1. 8 Rotational Dynamics describe/predict rotational behavior:
motion, energy, momentum.
with concepts of: rotational inertia & torque
Homework:
30, 33, 39, 60, 65, 83, 89, 111.

2. Translation and Rotation
Translation: up, down, left, right, in, out
Rotation:
clockwise (cw),
counterclockwise (ccw) //

3. Rotational Dynamics: Newton’s 2nd Law for Rotation

4. Mass-Distribution Effect
Larger radius
Larger Speed
Larger Effort  
Rotational Inertia ~
MR2

5. Rotational Inertia ( I )
kg(m)2
Example 3m 2m
4kg
5kg

6. Example: Four identical masses
Example: Four identical masses. Axis passes symmetrically through center of mass.

7. Example: Four identical masses. Axis passes through one end.

8. You Try It Calculate the Rotational Inertia of this system: 3m 4kg 2m

9. Calculated Rot. Inertias, p.273
rotational inertias of solid objects can be calculated
need to know: a, b, c, d, e, g, h, j, k.
omit: f, i

10. Rotational Kinetic Energy
Rotational K = ½(I)w2.
Example: Constant Power Source has 100kg, 20cm radius, solid disk rotating at 7000 rad/s.
I = ½MR2 = ½(100kg)(0.2m)2 = 2kgm2.
Rot K = ½ (2kgm2)(7000/s)2 = 49 MJ

11. Torque (t) [N·m] F F
= lever-arm

12. Torque Concept a small force can cause a large torque
a large force can create no torque

13. Rotationally Effective Application of Forces

14. Rotationally Ineffective Application of Forces

15. torque = Fsin(f) (r)

16. 1. A pair of forces with equal magnitudes and opposite directions is acts as shown. Calculate the torque on the wrench.

17. Example
Rod is 3m Long.

19. Newton’s 2nd Law (Rotation)

20. Concept Review Torque: rotational action
Rotational Inertia: resistance to change in rotational motion.
Torque ~ force x lever-arm

21. Equilibrium
Translational: net-force = 0
Rotational: net-torque = 0

22. The drawing shows a person whose weight is 584N
The drawing shows a person whose weight is 584N. Calculate the net force with which the floor pushes on each end of his body.

23. Rotational Work-Energy Theorem
(Work)rot = tDq.
Example: torque of 50 Nm is applied for one revolution.
rotational work = (50Nm)(2prad) = 314 J
(Rotational Work)net = DKrot.
Krot = ½Iw2.

24. Angular Momentum (L) analog of translational momentum L = Iw [kgm2/s]
Example: Disk R = 1m, M = 2kg, w = 10/s
I = ½MR2 = ½(1)(1)2 = 0.5
L = Iw = (0.5kgm2)(10/s) = 5kgm2/s

25. Conservation of Angular Momentum
For an isolated system
(Iw)before = (Iw)after
Example: Stationary disk M,R is dropped on rotating disk M, R, wi.
(½MR2)(wi) = (½MR2 + ½MR2)(wf)
(wf) = ½ (wi)

26. 8 Summary All TRANSLATIONAL quantities; speed, velocity, acceleration,
force, inertia, energy, and momentum,
have ROTATIONAL analogs.

27. Problem 33 Pivot at left joint, Fj = ?, but torque = 0.
ccw (Fm)sin15(18) = mg(26) = cw
ccw (Fm)sin15(18) = (3)g(26) = cw
(Fm) = (3)g(26)/sin15(18) = 160N
Note: any point of arm can be considered the pivot (since arm is at rest)

28. #39 Left force = mg = 30g, Right = 25g mg = 30g + 25g m = 55kg
ccw mg(xcg) = cw 30g(1.6)
(55)g(xcg) = 30g(1.6)
(55)(xcg) = 30(1.6)
Xcg = (30/55)(1.6)

29. #60, z-axis Each mass has r2 = 1.52 + 2.52.
I = sum mr2 = ( )( )

30. #65
First with no frictional torque, then with frictional torque as specified in problem.
M = 0.2kg, R = 0.15m, m1 = 0.4, m2 = 0.8

31. #83
Pulley M, R. what torque causes it to reach ang. Speed. 25/s in 3rev?
Alpha: use v-squared analog eqn.
Torque = Ia = (½MR2)(a)

32. #89, uniform sphere part Rolling at v = 5m/s, M = 2kg, R = 0.1m
K-total = ½mv2 + ½Iw2.
= ½(2)(5x5) + ½[(2/5)(2)(0.1x0.1)](5/0.1)2.
= = 35J
Roll w/o slipping, no heat created, mech energy is conserved, goes all to Mgh.
35 = Mgh h = 35/Mg = 35(19.6) = 1.79m

33. #111 Ice skater, approximate isolated system Therefore:
(Iw)before = (Iw)after
(100)(wi) = (92.5)(wf)
(wf) = (100/92.5)(wi)
K-rot increases by this factor squared times new rot. Inertia x ½.

