass and v = velocity
kg m s-1
orN s
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2.4 Understanding MomentumExampleA billiard ball A of mass 0.5 kg is moving from left to right with a velocity of 2 m s-1 while another billiard ball B of equal mass is moving from right to left with the same speed.
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2.4 Understanding Momentum
Negative sign shows the object is moving in opposite direction.
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2.4 Understanding Momentum
http://www.youtube.com/watch?v=qNou0xg3_cY
Principle of Conservation of Momentum
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2.4 Understanding Momentum
The principle of conservation of momentum states that the total momentum in a closed system is
constant, if no external force acts on the system, that is, the momentum of all objects before
a collision equals the momentum of all objects after a collision.
Principle of Conservation of Momentum
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2.4 Understanding Momentum
The principle of conservation of momentum is true for the following: a) Collision of two objects –elastic collision–inelastic collision
b) Explosion
Principle of Conservation of Momentum
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2.4 Understanding Momentum
http://phet.colorado.edu/sims/collision-lab/collision-lab_en.html
Principle of Conservation of Momentum
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2.4 Understanding Momentum
A collisionThe total momentum of the objects before a collision equals that after the collision.
An explosionThe sum of the
momentums remains as
zero after an explosion.
Principle of Conservation of Momentum
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2.4 Understanding Momentum
Elastic CollisionsPrinciple of Conservation of Momentum
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2.4 Understanding Momentum
Elastic CollisionsPrinciple of Conservation of Momentum
•Momentum is conserved.•Total energy is conserved.•Kinetic energy is conserved.
22112211 vmvmumum
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2.4 Understanding Momentum
Car A of mass 1000 kg moving at 20 m s-1 collides with Car B of mass 1200 kg moving at 10 m s-1 in the same direction. If the Car B is shunted forwards at 15 m s-1 by the impact, what is the velocity, v, of the Car A immediately after the crash?
Principle of Conservation of Momentum
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2.4 Understanding MomentumPrinciple of Conservation of Momentum
1-B
A
1-B
1-A
B
A
s m 15
?s m 10
s m 20
kg 1200kg 1000
v
vu
u
mm
1-A
A
A
A
BBAABBAA
s m 14
14000100018000100032000
)15(12001000)10(1200)20(1000
v
vvv
vmvmumum
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2.4 Understanding Momentum
Inelastic CollisionsPrinciple of Conservation of Momentum
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2.4 Understanding Momentum
Inelastic CollisionsPrinciple of Conservation of Momentum
•Momentum is conserved.•Total energy is conserved.•Kinetic energy is not conserved.the total kinetic energy after the collision is less than the total kinetic energy before the collision.
vmmumum )( 212211
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2.4 Understanding Momentum
A truck of mass 1200 kg moving at 30 m s-1 collides with a car of mass 1000 kg which is travelling in the opposite direction at 20 m s-1. After the collision, the two vehicles move together. What is the velocity of both vehicles immediately after collision?
Principle of Conservation of Momentum
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2.4 Understanding MomentumPrinciple of Conservation of Momentum
?s m 20
s m 30
kg 1000
kg 1200
1-car
1-lorry
car
lorry
vu
u
m
m
1-
carlorrycarcarlorrylorry
s m 27.7
220016000)10001200()20(1000)30(1200
)(
v
vv
vmmumum
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2.4 Understanding Momentum
ExplosionMeans the separation of objects which are initially at rest. Before explosion both
object stick together and at rest. After collision, both object move at opposite direction
Principle of Conservation of Momentum
2211
22110collisionsafter momentum total collisions before momentum total
vmvmvmvm
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2.4 Understanding Momentum
Example
A rifle of mass 5.0 kg fires a bullet of mass 50 g with a velocity of 20 m s-1. Calculate the recoil velocity. Explain why the recoil velocity of a rifle is much less than the velocity of the bullet.
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2.4 Understanding Momentum
http://www.youtube.com/watch?v=rY3H5a_gHAc
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2.4 Understanding Momentum
Solution
1-bullet
bullet
1- rifle
rifle
s m 0
g 50 s m 0
kg 5
u
mu
mBefore fire
1-bullet
bullet
rifle
rifle
s m 80
g 50 ?
kg 5
v
mvmAfter fire
1-rifle
rifle
rifle
rifle
rifle
rifle
bulletbulletrifleriflebulletbulletriflerifle
s m 8.05445
)80(05.05)80(05.050)80(05.05)0(05.0)0(5
v
v
vv
vv
vmvmumum
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2.4 Understanding Momentum
M(gun) x V(gun) = M(bullet) x V(bullet)
B I G x small = small x B I G
Since the bullet and the gun should have opposite and equal momentum, the velocity
of the bullet is much greater since the mass is much smaller.
Solution
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2.4 Understanding Momentum
Example
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2.4 Understanding MomentumApplication of Conservation of
Momentum
Rockets
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2.4 Understanding MomentumApplication of Conservation of
Momentum
Water Rockets
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2.4 Understanding MomentumApplication of Conservation of
Momentum
CO2 car
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2.4 Understanding Momentum
Conserved = maintain at a constant overall
total.
Principle of Conservation of Momentum
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2.4 Understanding Momentum
Closed system = the sum of
external forces acting on the system is zero
Principle of Conservation of Momentum