A bowling ball rolls 5.44 m/s along a frictionless gutter and runs into a horizontal spring at the end of the lane. The bowling ball compresses the spring and is then pushed back in the opposite direction by the spring, eventually losing contact with the spring. If the bowling ball has a mass of 1.80 kg, the spring is massless and has a spring constant of 41 N/m, how long does the bowling ball remain in contact with the spring?
A bowling ball rolls 5.44 m/s along a frictionless gutter and runs into a horizontal spring...
A mass of 0.5 kg moving along a horizontal frictionless surface encounters a spring having k = 200 N/m. The mass compresses the spring by 0.1 meters before reversing its direction. Consider the total time the mass is in contact with the spring. What is the total impulse delivered to the mass by the spring? (Let the initial direction of the mass's motion be the positive direction.)
An object slides along a frictionless horizontal surface with a speed of 25 m/s. It hits a horizontally placed spring that has an elastic constant of 5000 N/m. It compresses the spring 10-cm. What is the mass of the object?
A 2.0 kg mass is sliding without friction along a horizontal surface. It encounters a spring (k = 28 N/m), compresses it fully, and rebounds to move in the opposite direction. For what amount of time was the mass in contact with the spring?
A 2.80-kg box is sliding along a frictionless horizontal surface with a speed of 1.8 m/s when it encounters a spring. a. Determine the force constant of the spring, if the box compresses the spring 5.50 cm before coming to rest. b. Determine the initial speed the box would need in order to compress the spring by 1.30 cm. A box slides from rest down a frictionless ramp inclined at 39.0° with respect to the horizontal and is stopped at the bottom of...
In the figure, a 5.00-kg block is moving at 5 m/s along a horizontal frictionless surface toward an ideal massless spring that is attached to a wall. After the block collides with the spring, the spring is compressed a maximum distance of 0.68 m. What is the speed of the block in m/s when it has moved so that the spring is compressed to a distance of 0.495 m? 5.00 kg 5.00 m/s
A block of ice slides along a frictionless horizontal track with a speed of 1.2 m/s. At the end of the track is a horizontally mounted spring. The ice block slides along the track until it makes contact with the spring causing it to compress. What is the speed of the ice block when the spring has been compressed by 60% of the maximum compression length?
3./ A 1.2 kg block sliding at 6.0 m/s on a frictionless surface runs into and sticks to a spring. The spring is compressed 0.10 m before stopping the block and starting its motion back in the opposite direction. a. Calculate the energy of vibration. b. Calculate the force constant of the spring. c. Calculate the period of vibration of the system. d. Write the equation of motion of the block when its oscillating.
A uniform solid sphere rolls along a horizontal frictionless surface at 10 m/s and makes a smooth transition onto a frictionless incline having an angle of 300. How far up the incline does the sphere roll when it comes to a momentary stop? Note for a sphere I= 2/5Mr2, where M is the mass of the sphere and r is the radius of the sphere.
3. A 1.2 kg block sliding at 6.0 m/s on a frictionless surface runs into and sticks to a spring. The spring is compressed 0.10 m before stopping the block and starting its motion back in the opposite direction. a. Calculate the energy of vibration. b. Calculate the force constant of the spring. c. Calculate the period of vibration of the system. d. Write the equation of motion of the block when its oscillating. We were unable to transcribe this...
a 2.0 kg mass moves along a frictionless horizontal surface at a speed of 5.0 m/s. The mass encounters a 30 degree inclined surface with a constant friction force of 1.5 N. At 1 m high (vertical) the surface levels off and is again frictionless. the mass then encounters a spring with k=10 N/m a) how far is the spring compressed after the mass comes to rest? b) how far down the inclined plane will the mass move after bouncing...