9.5 Collisions in multiple dimensions (Page 2/4)

University physics volume 1 Page 2 / 4

Traffic collision

A small car of mass 1200 kg traveling east at 60 km/hr collides at an intersection with a truck of mass 3000 kg that is traveling due north at 40 km/hr ( [link] ). The two vehicles are locked together. What is the velocity of the combined wreckage?

An x y coordinate system is shown. A large truck mass m T = 3000 kilograms is moving north toward the origin with velocity v T. A small car mass m c = 1200 kilograms is moving east toward the origin with velocity v c, which is less than v T. — A large truck moving north is about to collide with a small car moving east. The final momentum vector has both x - and y -components.

Strategy

First off, we need a closed system. The natural system to choose is the (car + truck), but this system is not closed; friction from the road acts on both vehicles. We avoid this problem by restricting the question to finding the velocity at the instant just after the collision, so that friction has not yet had any effect on the system. With that restriction, momentum is conserved for this system.

Since there are two directions involved, we do conservation of momentum twice: once in the x -direction and once in the y -direction.

Solution

Before the collision the total momentum is

\vec{p} = m_{c} {\vec{v}}_{c} + m_{T} {\vec{v}}_{T} .

After the collision, the wreckage has momentum

\vec{p} = (m_{c} + m_{T}) {\vec{v}}_{w} .

Since the system is closed, momentum must be conserved, so we have

m_{c} {\vec{v}}_{c} + m_{T} {\vec{v}}_{T} = (m_{c} + m_{T}) {\vec{v}}_{w} .

We have to be careful; the two initial momenta are not parallel. We must add vectorially ( [link] ).

Arrow p c points horizontally to the right. Arrow p t points vertically upward. The head of p t meets the tail of p c. P t is longer than p t. A dashed line is shown from the tail of p t to the head of p c. The angle between the dashed line and p t, at the tail of p t, is labeled as theta. — Graphical addition of momentum vectors. Notice that, although the car’s velocity is larger than the truck’s, its momentum is smaller.

If we define the + x -direction to point east and the + y -direction to point north, as in the figure, then (conveniently),

\begin{matrix} {\vec{p}}_{c} & = & p_{c} \hat{i} = m_{c} v_{c} \hat{i} \\ {\vec{p}}_{T} & = & p_{T} \hat{j} = m_{T} v_{T} \hat{j} . \end{matrix}

Therefore, in the x -direction:

\begin{matrix} m_{c} v_{c} & = & (m_{c} + m_{T}) v_{w, x} \\ v_{w, x} & = & (\frac{m_{c}}{m_{c} + m_{T}}) v_{c} \end{matrix}

and in the y -direction:

\begin{matrix} m_{T} v_{T} & = & (m_{c} + m_{T}) v_{w, y} \\ v_{w, y} & = & (\frac{m_{T}}{m_{c} + m_{T}}) v_{T} . \end{matrix}

Applying the Pythagorean theorem gives

\begin{matrix} | {\vec{v}}_{w} | & = \sqrt{{[(\frac{m_{c}}{m_{c} + m_{t}}) v_{c}]}^{2} + {[(\frac{m_{t}}{m_{c} + m_{t}}) v_{t}]}^{2}} \\ = \sqrt{{[(\frac{1200 kg}{4200 kg}) (16.67 \frac{m}{s})]}^{2} + {[(\frac{3000 kg}{4200 kg}) (11.1 \frac{m}{s})]}^{2}} \\ = \sqrt{{(4.76 \frac{m}{s})}^{2} + {(7.93 \frac{m}{s})}^{2}} \\ = 9.25 \frac{m}{s} \approx 33.3 \frac{km}{hr} . \end{matrix}

As for its direction, using the angle shown in the figure,

θ = {tan}^{−1} (\frac{v_{w, x}}{v_{w, y}}) = {tan}^{−1} (\frac{7.93 m/s}{4.76 m/s}) = 59 ° .

This angle is east of north, or $31 °$ counterclockwise from the + x -direction.

Significance

As a practical matter, accident investigators usually work in the “opposite direction”; they measure the distance of skid marks on the road (which gives the stopping distance) and use the work-energy theorem along with conservation of momentum to determine the speeds and directions of the cars prior to the collision. We saw that analysis in an earlier section.

Check Your Understanding Suppose the initial velocities were not at right angles to each other. How would this change both the physical result and the mathematical analysis of the collision?

Were the initial velocities not at right angles, then one or both of the velocities would have to be expressed in component form. The mathematical analysis of the problem would be slightly more involved, but the physical result would not change.

Got questions? Get instant answers now!

Exploding scuba tank

A common scuba tank is an aluminum cylinder that weighs 31.7 pounds empty ( [link] ). When full of compressed air, the internal pressure is between 2500 and 3000 psi (pounds per square inch). Suppose such a tank, which had been sitting motionless, suddenly explodes into three pieces. The first piece, weighing 10 pounds, shoots off horizontally at 235 miles per hour; the second piece (7 pounds) shoots off at 172 miles per hour, also in the horizontal plane, but at a

19 °

angle to the first piece. What is the mass and initial velocity of the third piece? (Do all work, and express your final answer, in SI units.)

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Source: OpenStax, University physics volume 1. OpenStax CNX. Sep 19, 2016 Download for free at http://cnx.org/content/col12031/1.5

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