A hollow spherical shell with mass 2.05 kg rolls without slipping down a slope that makes an angle of 39.0 ∘ with the horizontal. Find the magnitude of the acceleration acm of the center of mass of the spherical shell. Take the free-fall acceleration to be g = 9.80 m/s2 . Find the magnitude of the frictional force acting on the spherical shell. Take the free-fall acceleration to be g = 9.80 m/s2 . Find the minimum coefficient of friction μ needed to prevent the spherical shell from slipping as it rolls down the slope.

A hollow spherical shell with mass 2.05 kg rolls without slipping down a slope that makes an angle of 39.0 ∘ with the horizontal. Find the magnitude of the acceleration acm of the center of mass of the spherical shell. Take the free-fall acceleration to be g = 9.80 m/s2 . Find the magnitude of the frictional force acting on the spherical shell. Take the free-fall acceleration to be g = 9.80 m/s2 . Find the minimum coefficient of friction μ needed to prevent the spherical shell from slipping as it rolls down the slope.

University Physics Volume 1

18th Edition

ISBN:9781938168277

Author:William Moebs, Samuel J. Ling, Jeff Sanny

Publisher:William Moebs, Samuel J. Ling, Jeff Sanny

Chapter12: Static Equilibrium And Elasticity

Section: Chapter Questions

Problem 37P: To get up on the roof, a person (mass 70.0 kg) places 6.00-m aluminum ladder (mass 10.0 kg) against...

See similar textbooks

Similar questions

A hollow spherical shell with mass 1.50 kg rolls without slipping down a slope that makes an angle of 37.0 degree with the horizontal. a) Find the magnitude of the acceleration of the center of mass of the spherical shell. Take the free-fall acceleration to be g = 9.80 m/s^2. b) Find the magnitude of the frictional force acting on the spherical shell. Take the free-fall acceleration to be g = 9.80 m/s^2.
A hollow spherical shell with mass 2.05 kg rolls without slipping down a slope that makes an angle of 39.0 ∘ with the horizontal. Find the magnitude of the acceleration acm of the center of mass of the spherical shell. Take the free-fall acceleration to be g = 9.80 m/s2 . Find the magnitude of the frictional force acting on the spherical shell. Take the free-fall acceleration to be g = 9.80 m/s2 .
Shown are two thin beams joined at right angles. The vertical beam is 15.0 kg and 1.00 m long and the horizontal beam is 25.0 kg and 2.00 m long.a. Find the center of gravity of the two joined beams. Express your answer in the form (x, y), taking the origin at the corner where the beams join.b. Calculate the gravitational torque on the joined beams about an axis through the corner. The beams are seen from the side.
A uniform solid ball has a mass of 20 g and a radius of 5 cm. It rests on a horizontal surface. A sharp force is applied to the ball in the horizontal direction 9 cm above the surface. The force rises linearly from 0 to a peak value of 40,000 N in s and then decreases linearly to 0 in another s. (The moment of inertia for a solid ball is) a) What is the velocity of the ball after the impact? b) What is the angular velocity of the ball after the impact? c) What is the velocity of the ball when it begins to roll without sliding. (This means). d) For how long does the ball slide on the surface given the coefficient of kinetic friction
Consider the U-beam section shown in the figure below. The beam section splits into 3 segments (assuming it to be made of uniform, material and the mass of the vertical segment is double the mass of the horizontal segments). Find the y-coordinate of the center of mass from the bottom of the beam section (in cm). 120 cm 30 cm 180 cm +40 cm T30 cm ---. Origin 120 cm O a. 120.0 Ob. 177.5 12:11 ENG 18/05/2021
A large turntable with radius 6.00 m rotates about a fixedvertical axis, making one revolution in 8.00 s. The moment of inertia ofthe turntable about this axis is 1200 kg . m2. You stand, barefooted, atthe rim of the turntable and very slowly walk toward the center, along aradial line painted on the surface of the turntable. Your mass is 70.0 kg.Since the radius of the turntable is large, it is a good approximation totreat yourself as a point mass. Assume that you can maintain your balanceby adjusting the positions of your feet. You find that you can reacha point 3.00 m from the center of the turntable before your feet beginto slip. What is the coefficient of static friction between the bottoms ofyour feet and the surface of the turntable?
A uniform hollow spherical ball of mass 2.14 kg and radius 0.56 m rolls without slipping up a ramp that rises at 30.0° above the horizontal. The speed of the ball at the base of the ramp is 3.42 m.s1. While the ball is moving up the ramp, find (a) the magnitude of the acceleration of its center of mass. m.s2 (b) the magnitude of the friction force acting on it due to the surface of the ramp. N
A uniform plate of height 0.970 m is cut in the form of a parabolic section. | y IV The lower boundary of the plate is defined by: y =0.600x². Find the distance from the rounded tip of the plate to the center of mass. Submit Answer Tries 0/12
A uniform plank of length 2.00 m and mass 30.0 kg issupported by three ropes, as indicated by the blue vectors inFigure P8.27. Find the tension in each rope when a 700.-Nperson is d = 0.500 m from the left end.
A 9.94 kg mass is moving in a circle around a center point, attached to the center by a rubber band, with initial angular velocity 1.08 (as pictured below). Initially the length of the rubber band is 2.54, but then the rubber band stretches and its length is 6.08. After this happens what is the angular velocity of the mass? Assume that the system consisting of the mass and rubber band is isolated from any external forces and that the mass of the rubber band is negligible.
A uniform cube with mass 0.700 kg and volume 0.0270 m^3 is sitting on the floor. A uniform sphere with radius 0.300 m and mass 0.900 kg sits on top of the cube. How far is the center of mass of the two-object system above the floor? Express your answer with the appropriate units.
Look for the center of mass of a uniform solid right circular cone using M as mass, R as radius and H as Height.