Static Equilibrium Physics 150/250 Center of Mass Types of Motion

Slides:

Advertisements

Similar presentations

Mechanics of Rigid Body. C

Advertisements

Physics 111: Mechanics Lecture 12

Monday October 20. Motion of a rigid body Body can translate only. In this case we can replace the body by a point located at the center of mass. Body.

ESC020: Rigid Body Mechanics

Force vs. Torque Forces cause accelerations

Angular Impulse Chapter 13 KINE 3301 Biomechanics of Human Movement.

Class 28 - Rolling, Torque and Angular Momentum Chapter 11 - Friday October 29th Reading: pages 275 thru 281 (chapter 11) in HRW Read and understand the.

Rotational Equilibrium and Rotational Dynamics

Rotation and Torque Lecture 09 Thursday: 12 February 2004.

Chapter 9 Rotational Dynamics.

Rotational Dynamics and Static Equilibrium. Torque From experience, we know that the same force will be much more effective at rotating an object such.

Dynamics of Rotational Motion

Chapter 12: Rolling, Torque and Angular Momentum.

Physics 106: Mechanics Lecture 07

Phy 211: General Physics I Chapter 10: Rotation Lecture Notes.

Physics 101: Lecture 18, Pg 1 Physics 101: Lecture 18 Rotational Dynamics l Today’s lecture will cover Textbook Sections : è Quick review of last.

Rotational Dynamics and Static Equilibrium

Chapter Eight Rotational Dynamics Rotational Dynamics.

D. Roberts PHYS 121 University of Maryland Physic² 121: Phundament°ls of Phy²ics I November 17, 2006.

Chapter 8 Rotational Equilibrium and Rotational Dynamics.

Rotational Dynamics. Moment of Inertia The angular acceleration of a rotating rigid body is proportional to the net applied torque:  is inversely proportional.

Work Let us examine the work done by a torque applied to a system. This is a small amount of the total work done by a torque to move an object a small.

Spring Topic Outline for Physics 1 Spring 2011.

 Torque: the ability of a force to cause a body to rotate about a particular axis.  Torque is also written as: Fl = Flsin = F l  Torque= force x.

A particle moves in a circle of radius r. Having moved an arc length s, its angular position is θ relative to its original position, where. An angular.

8.4. Newton’s Second Law for Rotational Motion

Chapter 9: Rotational Dynamics

Review for Test #3  Responsible for: - Chapters 9 (except 9.8), 10, and 11 (except 11.9) - The spring (6.2, 7.3, ) - Problems worked in class,

Rotational Motion 2 Coming around again to a theater near you.

Equations for Projectile Motion

Honors Physics Newton’s Second Law of Motion.  Newton’s First Law explains the results of zero net external force. –The body stays at rest or moves with.

Center of Mass, Moment of Inertia, & Rotational Equilibrium Rotation Physics Mr. McCallister.

What forces act upon the meter stick? Where should the force of gravity be considered to act? Center of Gravity – the single point on a body where the.

Center of Mass Torque. Center of Mass When analyzing the motion of an extended object, we treat the entire object as if its mass were contained in a single.

Types of Motion Topic 4 – Movement Analysis

9.4. Newton’s Second Law for Rotational Motion A model airplane on a guideline has a mass m and is flying on a circle of radius r (top view). A net tangential.

Rotational Kinetic Energy An object rotating about some axis with an angular speed, , has rotational kinetic energy even though it may not have.

 When an extended object, like a wheel, rotates about its axis, the motion cannot be analyzed by treating the object as a particle because at any given.

Rotational Motion 1. Translational Motion vs. Rotational Motion Translational motion ___________ ______________________________ Example: motion of a bullet.

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.

Physics 211 Force and Equilibrium Hookes Law Newtons Laws Weight Friction Free Body Diagrams Force Problems 4: Classical Mechanics - Newtons Laws.

Chapter 9 Rotational Dynamics

Definition of Torque Statics and Dynamics of a rigid object

Rotational Motion – Dynamics AP Physics. Rotational and Translational Equalities Rotational Objects roll Inertia TORQUE Angular Acceleration Rotational.

PHY205 Ch16: Rotational Dynamics 1.Combination Translational and Rotational motion and Atwood machine 2.Discuss Ball rolling down incline from 3 different.

Physics 207: Lecture 17, Pg 1 Lecture 17 (Catch up) Goals: Chapter 12 Chapter 12  Introduce and analyze torque  Understand the equilibrium dynamics of.

