A thin spherical shell of radius 1.32 meters rolls down a 8.25 meter high hill without...
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 1.9 m radius cylinder with a mass of 531.1 kg rolls without slipping down a hill which is 56.5 meters high. At the bottom of the hill, what fraction of its total kinetic energy is invested in rotational kinetic energy?
A 1.2 m radius cylinder with a mass of 8.8 kg rolls without slipping down a hill which is 5.7 meters high. At the bottom of the hill, what percentage of its total kinetic energy is invested in rotational kinetic energy?
A 1.2 m radius cylinder with a mass of 5.9 kg rolls without slipping down a hill which is 8.2 meters high. At the bottom of the hill, what fraction of its total kinetic energy is invested in rotational kinetic energy?
A spherical boulder of mass 98.1 kg and radius 22 cm rolls without slipping down a hill 13 m high from rest. (a)What is its angular momentum about its center when it is half way down the hill? Ans: 82.4 kg. m2/s (b)What is its angular momentum about its center when it is at the bottom? Ans: 116 kg. m2/s please show work thank you
A hoop rolls down a 4.25 m high hill without slipping. Randomized Variables d = 4.25 m what is the final speed of the hoop, in meters per second?
A spherical shell is released from rest and rolls down a θ = 28° incline without slipping and reaches the bottom with an angular speed of ω = 32.2 rad/s. The M = 1.5 kg sphere has a radius R = 0.60 m and a moment of inertia given as I = (2/3)MR2. Find the distance Δx that the sphere traveled on the incline in m.
3). A thin spherical shell is centered at the origin with radius 1.8 meter. The shell has a surface charge density of -5 C/m². At the center of the spherical shell (at the origin) there is a +2 C point charge. Calculate the magnitude of the electric field at 1.2 meters from the center of the spherical shell.
A spherical shell is released from rest and rolls down a 2 = 28° incline without slipping and reaches the bottom with an angular speed of w = 32.2 rad/s. The M = 1.5 kg sphere has a radius R = 0.60 m and a moment of inertia given as I = (2/3)MR2. R -AX 0 Find the distance Ax that the sphere traveled on the incline. m
1) A solid ball of mass M and radius R rolls without slipping down a hill with slope tan θ. (That is θ is the angle of the hill relative to the horizontal direction.) What is the static frictional force acting on it? It is possible to solve this question in a fairly simple way using two ingredients: a) As derived in the worksheet when an object of moment of inertia I, mass M and radius R starts at rest...