Consider a mass-spring system. The spring has a spring constant of 2.35e+3 N/m. On the end of the spring is a mass of 0.840 kg. At the moment that the block is at the system's equilibrium position, it has velocity 2.24 m/s. What will be the maximum displacement of the block from equilibrium if we ignore all friction.

Elements Of Electromagnetics
7th Edition
ISBN:9780190698614
Author:Sadiku, Matthew N. O.
Publisher:Sadiku, Matthew N. O.
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Consider a mass-spring system. The spring has a spring constant of 2.35e+3 N/m. On the end of the spring is a mass of 0.840 kg. At the
moment that the block is at the system's equilibrium position, it has velocity 2.24 m/s. What will be the maximum displacement of the
block from equilibrium if we ignore all friction.
Please enter a numerical answer below. Accepted formats are numbers or 'e' based scientific notation e g. 0.23.-2. 16, 523-8
Transcribed Image Text:Consider a mass-spring system. The spring has a spring constant of 2.35e+3 N/m. On the end of the spring is a mass of 0.840 kg. At the moment that the block is at the system's equilibrium position, it has velocity 2.24 m/s. What will be the maximum displacement of the block from equilibrium if we ignore all friction. Please enter a numerical answer below. Accepted formats are numbers or 'e' based scientific notation e g. 0.23.-2. 16, 523-8
Consider the mass-on-a-spring system as shown in the figure below. The spring has a spring constant of 1.74e+3 N/m, and the block
has a mass of 1.36 kg. There is a constant force of kinetic friction between the mass and the floor of 1.88 N. Starting with the spring
compressed by 0.171 m from its equilibrium position, how far will the block travel once it leaves the spring? (Assume that block leaves
the spring at the spring's equilibrium position, marked x=0 in the figure. Give your answer as the distance from the equilibrium position
to the final position of the block.)
Hint: How much work must friction do in order to bring the mass to a stop? How much distance is required for friction to do this work?
Image size: ML Max
m
X=0
Transcribed Image Text:Consider the mass-on-a-spring system as shown in the figure below. The spring has a spring constant of 1.74e+3 N/m, and the block has a mass of 1.36 kg. There is a constant force of kinetic friction between the mass and the floor of 1.88 N. Starting with the spring compressed by 0.171 m from its equilibrium position, how far will the block travel once it leaves the spring? (Assume that block leaves the spring at the spring's equilibrium position, marked x=0 in the figure. Give your answer as the distance from the equilibrium position to the final position of the block.) Hint: How much work must friction do in order to bring the mass to a stop? How much distance is required for friction to do this work? Image size: ML Max m X=0
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