When the applied force is not perpendicular to the crowbar, for example, the lever arm is found by drawing the perpendicular line from the fulcrum to
|
|
|
- Mervin Cameron
- 5 years ago
- Views:
Transcription
1 When the applied force is not perpendicular to the crowbar, for example, the lever arm is found by drawing the perpendicular line from the fulcrum to the line of action of the force. We call torques that produce counterclockwise rotation positive, and torques that produce clockwise rotation negative.
2 What is the net torque acting on the merrygo-round? a) +36 N m b) -36 N m c) +96 N m d) -60 N m e) +126 N m 96 N m (counterclockwise) - 60 N m (clockwise) = +36 N m (counterclockwise)
3 How far do we have to place the 3-N weight from the fulcrum to balance the system? a) 2 cm b) 27 cm c) 33 cm d) 53 cm F = 3 N l = / F = +1 N m = (+1 N m) / (3 N) = 0.33 m = 33 cm
4 The center of gravity is the point about which the weight of the object itself exerts no torque. We can locate the center of gravity by finding the point where it balances on a fulcrum. What s the center of gravity of a disk? A. any point on the edge of the disk. B. Center of the disk C. Any point half way between the center and the edge.
5 The center of gravity For a more complex object, we locate the center of gravity by suspending the object from two different points, drawing a line straight down from the point of suspension in each case, and locating the point of intersection of the two lines.
6 1J-21 Center of Gravity of an Irregular Lamina How can we find the Center of Gravity of Irregular shapes? Where is the Center of Gravity of the cut board? Why does the mass on the string hang straight down? 2/21/2012 Physics 214 2/21/2012 Fall
7 If the center of gravity lies below the pivot point, the object will automatically regain its balance when disturbed. The center of gravity returns to the position directly below the pivot point, where the weight of the object produces no torque.
8 1J-23 Corks & Forks Can the Center of Gravity lie at a point not on the object? How difficult is it to balance this system on a sharp point? Where is the C of G? THE CENTER OF GRAVITY IS NOT ON THE OBJECT. IT ACTUALLY LIES ALONG THE VERTICAL BELOW THE SHARP POINT. WHEN THE FORK IS MOVED THE CM RISES AND THIS MEANS THE SYSTEM IS IN STABLE EQUILIBRIUM. 2/21/2012 Physics 214 2/21/2012 Fall
9 1J - 24 double cone What happens to the center of mass? A). Going down the hill B). Going uphill C). Stay at rest D). Depend on the object shape 2/21/2012 9
10 1J-16 Walk the Plank What happens when a mass is placed at the end of a massive plank? Sum of Torque about Pivot X M g x m g = 0 m = M X / x Can you safely walk to the end of the plank? One can solve for either M or m, if the other quantity is known EVEN WITH A MASS AT THE END OF THE PLANK, THE SYSTEM CAN STILL BE IN EQUILIBRIUM 2/21/2012 Physics 214 2/21/2012 Fall
11 1J-28 Wine Bottle Holder Balance a Bottle and a Wooden Holder by Eliminating Net Torque M How does this system Balance? m 1 x1 x m2 2 Sum of Torque about Pivot m 1 x 1 g - m 2 x 2 g = 0 THE CENTER OF GRAVITY OF THE BOTTLE PLUS THE WOOD MUST LIE DIRECTLY OVER AND WITHIN THE BOUNDARY OF THE SUPPORT (PIVOT). FOR BALANCE THERE CAN BE NO NET TORQUE ON SYSTEM. 2/21/2012 Physics 214 2/21/2012 Fall
12 How far can the child walk without tipping the plank? For a uniform plank, its center of gravity is at its geometric center. The pivot point will be the edge of the supporting platform. The plank will not tip as long as the counterclockwise torque from the weight of the plank is larger than the clockwise torque from the weight of the child. The plank will verge on tipping when the magnitude of the torque of the child equals that of the plank.
