A 7.4kg block starts 1.2m above the ground, at the top of a frictionless ramp. At...
A 4.00 kg block starts sliding from rest from the top of a frictionless incline, the mass slides along a horizontal surface and collides with a spring compressing it a distance x. The spring will compress 3 meters with an applied force of 300N. A) Calulate the speed of the block at the halfway down the incline. B) Calculate the speed of the block at the bottom of the incline C) How much work is done on the block by...
3. A 4.00kg block (initially at rest) slides down a frictionless ramp which is inclined at 42° above horizontal. After sliding for 1.20m, the block hits a spring with spring constant k = 110 a) Calculate the speed of the block just before it hits the spring. b) Calculate maximum distance the spring compresses.
A 5kg block starts at a height of 10m above the ground and slides 20m down a rough surfaced incline. The work done by the frictional force in sliding down the incline is 240 J. It reaches the bottom of the incline and then enters a frictionless vertical loop of radius 2m. The speed of the block at the bottom of the hoop is 10.0m/s. The block performs one revolution and exits the loop.o sinu or mohe imImtombnes biduo nsotinpie...
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...
A block is placed on a frictionless ramp at a height hof 14.5 m above the ground. Starting from rest, the block slides down the ramp. At the bottom of the ramp, the block slides onto a frictionless horizontal track without slowing down. At the end of the horizontal track, the block slides smoothly onto a second frictionless ramp. 0 = 48.3° By = 25.5 How far along the second ramp does the block travel before coming to a momentary...
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 m is at rest at the top of a ramp of vertical height h. The block starts to slide down the frictionless ramp and reaches a speed v at the bottom. If the same block were to reach a speed 2v at the bottom, it would need to slide down a frictionless ramp of vertical height _____.
A block of mass 3.5 kg is sitting on a frictionless ramp with a spring at the bottom that has a spring constant of 435 N/m (refer to the figure). The angle of the ramp with respect to the horizontal is 29°. show answer Incorrect Answer 33% Part (a) The block, starting from rest, slides down the ramp a distance 52 cm before hitting the spring. How far, in centimeters, is the spring compressed as the block comes to momentary...
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...
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...