PHY131H1S - Class 20 Today: Gravitational Torque Rotational Kinetic Energy Rolling without Slipping Equilibrium with Rotation Rotation Vectors Angular.

Slides:



Advertisements
Similar presentations
AP Physics C Mechanics Review.
Advertisements

Rotational Equilibrium and Rotational Dynamics
Chapter 11 Angular Momentum
Angular Momentum The vector angular momentum of the point mass m about the point P is given by: The position vector of the mass m relative to the point.
Warm-up: Centripetal Acceleration Practice
ConcepTest 8.9 Moment of Inertia
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.
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.
Chapter 11 Rolling, Torque, and angular Momentum.
Chapter 13.
Rotational Equilibrium and Rotational Dynamics
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.
Torque and Angular Momentum
Chapter 11: Rolling Motion, Torque and Angular Momentum
Dynamics of Rotational Motion
Chapter 8 Rotational Equilibrium and Rotational Dynamics.
2008 Physics 2111 Fundamentals of Physics Chapter 11 1 Fundamentals of Physics Chapter 12 Rolling, Torque & Angular Momentum 1.Rolling 2.The Kinetic Energy.
Chapter 11 Angular Momentum.
PHY131H1S - Class 19 Today: Rotational Motion, Rotational Kinematics (some review of Ch.4) Newton’s 2nd Law of Rotation Torque Moment of Inertia Centre.
Dynamics of a Rigid Body
Physics 207: Lecture 17, Pg 1 Lecture 17 Goals: Chapter 12 Chapter 12  Define center of mass  Analyze rolling motion  Introduce and analyze torque 
Chapter 12: Rolling, Torque and Angular Momentum.
Rotational Kinetic Energy Conservation of Angular Momentum Vector Nature of Angular Quantities.
Physics 2211: Lecture 38 Rolling Motion
Using the “Clicker” If you have a clicker now, and did not do this last time, please enter your ID in your clicker. First, turn on your clicker by sliding.
Chapter 11 Rolling, Torque, and Angular Momentum In this chapter we will cover the following topics: -Rolling of circular objects and its relationship.
Chapter 10 Rotational Motion
Chapter 8 Rotational Equilibrium and Rotational Dynamics.
Classical Mechanics Review 4: Units 1-19
Chapter 8 Rotational Motion
Angular Momentum of a Particle
Chapter 11 Angular Momentum.
Rigid Body: Rotational and Translational Motion; Rolling without Slipping 8.01 W11D1 Today’s Reading Assignment Young and Freedman: 10.3.
Chapter 8: Torque and Angular Momentum
Rotational Dynamics Just as the description of rotary motion is analogous to translational motion, the causes of angular motion are analogous to the causes.
Chapter 9: Rotational Dynamics
Rolling, Torque, and Angular Momentum
Torque Chap 8 Units: m N 2.
Chapter 8 Rotational Motion.
Chapter 8 Rotational Motion.
Physics 111 Practice Problem Statements 10 Torque, Energy, Rolling SJ 8th Ed.: Chap 10.6 – 10.9 Contents 11-47, 11-49*, 11-55*, 11-56, 11-60*, 11-63,
Rotational Motion. 6-1 Angular Position, Velocity, & Acceleration.
Rotational and Translational Motion Dynamics 8
Rotational Dynamics and Static Equilibrium
Chapter 9 Rotational Dynamics.
Rotational Motion About a Fixed Axis
Tuesday, June 26, 2007PHYS , Summer 2006 Dr. Jaehoon Yu 1 PHYS 1443 – Section 001 Lecture #15 Tuesday, June 26, 2007 Dr. Jaehoon Yu Rotational.
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.
Cutnell/Johnson Physics 8th edition Reading Quiz Questions
Wednesday, Nov. 10, 2004PHYS , Fall 2004 Dr. Jaehoon Yu 1 1.Moment of Inertia 2.Parallel Axis Theorem 3.Torque and Angular Acceleration 4.Rotational.
Physics 207: Lecture 17, Pg 1 Lecture 17 (Catch up) Goals: Chapter 12 Chapter 12  Introduce and analyze torque  Understand the equilibrium dynamics of.
Lecture 18: Angular Acceleration & Angular Momentum.
Chapt. 10: Angular Momentum
Physics 1D03 - Lecture 351 Review. Physics 1D03 - Lecture 352 Topics to study basic kinematics forces & free-body diagrams circular motion center of mass.
Rigid Body: Rotational and Translational Motion; Rolling without Slipping 8.01 W11D1.
Angular Momentum. Definition of Angular Momentum First – definition of torque: τ = Frsinθ the direction is either clockwise or counterclockwise a net.
AP Physics 1 Exam Review Session 3
Chapter 11: Rolling Motion, Torque and Angular Momentum
Chapter 8 Rotational Motion
Aim: How do we explain the rolling motion of rigid bodies?
PHY131H1F - Class 17 Today: Finishing Chapter 10:
Rolling, Torque, and Angular Momentum
Chapter 8 Rotational Motion.
C9 – Rotational Energy Get a spring General Physics.
Chapter 8.
Chapter 11 Angular Momentum
Presentation transcript:

PHY131H1S - Class 20 Today: Gravitational Torque Rotational Kinetic Energy Rolling without Slipping Equilibrium with Rotation Rotation Vectors Angular Momentum

Pre-class reading quiz on Chapter 12

Last day I asked at the end of class: Why did that wooden disk roll faster down the hill than the metal hoop? ANSWER:

Gravitational Torque When calculating the torque due to gravity, you may treat the object as if

Example A 4.00 m long, 500 kg steel beam is supported 1.20 m from the right end. What is the gravitational torque about the support?

“Rolling Without Slipping” When a round object rolls without slipping, the distance the axis, or centre of mass, travels is equal to the change in angular position times the radius of the object. The speed of the centre of mass is The acceleration of the centre of mass is

Examples: What is the acceleration of a slipping object down a ramp inclined at angle θ ? [assume no friction] What is the acceleration of a solid disk rolling down a ramp inclined at angle θ ? [assume rolling without slipping] What is the acceleration of a hoop rolling down a ramp inclined at angle θ ? [assume rolling without slipping]

Linear / Rotational Analogy θ, ω, α Torque: τ Moment of Inertia: I,, Force: Mass: m LinearRotational Analogy Newton’s 2 nd law: Kinetic energy:

Rotational Energy A rotating rigid body has kinetic energy because all atoms in the object are in motion. The kinetic energy due to rotation is called rotational kinetic energy. Example: A 0.50 kg basketball rolls along the ground at 1.0 m/s. What is its total kinetic energy? [linear plus rotational]

Summary of some Different Types of Energy: Kinetic Energy due to linear motion of centre of mass: Gravitational Potential Energy Spring Potential Energy: Rotational Kinetic Energy: Thermal Energy (often created by friction) –An object can possess any or all of the above. –One way of transferring energy to or out of an object is work: Work done by a constant force:

Updated Conservation of Energy…

Compare and Contrast Soup Cans About same mass About same radius and shape Thick paste, so when this can is rolling, the contents rotate along with the can as one solid object, like a solid cylinder Low viscosity liquid, so the can itself rolls while the liquid may just “slide” along.

Two soup cans begin at the top of an incline, are released from rest, and allowed to roll without slipping down to the bottom. Which will win? Predict: A.Cream of Mushroom will win B.Chicken Broth will win C.Both will reach the bottom at about the same time. Soup Race

Equilibrium When Rotation is Possible The condition for a rigid body to be in static equilibrium is that there is no net force and no net torque. An important branch of engineering called statics analyzes buildings, dams, bridges, and other structures in total static equilibrium. No matter which pivot point you choose, an object that is not rotating is not rotating about that point. For a rigid body in total equilibrium, there is no net torque about any point.

Static Equilibrium Problems In equilibrium, an object has no net force and no net torque. Draw an extended free-body diagram that shows where each force acts on the object. Set up x and y axes, and choose a rotation axis. All of these choices should be done to simplify your calculations. Each force has an x and y component and a torque. Sum all of these up. Three equations which you can use are:

A student holds a meter stick straight out with one or more masses dangling from it. Rank in order, from most difficult to least difficult, how hard it will be for the student to keep the meter stick from rotating.

The Angular Velocity Vector The magnitude of the angular velocity vector is ω. The angular velocity vector points along the axis of rotation in the direction given by the right-hand rule as illustrated above.

Linear / Rotational Analogy θ, ω, α Torque: τ Moment of Inertia: I,, Force: Mass: m LinearRotational Analogy Newton’s 2 nd law: Kinetic energy: Momentum:

A bicycle is traveling toward the right.

If there is no net external torque on a system, then its angular momentum is a constant. If there is no net external force on a system, then its momentum is a constant. If there is no work or heat being exchanged with a system and its surroundings, then its energy is constant.

is constant when there are no external torques. I is highI is low

Two buckets spin around in a horizontal circle on frictionless bearings. Suddenly, it starts to rain. As a result,

Before Class 21 on Monday There is a MasteringPhysics problem set due tonight! Please submit this before 11:59pm if you have not already done so. Please read Knight Chapter 14, sections 14.1 through Something to think about: A block is oscillating on a spring with a period of 2 seconds. What is the period if the mass is doubled? What is the period if the spring constant is doubled?