13 An 80-N plank is placed on a dock as shown. The plank is uniform in density so the center of gravity of the plank is located at the center of the plank. A 150-N boy standing on the plank walks out slowly from the edge of the dock. What is the torque exerted by the weight of the plank about the pivot point at the edge of the dock? a) +80 N m b) -80 N m c) +160 N m d) -160 N m e) +240 N m f) -240 N m
14 Rotational Inertia and Newton s Second Law In linear motion, net force and mass determine the acceleration of an object. For rotational motion, torque determines the rotational acceleration. The rotational counterpart to mass is rotational inertia or moment of inertia. Just as mass represents the resistance to a change in linear motion, rotational inertia is the resistance of an object to change in its rotational motion. Rotational inertia is related to the mass of the object. It also depends on how the mass is distributed about the axis of rotation.
15 Simplest example: a mass at the end of a light rod A force is applied to the mass in a direction perpendicular to the rod. The rod and mass will begin to rotate about the fixed axis at the other end of the rod. The farther the mass is from the axis, the faster it moves for a given rotational velocity.
16 Simplest example: a mass at the end of a light rod To produce the same rotational acceleration, a mass at the end of the rod must receive a larger linear acceleration than one nearer the axis. F = ma It is harder to get the system rotating when the mass is at the end of the rod than when it is nearer to the axis. I case the distance are equal, it s harder to move a heavier mass.
17 Rotational Inertia and Newton s Second Law Newton s second law for linear motion: F net = ma Newton s second law for rotational motion: F R = m R v = ω R F R = m R net = I The rotational acceleration produced is equal to the torque divided by the rotational inertia.
Center of Gravity Pearson Education, Inc.
Center of Gravity = The center of gravity position is at a place where the torque from one end of the object is balanced by the torque of the other end and therefore there is NO rotation. Fulcrum Point
Chapter 8 Rotational Motion and Equilibrium. 1. Give explanation of torque in own words after doing balance-the-torques lab as an inquiry introduction
Chapter 8 Rotational Motion and Equilibrium Name 1. Give explanation of torque in own words after doing balance-the-torques lab as an inquiry introduction 1. The distance between a turning axis and the
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.
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. Archimedes, 87 1 BC EXAM Tuesday March 6, 018 8:15 PM 9:45 PM Today s Topics:
Chapter 8 Lecture. Pearson Physics. Rotational Motion and Equilibrium. Prepared by Chris Chiaverina Pearson Education, Inc.
Chapter 8 Lecture Pearson Physics Rotational Motion and Equilibrium Prepared by Chris Chiaverina Chapter Contents Describing Angular Motion Rolling Motion and the Moment of Inertia Torque Static Equilibrium
Torque. Objectives. Assessment. Assessment. Equations. Physics terms 6/2/14
Objectives Calculate torque given the lever arm (perpendicular distance) and the force. Calculate torque in newton meters and in pound feet. Interpret positive and negative signs in the context of torque.
LECTURE 22 EQUILIBRIUM. Instructor: Kazumi Tolich
LECTURE 22 EQUILIBRIUM Instructor: Kazumi Tolich Lecture 22 2 Reading chapter 11-3 to 11-4 Static equilibrium Center of mass and balance Static equilibrium 3 If a rigid object is in equilibrium (constant
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.
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. The bat wobbles about a special point. This point stays
Parallel Forces. Forces acting in the same or in opposite directions at different points on an object.
Parallel Forces Forces acting in the same or in opposite directions at different points on an object. Statics refers to the bodies in equilibrium. Equilibrium deals with the absence of a net force. When
Contents. Concept Map
Contents 1. General Notes on Forces 2. Effects of Forces on Motion 3. Effects of Forces on Shape 4. The Turning Effect of Forces 5. The Centre of Gravity and Stability Concept Map April 2000 Forces - 1
P12 Torque Notes.notebook. March 26, Torques
Torques The size of a torque depends on two things: 1. The size of the force being applied (a larger force will have a greater effect) 2. The distance away from the pivot point (the further away from this
Chapter 8 Rotational Motion and Dynamics Reading Notes
Name: Chapter 8 Rotational Motion and Dynamics Reading Notes Section 8-1: Angular quantities A circle can be split into pieces called degrees. There are 360 degrees in a circle. A circle can be split into
Chapter 8 Rotational Motion
Chapter 8 Rotational Motion Chapter 8 Rotational Motion In this chapter you will: Learn how to describe and measure rotational motion. Learn how torque changes rotational velocity. Explore factors that
Torque rotational force which causes a change in rotational motion. This force is defined by linear force multiplied by a radius.
