A block of mass M 5.0 kgis hanging at equilibrium from an ideal spring with spring constant k = 250N/m. The block is pulled ( m below its equilibrium position and release
A block of mass M 5.0 kgis hanging at equilibrium from an ideal spring with spring constant k = 250N/m. The block is pulled ( m below its equilibrium position and release
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![A block of mass M 5.0 kgis hanging at
equilibrium from an ideal spring with spring
constant k = 250N/m. The block is pulled 0.15
m below its equilibrium position and released
from rest. The first block is again brought to rest
at equilibrium. An identical block is launched up
into the first block. The new block is moving
with a speed of v = 5.0 m when it collides with
Vo
and sticks to the original block. (g) Calculate the
maximum compression of the spring after the
collision of the two blocks.
k
M
M](/v2/_next/image?url=https%3A%2F%2Fcontent.bartleby.com%2Fqna-images%2Fquestion%2Fed7bb39c-a74a-47c0-9334-347fd148135c%2F5a23ae8d-974a-422b-b0d2-936b5b0fe10d%2Fs058eq5_processed.jpeg&w=3840&q=75)
Transcribed Image Text:A block of mass M 5.0 kgis hanging at
equilibrium from an ideal spring with spring
constant k = 250N/m. The block is pulled 0.15
m below its equilibrium position and released
from rest. The first block is again brought to rest
at equilibrium. An identical block is launched up
into the first block. The new block is moving
with a speed of v = 5.0 m when it collides with
Vo
and sticks to the original block. (g) Calculate the
maximum compression of the spring after the
collision of the two blocks.
k
M
M
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