Presentation is loading. Please wait.

Presentation is loading. Please wait.

Lecture 13: Rotational Kinetic Energy and Rotational Inertia l Review: Rotational Kinematics l Rotational Kinetic Energy l Rotational Inertia l Torque.

Published byMarcus O’Brien’ Modified over 8 years ago

Similar presentations

Presentation on theme: "Lecture 13: Rotational Kinetic Energy and Rotational Inertia l Review: Rotational Kinematics l Rotational Kinetic Energy l Rotational Inertia l Torque."— Presentation transcript:

1 Lecture 13: Rotational Kinetic Energy and Rotational Inertia l Review: Rotational Kinematics l Rotational Kinetic Energy l Rotational Inertia l Torque l Rotational Dynamics l Equilibrium

2 Recall: Rotational Kinematics Angular Linear And for a point at a distance R from the rotation axis: x T =  R  v T =  R  a T =  R

3 Comment on Axes and Signs (i.e. what is positive and negative) l Whenever we talk about rotation, it is implied that there is a rotation “axis”. l This is usually called the “z” axis (we usually omit the z subscript for simplicity). Counter-clockwise (increasing  ) is usually called positive. Clockwise (decreasing  ) is usually called negative. z 

4 Rotational Kinetic Energy Consider a mass M on the end of a string being spun around in a circle with radius R and angular frequency   Mass has speed v =  R è Mass has kinetic energy »K = ½ M v 2 »K = ½ M  2 r 2 l Rotational Kinetic Energy is energy due to circular motion of object. M

5 Kinetic Energy of Rotating Disk Consider a disk with radius R and mass M, spinning with angular frequency   Each “piece” of disk has speed v i =  r i è Each “piece” has kinetic energy »K i = ½ m i v 2 » = ½ m i  2 r i 2 è Combine all the pieces »  K i =  ½ m i  2 r 2 » = ½ (  m i r i 2 )  2 » = ½ I  2 riri I is called the Rotational Inertia

6 Rotational Inertia I l Tells how much “work” is required to get object spinning. Just like mass tells you how much “work” is required to get object moving. è K tran = ½ m v 2 Linear Motion  K rot = ½ I  2 Rotational Motion I   m i r i 2 (units kg-m 2 ) l Note! Rotational Inertia depends on what axis you are spinning about (the r i in the equation).

7 Rotational Inertia Table For objects with finite number of masses, use I =  m r 2. l For “continuous” objects, use table below:

8 Summary Rotational Kinetic Energy K rot = ½ I  2 Rotational Inertia I =  m i r i 2 l Energy is Still Conserved!

9 Pulley Example l A solid disk wheel is fixed at its center and has a string wrapped around it and then attached to a block. The mass of the pulley is 5 kg, the radius of the pulley is 0.2 m, and the mass of the block is 8 kg. After the block has fallen 1.5 m, how fast is the block moving and how fast is the disk rotating? è We will use conservation of energy: è Remember: »K trans = ½ m v 2 »K rot = ½ I  2 »U = m g y 5 kg 8 kg 1.5 m

10 Pulley Example l A solid disk wheel is fixed at its center and has a string wrapped around it and then attached to a block. The mass of the pulley is 5 kg, the radius of the pulley is 0.2 m, and the mass of the block is 8 kg. After the block has fallen 1.5 m, how fast is the block moving and how fast is the disk rotating? è Initial K rot and K tran is zero. è Final U is zero. 5 kg 8 kg 1.5 m

11 Pulley Example l A solid disk wheel is fixed at its center and has a string wrapped around it and then attached to a block. The mass of the pulley is 5 kg, the radius of the pulley is 0.2 m, and the mass of the block is 8 kg. After the block has fallen 1.5 m, how fast is the block moving and how fast is the disk rotating? è Remember: »I = ½ m R 2 for a disk »v =  R so  = v/R 5 kg 8 kg 1.5 m

12 Pulley Example l A solid disk wheel is fixed at its center and has a string wrapped around it and then attached to a block. The mass of the pulley is 5 kg, the radius of the pulley is 0.2 m, and the mass of the block is 8 kg. After the block has fallen 1.5 m, how fast is the block moving and how fast is the disk rotating? è R 2 cancels from the last term. è Simplify: 5 kg 8 kg 1.5 m

13 Pulley Example l A solid disk wheel is fixed at its center and has a string wrapped around it and then attached to a block. The mass of the pulley is 5 kg, the radius of the pulley is 0.2 m, and the mass of the block is 8 kg. After the block has fallen 1.5 m, how fast is the block moving and how fast is the disk rotating? è Solve: 5 kg 8 kg 1.5 m v f = 4.73 m/s

14 Torque l Rotational effect of force. Tells how effective force is at twisting or rotating an object.  = r F sin  r F perpendicular è Units: N-m è Sign: CCW rotation is positive F  r

15 Work Done by Torque Recall W = F d cos  l For a wheel: è W = F tangential s = F tangential r  (  in radians) W =    P = W/t =  /t  P 

16 Equilibrium l Conditions for Equilibrium:   F = 0 Translational Equilibrium (Center of Mass)    = 0 Rotational Equilibrium »May choose any axis of rotation…. But Choose Wisely!