Warm up A remote-controlled car's wheel accelerates at 22.4 rad/s 2. If the wheel begins with an angular speed of 10.8 rad/s, what is the wheel's angular speed after exactly three full turns? AP Physics
Rotational Dynamics continued
Chapter 9 Rotational Dynamics continued 9.1 The Action of Forces and Torques on Rigid Objects Chapter 8 developed the concepts of angular motion. θ : angles and radian measure for angular variables ω :
Torque. Introduction. Torque. PHY torque - J. Hedberg
Torque PHY 207 - torque - J. Hedberg - 2017 1. Introduction 2. Torque 1. Lever arm changes 3. Net Torques 4. Moment of Rotational Inertia 1. Moment of Inertia for Arbitrary Shapes 2. Parallel Axis Theorem
Rotation Quiz II, review part A
Rotation Quiz II, review part A 1. A solid disk with a radius R rotates at a constant rate ω. Which of the following points has the greater angular velocity? A. A B. B C. C D. D E. All points have the
Unit 4 Statics. Static Equilibrium Translational Forces Torque
Unit 4 Statics Static Equilibrium Translational Forces Torque 1 Dynamics vs Statics Dynamics: is the study of forces and motion. We study why objects move. Statics: is the study of forces and NO motion.
Chapter 8 - Rotational Dynamics and Equilibrium REVIEW
Pagpalain ka! (Good luck, in Filipino) Date Chapter 8 - Rotational Dynamics and Equilibrium REVIEW TRUE/FALSE. Write 'T' if the statement is true and 'F' if the statement is false. 1) When a rigid body
Chapter 8 continued. Rotational Dynamics
Chapter 8 continued Rotational Dynamics 8.4 Rotational Work and Energy Work to accelerate a mass rotating it by angle φ F W = F(cosθ)x x = s = rφ = Frφ Fr = τ (torque) = τφ r φ s F to s θ = 0 DEFINITION
Equilibrium. For an object to remain in equilibrium, two conditions must be met. The object must have no net force: and no net torque:
Equilibrium For an object to remain in equilibrium, two conditions must be met. The object must have no net force: F v = 0 and no net torque: v τ = 0 Worksheet A uniform rod with a length L and a mass
Chapter 9. Rotational Dynamics
Chapter 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 and rotation. 1) Torque Produces angular
Rotational Equilibrium
Rotational Equilibrium 6-1 Rotational Equilibrium INTRODUCTION Have you ever tried to pull a stubborn nail out of a board or develop your forearm muscles by lifting weights? Both these activities involve
Torques and Static Equilibrium
Torques and Static Equilibrium INTRODUCTION Archimedes, Greek mathematician, physicist, engineer, inventor and astronomer, was widely regarded as the leading scientist of the ancient world. He made a study
Rotational Mechanics Part II Torque. Pre AP Physics
Rotational Mechanics Part II Torque Pre AP Physics We have so far discussed rotational kinematics the description of rotational motion in terms of angle, angular velocity and angular acceleration. Now
Use the following to answer question 1:
Use the following to answer question 1: On an amusement park ride, passengers are seated in a horizontal circle of radius 7.5 m. The seats begin from rest and are uniformly accelerated for 21 seconds to
Answers to selected problems from Essential Physics, Chapter 10
Answers to selected problems from Essential Physics, Chapter 10 1. (a) The red ones have the same speed as one another. The blue ones also have the same speed as one another, with a value twice the speed
Rotational Equilibrium
Rotational Equilibrium In this laboratory, we study the conditions for static equilibrium. Axis Through the Center of Gravity Suspend the meter stick at its center of gravity, with its numbers increasing
Section 2: Static Equilibrium II- Balancing Torques
Section 2: Static Equilibrium II- Balancing Torques Last Section: If (ie. Forces up = Forces down and Forces left = Forces right), then the object will have no translatory motion. In other words, the object
