Higher Physics – Unit 1 1.4 – Momentum and Impulse.
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Transcript of Higher Physics – Unit 1 1.4 – Momentum and Impulse.
![Page 1: Higher Physics – Unit 1 1.4 – Momentum and Impulse.](https://reader036.fdocuments.us/reader036/viewer/2022062308/56649ddb5503460f94ad243b/html5/thumbnails/1.jpg)
Higher Physics – Unit 1
1.4 – Momentum and Impulse
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Momentum
The momentum of an object is the product of it’s mass and velocity.
The MOMENTUM of an object is calculated by:
v mp
momentum(kg ms-1)
mass(kg)
velocity(ms-1)
Momentum is a vector (has both magnitude and direction).
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Collisions
Before Collision
After Collision
12 ms-1
stationary
stationary
12 ms-1
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Before Collision
After Collision
stationary
12 ms-1
stationary
12 ms-1
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Results
Before Collision
After Collision
Mass Velocity
1 12
Mass Velocity
2 6
2 12 3 8
1 12 3 4
2 12 4 6
Conclusion
velocity mass velocity mass
BEFORE AFTER
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Momentum and Collisions
The total momentum is CONSERVED in collisions provided there are no external forces (e.g. friction).
v1
m1 m2
v2
=> m1 m2
v3
total momentum before = total momentum after
3212211 v mm v m v m
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Example 1
A 7kg mass travelling at 8 ms-1 collides and sticks to a stationary 4 kg mass.
Calculate the velocity just after impact.
8 ms-1
7kg
4kg
stationary
7kg
4kg
v
total momentum before = total momentum after
3212211 v mm v m v m v 11 04 87
56 v 11 -1ms 5.1 v to the right
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Example 2
A car of mass 1,000 kg is travelling at 5 ms-1.
It collides and joins with a 1,200 kg car travelling at 3 ms-1.
Calculate the velocity of the cars just after impact.
5 ms-1
1000 kg
1200 kg
3 ms-1
1000 kg
1200 kg
v3
total momentum before = total momentum after
3212211 v mm v m v m v 2200 31200 51000
8600 v 2200 -1ms 3.9 v to the right
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Worksheet – Momentum and Collisions
Q1 – Q6
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Is Momentum Conserved?
Diagram
m2
linear air track
m1
Electronic Timer
Light Gate
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Procedure
Vehicle 1 is sprung along the air track.
It breaks the first light gate and a velocity is given.
It collides and sticks to the second vehicle.
They both move together and break the second light gate, giving a second velocity.
kg m1
-11 ms v
kg m2
-12 ms v
kg m3
-13 ms v
Results
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2211 v m v m before momentum total
-1ms kg
33 v m after momentum total
-1ms kg
Conclusion
total momentum before = total momentum after
Momentum is CONSERVED.
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Elastic Collisions
KINETIC ENERGY CONSERVED
MOMENTUM CONSERVED
Example 1
A 200 kg vehicle is travelling at 6 ms-1 when it collides with a stationary 100 kg vehicle.
After the collision, the 200 kg vehicle moves off at 2 ms-1 and the 100 kg vehicle at 8 ms-1.
Show the collision is elastic.
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6 ms-1
200 kg
100 kg
stationary
2 ms-1
200 kg
100 kg
8 ms-1
Momentum
2211 v m v m
-1ms kg 1200
Momentum has been conserved.
Before
4231 v m v m
0100 6200 8100 2200 -1ms kg 1200
After
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Kinetic Energy
Before After
2K v m
21
E
22 0 100
21
6 200 21
J 3600EK
2K v m
21
E
22 8 100
21
2 200 21
J 3600EK
Kinetic Energy has been conserved.
As momentum and kinetic energy are conserved, ELASTIC collision.
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Inelastic Collisions
Kinetic Energy NOT Conserved
MOMENTUM CONSERVED
Example 1
A trolley of mass 3 kg is travelling at 5 ms-1 when it collides with a stationary 1 kg trolley.
Afterwards, they move off at 3 ms-1 and 6 ms-1 respectively.
Show that this collision is inelastic.
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5 ms-1
3 kg
1 kg
stationary
3 ms-1
3 kg
1 kg
6 ms-1
Momentum
2211 v m v m
-1ms kg 15
Momentum has been conserved.
Before
4231 v m v m
01 53 61 33 -1ms kg 15
After
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Kinetic Energy
Before After
2K v m
21
E
22 0 1
21
5 3 21
J 37.5EK
2K v m
21
E
22 6 1
21
3 3 21
J 31.5EK
Kinetic Energy has NOT been conserved.
As momentum is conserved and kinetic is not, INELASTIC collision.
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Note
In reality, most collisions are inelastic.
Some of the kinetic energy is converted to heat and sound energy on impact.
TOTAL ENERGY is always CONSERVED
total energy = kinetic energy + heat energy + sound energy
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Worksheet – Elastic and Inelastic Collisions
Q1 – Q3
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Head On Collisions
Head on collisions involve objects travelling in opposite directions.
One direction is POSITIVE, the other then has to be NEGATIVE.Example 1
A 4 kg object travels at 12 ms-1 and collides head on with a 3 kg object travelling with a speed of 7 ms-1.
After the collision, they both move off together.
(a) calculate the velocity of the objects just after impact.
(b) determine whether the collision is elastic or inelastic.
