Rolling Motion of a Rigid Object

Slides:

Advertisements

Similar presentations

A ladybug sits at the outer edge of a merry-go-round, and a gentleman bug sits halfway between her and the axis of rotation. The merry-go-round makes a.

Advertisements

今日課程內容 CH10 轉動轉動牛頓第二運動定律轉動動能轉動慣量 Angular Quantities Here is the correspondence between linear and rotational quantities:

Rotational Inertia & Kinetic Energy

Chapter 11 Angular Momentum

Comparing rotational and linear motion

Physics 106: Mechanics Lecture 04

MSTC Physics Chapter 8 Sections 3 & 4.

Rotational Motion Chapter Opener. Caption: You too can experience rapid rotation—if your stomach can take the high angular velocity and centripetal acceleration.

L24-s1,8 Physics 114 – Lecture 24 §8.5 Rotational Dynamics Now the physics of rotation Using Newton’s 2 nd Law, with a = r α gives F = m a = m r α τ =

Chapter 9 Rotational Dynamics. 9.5 Rotational Work and Energy.

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 7C lecture 13 Rigid body rotation

Rigid body rotations inertia. Constant angular acceleration.

Physics 111: Mechanics Lecture 10 Dale Gary NJIT Physics Department.

Chapter 11: Rolling Motion, Torque and Angular Momentum

Chapter 11 Rolling, Torque, and Angular Momentum In this chapter we will cover the following topics: -Rolling of circular objects and its relationship.

Rotational Kinematics

Physics 2 Chapter 10 problems Prepared by Vince Zaccone

Physics 218, Lecture XX1 Physics 218 Lecture 20 Dr. David Toback.

Classical Mechanics Review 4: Units 1-19

Rotational Work and Kinetic Energy Dual Credit Physics Montwood High School R. Casao.

Rotational Kinetic Energy. Kinetic Energy The kinetic energy of the center of mass of an object moving through a linear distance is called translational.

Physics. Session Rotational Mechanics - 5 Session Objectives.

Rotational Motion Chap NEW CONCEPT ‘Rotational force’: Torque Torque is the “twisting force” that causes rotational motion. It is equal to the.

Chapter 8 Rotational Motion

Rolling. Rolling Condition – must hold for an object to roll without slipping.

Physics. Session Rotational Mechanics - 6 Session Objectives.

Rotation and angular momentum

Rolling Motion of a Rigid Object AP Physics C Mrs. Coyle.

Chap. 11B - Rigid Body Rotation

Angular Momentum of a Particle

Chapter 11 Angular Momentum.

CHAPTER 11 : ROLLING MOTION AND ANGULAR MOMENTUM

Chapters 10, 11 Rotation and angular momentum. Rotation of a rigid body We consider rotational motion of a rigid body about a fixed axis Rigid body rotates.

Chapter 10 Rotational Kinematics and Energy. Units of Chapter 10 Angular Position, Velocity, and Acceleration Rotational Kinematics Connections Between.

ROTATIONAL MOTION AND EQUILIBRIUM

T071 Q17. A uniform ball, of mass M = kg and radius R = 0

Physics 201: Lecture 19, Pg 1 Lecture 19 Goals: Specify rolling motion (center of mass velocity to angular velocity Compare kinetic and rotational energies.

Example Problem The parallel axis theorem provides a useful way to calculate I about an arbitrary axis. The theorem states that I = Icm + Mh2, where Icm.

1 Honors Physics 1 Class 15 Fall 2013 Rolling motion Noninertial reference frames Fictitious forces.

Rotational and Translational Motion Dynamics 8

Work, Power and Energy in Rotational Motion AP Physics C Mrs. Coyle.

10/10/2012PHY 113 A Fall Lecture 171 PHY 113 A General Physics I 9-9:50 AM MWF Olin 101 Plan for Lecture 17: Chapter 10 – rotational motion 1.Angular.

Rotation of a Rigid Object about a Fixed Axis

Rotational kinematics and energetics

Rotational Motion. 6-1 Angular Position, Velocity, & Acceleration.

Rotational and Translational Motion Dynamics 8

1 Rotation of a Rigid Body Readings: Chapter How can we characterize the acceleration during rotation? - translational acceleration and - angular.