Static equilibrium. Objectives. Physics terms. Assessment. Brainstorm. Equations 6/3/14
Static equilibrium Objectives State the conditions of static equilibrium in terms of forces and torques. Draw a free-body diagram of a lever showing all forces. Use the condition of equilibrium to solve
Chapter 9. Rotational Dynamics
Chapter 9 Rotational Dynamics 9.1 The Action of Forces and Torques on Rigid Objects In pure translational motion, all points on an object travel on parallel paths. The most general motion is a combination
General Physics (PHY 2130)
General Physics (PHY 130) Lecture 0 Rotational dynamics equilibrium nd Newton s Law for rotational motion rolling Exam II review http://www.physics.wayne.edu/~apetrov/phy130/ Lightning Review Last lecture:
Serway_ISM_V1 1 Chapter 8
Serway_ISM_V1 1 Chapter 8 8 Rotational Equilibrium and Rotational Dynamics ANSWERS TO MULTIPLE CHOICE QUESTIONS 1. Assuming a unifm, solid disk, its moment of inertia about a perpendicular axis through
Circular Motion Tangential Speed. Conceptual Physics 11 th Edition. Circular Motion Rotational Speed. Circular Motion
Conceptual Physics 11 th Edition Circular Motion Tangential Speed The distance traveled by a point on the rotating object divided by the time taken to travel that distance is called its tangential speed
Chapter 8: Rotational Motion
Lecture Outline Chapter 8: Rotational Motion This lecture will help you understand: Circular Motion Rotational Inertia Torque Center of Mass and Center of Gravity Centripetal Force Centrifugal Force Rotating
Moments, Levers and Centre of Gravity
Second Year Science Moments, Levers and Centre of Gravity Ms Rochford In this topic: Levers Moment of a force Centre of Gravity Levers Levers are everywhere! Levers Lever: a rigid body that can rotate
3. If you drag a rip-cord 2.0m across a wheel and it turns 10rad, what is the radius of the wheel? a. 0.1m b. 0.2m c. 0.4m d.
1. Two spheres are rolled across the floor the same distance at the same speed. Which will have the greater angular velocity? a. the smaller sphere b. the larger sphere c. the angular velocities will be
2008 FXA THREE FORCES IN EQUILIBRIUM 1. Candidates should be able to : TRIANGLE OF FORCES RULE
THREE ORCES IN EQUILIBRIUM 1 Candidates should be able to : TRIANGLE O ORCES RULE Draw and use a triangle of forces to represent the equilibrium of three forces acting at a point in an object. State that
Torque. Physics 6A. Prepared by Vince Zaccone For Campus Learning Assistance Services at UCSB
Physics 6A Torque is what causes angular acceleration (just like a force causes linear acceleration) Torque is what causes angular acceleration (just like a force causes linear acceleration) For a torque
Big Idea 4: Interactions between systems can result in changes in those systems. Essential Knowledge 4.D.1: Torque, angular velocity, angular
Unit 7: Rotational Motion (angular kinematics, dynamics, momentum & energy) Name: Big Idea 3: The interactions of an object with other objects can be described by forces. Essential Knowledge 3.F.1: Only
= o + t = ot + ½ t 2 = o + 2
Chapters 8-9 Rotational Kinematics and Dynamics Rotational motion Rotational motion refers to the motion of an object or system that spins about an axis. The axis of rotation is the line about which the
( )( ) ( )( ) Fall 2017 PHYS 131 Week 9 Recitation: Chapter 9: 5, 10, 12, 13, 31, 34
Fall 07 PHYS 3 Chapter 9: 5, 0,, 3, 3, 34 5. ssm The drawing shows a jet engine suspended beneath the wing of an airplane. The weight W of the engine is 0 00 N and acts as shown in the drawing. In flight
Theme 2 - PHYSICS UNIT 2 Forces and Moments. A force is a push or a pull. This means that whenever we push or pull something, we are doing a force.
