15. Momentum and impulse
From Mechanics
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Momentum is defined as the product of the mass and velocity of a body. | Momentum is defined as the product of the mass and velocity of a body. | ||
| - | Momentum = mv | + | Momentum = |
| + | <math>mv</math> | ||
| + | or Momentum = | ||
| + | <math>m\mathbf{v}</math> | ||
| - | If the velocity of a body, of mass m, changes from u to v, then | ||
| - | Change in momentum or impulse = mv - mu | + | If the velocity of a body, of mass |
| + | <math>m</math> | ||
| + | , changes from | ||
| + | <math>u</math> | ||
| + | to | ||
| + | <math>v</math> | ||
| + | , then | ||
| + | |||
| + | Change in momentum or impulse = | ||
| + | <math>mv</math> | ||
| + | - | ||
| + | <math>mu</math> | ||
| + | |||
We often use | We often use | ||
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or | or | ||
<math>\mathbf{I}=\mathbf{F}t</math> | <math>\mathbf{I}=\mathbf{F}t</math> | ||
| - | can be used where F is constant or where F is assumed to be constant and represents the average force. | + | can be used where |
| + | <math>F</math> | ||
| + | is constant or where | ||
| + | <math>F</math> | ||
| + | is assumed to be constant and represents the average force. | ||
| + | |||
| + | |||
| + | |||
| + | '''[[Example 15.1]]''' | ||
| - | Example 15.1 | ||
Find the momentum of a car, of mass 1.2 tonnes, travelling in a straight line | Find the momentum of a car, of mass 1.2 tonnes, travelling in a straight line | ||
| - | at 30 | + | at 30 <math>\text{m}{{\text{s}}^{-1}}</math>. |
| + | |||
| + | '''Solution''' | ||
| - | Solution | ||
Note that 1.2 tonnes is 1200 kg. Using Momentum = mv gives: | Note that 1.2 tonnes is 1200 kg. Using Momentum = mv gives: | ||
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| - | Example 15.2 | + | '''[[Example 15.2]]''' |
| - | A car, of mass 1.1 tonnes, which was initially travelling at 6 | + | |
| + | A car, of mass 1.1 tonnes, which was initially travelling at 6 <math>\text{m}{{\text{s}}^{-1}}</math> is brought to rest in 2.2 seconds by a wall. Find the average force exerted by the wall on the car. | ||
| + | |||
| + | '''Solution''' | ||
| - | Solution | ||
First find the impulse (change in momentum). | First find the impulse (change in momentum). | ||
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The average force has magnitude 3000 N | The average force has magnitude 3000 N | ||
| - | Example 15.3 | ||
| - | The speed of a car, travelling in a straight line, is reduced from 20 ms-1 to | ||
| - | 15 ms-1 in 20 seconds. The mass of the car is 1200 kg. Find the average force acting on the car. | ||
| - | Solution | + | |
| + | '''[[Example 15.3]]''' | ||
| + | |||
| + | |||
| + | The speed of a car, travelling in a straight line, is reduced from 20 <math>\text{m}{{\text{s}}^{-1}}</math> to | ||
| + | 15 <math>\text{m}{{\text{s}}^{-1}}</math> in 20 seconds. The mass of the car is 1200 kg. Find the average force acting on the car. | ||
| + | |||
| + | '''Solution''' | ||
| + | |||
First find the impulse (change in momentum). | First find the impulse (change in momentum). | ||
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| - | Example 15.4 | + | '''[[Example 15.4]]''' |
| - | + | ||
| - | + | A ball has a mass of 200 grams. It initially travels horizontally at 10 <math>\text{m}{{\text{s}}^{-1}}</math>. After being hit it travels at 16 <math>\text{m}{{\text{s}}^{-1}}</math> at an angle of 60<math>{}^\circ </math> above the horizontal. Find the initial and final momentum of the ball and the change in momentum. | |
| - | The diagrams show the initial and final velocities of the ball and the unit vectors i and j. | + | '''Solution''' |
| + | |||
| + | The diagrams show the initial and final velocities of the ball and the unit vectors <math>\mathbf{i}</math> and <math>\mathbf{j}</math>. | ||
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\end{align}</math> | \end{align}</math> | ||
| - | Example 15.5 | + | '''[[Example 15.5]]''' |
| - | A ball is travelling horizontally at 8 | + | |
| + | A ball is travelling horizontally at 8 <math>\text{m}{{\text{s}}^{-1}}</math>, when it is hit. After being hit it initially travels upwards at 6 <math>\text{m}{{\text{s}}^{-1}}</math>. The mass of the ball is 300 grams. Find the magnitude and direction of the impulse on the ball. | ||
| + | |||
| + | '''Solution''' | ||
| - | + | The diagrams show the initial and final velocities of the ball and the unit vectors <math>\mathbf{i}</math> and <math>\mathbf{j}</math>. | |
| - | The diagrams show the initial and final velocities of the ball and the unit vectors i and j. | + | |
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The diagram shows the impulse. | The diagram shows the impulse. | ||
| - | The magnitude of the impulse, I, is found | + | The magnitude of the impulse, <math>I</math>, is found |
using Pythagoras: | using Pythagoras: | ||
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| - | The angle, | + | The angle, <math>\alpha </math>, can be found using trigonometry: |
Revision as of 14:06, 24 September 2009
| Theory | Exercises |
15. Momentum and Impulse
Key Results
Momentum is defined as the product of the mass and velocity of a body.