17 Equilibrium Example l A 50 kg diver stands at the end of a 4.6 m diving board. Neglecting the weight of the board, what is the force each pivot exerts on the diving board? è First, draw a FBD: F1F1 F2F2 FgFg

18 Equilibrium Example l A 50 kg diver stands at the end of a 4.6 m diving board. Neglecting the weight of the board, what is the force each pivot exerts on the diving board? è Write down  F = 0: -F 1 + F 2 – F g = 0 -F 1 + F 2 – (50 kg)(9.8 m/s 2 ) = 0 Note: there are two unknowns so we need another equation…

19 Equilibrium Example l A 50 kg diver stands at the end of a 4.6 m diving board. Neglecting the weight of the board, what is the force each pivot exerts on the diving board? è Pick a pivot point: F1F1 F2F2 FgFg

20 Equilibrium Example l A 50 kg diver stands at the end of a 4.6 m diving board. Neglecting the weight of the board, what is the force each pivot exerts on the diving board? è Write down  = 0: F 1 (0 m) + F 2 (1.2 m) – (50 kg)(9.8 m/s 2 )(4.6 m) = 0 F 2 (1.2 m) – (50 kg)(9.8 m/s 2 )(4.6 m) = 0

21 Equilibrium Example l A 50 kg diver stands at the end of a 4.6 m diving board. Neglecting the weight of the board, what is the force each pivot exerts on the diving board? è Solve: F 2 (1.2 m) – (50 kg)(9.8 m/s 2 )(4.6 m) = 0 F 2 = 1878 N -F 1 + F 2 – (50 kg)(9.8 m/s 2 ) = 0 -F 1 + (1878 N) – (50 kg)(9.8 m/s 2 ) = 0 F 1 = 1388 N

22 Summary l Torque is a Force that causes rotation   = F r sin   Work done by torque: W =  l Equilibrium   F = 0   = 0 »May choose any axis.

Download ppt "Lecture 13: Rotational Kinetic Energy and Rotational Inertia l Review: Rotational Kinematics l Rotational Kinetic Energy l Rotational Inertia l Torque."

Similar presentations

Equilibrium and Torque

Equilibrium and Torque
Lecture 15 Rotational Dynamics.

Lecture 15 Rotational Dynamics.
Physics 101: Lecture 13 Rotational Kinetic Energy and Inertia

Physics 101: Lecture 13 Rotational Kinetic Energy and Inertia
Two-Dimensional Rotational Dynamics W09D2. Young and Freedman: 1

Two-Dimensional Rotational Dynamics W09D2. Young and Freedman: 1
Warm-up: Centripetal Acceleration Practice

Warm-up: Centripetal Acceleration Practice
It’s gravy n I got it all smothered, like make-up I got it all covered

It’s gravy n I got it all smothered, like make-up I got it all covered
Torque and Equilibrium

Torque and Equilibrium
Torque Looking back Looking ahead Newton’s second law.

Torque Looking back Looking ahead Newton’s second law.
Physics 101: Lecture 14 Torque and Equilibrium

Physics 101: Lecture 14 Torque and Equilibrium
Physics 101: Chapter 9 Today’s lecture will cover Textbook Sections 9.1 - 9.6 1.

Physics 101: Chapter 9 Today’s lecture will cover Textbook Sections
Physics 106: Mechanics Lecture 04

Physics 106: Mechanics Lecture 04
Chapter 9 Rotational Dynamics.

Chapter 9 Rotational Dynamics.
Ch 9. Rotational Dynamics In pure translational motion, all points on an object travel on parallel paths. The most general motion is a combination of translation.

Ch 9. Rotational Dynamics In pure translational motion, all points on an object travel on parallel paths. The most general motion is a combination of translation.
Physics 111: Lecture 19, Pg 1 Physics 111: Lecture 19 Today’s Agenda l Review l Many body dynamics l Weight and massive pulley l Rolling and sliding examples.

Physics 111: Lecture 19, Pg 1 Physics 111: Lecture 19 Today’s Agenda l Review l Many body dynamics l Weight and massive pulley l Rolling and sliding examples.
Physics 207: Lecture 16, Pg 1 Lecture 16Goals: Chapter 12 Chapter 12  Extend the particle model to rigid-bodies  Understand the equilibrium of an extended.

Physics 207: Lecture 16, Pg 1 Lecture 16Goals: Chapter 12 Chapter 12  Extend the particle model to rigid-bodies  Understand the equilibrium of an extended.
A 40-kg mass placed 1.25 m on the opposite side of the support point balances a mass of 25 kg, placed (x) m from the support point of a uniform beam. What.

A 40-kg mass placed 1.25 m on the opposite side of the support point balances a mass of 25 kg, placed (x) m from the support point of a uniform beam. What.
Lecture 37, Page 1 Physics 2211 Spring 2005 © 2005 Dr. Bill Holm Physics 2211: Lecture 37 l Work and Kinetic Energy l Rotational Dynamics Examples çAtwood’s.

Lecture 37, Page 1 Physics 2211 Spring 2005 © 2005 Dr. Bill Holm Physics 2211: Lecture 37 l Work and Kinetic Energy l Rotational Dynamics Examples çAtwood’s.
Physics 101: Lecture 15, Pg 1 Physics 101: Lecture 15 Rolling Objects l Today’s lecture will cover Textbook Chapter 8.5-8.7 Exam III.

Physics 101: Lecture 15, Pg 1 Physics 101: Lecture 15 Rolling Objects l Today’s lecture will cover Textbook Chapter Exam III.
Physics 111: Mechanics Lecture 10 Dale Gary NJIT Physics Department.

Physics 111: Mechanics Lecture 10 Dale Gary NJIT Physics Department.
Physics 201: Lecture 18, Pg 1 Lecture 18 Goals: Define and analyze torque Introduce the cross product Relate rotational dynamics to torque Discuss work.

Physics 201: Lecture 18, Pg 1 Lecture 18 Goals: Define and analyze torque Introduce the cross product Relate rotational dynamics to torque Discuss work.

Similar presentations

Ads by Google