34. Example: Thin rod formulas.

35. K = Ktranslation + Krotation

36. Angular Momentum Symbol: L Unit: kg·m2/s L = mvr = m(rw)r = mr2w = Iw.
v is perpendicular to axis
r is perpendicular distance from axis to line containing v.

37. Angular Momentum Symbol: L Unit: kg·m2/s L = mvr = m(rw)r = mr2w = Iw.
v is perpendicular to axis
r is perpendicular distance from axis to line containing v.

38. 13) Consider a bus designed to obtain its motive power from a large rotating flywheel (1400. kg of diameter 1.5 m) that is periodically brought up to its maximum speed of rpm by an electric motor at the terminal. If the bus requires an average power of 12. kilowatts, how long will it operate between recharges?
Answer: 39. minutes
Diff: 2 Var: 1 Page Ref: Sec. 8.4

39. 6) A 82. 0 kg painter stands on a long horizontal board 1
6) A 82.0 kg painter stands on a long horizontal board 1.55 m from one end. The 15.5 kg board is 5.50 m long. The board is supported at each end.
(a) What is the total force provided by both supports?
(b) With what force does the support, closest to the painter, push upward?

40. 28) A 4.0 kg mass is hung from a string which is wrapped around a cylindrical pulley (a cylindrical shell). If the mass accelerates downward at 4.90 m/s2, what is the mass of the pulley?
A) 10.0 kg
B) 4.0 kg
C) 8.0 kg
D) 2.0 kg
E) 6.0 kg

41. (a) 2.0 kg-m2 (b) 2.3 kg-m2 (c) 31. rpm
19) A solid disk with diameter 2.00 meters and mass 4.0 kg freely rotates about a vertical axis at 36. rpm. A 0.50 kg hunk of bubblegum is dropped onto the disk and sticks to the disk at a distance d = 80. cm from the axis of rotation.
(a) What was the moment of inertia before the gum fell?
(b) What was the moment of inertia after the gum stuck?
(c) What is the angular velocity after the gum fell onto the disk?
(a) 2.0 kg-m2
(b) 2.3 kg-m2
(c) 31. rpm

43. 3. The drawing shows the top view of two doors
3. The drawing shows the top view of two doors. The doors are uniform and identical. The mass of each door is M and width as shown below is L. How do their rotational accelerations compare?

44. A Ring, a Solid-Disk, and a Solid-Sphere are released from rest from the top of an incline. Each has the same mass and radius. Which will reach the bottom first?

45. 5. The device shown below is spinning with rotational rate wi when the movable rods are out. Each moveable rod has length L and mass M. The central rod is length 2L and mass 2M.
Calculate the factor by which the angular velocity is increased by pulling up the arms as shown.

46. How large is the height h in the drawing? The ball’s initial speed is 4.0 m/s. Does it depend on M and R?
solid ball rolls without slipping

47. Rotational Review
(angles in radians)
+ 4 kinematic equations

48. Graph showing mt2 is more constant than mt

49. L = Iw Angular Momentum Calculation
Example: Solid Disk M = 2kg R = 25cm
Spins about its center-of-mass at 35 rev/s

50. 4. A one-meter-stick has a mass of 480grams.
a) Calculate its rotational inertia about an axis perpendicular to the stick and through one of its ends.
b) Calculate its rotational inertia about an axis perpendicular to the stick and through its center-of-mass.
c) Calculate its angular momentum if spinning on axis (b) at a rate of 57rad/s.

51. Conservation of Angular Momentum
Example: 50 grams of putty shot at 3m/s at end of 200 gram thin 80cm long rod free to rotate about its center.
Li = mvr = (0.050kg)(3m/s)(0.4m)
Lf = Iw = {(1/12)(0.200kg)(0.8m)2 + (0.050kg)(0.4m)2}(w)
final rotational speed of rod&putty =