Max Compression Distance x: Solving the Compression Distance Problem

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The discussion focuses on solving the compression distance problem involving two colliding objects and a spring. An object with mass m1=10 kg moving at v1=30 m/s collides with a stationary object of mass m2=5 kg, resulting in a final velocity (Vf) of 20 m/s after the collision. The energy conservation principle is applied to find the maximum compression distance (x) of a spring with a spring constant (k) of 80 N/m, using the equation for kinetic energy and potential energy stored in the spring.

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Problem: An object of mass m1= 10 kg moving to the right with a velocity v1=30 m/s, collides with a second object of mass m2=5kg, which is initially at rest. The 2 objects stick together, and they continue to move with the same velocity V. The moving system of 2 blocks compresses a light spring, having a spring constant k=80 N/m. Calculate the max. compression distance x, of the spring.

m1v1 + m2v2 = (m1+m2)vf
(10)(30)+(5)(0)=(10+5)vf
300=15vf
Vf=300/15=20

KE=U spring

I stuck on how to finish solve the problem.
 
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You need to account for the energy stored in the spring. it is given by
\frac{1}{2} k x^2
where k is the spring constant and x is the distance from the equilibrium position.
 
In other words, after you have found the 20 m/s velocity, this becomes an energy conservation problem to get the spring compression.
 

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