Finding x: Block Sliding on Spring SHM

AI Thread Summary
The discussion focuses on a system where a block of mass m is attached to a spring and has another block resting on top, with static friction between them. The key point is determining the condition under which the top block begins to slide off, which occurs when the frictional force equals the spring force. The equation umg = ma is used to express the maximum acceleration the top block can withstand before sliding. Participants clarify that the spring force is equal to the frictional force at the point of sliding, leading to the relationship kx = 2ma. The conversation emphasizes the need to derive the acceleration of the system as a function of the distance from the equilibrium position.
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A block of mass m is attached to a horizontal spring with constant k. resting on top of this block is another block of mass m. a coefficient of static friction mu exists between the two blocks. now suppose the spring is initially at equilibrium length, and someone gives it a push. the block moves in SHM in response. At a certain distance from equilibrium, the top block starts wo slide off the bottom one, find the x in terms of the given quantities and g.

So with the the moment when the top block slides off the block is when umg=ma? and where do I go from here?
 
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<br /> \mu mg = kx<br />

The spring force = the frictional force.
 
physicsss said:
So with the the moment when the top block slides off the block is when umg=ma?
Right. So this tells you the maximum acceleration that the top block can withstand before it starts sliding. So find the acceleration of the system as a function of distance from the equilibrium postion. (You know the force on the system from the spring, and you know the mass of the system.)
 
Hey futb0l,

Are you sure about that? I could be wrong but for the top block ma &lt;_= \mu m g (couldn't figure out less than or equal sign) . So when it isn't slipping kx = 2ma
 

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