Forces A force is a push or a pull. This means that whenever we push or pull something, we are doing a force. Forces are measured in Newtons (N) after the great physicist Sir Isaac Newton. The instrument
Chapter 9. Rotational Dynamics
Chapter 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 and rotation. 1) Torque Produces angular
Application of Forces. Chapter Eight. Torque. Force vs. Torque. Torque, cont. Direction of Torque 4/7/2015
Raymond A. Serway Chris Vuille Chapter Eight Rotational Equilibrium and Rotational Dynamics Application of Forces The point of application of a force is important This was ignored in treating objects as
Chapter 9. Rotational Dynamics
Chapter 9 Rotational Dynamics 9.1 The Action of Forces and Torques on Rigid Objects In pure translational motion, all points on an object travel on parallel paths. The most general motion is a combination
Physics 201 Lab 9: Torque and the Center of Mass Dr. Timothy C. Black
Theoretical Discussion Physics 201 Lab 9: Torque and the Center of Mass Dr. Timothy C. Black For each of the linear kinematic variables; displacement r, velocity v and acceleration a; there is a corresponding
7 th week Lectures Feb
7 th week Lectures Feb.19. 23. 2018. Moving in circles Torques Why is a wrench useful? Angular momentum Spinning at the Olympics Center of Gravity Useful info for crossing Niagara falls on a wire The New
Chapter 8 continued. Rotational Dynamics
Chapter 8 continued Rotational Dynamics 8.4 Rotational Work and Energy Work to accelerate a mass rotating it by angle φ F W = F(cosθ)x x = rφ = Frφ Fr = τ (torque) = τφ r φ s F to x θ = 0 DEFINITION OF
AP Physics 1 Rotational Motion Practice Test
AP Physics 1 Rotational Motion Practice Test MULTIPLE CHOICE. Choose the one alternative that best completes the statement or answers the question. 1) A spinning ice skater on extremely smooth ice is able
Phys101 Lectures 19, 20 Rotational Motion
Phys101 Lectures 19, 20 Rotational Motion Key points: Angular and Linear Quantities Rotational Dynamics; Torque and Moment of Inertia Rotational Kinetic Energy Ref: 10-1,2,3,4,5,6,8,9. Page 1 Angular Quantities
Physics 1A Lecture 10B
Physics 1A Lecture 10B "Sometimes the world puts a spin on life. When our equilibrium returns to us, we understand more because we've seen the whole picture. --Davis Barton Cross Products Another way to
General Physics I. Lecture 9: Vector Cross Product. Prof. WAN, Xin ( 万歆 )
General Physics I Lecture 9: Vector Cross Product Prof. WAN, Xin ( 万歆 ) xinwan@zju.edu.cn http://zimp.zju.edu.cn/~xinwan/ Outline Examples of the rotation of a rigid object about a fixed axis Force/torque
Chapter 9 Rotational Dynamics
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
Chapter 9-10 Test Review
Chapter 9-10 Test Review Chapter Summary 9.2. The Second Condition for Equilibrium Explain torque and the factors on which it depends. Describe the role of torque in rotational mechanics. 10.1. Angular
Test 7 wersja angielska
Test 7 wersja angielska 7.1A One revolution is the same as: A) 1 rad B) 57 rad C) π/2 rad D) π rad E) 2π rad 7.2A. If a wheel turns with constant angular speed then: A) each point on its rim moves with
AP Physics Multiple Choice Practice Torque
AP Physics Multiple Choice Practice Torque 1. A uniform meterstick of mass 0.20 kg is pivoted at the 40 cm mark. Where should one hang a mass of 0.50 kg to balance the stick? (A) 16 cm (B) 36 cm (C) 44
PSI AP Physics I Rotational Motion
PSI AP Physics I Rotational Motion Multiple-Choice questions 1. Which of the following is the unit for angular displacement? A. meters B. seconds C. radians D. radians per second 2. An object moves from
PSI AP Physics I Rotational Motion
PSI AP Physics I Rotational Motion Multiple-Choice questions 1. Which of the following is the unit for angular displacement? A. meters B. seconds C. radians D. radians per second 2. An object moves from
Physics 8 Wednesday, October 25, 2017
Physics 8 Wednesday, October 25, 2017 HW07 due Friday. It is mainly rotation, plus a couple of basic torque questions. And there are only 8 problems this week. For today, you read (in Perusall) Onouye/Kane
Moments of forces. Rudolf arnheim
T C Y Moments of forces The photograph shows a mobile tower crane, consisting of the main vertical section housing the engine, winding gear and controls and the boom which supports the load and the counterweight.
