Question

Notify Me Bookmark

A block of mass m = 5.78 kg is attached to a spring that is resting on a horizontal, frictionless table. The block is pushed into the spring, compressing it by 5.00 m, and is then released from rest. The spring begins to push the block back toward the equilibrium position at x = 0 m. The graph shows the component of the force (in newtons) exerted by the spring on the block versus the position of the block (in meters) relative to equilibrium. Use the graph to answer the questions. How much work W is done by the spring in pushing the block from its initial position at x = −5.00 m to x = 2.86 m? W = J What is the speed v of the block when it reaches x = 2.86 m? v = m/s What is the maximum speed vmax of the block? vmax = m/s

A block of mass m = 5.78 kg is attached to a spring that is resting on a horizontal, frictionless table. The block is pushed into the spring, compressing it by 5.00 m, and is then released from rest. The spring begins to push the block back toward the equilibrium position at x = 0 m. The graph shows the component of the force (in newtons) exerted by the spring on the block versus the position of the block (in meters) relative to equilibrium. Use the graph to answer the questions. How much work W is done by the spring in pushing the block from its initial position at x = −5.00 m to x = 2.86 m? W = J What is the speed v of the block when it reaches x = 2.86 m? v = m/s What is the maximum speed vmax of the block? vmax = m/s

Image text
A block of mass m = 5.78 k g is attached to a spring that is resting on a horizontal, frictionless table. The block is pushed into the spring, compressing it by 5.00 m , and is then released from rest. The spring begins to push the block back toward the equilibrium position at x = 0 m . The graph shows the component of the force (in newtons) exerted by the spring on the block versus the position of the block (in meters) relative to equilibrium. Use the graph to answer the questions.
How much work W is done by the spring in pushing the block from its initial position at x = 5.00 m to x = 2.86 m ?
W =
J
What is the speed v of the block when it reaches x = 2.86 m ?
v = m / s
What is the maximum speed v max of the block?
v max = m / s

Detailed Answer

0 0

Please enter your email here. You will get email when this question is answered by our tutor.

Doubtrix Logo

Problem is not yet solved!

Click on Notify me to get email when question is answered.

Join Doubtrix with 7-days free trial

  • Icon Correct & Verified Answers
  • Icon No AI-Generated Answers
  • Icon Video Solution for Difficult Questions
  • Icon Work With Experts to Reach at Correct Answers
Notify me Login Sign Up

Similar/Related Questions

A block of mass m = 5.78 kg is attached to a spring that is resting on a horizontal, frictionless table. The block is pushed into the spring, compressing it by 5.00 m, and is then released from rest. The spring begins to push the block back toward the equilibrium position at x = 0 m. The graph shows the component of the force (in newtons) exerted by the spring on the block versus the position of the block (in meters) relative to equilibrium. Use the graph to answer the questions. How much work W is done by the spring in pushing the block from its initial position at x = −5.00 m to x = 2.86 m? W = J What is the speed v of the block when it reaches x = 2.86 m? v = m/s What is the maximum speed vmax of the block? vmax = m/s
Solution
0 0

Work. A block of mass m = 2.00 kg is attached to a spring of force constant k = 500 N/m as shown on the right. The block is pulled to a position xi = 5.00 cm to the right of equilibrium and released from rest. There is friction between the surface and the block. The coefficient of friction between block and surface is μk = 0.350. (a) (3 pts) What is the work done by the elastic force during the displacement? (b) (2 pts) What is the work done by the kinetic friction on the block during its motion? (2 pts) (d) (5 pts) What is the speed of the block as it passes through the equilibrium position? Use work-kinetic energy theorem.
Solution
0 0

Integrated Concepts - Simple Harmonic Motion, Collision (stick together) As in Figure (a), a 3.91 kg block is attached to a spring with a force constant of 700.00 N/m. The green vertical dashed line indicates the equilibrium position (x = 0). A bullet of 0.075 kg moves toward the block at a speed of v0 = 470.00 m/s. The bullet is embedded in the block after the collision as in figure (b). (i) Find the common speed v of the Block + Bullet after the collision. Hint: What physics law is used for collisions? m/s (ii) The Block+Bullet moves on a frictionless horizontal surface and compresses the spring. What is the x in Figure (c) when the Block+Bullet reaches a momentary rest? Report x as NEGATIVE. m (iii) How much time does it take the Block+Bullet to move from figure (b) to figure (c)? (iv) What is the speed of the Block+Bullet when it reaches x2 = −0.46 m? m/sIntegrated Concepts - Simple Harmonic Motion, Collision (stick together) As in Figure (a), a 3.91 kg block is attached to a spring with a force constant of 700.00 N/m. The green vertical dashed line indicates the equilibrium position (x = 0). A bullet of 0.075 kg moves toward the block at a speed of v0 = 470.00 m/s. The bullet is embedded in the block after the collision as in figure (b). (i) Find the common speed v of the Block + Bullet after the collision. Hint: What physics law is used for collisions? m/s (ii) The Block+Bullet moves on a frictionless horizontal surface and compresses the spring. What is the x in Figure (c) when the Block+Bullet reaches a momentary rest? Report x as NEGATIVE. m (iii) How much time does it take the Block+Bullet to move from figure (b) to figure (c)? (iv) What is the speed of the Block+Bullet when it reaches x2 = −0.46 m? m/s
Solution
0 0