A uniform hollow spherical ball of mass 1.75 kg and radius 40.0 cm 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 2.63 m/s. How do we know that acceleration of the ball is constant considering newtons second law of motion? we are not allowed to use conservation of energy. We are only to use newtons second law for rotation
A uniform hollow spherical ball of mass 1.75 kg and radius 40.0 cm rolls without slipping...
help 8) A uniform hollow spherical ball of mass 1.75 kg and radius 40.0 em is rolling up a ramp that rises at 30.0° above the horizontal. Speed of the ball at the base of the ramp is 8.20 m/s. Moment of inertia of hollow sphere is given by I-(2/3)m r. (a) What is the angular velocity of the ball at the base of the ramp? (b) Determine how far up the ramp does it roll before it starts to...
A solid uniform spherical ball of mass 2.0 kg and radius 0.50 m rolls without slipping down a ramp that makes a 15 degree angle with the horizontal. What is the center-of-mass speed (in m/s) of the ball after it rolls 0.50 m down the ramp? A) 1.8 B) 2.5 C) 4.5 D) 7.0 E) None of these
A hollow spherical shell with mass 1.65 kg rolls without slipping down a slope that makes an angle of 40.0 ∘ with the horizontal. PART A) 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 . Part B Find the magnitude of the frictional force acting on the spherical shell. Take the free-fall acceleration to be g = 9.80 m/s2 .
A uniform hollow spherical shell of mass M and radius R rolls without slipping down an inclined plane. The plane has a length of L and is at an angle (theta). What is its speed at the bottom?
A hollow spherical shell with mass 1.85 kg rolls without slipping down a slope that makes an angle of 40.0 ° with the horizontal, own Part A 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/s. View Available Hint(s) VO AED ? acma_cm = m/s2 ho Submit Part B Find the magnitude of the frictional force acting on the spherical shell. Take the...
A hollow cylinder is released from rest and rolls down the incline without slipping. The incline has an angle of thera=40 degrees with the horizontal. The mass and radius of the cylinder is M=5kg and R=0.55m respectively. Moment of inertia of a hollow cylinder is I=MR^2. a)Draw the free body diagram of the hollow cylinder showing all the forces and their components. b) Using newtons 2nd law for linear and rotational motion, derive an expression for linear acceleration of the...
A hollow, spherical shell with mass 3.00 kg rolls without slipping down a 37.0 ∘ slope. Find the acceleration.
A hollow spherical shell with mass 2.50 kg rolls without slipping down a slope that makes an angle of 36.0degrees 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/s^2, then 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.
Bowling Ball. A bowling ball rolls without slipping up a ramp that slopes upward at an angle to the horizontal. Treat the ball as a uniform solid sphere of mass M and radius R, ignoring the finger holes. a) Draw the free-body diagram for the ball. Explain why the friction force must be directed up the ramp. b )What is the acceleration of the center of mass of the ball? c) What minimum coefficient of static friction is needed to...
A hollow, spherical shell with mass 2.00 kg rolls without slipping down a 33.0 slope. 1. Find the acceleration. 2. Find the friction force. 3. Find the minimum coefficient of static friction needed to prevent slipping.