Potential Energy and Conservation of Energy Problems

AI Thread Summary
The discussion focuses on solving potential energy and conservation of energy problems in AP Physics C: Mechanics. Participants analyze specific homework questions involving a block sliding on a frictionless surface, spring compression, and a man jumping into a fire net. Key equations for mechanical energy, potential energy, and kinetic energy are referenced, with attempts to clarify misunderstandings about energy transfer and calculations. The correct answers to the problems are confirmed, emphasizing the importance of correctly applying energy conservation principles. The conversation highlights common pitfalls in setting up equations and understanding energy conversions.
Matthew.C21
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Hi everybody! So this is my first time using this forum. I'm currently taking AP Physics C: Mechanics in high school and I have some questions concerning Potential Energy and Conservation of Energy. Thanks for taking the time to help me!

Homework Statement



32. A 4.0-lb block slides along a horizontal frictionless surface at 8 ft/s. It is brought to rest by compressing a very long spring of spring constant (1/8) lb/ft. The maximum spring compressing is:
A. 4 ft
B. 8 ft (Correct Answer)
C. 16 ft
D. 2 ft
E. 45 ft

33. A block of mass m is initially moving to the right on a horizontal frictionless surface at a speed v. It then compresses a spring of spring constant k. At the instant when the kinetic energy of the block is equal to the potential energy of the spring, the spring is compressed a distance of:
A. v sqrt(m/2k) (Correct Answer)
B. (1/2)mv^2
C. (1/4)mv^2
D. mv^2/4k
E. (1/4)sqrt(mv/k)

34. A 200-lb man jumps out of a window into a fire net 30 ft below. The net stretches 6 ft before bringing the man to rest and tossing him back into the air. The maximum potential energy in (ft*lb) of the net is:
A. 7200 (Correct Answer)
B. 6000
C. 1800
D. 1200
E. 600


Homework Equations



Emech = K + U
U = 1/2k(x)^2
U = mgh
K = 1/2m(v)^2


The Attempt at a Solution



32. 1/2 (1/8) x^2 = 1/4 (4) 8^2 <<<< Doesn't work, don't know how I should be setting up the equation.

33. 1/2 kx^2 = 1/2 mv^2
kx^2 = mv^2
x^2 = mv^2/k
x = v sqrt(m/k) <<<< Why am I missing the 2k?

34. mgh = 1/2kx^2
200*32*3 = 1/2*k*6^2
192000 = 18k
k = 10,666.67
U = 1/2 (10,666.67) 6^2 <<<< WAYYYY off.
 
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Welcome to PF.

What are you stuck on?
 
After looking over the problem, I realized that i forgot to divide the lb by gravity. That takes care of 32 and 34. For 33, I don't really understand why the answer is vsqrt(m/2k) instead of vsqrt(m/k)
 
Your energy equation is incorrect. If the initial velocity of the block is v, when the block hits the spring, it will lose kinetic energy which will be converted to potential energy. When the potential energy of the spring is equal to the kinetic energy of the block, let the velocity of the block be v1.

The potential energy gained by the spring is equal to the difference in kinetic energy of the block (initial-current). The current kinetic energy of the block is equal to the potential energy which gives you your answer. Try to set it up.
 
so Usp = Etotal - Ek?
 
The point to realize is that your use of the equation, "1/2 kx^2 = 1/2 mv^2" transfers all energy from the block, to the spring; but, the problem statement requests that you determine the position where Kblock = Uspring. Because Uspring started at zero, the point where the magnitudes are equivalent is 1/2Kblock initial, i.e. the block transfers half of its energy to the spring.
 

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