A cylinder of mass 10 kg and radius 15 cm is rolling perfectly on a plane of inclination 30°. The coefficient of static friction µ_{s} = 0.25.

**(a)** How much is the force of friction acting on the cylinder?

**(b)** What is the work done against friction during rolling?

**(c)** If the inclination θ of the plane is increased, at what value of θ does the cylinder begin to skid, and not roll perfectly?

Asked by Abhisek | 1 year ago | 174

Given,

mass, m = 10 kg

Radius, r = 15 cm = 0.15 m

Co-efficient of kinetic friction, µ_{s }= 0.25

Angle of inclination, θ = 30°

We know, moment of inertia of a solid cylinder

about its geometric axis, I = (\( \dfrac{1}{2}\))mr^{2}

The acceleration of the cylinder is given as:

a = mg Sinθ / [m + (I/r^{2}) ]

= mg Sinθ / [m + { (\( \dfrac{1}{2}\))mr^{2 }/ r^{2 }} ]

= (\( \dfrac{2}{3}\)) g Sin 30°

a = (\( \dfrac{2}{3}\)) × 9.8 × (\( \dfrac{1}{2}\)) = 3.26 ms^{-2}

**(a)** Using Newton’s second law of motion, we can write net force as:

f_{NET} = ma

mg Sin 30° – f = ma

f = mg Sin 30° – ma

= 10 × 9.8 × (\( \dfrac{1}{2}\))- 10 × 3.26

= 49 – 32.6 = 16.3N

**(b) **There is no work done against friction during rolling.

**(c)** We know for rolling without skidding :

μ = (\( \dfrac{1}{3}\)) tan θ

tan θ = 3μ = 3 × 0.25

∴ θ = tan^{-1} (0.75) = 36.87°

Separation of Motion of a system of particles into motion of the centre of mass and motion about the centre of mass:

**(i)** Show p = p’_{i} + m_{i}V

Where p_{i} is the momentum of the i^{th} particle (of mass m_{i} ) and p’_{i} = m_{i}v_{i}‘. Note v’_{i} is the velocity of the i^{th} particle with respect to the centre of mass.

Also, verify using the definition of the centre of mass that Σp’_{i} = 0

**(ii)** Prove that K = K′ + \( \dfrac{1}{2}\)MV^{2}

Where K is the total kinetic energy of the system of particles, K′ is the total kinetic energy of the system when the particle velocities are taken relative to the centre of mass and MV^{2} /2 is the kinetic energy of the translation of the system as a whole.

**(iii)** Show L = L’+ R × MV

where L’ = ∑r’_{i} × p’_{i} is the angular momentum of the system about the centre of mass with velocities considered with respect to the centre of mass. Note r’_{i} = r_{i} – R, rest of the notation is the standard notation used in the lesson. Note L’ and MR × V can be said to be angular momenta, respectively, about and of the centre of mass of the system of particles.

**(iv)** Prove that :

\( \dfrac{dL’}{dt}\)= ∑ r’_{i} x \( \dfrac{dp’}{dt}\)

Further prove that :

\( \dfrac{dL’}{dt}\) = τ’_{ext}

Where τ’_{ext} is the sum of all external torques acting on the system about the centre of mass. ( Clue : Apply Newton’s Third Law and the definition of centre of mass . Consider that internal forces between any two particles act along the line connecting the particles.)

Read each statement below carefully, and state, with reasons, if it is true or false;

**(a)** During rolling, the force of friction acts in the same direction as the direction of motion of the CM of the body.

**(b) **The instantaneous speed of the point of contact during rolling is zero.

**(c)** The instantaneous acceleration of the point of contact during rolling is zero.

**(d) **For perfect rolling motion, work done against friction is zero.

**(e)** A wheel moving down a perfectly frictionless inclined plane will undergo slipping (not rolling) motion.

A solid disc and a ring, both of radius 10 cm are placed on a horizontal table simultaneously, with an initial angular speed equal to 10 π rad s^{-1}. Which of the two will start to roll earlier? The coefficient of kinetic friction is µ_{k} = 0.2.

Explain why friction is necessary to make the disc in Figure roll in the direction indicated.

**(a)** Give the direction of frictional force at B, and the sense of frictional torque, before perfect rolling begins.

**(b)** What is the force of friction after perfect rolling begins?

A disc rotating about its axis with angular speed ω_{o} is placed lightly (without any translational push) on a perfectly frictionless table. The radius of the disc is R. What are the linear velocities of the points A, B and C on the disc shown in Figure. Will the disc roll in the direction indicated?