is the study of and. We study objects. is the study of and. We study objects.
Static Equilibrium Translational Forces Torque Unit 4 Statics Dynamics vs Statics is the study of and. We study objects. is the study of and. We study objects. Recall Newton s First Law All objects remain
End-of-Chapter Exercises
End-of-Chapter Exercises Exercises 1 12 are conceptual questions that are designed to see if you have understood the main concepts of the chapter. 1. Figure 11.21 shows four different cases involving a
General Physics I. Lecture 8: Rotation of a Rigid Object About a Fixed Axis. Prof. WAN, Xin ( 万歆 )
General Physics I Lecture 8: Rotation of a Rigid Object About a Fixed Axis Prof. WAN, Xin ( 万歆 ) xinwan@zju.edu.cn http://zimp.zju.edu.cn/~xinwan/ New Territory Object In the past, point particle (no rotation,
It will be most difficult for the ant to adhere to the wheel as it revolves past which of the four points? A) I B) II C) III D) IV
AP Physics 1 Lesson 16 Homework Newton s First and Second Law of Rotational Motion Outcomes Define rotational inertia, torque, and center of gravity. State and explain Newton s first Law of Motion as it
Use the following equation to calculate the moment of child B about the pivot of the see-saw. moment of a force = force distance
Q1.Two children, A and B, are sitting on a see-saw, as shown in the figure below. The see-saw is balanced. (a) Use the following equation to calculate the moment of child B about the pivot of the see-saw.
PHYSICS. Chapter 12 Lecture FOR SCIENTISTS AND ENGINEERS A STRATEGIC APPROACH 4/E RANDALL D. KNIGHT Pearson Education, Inc.
PHYSICS FOR SCIENTISTS AND ENGINEERS A STRATEGIC APPROACH 4/E Chapter 12 Lecture RANDALL D. KNIGHT Chapter 12 Rotation of a Rigid Body IN THIS CHAPTER, you will learn to understand and apply the physics
GIANCOLI READING ACTIVITY Lesson 8-4
AP PHYSICS Name: Period: Date: DEVIL PHYSICS BADDEST CLASS ON CAMPUS 1. Big Idea(s): GIANCOLI READING ACTIVITY Lesson 8-4 a. Big Idea 3: The interactions of an object with other objects can be described
Chapter 6, Problem 18. Agenda. Rotational Inertia. Rotational Inertia. Calculating Moment of Inertia. Example: Hoop vs.
