Chapter 9 Rotational Dynamics

Similar documents
CHAPTER 8 TEST REVIEW MARKSCHEME

AP Physics Multiple Choice Practice Torque

Torque. Physics 6A. Prepared by Vince Zaccone For Campus Learning Assistance Services at UCSB

Lecture 14. Rotational dynamics Torque. Give me a lever long enough and a fulcrum on which to place it, and I shall move the world.

Recap I. Angular position: Angular displacement: s. Angular velocity: Angular Acceleration:

Torque rotational force which causes a change in rotational motion. This force is defined by linear force multiplied by a radius.

Physics 8 Monday, October 28, 2013

Lab 2: Equilibrium. Note: the Vector Review from the beginning of this book should be read and understood prior to coming to class!

Chapter 9. Rotational Dynamics

Physics 8 Friday, October 20, 2017

Chapter 9. Rotational Dynamics

PHYSICS 149: Lecture 21

Chapter 6, Problem 18. Agenda. Rotational Inertia. Rotational Inertia. Calculating Moment of Inertia. Example: Hoop vs.

Static Equilibrium and Torque

Name Date Period PROBLEM SET: ROTATIONAL DYNAMICS

Section 2: Static Equilibrium II- Balancing Torques

P12 Torque Notes.notebook. March 26, Torques

Static equilibrium. Objectives. Physics terms. Assessment. Brainstorm. Equations 6/3/14

is the study of and. We study objects. is the study of and. We study objects.

Phys 1401: General Physics I

Torque. Introduction. Torque. PHY torque - J. Hedberg

Center of Mass. A baseball thrown into the air follows a smooth parabolic path. A baseball bat thrown into the air does not follow a smooth path.

Physics 8 Friday, November 4, 2011

Section 2: Static Equilibrium II- Balancing Torques

Chapter 12 Static Equilibrium

PHYSICS - CLUTCH 1E CH 12: TORQUE & ROTATIONAL DYNAMICS.

PHYSICS - CLUTCH CH 12: TORQUE & ROTATIONAL DYNAMICS.

Physics 201 Lab 9: Torque and the Center of Mass Dr. Timothy C. Black

Chapter 10. Rotation

Chapter 8 - Rotational Dynamics and Equilibrium REVIEW

Chapter 9 TORQUE & Rotational Kinematics

use one of the methods to compute the magnitude of the torque, given the magnitudes of the force and position vector

Phys 1401: General Physics I

Announcements Oct 16, 2014

Centripetal force keeps an object in circular motion Rotation and Revolution

Chapter 8 Rotational Motion and Equilibrium. 1. Give explanation of torque in own words after doing balance-the-torques lab as an inquiry introduction

Physics 2210 Homework 18 Spring 2015

Unit 4 Statics. Static Equilibrium Translational Forces Torque

Equilibrium & Elasticity

Physics 101: Lecture 15 Torque, F=ma for rotation, and Equilibrium

Equilibrium. For an object to remain in equilibrium, two conditions must be met. The object must have no net force: and no net torque:

Physics 8 Wednesday, October 25, 2017

Answers to selected problems from Essential Physics, Chapter 10

Rotational Dynamics continued

Physics 6A Lab Experiment 6

Torque. 1. Torque - To make an object rotate, we must apply a force at a certain distance away from the axis => ex) opening a door

= o + t = ot + ½ t 2 = o + 2

Chapter 8. Rotational Equilibrium and Rotational Dynamics

Exam 3 Practice Solutions

PHYSICS - CLUTCH CH 13: ROTATIONAL EQUILIBRIUM.

Rotational N.2 nd Law

Rotational Equilibrium

PHY 111L Activity 9 Moments of Inertia

Oscillations. Oscillations and Simple Harmonic Motion

Chapter 8 Rotational Motion

Physics 1A Lecture 10B

Rotational Dynamics. A wrench floats weightlessly in space. It is subjected to two forces of equal and opposite magnitude: Will the wrench accelerate?


CHAPTER 12 STATIC EQUILIBRIUM AND ELASTICITY. Conditions for static equilibrium Center of gravity (weight) Examples of static equilibrium

Rotational N.2 nd Law

AP Physics 1 Rotational Motion Practice Test

Q16.: A 5.0 kg block is lowered with a downward acceleration of 2.8 m/s 2 by means of a rope. The force of the block on the rope is:(35 N, down)

Please read this introductory material carefully; it covers topics you might not yet have seen in class.