1/15/16Oregon State University PH 212, Class 61 Here are some of the direct analogies between (linear) translational and rotational motion: Quantity or.

-Angular and Linear Quantities -Rotational Kinetic Energy -Moment of Inertia AP Physics C Mrs. Coyle.

Chapter 12 Lecture 21: Static Equilibrium and Elasticity: I HW8 (problems):11.7, 11.25, 11.39, 11.58, 12.5, 12.24, 12.35, Due on Friday, April 1.

Today: (Ch. 8)  Rotational Motion.

Wednesday, Nov. 13, 2002PHYS , Fall 2002 Dr. Jaehoon Yu 1 PHYS 1443 – Section 003 Lecture #17 Wednesday, Nov. 13, 2002 Dr. Jaehoon Yu 1.Conditions.

Physics Section 4.2 Apply Newton’s 1st Law of Motion Newton’s 1 st Law of Motion (Law of Inertia) An object at rest remains at rest and an object in motion.

Angular Motion AP Physics 1. Revolving Motion vs Rotating Motion The Earth ____________ around the Sun while _____________ around an axis. Revolving Rotating.

AP Physics 1 Exam Review Session 3

Rotational Motion.

Ch 8 : Rotational Motion .

Lecture 16 Newton Mechanics Inertial properties,Generalized Coordinates Ruzena Bajcsy EE

Angular momentum has the same SI units as momentum.

College Physics, 7th Edition

Poll You push a bobsled on ice. There is a kinetic frictional force on the bobsled by the ice. The kinetic frictional force on the bobsled while you are.

Rotational Dynamics Chapter 9.

الفصل 1: الحركة الدورانية Rotational Motion

Devil physics The baddest class on campus Pre-IB Physics

Lecture 17 Goals: Chapter 12 Define center of mass

PHYS 1443 – Section 003 Lecture #17

Rotational Inertia 8.2.

Rotational Dynamics.

Rotational Statics i.e. “Torque”

Rotational Kinematics

Presentation transcript:

Static Equilibrium Physics 150/250 Center of Mass Types of Motion Torque Types of Static Equilibrium Translational - Rotational Conditions for Equilibrium Center of Gravity Free Body Diagrams 1

Average position of the masses Center of Mass = Average position of the masses For example: 6 kg at x=5m & 7 kg at x=10m x coordinate of center of mass = Think of the average height of 6 monsters that are 5m high and 7 that are 10 m high 2

Motion of an object can be analyzed into three types translation of the center of mass rotation (rigid) about the center of mass vibration (elastic) about center of mass 3

4

Translational Acceleration is caused by the total force on the object If the total force FTot= 0 then there is no Translational Acceleration (acceleration of center of mass) acm = 0 5

If velocity of center of mass is initially zero it will stay zero Thus vcm = constant If velocity of center of mass is initially zero it will stay zero There may be rotation or vibrational motion around center of mass 6

Rotational acceleration is caused by the total turning force = TORQUE about the center of mass. 7

Tangential Force Radial Force 8

Force r 9

Force (F) r 1 0

1 1

Linear = Translational Angular = Rotational Total Force = 0; Total Torque not zero Total Force not 0; Total Torque = 0 1 2

angular acceleration  = 0 If the total torque Tot= 0 then there is no Rotational Acceleration (change of angular speed) angular acceleration  = 0 1 3

Thus angular speed  = constant If angular speed is initially zero it will stay zero 1 4

There will be no vibration about center of mass If object is RIGID There will be no vibration about center of mass 1 5

Static Equilibrium for rigid objects vcm = 0  = 0 FTot = 0 Tot = 0 1 6

Equilibrium for Rigid Objects Conditions for Static Equilibrium for Rigid Objects

The center of mass of an object will not accelerate if the total force on the object is zero Ftot   a   TRANSLATIONAL EQUILIBRIUM cm An object will have zero angular acceleration if the total torque on the object is zero           ROTATIONAL EQUILIBRIUM

If the initial velocity of the center of mass is zero and the initial angular velocity is zero they will remain zero if Ftot  thus acm    thus a 0 When this is so the object is said to be in STATIC EQUILIBRIUM

Properties of Torque 18

t t = = forces The torque of a force about any point on . the line of action of that force is zero If a body is in translational equilibrium and the net torque is zero with respect to one point in the body then it is zero with respect to all points in the body . t t = = forces 1 9

Center of Gravity The position where the force of gravity acts on the object or rigidly connected objects 2 0

Free Body Diagrams F1 N1 N2 W1 W2 F2 2 1