Momentum = \displaystyle mv or Momentum = \displaystyle m\mathbf{v}
If the velocity of a body, of mass
\displaystyle m
, changes from
\displaystyle u
to
\displaystyle v
, then
Change in momentum or impulse = \displaystyle mv - \displaystyle mu
We often use
\displaystyle I=mv-mu or \displaystyle \mathbf{I}=m\mathbf{v}-m\mathbf{u}
The relationships
\displaystyle I=Ft
or
\displaystyle \mathbf{I}=\mathbf{F}t
can be used where
\displaystyle F
is constant or where
\displaystyle F
is assumed to be constant and represents the average force.
Find the momentum of a car, of mass 1.2 tonnes, travelling in a straight line
at 30 \displaystyle \text{m}{{\text{s}}^{-1}}.
Solution
Note that 1.2 tonnes is 1200 kg. Using Momentum = mv gives:
\displaystyle \begin{align}
& \text{Momentum}=1200\times 30 \\
& =36000\text{ Ns}
\end{align}
A car, of mass 1.1 tonnes, which was initially travelling at 6 \displaystyle \text{m}{{\text{s}}^{-1}} is brought to rest in 2.2 seconds by a wall. Find the average force exerted by the wall on the car.
Solution
First find the impulse (change in momentum).
\displaystyle \begin{align} & \text{Impulse }=mv-mu \\ & =1100\times 0-1100\times 6 \\ & =-6600\text{ Ns} \end{align}
Use the formula
\displaystyle \text{Impulse }=Ft
\displaystyle \begin{align} & -6600=F\times 2.2 \\ & F=-3000\text{ N} \end{align}
The average force has magnitude 3000 N
The speed of a car, travelling in a straight line, is reduced from 20 \displaystyle \text{m}{{\text{s}}^{-1}} to
15 \displaystyle \text{m}{{\text{s}}^{-1}} in 20 seconds. The mass of the car is 1200 kg. Find the average force acting on the car.
Solution
First find the impulse (change in momentum).
\displaystyle \begin{align}
& \text{Impulse }=mv-mu \\
& 1200\times 15-1200\times 20 \\
& =-6000\text{ Ns}
\end{align}
Use the formula
\displaystyle \text{Impulse }=Ft
\displaystyle \begin{align} & -6000=F\times 20 \\ & F=-300\text{ N} \\ \end{align}
A ball has a mass of 200 grams. It initially travels horizontally at 10 \displaystyle \text{m}{{\text{s}}^{-1}}. After being hit it travels at 16 \displaystyle \text{m}{{\text{s}}^{-1}} at an angle of 60\displaystyle {}^\circ above the horizontal. Find the initial and final momentum of the ball and the change in momentum.
Solution
The diagrams show the initial and final velocities of the ball and the unit vectors \displaystyle \mathbf{i} and \displaystyle \mathbf{j}.
\displaystyle \begin{align}
& \text{Initial Momentum }=\text{ m}\mathbf{u} \\
& =0.2\times 10\mathbf{i} \\
& =2\mathbf{i}
\end{align}
\displaystyle \begin{align} & \text{Final Momentum }=m\mathbf{v} \\ & =0.2(16\cos 60{}^\circ \mathbf{i}+16\sin 60{}^\circ \mathbf{j}) \\ & =3.2\cos 60{}^\circ \mathbf{i}+3.2\sin 60{}^\circ \mathbf{j} \end{align}
\displaystyle \begin{align} & \text{Change of Momentum }=m\mathbf{v}-m\mathbf{u} \\ & =3.2\cos 60{}^\circ \mathbf{i}+3.2\sin 60{}^\circ \mathbf{j}-2\mathbf{i} \\ & =-0.4\mathbf{i}+2.77\mathbf{j} \end{align}
A ball is travelling horizontally at 8 \displaystyle \text{m}{{\text{s}}^{-1}}, when it is hit. After being hit it initially travels upwards at 6 \displaystyle \text{m}{{\text{s}}^{-1}}. The mass of the ball is 300 grams. Find the magnitude and direction of the impulse on the ball.
Solution
The diagrams show the initial and final velocities of the ball and the unit vectors \displaystyle \mathbf{i} and \displaystyle \mathbf{j}.
\displaystyle \begin{align}
& \text{Initial Momentum }=\text{ }m\mathbf{u} \\
& =0.3\times 8\mathbf{i} \\
& =2.4\mathbf{i}
\end{align}
\displaystyle \begin{align}
& \text{Final Momentum }=m\mathbf{v} \\
& =0.3\times 6\mathbf{j} \\
& =1.8\mathbf{j}
\end{align}
\displaystyle \begin{align} & \text{Impulse }=m\mathbf{v}-m\mathbf{u} \\ & =1.8\mathbf{j}-2.4\mathbf{i} \end{align}
The diagram shows the impulse.
The magnitude of the impulse, \displaystyle I, is found using Pythagoras:
\displaystyle I=\sqrt{{{1.8}^{2}}+{{2.4}^{2}}}=3\text{ Ns}
The angle, \displaystyle \alpha , can be found using trigonometry:
