Lecture 19

1. Lecture 19 Goals: • Specify rolling motion (center of mass velocity to angular velocity • Compare kinetic and rotational energies with rolling • Work combined force and torque problems • Revisit vector cross product • Introduce angular momentum

2. Connection with Center-of-mass motion • If an object of mass M is moving linearly at velocity VCMwithout rotating then its kinetic energy is • If an object with moment of inertia ICMis rotating in place about its center of mass at angular velocityw then its kinetic energy is • If the object is both moving linearly and rotating then

3. But what of Rolling Motion 2VCM CM VCM • Consider a cylinder rolling at a constant speed. • Contact point has zero velocity in the laboratory frame. • Center of wheel has a velocity of VCM • Top of wheel has a velocity of 2VCM

4. Rolling Motion • Now consider a cylinder rolling at a constant speed. VCM CM The cylinder is rotating about CM and its CM is moving at constant speed (VCM). Thus its total kinetic energy is given by :

5. Motion Both with |vt| = |vCM | Rotation only vt = wR Sliding only 2VCM VCM CM CM CM VCM • Again consider a cylinder rolling at a constant speed.

6. Concept question • For a hoop of mass M and radius R that is rolling without slipping, which is greater, its translational or its rotational kinetic energy? • Translational energy is greater • Rotational energy is greater • They are equal • The answer depends on the radius • The answer depends on the mass

7. Example :Rolling Motion Disk has radius R M M M M M h M v ? q M • A solid cylinder is about to roll down an inclined plane. What is its speed at the bottom of the plane ? • Use Work-Energy theorem Mgh = ½ Mv2 + ½ ICMw2 and v =wR Mgh = ½ Mv2 + ½ (½ M R2)(v/R)2 = ¾ Mv2 v = 2(gh/3)½

8. Question: The Loop-the-Loop … with rolling ball has mass m & r <<R U=mg2R h ? R • To complete the loop-the-loop, how does the height h compare with rolling as to that with frictionless sliding? • hrolling > hsliding • hrolling = hsliding • hrolling < hsliding

9. Example: Loop-the-Loop with rolling • To complete the loop the loop, how high do we have to release a ball with radius r (r <<R) ? • Condition for completing the loop the loop: Circular motion at the top of the loop (ac = v2 / R) • Use fact that E = U + K = constant (or work energy) Ub=mgh ball has mass m & r <<R Recall that “g” is the source of the centripetal acceleration and N just goes to zero is the limiting case. Also recall the minimum speed at the top is U=mg2R h ? R

10. Example: Loop-the-Loop with rolling • Work energy (DK = W) • Kf = KCM + KRot = mg (h-2R) (at top) • Kf = ½ mv2 + ½ 2/5 mr2w2 = mg (h-2R) & v=wr • ½ mgR + 1/5 mgR = mg(h-2R)  h = 5/2R+1/5R Ub=mgh ball has mass m & r <<R U=mg2R h ? R Just a little bit more….

11. Torque :Rolling Motion (center of mass point) N mg q fs q • A solid cylinder, with mass m and radius R, is rolling without slipping down an inclined plane. • What is its angular acceleration a? 1. SFx = m acm = mg sin q - fs  m Racm = mgR sin q - Rfs SFy = 0 = N – mg cos q (not used) 2. St = -R fs = Icma 3. a = - acm / R  -mR2a= mgR sin q + Ia  -mR2a – Ia = mgR sin q a = -mgR sin q / (mR2 + I) = -2g sin q / 3R

12. Torque :Rolling Motion (contact point) • A solid cylinder, with mass m and radius R, is rolling without slipping down an inclined plane. • What is its angular acceleration a? 1. St = -R mg sin q= I a 2. I = mR2 + Icm • = -mgR sin q / (mR2 + Icm) • = 2g sin q / 3R N mg q fs q

13. Torque :Come back spool (contact point) N F mg fs N N F F mg mg fs fs • A solid cylinder, with mass m, inner radius r and outer radius R, being pulled by a horizontal force F at radius r? If the cylinder does not slip then what is the angular acceleration? 1. St = -rF= I a 2. I = mR2 + Icm = 3/2 mR2 • = -rF / (mR2 + Icm) = -2Fr/ 3R 1. St = rF= I a 2. I = mR2 + Icm • = 2Fr/ 3R 1. St = 0= I a • = 0

14. Torque : Limit of Rolling (center of mass) • A solid cylinder, with mass m and radius R, being pulled by a horizontal force F on its axis of rotation. If ms is the coefficient of static friction at the contact point, what is the maximum force that can be applied before slipping occurs? 1. SFx = m acm = F - fs 2.SFy = 0 = N – mg 3.St = -R fs = Icma  - acm = - fs mR2/ Icm 4. fs≤ms N = ms mg (maximum) 5. acm = - a R m acm = fs mR2/ Icm = F - fs fs (1+ mR2/ Icm ) = ms mg (1+ mR2/ Icm ) = F F = ms mg (1+ mR2/ ( ½ mR2) ) = 3 ms mg N F mg fs

15. Modified Atwood’s Machine (More torques) N T T T1 m2g T1 m1g • Two blocks, as shown, are attached by a massless string which passes over a pulley with radius R and rotational inertia I = ½ MR2. The string moves past the pulley without slipping. The surface of the table is frictionless. • What are the tensions in the strings ? mass 1 S Fy = m1 ay= -m1g +T1 mass 2 S Fx = m2 ax = –T pulley S t = Ia = R T1 – R T ay = ax= -aR = a m1 a= -m1g +T1 m2 a = –T -I a / R = R T1 – R T

16. Modified Atwood’s Machine (More torques) N T T T1 m2g T1 m1g • Two blocks, as shown, are attached by a massless string which passes over a pulley with radius R and rotational inertia I. The string moves past the pulley without slipping. The surface of the table is frictionless. • What are the tensions in the strings? 1. m1 a= – m1g +T1 2. m2 a= –T 3. -I a / R = R T1 – R T Solve for a -I a / R2 = m1 a+m1g + m2 a a = – m1g / (m1 + ½ M + m2) T= - m2 a T1= m1 a+ m1g

17. Angular Momentum • We have shown that for a system of particles, momentum is conserved if • Are the rotational equivalents? angular momentum is conserved if

18. For Thursday • Read all of chapter 10 (gyroscopes will not be tested) • HW9