Structures Activity 2 Levers

Big Ideas 3 & 5: Circular Motion and Rotation 1 AP Physics 1

General Physics (PHY 2130)

PHYSICS 111 SPRING EXAM 2: March 7, 2017; 8:15-9:45 pm

Torque and levers * Free High School Science Texts Project. 1 Torque and Levers

Chapter 8. Rotational Motion

2008 FXA THREE FORCES IN EQUILIBRIUM 1. Candidates should be able to : TRIANGLE OF FORCES RULE

Chapter 8. Centripetal Force and The Law of Gravity

Rotational Equilibrium

Chapter 12: Rotation of Rigid Bodies. Center of Mass Moment of Inertia Torque Angular Momentum Rolling Statics

Rotation. I. Kinematics - Angular analogs

Rotation review packet. Name:

Physics 111. Lecture 22 (Walker: ) Torque Rotational Dynamics Static Equilibrium Oct. 28, 2009

Static Equilibrium; Torque

Rotation. Rotational Variables

Solution Only gravity is doing work. Since gravity is a conservative force mechanical energy is conserved:

AP Physics QUIZ Chapters 10

LECTURE 22 EQUILIBRIUM. Instructor: Kazumi Tolich

Chapter 9-10 Test Review

Unit 1: Equilibrium and Center of Mass

Pre-AP Physics Review Problems

11. (7 points: Choose up to 3 answers) What is the tension,!, in the string? a.! = 0.10 N b.! = 0.21 N c.! = 0.29 N d.! = N e.! = 0.

PHY 1150 Doug Davis Chapter 8; Static Equilibrium 8.3, 10, 22, 29, 52, 55, 56, 74

TEST REPORT. Question file: P Copyright:

Definition. is a measure of how much a force acting on an object causes that object to rotate, symbol is, (Greek letter tau)

4.0 m s 2. 2 A submarine descends vertically at constant velocity. The three forces acting on the submarine are viscous drag, upthrust and weight.

Lecture 8. Torque. and Equilibrium. Pre-reading: KJF 8.1 and 8.2

Application of Forces. Chapter Eight. Torque. Force vs. Torque. Torque, cont. Direction of Torque 4/7/2015

Equilibrium and Torque

Announcements Oct 17, 2013

Equilibrium and Torque

Chapter 11 Rotational Dynamics and Static Equilibrium. Copyright 2010 Pearson Education, Inc.

PHYSICS 221, FALL 2011 EXAM #2 SOLUTIONS WEDNESDAY, NOVEMBER 2, 2011

Rotational Kinetic Energy

Statics. Phys101 Lectures 19,20. Key points: The Conditions for static equilibrium Solving statics problems Stress and strain. Ref: 9-1,2,3,4,5.

Textbook Reference: Wilson, Buffa, Lou: Chapter 8 Glencoe Physics: Chapter 8

Chapter 8. Rotational Equilibrium and Rotational Dynamics

Transcription:

Chapter 9 ROTATIONAL DYNAMICS PREVIEW A force acting at a perpendicular distance from a rotation point, such as pushing a doorknob and causing the door to rotate on its hinges, produces a torque. If the sum of the torques acting on an object is zero, we say that the object is in equilibrium. The weight of an object can produce a torque, and we say that the point at which an object s weight can be considered to be concentrated is its center of gravity. The content of sections,, and 3, and 7 (Example 9) in chapter 9 of the textbook is included on the AP Physics B exam. QUICK REFERENCE Important Terms center of gravity the point on a rigid body at which its weight can be considered to act when calculating the torque due to its weight equilibrium a rigid body is in equilibrium if the net force and net torque acting on the body are both zero. lever arm the distance between the line of action of a force acting on a body and the axis of rotation. torque the vector product of a force acting on a body and the lever arm at which it acts Equations and Symbols F x cg W x W x W W where τ = torque F = force = lever arm which is perpendicular to the applied force x cg = position of the center of gravity of a system of particles W = weight x = position of an object relative to some chosen origin 4

Ten Homework Problems Chapter 9 Problems, 3, 4, 6, 7, 0, 4, 6, 0, 63 DISCUSSION OF SELECTED SECTIONS 9. 9.3 Torque, Equilibrium, and Center of Gravity Torque is the result of a force acting at a distance from a rotational axis, and may cause a rotation about the axis. Torque is the vector product of the displacement vector r (as in radius) from the rotational axis and the force F: T r F The unit for torque is the newton-meter. By the right-hand rule, place your fingers in the direction of r, and cross them into the direction of the force F, and the torque vector T points in the direction of your thumb. To open a hinged door, you apply a force to the doorknob which is mounted a certain distance from the hinges, and create a torque which causes the door to rotate. When you use a wrench to tighten a bolt, you apply a force at the end of the wrench to get the most torque to turn the bolt. If the force is applied to the wrench so that there is an angle between the displacement vector r and the force vector F, then the magnitude of the torque becomes = rfsin F r For a torque to be produced there must a component of the force which is perpendicular to the radius vector. A force and a radius which are parallel to each other will not produce a torque, since the sine of the angle between them is zero. F θ Fsinθ r For a system in static equilibrium, the sum of the forces must equal zero, and the sum of the torques must also equal zero. This is illustrated in the next example. 5

