How Far is the Spring Compressed by the Sliding Block?

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Bones
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Homework Statement


A 5.0 kg block slides along a horizontal surface with a coefficient of friction µk = 0.30. The block has a speed v = 2.1 m/s when it strikes a massless spring head-on (as in the figure).
http://www.webassign.net/gianpse4/8-18.gif
(a) If the spring has force constant k = 120 N/m, how far is the spring compressed?
(b) What minimum value of the coefficient of static friction, µs, will assure that the spring remains compressed at the maximum compressed position?
If µs is less than this, what is the speed of the block when it detaches from the decompressing spring? [Hint: Detachment occurs when the spring reaches its natural length (x = 0).]

Homework Equations





The Attempt at a Solution


a) -1/2(5.0kg)(2.1m/s)^2 + 1/2(120N/m)(x^2) = (0.30)(5.0kg)(9.8m/s^2)(cos 180)(x)
x=0.323m
b) I took u(5.0kg)(9.8m/s^2)(0.323m)(cos 180) = -1/2(120N/m)(0.323m)^2 which is not correct. Can someone help me get the correct equation??
 
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Please help, I am really stuck!
 
Any help at all would be appreciated ;)
 
Bones said:

Homework Statement


A 5.0 kg block slides along a horizontal surface with a coefficient of friction µk = 0.30. The block has a speed v = 2.1 m/s when it strikes a massless spring head-on (as in the figure).
http://www.webassign.net/gianpse4/8-18.gif
(a) If the spring has force constant k = 120 N/m, how far is the spring compressed?
(b) What minimum value of the coefficient of static friction, µs, will assure that the spring remains compressed at the maximum compressed position?
If µs is less than this, what is the speed of the block when it detaches from the decompressing spring? [Hint: Detachment occurs when the spring reaches its natural length (x = 0).]

3. The Attempt at a Solution
a) -1/2(5.0kg)(2.1m/s)^2 + 1/2(120N/m)(x^2) = (0.30)(5.0kg)(9.8m/s^2)(cos 180)(x)
x=0.323m

b) I took u(5.0kg)(9.8m/s^2)(0.323m)(cos 180) = -1/2(120N/m)(0.323m)^2 which is not correct. Can someone help me get the correct equation??

For a) I would write your equation as the KE of the mass = the work to compress the spring and the work against friction:

mV2/2 = kx2/2 + u*m*g*x

That yields for me 600x2 + 14.7x - 11.025 = 0

Using the quadratic formula that yields a different answer than you suggest.
 
How did you get 600x^2 from 120x^2/2??
 
I am still not getting part B.
 
Bones said:
I am still not getting part B.

If it is at equilibrium then the frictional force (using the static coefficient) must be equal to or greater than the kx from the spring detent:

F = kx needs to balance the us*m*g
 
You were attempting to use the work relationship when you were asked what condition needed to be met for the forces to balance.

You would use the work energy relationship figuring the transfer of potential in the spring back to the kinetic and friction for the outward rebound.
 
Last edited:
Bones said:
So umgx=1/2kx^2?

No. Not quite.

The excess of that is the kinetic energy remaining in the block.

mV2/2 = kx2/2 - u*m*g*x
 
How do I figure that part out?
 
The F = kx needs to balance the us*m*g

So umg=1/2kx^2
 
Bones said:
The F = kx needs to balance the us*m*g

So umg=1/2kx^2

No. 1/2 k*x2 is WORK. Units are N-m

u*m*g is Force. Units are N.

The force of a spring is given as F = kx. Units are N.

So it's u*m*g = k*x