A mass 3 kg is released from rest at a height of 5 meters and slides...
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 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...
An object of mass 3kg is released from rest from a height h of 13 meters above the ground on a ramp. The object then slides down along a horizontal surface along a distance of d=20 meters where friction is present (\mu_s=0.5 and \mu_k=0.2), and compresses a horizontal spring initially unstretched until it finally comes to rest. If k=300N/m, by how much does the spring compresses (maximally) upon impact?
1 45 kg is released from rest from the top of a rough ramp, with Mass - coefficient of kinetic friction 0.25 between the block and the incline, of height 3.2 m and length d 5.5 m. At the bottom of the ramp, the mass slides on a horizontal, frictionless surface until it compresses a spring of spring constant k 2. 110 N/m. a. Calculate the speed of the mass at the bottom of the ramp? b. How far does...
As shown in the figure below, a 2.25-kg block is released from rest on a ramp of height h. When the block is released, it slides without friction to the bottom of the ramp, and then continues across a surface that is frictionless except for a rough patch of width 15.0 cm that has a coefficient of kinetic friction μk = 0.520. Find h such that the block's speed after crossing the rough patch is 4.20 m/s. An object with a...
A mass of 1.8 kilograms is placed at height 0.5 meters above the dotted line above on a planar surface inclined at an angle of 30 degrees to the horizontal. The coefficient of kinetic friction between the mass and the inclined portion of the surface is 0.26. The mass is released, slides down the incline and compresses a spring with spring constant 1037.7 N/m. What is the largest compression in meters experienced by this spring?
A mass of 2.1 kilograms is placed at height 0.3 meters above the dotted line above on a planar surface inclined at an angle of 30 degrees to the horizontal. The coefficient of kinetic friction between the mass and the inclined portion of the surface is 0.32. The mass is released, slides down the incline and compresses a spring with spring constant 900.1 N/m. What is the largest compression in meters experienced by this spring?
TOELEN A mass of 2.1 kilograms is placed at height 0.5 meters above the dotted line above on a planar surface inclined at an angle of 30 degrees to the horizontal. The coefficient of kinetic friction between the mass and the inclined portion of the surface is 0.39. The mass is released, slides down the incline and compresses a spring with spring constant 1.120.4 N/m. What is the largest compression in meters experienced by this spring?
In the figure, block 1 of mass m1 slides from rest along a frictionless ramp from height h = 2.4 m and then collides with stationary block 2, which has mass m2 = 2m1. After the collision, block 2 slides into a region where the coefficient of kinetic friction μk is 0.2 and comes to a stop in distance d within that region. What is the value of distance d if the collision is (a) elastic and (b) completely inelastic?...
In the figure, block 1 of mass 2.00 kg slides from rest along a frictionless ramp from height h = 2.60 m and then collides with stationary block 2, which has mass 4.50 kg. The spring shown has a spring constant of 31.5 N/m. (a) How fast is block 1 moving just before contacting block 2? (b) Assume the whole path is frictionless, and the collision is completely inelastic, how far does the spring compress? (c) Now, assume you test...