5) If the block has mass of 35 kg and its initial velocity is 2.7 m/s (at x = 3 m), determine the maximum compression of the spring (after the block has pushed in the spring and come to a stop). The spring constant is given in the image. Your answer must include 3 places after the decimal point and the proper unit. Take g = 9.81 m/s².
5) If the block has mass of 35 kg and its initial velocity is 2.7 m/s (at x = 3 m), determine the maximum compression of the spring (after the block has pushed in the spring and come to a stop). The spring constant is given in the image. Your answer must include 3 places after the decimal point and the proper unit. Take g = 9.81 m/s².
Principles of Heat Transfer (Activate Learning with these NEW titles from Engineering!)
8th Edition
ISBN:9781305387102
Author:Kreith, Frank; Manglik, Raj M.
Publisher:Kreith, Frank; Manglik, Raj M.
Chapter5: Analysis Of Convection Heat Transfer
Section: Chapter Questions
Problem 5.18P: The drag on an airplane wing in flight is known to be a function of the density of air (), the...
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Question
Transcribed Image Text:3. For this series of 5 questions, a block is released from the position shown with a
certain initial velocity. It then slides down the smooth (friction-less) path for which
the function is given in the image. You will be asked to solve for different things.
Please pay attention: the numbers may change from problem to problem since they
are randomized.
5) If the block has mass of 35 kg and its initial velocity is 2.7 m/s (at x = 3 m),
determine the maximum compression of the spring (after the block has pushed in the
spring and come to a stop). The spring constant is given in the image. Your answer
must include 3 places after the decimal point and the proper unit. Take g = 9.81
m/s².
k = 5 kN/m
puudu
Your Answer:
Answer
units
y = 0.25x².
3 m
v
X
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