Difference between revisions of "Forest UCM MnAM InElasticCol"

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a.) Find the final speed of the car if both men run and jump off simultaneously.
 
a.) Find the final speed of the car if both men run and jump off simultaneously.
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 +
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At the instant the hobo jumps off with speed <math>u</math> the railcar will move in the opposite direction at some speed <math>v</math>.  Since the hobo's speed is relative to the car, the hobos speed relative to the ground is <math>u-v</math>.
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;conservationof momentum
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:<math>\Rightarrow 0 = 2m(u-v) - Mv</math>
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 +
or
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: v = \frac{}{}

Revision as of 02:50, 12 September 2014

An Inelastic collision conservers Momentum But Not energy

Consider a collision between two bodies of mass [math]m_1[/math] and [math]m_2[/math] initially moving at speeds [math]v_1[/math] and [math]v_2[/math] respectively. They stick together after they collide so that each is moving at the same velocity [math]v[/math] after the collision.


If there are no external force then

Conservation of momentum
[math]m_1 v_1 + m_2 v_2 = \left (m_1 + m_2 \right ) v[/math]

Given that the amsses and initially velocities are known we can solve for v such that

[math]v= \frac{m_1 v_1 + m_2 v_2}{m_1 + m_2}[/math]

Forest_UCM_MnAM#Inelastic_Collision_of_2_bodies

problem 3.4 two hobos

Two hobos are standing at one end of a stationary railroad flatcar of mass [math]M[/math]. Each hobo has a mass [math]m[/math] and the flatcar has frictionless wheels. A hobo can run to the other end of the car and jump off with a speed [math]u[/math] with respect to the car.

a.) Find the final speed of the car if both men run and jump off simultaneously.


At the instant the hobo jumps off with speed [math]u[/math] the railcar will move in the opposite direction at some speed [math]v[/math]. Since the hobo's speed is relative to the car, the hobos speed relative to the ground is [math]u-v[/math].

conservationof momentum
[math]\Rightarrow 0 = 2m(u-v) - Mv[/math]

or

v = \frac{}{}