Agenda Today: Homework quiz, moment of inertia and torque Thursday: Statics problems revisited, rolling motion Reading: Start Chapter 8 in the reading Have to cancel office hours today: will have extra
Page 2 (20) Page 3 (12) Page 4 (14) Page 5 (14) Total (60) PHYSICS 11 (Fall 2003) Exam 3. Elementary Physics November 21, 2003 SCORE BOX
INSTRUCTIONS: Except for the multiple choice questions 1 5, you must show all your work. An answer will not be enough; understanding must be demonstrated as well. This can take the form of a clear calculation,
Cutnell/Johnson Physics
Cutnell/Johnson Physics Classroom Response System Questions Chapter 9 Rotational Dynamics Interactive Lecture Questions 9.1.1. You are using a wrench in an attempt to loosen a nut by applying a force as
Chapter 8 Rotational Equilibrium and Rotational Dynamics Force vs. Torque Forces cause accelerations Torques cause angular accelerations Force and
Chapter 8 Rotational Equilibrium and Rotational Dynamics Force vs. Torque Forces cause accelerations Torques cause angular accelerations Force and torque are related Torque The door is free to rotate about
Name Date Period PROBLEM SET: ROTATIONAL DYNAMICS
Accelerated Physics Rotational Dynamics Problem Set Page 1 of 5 Name Date Period PROBLEM SET: ROTATIONAL DYNAMICS Directions: Show all work on a separate piece of paper. Box your final answer. Don t forget
Static Equilibrium and Torque
10.3 Static Equilibrium and Torque SECTION OUTCOMES Use vector analysis in two dimensions for systems involving static equilibrium and torques. Apply static torques to structures such as seesaws and bridges.
Chapter 8. Rotational Equilibrium and Rotational Dynamics
Chapter 8 Rotational Equilibrium and Rotational Dynamics Force vs. Torque Forces cause accelerations Torques cause angular accelerations Force and torque are related Torque The door is free to rotate about
Chapter 5: Turning Effects of Forces
Chapter 5: Turning Effects of Forces Brief Recap [Centre of Gravity] 1. The centre of gravity of an object is defined as the point through which its whole weight appears to act for any orientation of the
Rotational Dynamics. A wrench floats weightlessly in space. It is subjected to two forces of equal and opposite magnitude: Will the wrench accelerate?
Rotational Dynamics A wrench floats weightlessly in space. It is subjected to two forces of equal and opposite magnitude: Will the wrench accelerate? A. yes B. no C. kind of? Rotational Dynamics 10.1-3
We define angular displacement, θ, and angular velocity, ω. What's a radian?
We define angular displacement, θ, and angular velocity, ω Units: θ = rad ω = rad/s What's a radian? Radian is the ratio between the length of an arc and its radius note: counterclockwise is + clockwise
Chapter 8 continued. Rotational Dynamics
Chapter 8 continued Rotational Dynamics 8.6 The Action of Forces and Torques on Rigid Objects Chapter 8 developed the concepts of angular motion. θ : angles and radian measure for angular variables ω :
STATIC EQUILIBRIUM. Purpose
Purpose Theory STATIC EQUILIBRIUM a. To understand torque by experimentally measuring and manipulating them. b. To determine static equilibrium conditions by different torques that operate on a system.
Chapter 5 The Force Vector
Conceptual Physics/ PEP Name: Date: Chapter 5 The Force Vector Section Review 5.1 1. Indicate whether each of the following units of measurement are scalar or vector units: Speed _scalar time scalar mass
Physics. Chapter 8 Rotational Motion
Physics Chapter 8 Rotational Motion Circular Motion Tangential Speed The linear speed of something moving along a circular path. Symbol is the usual v and units are m/s Rotational Speed Number of revolutions
Chapter 8. Centripetal Force and The Law of Gravity
Chapter 8 Centripetal Force and The Law of Gravity Centripetal Acceleration An object traveling in a circle, even though it moves with a constant speed, will have an acceleration The centripetal acceleration
Turning Forces and Levers. Junior Science
Turning Forces and Levers Junior Science Lesson Objectives Understand the terms - Lever, Fulcrum, Turning effect, Moment Recall the formula M= Fd and be able to calculate the moment of a force Be able
Welcome back to Physics 211
Welcome back to Physics 211 Today s agenda: Torque Rotational Dynamics Current assignments Prelecture Thursday, Nov 20th at 10:30am HW#13 due this Friday at 5 pm. Clicker.1 What is the center of mass of