Example Two children sit on a see-saw which is 3 m long and pivoted on an axis at its center. The first child has a mass m of 5 kg and sits at the left end of the see-saw, while the second child has a mass m of 50 kg and sits somewhere on the see-saw to the right of the axis. At what distance r from the axis should the second child sit to keep the see-saw horizontal? 3 m r m m For the see-saw to remain horizontal, the torque on the left must equal the torque on the right. The forces acting on the see-saw on either side are just the weight mg of each child. So, Torque on the left = Torque on the right r F r F m gr m gr Dividing out the g s and solving for r we get mr (5kg)(.5 m) r 0. 75m to the right of the axis. m 50 kg Could you have guessed this answer before we worked it out? Since the child on the right is twice as heavy as the child on the left, he should sit half as far from the axis on the right side to balance the torque the lighter child is producing on the left side. Example A mechanic applies a force of 400 N to the end of a 5-cm wrench at an angle of 30 from the horizontal, as shown below. If the bolt does not turn, what is the reaction torque the bolt must be providing? F=400 N 30 0.5 m 6

Solution The reaction torque provided by the bolt is equal to the torque the mechanic is applying to the bolt. T rf sin 0.5m 400 N sin 30 30 Nm If the vector sum of the torques is not zero, the object will rotate with an angular acceleration. The AP Physics B exam typically only deals with equilibrium, that is, the sum of the torques is zero. CHAPTER 9 REVIEW QUESTIONS For each of the multiple choice questions below, choose the best answer. Unless otherwise noted, use g = 0 m/s and neglect air resistance.. Torque (A) is the vector product of displacement and force. (B) is a scalar and has no direction associated with it. (C) is always equal to force. (D) is always greater for shorter lever arms. (E) must always equal zero. F 4 F 3 F A B C D E 3 4. Two blocks of mass 3 kg and 4 kg hung from the ends of a rod of negligible mass which is marked in seven equal parts as shown. At which of the points indicated should a string be attached if the rod is to remain horizontal when suspended from the string? (A) A (B) B (C) C (D) D (E) E F 5 F 3. The figure above shows a flat object lying on a table of negligible friction. Five forces are separately applied to the object as shown. Which of the five forces will NOT cause the object ot rotate about the center of the object? (A) F (B) F (C) F 3 (D) F 4 (E) F 5 7

L l θ 4. Two masses are mounted on either end of a bar of negligible mass. The bar is marked off in quarters. The center of mass of the system C is labeled as shown. The ratio of m to m is (A) 4 (B) 3 (C) (D) (E) 3 m C m m 5. The figure above shows a mass m hanging from the end of a massless rod which is pivoted on a fulcrum as shown. A string is tied at an angle θ from the horizontal at the right end of the rod to keep the rod from rotating. Which of the following is a correct equation for finding the tension F T in the string? (A) mgl F T (B) mgl F T cos (C) mgl F T sin (D) mg FT (E) mg sin F T 8

Free Response Question Directions: Show all work in working the following question. The question is worth 0 points, and the suggested time for answering the question is about 0 minutes. The parts within a question may not have equal weight.. (0 points) In the laboratory, you are asked to determine the mass of a meter stick without using a scale of any kind. In addition to the meter stick, you may use any or all of the following equipment: a set of known masses four weight hangers tape a fulcrum upon which the string stopwatch meter stick can be mounted and pivoted (a) Briefly list the steps in your procedure that will lead you to the mass of the stick. Include definitions of any parameters that you will measure. (b) On the list of equipment before part (a) place check marks beside each additional piece of equipment you will need to do this experiment. (c) Show the calculations you would perform to find the mass of the meter stick. meter 9

ANSWERS AND EXPLANATIONS TO CHAPTER 9 REVIEW QUESTIONS Multiple Choice. A Torque is defined as the vector (cross) product of displacement (lever arm) and force.. D For the sum of the torques to be zero, 3gr3 m4 gr4 m, or kg 4 units 4kg 3 units 3. 3. B The line of action of F passes through the center of rotation, and thus cannot produce a torque about the center (r = 0). 4. B The center of mass is 3 times farther from the lighter mass than the heavier mass, so the heavier mass m must be 3 times larger than the lighter mass m. 5. C The free-body diagram for the system is shown below. L l θ mg F N Fsinθ F T The sum of the torques about the fulcrum (which applies a normal force to the rod) must equal zero. Thus, the hanging weight acting at L must balance the downward component of the tension acting at l: mgl F T sin. Free Response Question Solution (a) 4 points Mount the meter stick on the fulcrum so that it is pivoted on a point other than the center of the stick. Hang two unequal weights on either side of the meter stick at such distances that the meter stick remains horizontal. Record the value of each mass and the distance from the fulcrum to each mass. Let m be the mass on the left and l be the distance from the fulcrum to m. Likewise, let m be the mass on the left and l be the distance from the fulcrum to m. Let C be the center of the meter stick. Repeat the procedure using different masses and distances. 0

l l C m m (b) 3 points We can check the set of known masses, the fulcrum, and two of the weight hangers. (c) 3 points The free-body diagram for the stick would look like this: l M l l m g Mg Fulcrum m g where M is the unknown mass of the meter stick, and l M is the distance from the fulcrum to the center of mass of the meter stick. For equilibrium, the sum of the torques is zero, that is, the torque caused by the masses on the left of the fulcrum must equal the caused by the masses on the right of the fulcrum: m g Mg M m g mg m g M g M Substitute the measured values from part (a) to find a value for the mass of the meter stick.

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback