Block A (M = 10 kg) is released from rest and slides down an initially frictionless...
Block A (M = 10 kg) is released from rest and slides
down an initially frictionless ramp (θ= 30°, L = 10 m). It
then passes over a rough patch of ground (µk=
0.633 and d = 5m) before impacting block B. Block B
(m = 20 kg) is initially at rest and suspended by a rigid
bar of negligible mass and length R = 5m. The coefficient
of restitution during the impact is e = 0.75. Determine
the maximum...
3.0 kg block slides down a frictionless ramp of height 3.0
meters starting from rest. it then traverses a 2.0 metter rough
patch with a coefficient of kinetic friction 0.35 It then gets to a
smooth area where it compresses a horizontal spring of spring
constant 50 n/m.
Please help me Solve the rest of the physics problem
The answers to part A is x= 1.64 meters and part b is 1.58
meters
Problem 1 A 3.0 kg block slides...
A block (6 kg) starts from rest and slides down a frictionless ramp #1 of height 6 m. The block then slides a horizontal distance of 1 m on a rough surface with kinetic coefficient of friction μk = 0.5. Next, it slides back up another frictionless ramp #2. Find the following numerical energy values: 1.Initial gravitational potential energy on Ramp #1: U1G = J 2.Kinetic energy at bottom of Ramp #1 before traveling across the rough surface: K =...
A block of mass m1 = 5.0 kg is released from a height of 5.0 m (point A) down a smooth, curved ramp. It makes an elastc headdon collision with a block of mass m2 = 10 kg that is initally at rest. (a) What is the maximum height reached by m1 afer the collision? (b) Afer the collision, m2 glides smoothly untl it hits a rough patch and eventually comes to a stop. What is the length of the...
As shown below (not to scale), a block of mass starts from rest
and slides down a frictionless ramp of height h. Upon reaching the
bottom of the ramp, it continues to slide across a flat
frictionless surface. It then crosses a "rough patch" on the
surface of length d=10m. This rough patch has a coefficient of
kinetic friction uK=.1. After crossing the rough patch, the block's
final speed is vf=2m/s. What is the height of the ramp? Hint: I...
The 2,5-kg block A is released from rest in the position shown and slides down on a curved surface. The block then hits the 3-kg pallet B. The block and the pallet move together and come to rest after sliding a distance d across the floor. Suppose that the curved surface is rough and velocity of block A before hitting the pallet B is 5,5 m/s. Determine the impulse exerted by the pallet B on the block A during impact....
A 3.0 kg block slides down a frictionless wedge of height of 3.0 meters starting from rest. It then traverses a 2.0 meter rough patch with a coefficient of kinetic friction 0.35. It then gets to a smooth area where it compresses a horizontal spring of spring constant 50 N/m. a. How much is the spring compressed when the mass briefly comes to a stop? b. How high up the ramp does the mass make it when it makes it...
A 15 kg box, initially at rest, slides down a frictionless ramp 10 m high. (a) Compute the velocity of the box as it reach the bottom of the ramp. (b) If it continuously slide horizontally in a horizontal plane with a coefficient of friction μ,-0.15, how far from the bottom of the ramp would it slide before coming into a complete stop? 1.
1. (30 points) A 2-kg block A is pushed up against a spring compressing it a distance r-0.1 m (i.e., the spring is unattached to the block). The block is then released from rest and slides down the 20° incline u it strikes a 1-kg sphere B that is suspended from a 1-m inextensible rope. The spring constant 800 N/m, the coefficient of friction between A and the ground i length of the spring d-1.5, and the coefficient of restitution...
a block of mass 10 kg is initially at rest when it slides down a frictionless incline whose height is 10 m and is pitched at an angle of 30 degrees. At the bottom of the incline the mass encounters a horizontal surface that has a coefficient of kinetic friction of 0.4 with the mass. How far from the bottom of the incline will the mass come to a stop?