Section 2: Static Equilibrium II- Balancing Torques
Section 2: Static Equilibrium II- Balancing Torques Last Section: If (ie. Forces up = Forces down and Forces left = Forces right), then the object will have no translatory motion. In other words, the object
Lab 5: Rotational motion at the playground Essentials of Physics: PHYS 101
NAME DATE Lab 5: Rotational motion at the playground Essentials of Physics: PHYS 101 Important note: this lab meets at the playground located at the SW corner of 23 rd and University streets, about 7 blocks
Chapter 9: Rotational Dynamics Tuesday, September 17, 2013
Chapter 9: Rotational Dynamics Tuesday, September 17, 2013 10:00 PM The fundamental idea of Newtonian dynamics is that "things happen for a reason;" to be more specific, there is no need to explain rest
Recap I. Angular position: Angular displacement: s. Angular velocity: Angular Acceleration:
Recap I Angular position: Angular displacement: s Angular velocity: Angular Acceleration: Every point on a rotating rigid object has the same angular, but not the same linear motion! Recap II Circular
Chapter 8. Rotational Motion
Chapter 8 Rotational Motion The Action of Forces and Torques on Rigid Objects In pure translational motion, all points on an object travel on parallel paths. The most general motion is a combination of
Physics 130: Questions to study for midterm #1 from Chapter 8
Physics 130: Questions to study for midterm #1 from Chapter 8 1. If the beaters on a mixer make 800 revolutions in 5 minutes, what is the average rotational speed of the beaters? a. 2.67 rev/min b. 16.8
AP Physics 1- Torque, Rotational Inertia, and Angular Momentum Practice Problems FACT: The center of mass of a system of objects obeys Newton s second law- F = Ma cm. Usually the location of the center
Chapter 8. Rotational Equilibrium and Rotational Dynamics
Chapter 8 Rotational Equilibrium and Rotational Dynamics 1 Force vs. Torque Forces cause accelerations Torques cause angular accelerations Force and torque are related 2 Torque The door is free to rotate
Physics 201, Practice Midterm Exam 3, Fall 2006
Physics 201, Practice Midterm Exam 3, Fall 2006 1. A figure skater is spinning with arms stretched out. A moment later she rapidly brings her arms close to her body, but maintains her dynamic equilibrium.
Review PHYS114 Chapters 4-7
Review PHYS114 Chapters 4-7 MULTIPLE CHOICE. Choose the one alternative that best completes the statement or answers the question. 1) A 27 kg object is accelerated at a rate of 1.7 m/s 2. What force does
31 ROTATIONAL KINEMATICS
31 ROTATIONAL KINEMATICS 1. Compare and contrast circular motion and rotation? Address the following Which involves an object and which involves a system? Does an object/system in circular motion have
Dynamics. Dynamics of mechanical particle and particle systems (many body systems)
Dynamics Dynamics of mechanical particle and particle systems (many body systems) Newton`s first law: If no net force acts on a body, it will move on a straight line at constant velocity or will stay at
Problem Set x Classical Mechanics, Fall 2016 Massachusetts Institute of Technology. 1. Moment of Inertia: Disc and Washer
8.01x Classical Mechanics, Fall 2016 Massachusetts Institute of Technology Problem Set 10 1. Moment of Inertia: Disc and Washer (a) A thin uniform disc of mass M and radius R is mounted on an axis passing
1 The diagram shows an object of weight W and an object of weight Z balanced on a uniform metre rule. object of weight W. object of weight Z
1 The diagram shows an object of weight W and an object of weight Z balanced on a uniform metre rule. object of weight W a b 50 cm mark object of weight Z metre rule Which equation relating to W, Z, a
Rotational Motion. Chapter 8: Rotational Motion. Angular Position. Rotational Motion. Ranking: Rolling Cups 9/21/12
Rotational Motion Chapter 8: Rotational Motion In physics we distinguish two types of motion for objects: Translational Motion (change of location): Whole object moves through space. Rotational Motion
Rotational N.2 nd Law
Lecture 0 Chapter 1 Physics I Rotational N. nd Law Torque Course website: http://faculty.uml.edu/andriy_danylov/teaching/physicsi IN THIS CHAPTER, you will continue discussing rotational dynamics Today