Distance travelled by the case down a ramp w/a spring at the bottom

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A 5.0 kg case of bottled water slides down a 25-degree ramp and compresses a spring by 5.5 cm upon impact. The spring constant is calculated to be 13,000 N/m using the spring's force at 2.0 cm compression. The energy equations involve gravitational potential energy and spring potential energy, with the correct height expression requiring the sine of the angle, not cosine. The initial confusion stemmed from misinterpreting the significance of the 2.0 cm compression, which is solely for calculating the spring constant and not relevant to the final compression. The case of water travels a distance of 0.6139 m down the ramp before hitting the spring.
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Homework Statement



A 5.0 kg case of bottled Spring water is released from rest down a shipping ramp inclined 25oto the horizontal. At the base of the ramp, oriented parallel to its surface, is a spring that can be compressed 2.0 cm by a force 260 N. The case of water moves down the ramp and compresses the sring by 5.5 cm. How far has the case of water traveled down the ramp from its point of release before hitting the spring?

Homework Equations


Fspring= kx
E=mgh
E=0.5*kx2

The Attempt at a Solution


know that the force exerted by the spring is 260 at x=0.02 m i figured out k which is 13000N/m. i know that h= dcos \vartheta. i set up the equation
mgdcos\vartheta= 0.5*kx2 where x now equals the difference between 5.5cm and 2.0cm and solved for d i ended up getting 1.8m when the answer is actually half that i was wondering what i did wrong??
 

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Check your expression for "h."
 
if i use sin theta i get -1.2278 m
 
It should be sin, not cos. And x is not the difference between 5.5 cm and 2.0 cm, it's just 5.5 cm, i.e. the amount by which the spring is compressed.
 
ok...so then the 2.0 cm was just given to us to figure out the force and has nothing to do with the actual compression of the spring when the bottle hits it..??
 
brunettegurl said:
ok...so then the 2.0 cm was just given to us to figure out the force and has nothing to do with the actual compression of the spring when the bottle hits it..??

Right. The 2.0 cm figure is only used to determine the spring constant.
 

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