1 Work in Rotational Motion Find the work done by a force on the object as it rotates through an infinitesimal distance ds = r d  The radial component.

AP Physics C Montwood High School R. Casao. When a wheel moves along a straight track, the center of the wheel moves forward in pure translation. A point.

Chapter 11 Angular Momentum. The Vector Product and Torque The torque vector lies in a direction perpendicular to the plane formed by the position vector.

Physics 101: Lecture 13, Pg 1 Physics 101: Lecture 13 Rotational Kinetic Energy and Inertia Exam II.

10-5 Rotational Dynamics; Torque and Rotational Inertia

R OTATIONAL W ORK AND P OWER  Recall that work W is given by a force F times a distance s: Topic 2.3 Extended A – Rotational work and kinetic energy.

Perfect Rolling (no sliding!) Consider a disk rolling without slipping with a Uniform Acceleration. While most points both rotate and move linearly, the.

Rotational Inertia & Kinetic Energy AP Phys 1. Linear & Angular LinearAngular Displacementxθ Velocityv  Accelerationa  InertiamI KE½ mv 2 ½ I  2 N2F.

Chapter 10 Lecture 18: Rotation of a Rigid Object about a Fixed Axis: II.

Rotational Dynamics.

Center of mass 1. Definitions From these definitions follows:

Phys211C10 p1 Dynamics of Rotational Motion Torque: the rotational analogue of force Torque = force x moment arm  = Fl moment arm = perpendicular distance.

Angular Momentum. Definition of Angular Momentum First – definition of torque: τ = Frsinθ the direction is either clockwise or counterclockwise a net.

Rotational Inertia & Kinetic Energy

Aim: How do we explain the rolling motion of rigid bodies?

Rotational Kinematics and Energy

Rotational Dynamics Continued

Section 10.8: Energy in Rotational Motion

Chapter 11 Angular Momentum

Rotational Kinetic Energy Ekr (J)

Rotational Kinetic Energy

Rotational Kinetic Energy

Presentation transcript:

Rolling Motion of a Rigid Object AP Physics C

Rolling Motion: a combination of pure translation and pure rotation.

For pure rolling motion there is “rolling without slipping”, so at point P vp =0. All points instantaneously rotate about the point of contact between the object and the surface (P).

vp’ = 2 vcm

Rolling Motion

Speed and Acceleration of the CM of a Rolling Object vcm = ωR acm = α R

Red Line: Path of a particle on a rolling object (cycloid) Green line: Path of the center of mass of the rolling object

http://cnx.org/content/m14374/latest/

The Total Kinetic Energy of a Rolling Object is the sum of the rotational and the translational kinetic energy. K = ½ ICM ω2 + ½ MvCM2

Note Rolling is possible when there is friction between the surface and the rolling object. The frictional force provides the torque to rotate the object.

Ex: Accelerated Rolling Motion Ki + Ui = Kf + U f Mgh = ½ ICM ω2 + ½ MvCM2 vcm = ωR There is no frictional work. Why not? Does friction cause a displacement at its point of action?

Ex: #52 A bowling ball (on a horizontal surface) has a mass M, radius R, and a moment of inertia of (2/5)MR2 . If it starts from rest, how much work must be done on it to set it rolling without slipping at a linear speed v? Express the work in terms of M and v. Hint: use kinetic energy theorem. Ans: (7/10)Mv2

Ex: #54 A uniform solid disk and a uniform hoop are placed side by side at the top of an incline of height h. If they are released from rest and roll without slipping, which object reaches the bottom first? Verify your answer by calculating their speeds when they reach the bottom in terms of h. Use conservation of energy Ans: The disk, vdisk =(4gh/3)1/2 , vring =(gh)1/2

Physics C: Rotational Motion Sample Problem 3/31/2017 A solid sphere of mass M and radius R rolls from rest down a ramp of height h and angle . Use Conservation of Energy to find the linear acceleration and the speed at the bottom of the ramp. Use kinematics for acceleration because force is constant. Bertrand

Physics C: Rotational Motion Sample Problem 3/31/2017 A solid sphere of mass M and radius R rolls from rest down a ramp of length L and angle q. Use Rotational Dynamics to find the linear acceleration and the speed at the bottom of the ramp. Bertrand