Maximum Acceleration of Oscillating Blocks

AI Thread Summary
The discussion revolves around calculating the maximum acceleration of two blocks oscillating on a spring while maintaining contact. The key formula derived is a_max = (m/(m+M))g, where "m" is the mass of the smaller block and "M" is the mass of the larger block. Participants explore various methods to prove this, including using forces and energy equations, but encounter challenges due to missing variables like amplitude. There is confusion about whether the maximum acceleration can simply be equal to gravitational acceleration (g), with some participants suggesting that it must be greater to keep the blocks together. Ultimately, the consensus leans towards the derived formula being correct, emphasizing the importance of considering both masses in the system.
radtad
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Im not sure exactly what to do with a part of this problem

A 5 kg block is fastened to a vertical spring that has a spring constant of 1000 Newtons per meter. A 3 kg block rests on top of the 5 kg block. The blocks are pushed down and released so that they oscillate.

Determine the magnitude of the max acceleration that the blocks can attain and still remain in contact at all times.

There are other parts of the problem but nothing before this that would help with this part.

Now I am pretty sure that the max acceleration would be g, the accleration due to gravity but I don't know how to go about it to prove with formulas Am i even correct in this assumption?
THanks for the help
 
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Post your work.My answer is
a_{max}=\frac{m}{m+M}g
,where "m" is the mass of the smaller body,and "M" is the mass of the heavier body.
Numerically,for g\sim 10ms^{-2},a_{max}\sim 3.75ms^{-2} [/tex]<br /> <br /> Daniel.
 
well first i just assumed it would be g.
Now i keep hitting dead ends trying various methods.

i tried using amax=Aw^2 and then got stuck without an amplitude.
I tried Fnet=ma and then plugged in kx=(m+M)amax but don't have an x value. So I am really not sure where to go with this
 
radtad said:
well first i just assumed it would be g.
Now i keep hitting dead ends trying various methods.

i tried using amax=Aw^2 and then got stuck without an amplitude.
I tried Fnet=ma and then plugged in kx=(m+M)amax but don't have an x value. So I am really not sure where to go with this

What's the condition of equilibrium for the small body (being attached to the big one) ?Why would it lose contact with the larger one?

Daniel.
 
the upward force from the spring is greater than its weight?
 
Exactement.Next question.What's the connection between the maximum acceleration and maximum distance from the equilibrium point??

Daniel.
 
max acceleration = amplitude times angular frequency squared
amplitude would be the max distance from the equilibrium point for the max acceleration right?
 
would it be that at the point where amax without disattachment occurs Fg=Fs so mg/k=x
 
Exactly,u're on the right track.Put it all together now and post your work.

Daniel.
 
  • #10
Fnet=ma
Fs-Fg=(m+M)amax
amax=(kx-(m+M)g)/(m+M)
amax=k((m+M)g)/k)-(m+M)g)/(m+M)
amax=0/(m+M)

obviously i screwed something up
also why wouldn't the max acceleration of the blocks in order to remain together just be the acceleration due to gravity? Wouldn't the blocks have to be accelerating faster than that in order to keep the block that is not attached moving after the block attached to the spring has reached the max x value and starts mvoing back down the spring?
 
  • #11
Obviously one of us is wrong.It may be me,or it may be.
The second law of dynamics for the small body is
m\vec{a}=m\vec{g}+\vec{F}_{el,max}=\vec{0}
,because the small body must be imponderable (its's accleration in the reference system of the big body it is attached to is zero).
F_{el,max}=kA

From these 2 eq.u find:
A=\frac{mg}{k}

The maximum acceleration is
a_{max}=\omega^{2}A=\frac{k}{M+m}\frac{mg}{k}=\frac{m}{M+m}g

Daniel.

PS.We need a third party... :-p
 
  • #12
yea i think we need a 3rd party bc one of my friends in my class is telling me its just g and that I am thinking about it too much so i don't know
 
  • #13
radtad said:
yea i think we need a 3rd party bc one of my friends in my class is telling me its just g and that I am thinking about it too much so i don't know

Just as a different point of view(i'm not sure if it's right or not):

We can try using energy to solve this: We know the max height is 2x, due to the oscillation.

so

kx^2/2 = mg(2x)

kx = 4mg = Fspring.

Fspring/m = acceleration = 4g.
 
  • #14
I'm sorry,but it's not valid.There are two bodies implied in the interaction with the spring.U cannot make abstraction of the bigger one.
Besides,your result is absurdly large.

Daniel.
 
  • #15
i think I am going to go with amax=g but ill let u guys know what it turns out to be when i get the homework back monday
 
  • #16
apchemstudent said:
Just as a different point of view(i'm not sure if it's right or not):

We can try using energy to solve this: We know the max height is 2x, due to the oscillation.

so

kx^2/2 = mg(2x)

kx = 4mg = Fspring.

Fspring/m = acceleration = 4g.

Actually my answer should've been 3g, forgot about the net force. As for dexter... i don't understand why my answer would be wrong.
 
  • #17
dextercioby said:
Obviously one of us is wrong.It may be me,or it may be.
The second law of dynamics for the small body is
m\vec{a}=m\vec{g}+\vec{F}_{el,max}=\vec{0}
,because the small body must be imponderable (its's accleration in the reference system of the big body it is attached to is zero).
F_{el,max}=kA

From these 2 eq.u find:
A=\frac{mg}{k}

Why didn't you use (m+M)a=(m+M)g + Fel=0 with Fel=kA leading to A=(m+M)g/k?

With this you get max acceleration=g.
 
  • #18
Yes,you're right,i was an idiot,i forgot that those two bodies are joint together and the 2nd law should apply on the whole body.

I appologize again.I was really tired and semi-drunk... :-p

Daniel.
 
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