Solving for Maximum Speed: Object on Spring with Force Constant of 19.6N/m

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SUMMARY

The discussion focuses on calculating the maximum speed of a 0.40 kg object attached to a spring with a force constant of 19.6 N/m, compressed by 4.0 cm. Using the conservation of mechanical energy, the maximum speed is determined to be 0.28 m/s. The conversation also addresses how to find the position x where the object's speed equals half of the maximum speed, emphasizing the need to consider both potential and kinetic energy at different states. The correct approach involves setting the potential energy equal to the kinetic energy at the specified speed.

PREREQUISITES
  • Understanding of Hooke's Law (F = -kx)
  • Knowledge of conservation of mechanical energy principles
  • Familiarity with kinetic energy and potential energy equations
  • Basic calculus for integrating force over distance
NEXT STEPS
  • Study the conservation of mechanical energy in oscillatory systems
  • Learn about the relationship between potential energy and kinetic energy in springs
  • Explore the concept of simple harmonic motion (SHM) and its equations
  • Investigate the effects of varying spring constants on oscillation speed
USEFUL FOR

Students in physics, particularly those studying mechanics and oscillatory motion, as well as educators looking to clarify concepts related to energy conservation in spring systems.

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Homework Statement


A 0.40kg object connected to a light spring with a force constant of 19.6N/m oscillates on a frictionless horizontal surface. If the spring is compressed 4.0 cm and released from rest, determine (a) the maximum speed of the object.


Homework Equations



F = -kx

The Attempt at a Solution



Does this involve kinetic energy?
 
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Yes, you need to use the conservation of mechanical energy principle.
 


so KE + KEs = 0

1/2mv^2 + 1/2kx^2 = 0

solve for v?
 


Close, but the spring has no kinetic energy only the attached mass. The spring can store what type of energy? Also set it up so its all the energy at state 1 equal to all the energy at state 2 (the point of interest).
 


sorry not kinetic energy but potential energy.
 


Yes so you should arrive at:
PEs = KE
which would give the same result as if you used the work kinetic energy theorem:
Ws = KE2-KE1
where Ws is the work done by the spring on the block and is equal to the integral of the spring force with respect to x or:
Ws = integral of Fdx = (1/2)kx^2
 


kjohnson said:
Yes so you should arrive at:
PEs = KE
which would give the same result as if you used the work kinetic energy theorem:
Ws = KE2-KE1
where Ws is the work done by the spring on the block and is equal to the integral of the spring force with respect to x or:
Ws = integral of Fdx = (1/2)kx^2

so 1/2mv^2 = 1/2kx^2
v = square root (kx^2/m)
 


correct.
 


k. i got the answer, the max speed is 0.28m/s.

The next part of the question is, for what value of x does the speed equal one-half the maximum speed.

What i did was to solve for x with v = 1/2(max speed)

I got the answer wrong.

Can someone point out where i went wrong?
 
  • #10


Again use the conservation of energy. Is your energy at state 1 (the compressed state) any different from part a? Then what forms of energy are present at state 2?
 
  • #11


at state 2, is it half the compressed state?
 
  • #12


No, that distance x is the unknown you are asked to solve for. At state 1 the only energy is potential energy which you know. At state two you know the kinetic energy of the mass because you know v=vmax/2, but you don't know the potential energy of the spring=(1/2)kx^2...
 
  • #13


So in state 1 there is potential energy, no kinetic energy. State 2 there's kinetic energy, where v is half of the max speed and there's potential energy and that's when we solve for x.
 
  • #14


correct.
 
  • #15


Thanks for you help! =)
 

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