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12 ms-1
4 kg
3 kg
4 kg
3 kg
v-7 ms-1
total momentum before = total momentum after
v mm v m v m 212211
v 34 7-3 124
21-48 v7
-1ms 3.86 v to the right27 v7
(a)
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(b) Kinetic Energy
Before After
2K v m
21
E
22 7- 3
21
12 4 21
J 361.5EK
2K v m
21
E
23.86 7 21
J 52.1EK
Kinetic Energy has NOT been conserved.
INELASTIC collision.
73.5288
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Example 2
Two objects collide as shown.
5 ms-1
7 kg
4 kg
2 ms-1
7 kg
4 kg
v-3 ms-1
(a) Calculate the velocity at which the 4 kg object moves, just after impact.
(b) Determine whether the collision is elastic or inelastic.
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total momentum before = total momentum after
42312211 v m v m v m v m
v4 27 3-4 57
4v14 12-35
-1ms 2.25 v to the right
4v 14-23
9 4v
(a)
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Kinetic Energy
Before After
2K v m
21
E
22 3- 4
21
5 7 21
2K v m
21
E
22 2.25 4
21
2 7 21
10.1314
(b)
1887.5
J 105.5EK J 24.13EK
Kinetic Energy has NOT been conserved.
INELASTIC collision.
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Explosions
MOMENTUM CONSERVED
In all explosions:
BEFORE AFTERv2
stationary
v1
m1 m2
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total momentum before = total momentum after
2211 v m v m v m
2211 v m v- m 0
2211 v m v m - 0
Example 1
A 5 kg gun fires a 0.1 kg shell at 80 ms-1.
The gun recoils after firing the shell.
Calculate the recoil speed of the gun.
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BEFORE AFTER
5 kg0.1 kg
stationary
5 kg0.1 kg
80 ms-1
v
total momentum before = total momentum after
2211 v m v m v m
800.1 v 5 0
8 5v- -1ms 1.6- v backward
s
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Example 2
Two trolleys initially at rest and touching, fly apart when the plunger is released.
One trolley with a mass of 2 kg moves off with a speed of 4 ms-
1.
The other trolley moves off in the opposite direction with a speed of 5 ms-1.
Calculate the mass of this trolley.
5 ms-1
2 kg
m
-4 ms-1
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total momentum before = total momentum after
2211 v m v m v m
5m 4-2 0
8 5m kg 1.6 m
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Worksheet – Head On Collisions and Explosions
Q1 – Q8
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Impulse & Change in Momentum
Consider the following equations:
a mF t
uva
Combining these equations: a mF
t
u-v mF
mu - mv t F
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mu - mv t F
IMPULSE (F t) = CHANGE IN MOMENTUM (mv – mu)
force(N)
time(s)
mass(kg) final velocity
(ms-1)
initial velocity(ms-1)
Impulse
IMPULSE is the product of the FORCE and the TIME during which it acts.
The units of impulse are N s (Newton Seconds).
Impulse is a vector quantity.
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Change In Momentum
The change in momentum is the difference in momentum from when the object is moving at its initial speed until it reaches its final speed.
The unit of change in momentum is kg ms-1.
Impulse and change in momentum are equal to each other.
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Example 1
A golf ball of mass 50 g is hit off the tee at 30 ms-1.
The time of contact between club and ball is 25 ms (milliseconds).
Calculate the average force exerted on the ball.
g 50mkg 0.05-1ms 0u
-1ms 30vms 25t
s 10 25 -3
mu - mv t F
00.05 - 300.05 1025 F 3
3-10251.5
F
N 60 F
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Impulse, Force and Time
force / N
time / s
force / N
time / s
graph under area impulse
hb21
graph under area impulse
hb21
bl
impulse = area under force-time graph
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Example 1
A 50 g golf ball is hit off the tee by a force which varies with time as shown.
force / N
time / ms30
40
0
Calculate the speed of the golf ball off the tee.
graph under area impulse
hb21
40103021
3-
s N 0.6
mu-mv impulse
0 0.05-v 0.05 0.6
0.6v 0.05
0.050.6
v
1ms 12v
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Change In Momentum
Air Bags
A passenger in a car involved in a collision will experience a force which will bring him to a stop.
NO Air Bag AIR BAG
• Head hits hard object eg. steering wheel
• In contact for a short time
• Large force involved
• Lots of Damage
• Head hits air bag
• In contact for a longer time
• Smaller force involved
• Less damage
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In both cases the change in momentum and therefore the impulse are the same.
However, the force-time graphs will differ in shape although the area under the line will be the same.
NO Air Bag AIR BAG
force / N
time / s
force / N
time / s
Large force.
Short time.
Small force.
Long time.
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The purpose of the crumple-zone is to
A decrease the driver’s change in momentum per second
B increase the driver’s change in momentum per second
C decrease the driver’s final velocity
D increase the driver’s total change in momentum
E decrease the driver’s total change in momentum.
Crumple Zone
A car is designed with a “crumple zone” so that the front of the car collapses during impact.
Less damage is caused if the change in momentum is over a long period of time.
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Worksheet – Impulse and Change In Momentum
Q1 – Q16
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Rebounds
Example 1
A 5 kg tyre hits a wall at 4 ms-1 and rebounds at 3 ms-1.
Calculate the change in momentum of the tyre.
4 ms-1
3 ms-1
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change in momentum = mv - mu
45 3-5
20 15 1ms kg 35
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