Question 1 Hanging Mass - Part A: A 8.0 kg mass is suspended vertically below a spring. The spring-mass system begins at rest. Question 1 Hanging Mass - Part D We now grab hold of the 8 kg mass and apply a downward force, causing the spring to stretch. Of the forces you drew in Part A, which force or forces (if any) have increased in magnitude? Which force or forces (if any) decreased in magnitude? Which force or forces (if any) remained the same size? Question 1 Mass Hanging on a Spring - Part E Suppose an applied force of 150 N causes the spring to stretch and increase its length by 0.3 m. What is the spring constant of this spring? Question 1 Hanging Mass - Part F: We let go of the mass on spring, and the mass begins to move in simple harmonic motion. During its motion, there are two points along its cycle where the instantaneous speed of the mass will be 0 m/s. Qualitatively describe the spring at these locations (un-stretched, stretched to its maximum for the cycle, stretched but less than its maximum stretched amount, compressed to its maximum, etc). At each of these points, what will be the direction of the acceleration of the mass?
Question 1 Hanging Mass - Part A: A 8.0 kg mass is suspended vertically below a spring. The spring-mass system begins at rest. Question 1 Hanging Mass - Part D We now grab hold of the 8 kg mass and apply a downward force, causing the spring to stretch. Of the forces you drew in Part A, which force or forces (if any) have increased in magnitude? Which force or forces (if any) decreased in magnitude? Which force or forces (if any) remained the same size? Question 1 Mass Hanging on a Spring - Part E Suppose an applied force of 150 N causes the spring to stretch and increase its length by 0.3 m. What is the spring constant of this spring? Question 1 Hanging Mass - Part F: We let go of the mass on spring, and the mass begins to move in simple harmonic motion. During its motion, there are two points along its cycle where the instantaneous speed of the mass will be 0 m/s. Qualitatively describe the spring at these locations (un-stretched, stretched to its maximum for the cycle, stretched but less than its maximum stretched amount, compressed to its maximum, etc). At each of these points, what will be the direction of the acceleration of the mass?
College Physics
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ISBN:9781305952300
Author:Raymond A. Serway, Chris Vuille
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Chapter1: Units, Trigonometry. And Vectors
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Problem 1CQ: Estimate the order of magnitude of the length, in meters, of each of the following; (a) a mouse, (b)...
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This is a multiple part question, please help with what you are able to, thank you so much.
Part A provides the information needed but I just need help with part D, E, and F, if possible. Thank you again.
Transcribed Image Text:Question 1 Hanging Mass - Part A:
A 8.0 kg mass is suspended vertically below a spring. The spring-mass
system begins at rest.
Question 1 Hanging Mass - Part D
We now grab hold of the 8 kg mass and apply a downward force,
causing the spring to stretch.
Of the forces you drew in Part A, which force or forces (if any) have
increased in magnitude? Which force or forces (if any) decreased in
magnitude? Which force or forces (if any) remained the same size?
Question 1 Mass Hanging on a Spring - Part E
Suppose an applied force of 150 N causes the spring to stretch and
increase its length by 0.3 m. What is the spring constant of this spring?
Question 1 Hanging Mass - Part F:
|We let go of the mass on spring, and the mass begins to move in
simple harmonic motion. During its motion, there are two points along
its cycle where the instantaneous speed of the mass will be 0 m/s.
Qualitatively describe the spring at these locations (un-stretched,
stretched to its maximum for the cycle, stretched but less than its
maximum stretched amount, compressed to its maximum, etc). At each
of these points, what will be the direction of the acceleration of the
mass?
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