Free Body Diagrams For any complicated situation, Isolate each object;

Slides:

Advertisements

Similar presentations

Advertisements

AP Physics C Multiple Choice Dynamics.

Chapter 5 – Force and Motion I

Q5.1 A car engine is suspended from a chain linked at O to two other chains. Which of the following forces should be included in the free-body diagram.

Chapter 7. Newton’s Third Law

Chapter 4 The Laws of Motion.

Force Scenario Solutions

PHY 2048C General Physics I with lab Spring 2011 CRNs 11154, & Dr. Derrick Boucher Assoc. Prof. of Physics Sessions 6-7, Chapter 7.

1 Chapter Four Newton's Laws. 2  In this chapter we will consider Newton's three laws of motion.  There is one consistent word in these three laws and.

Section 4-7 Solving Problems with Newton’s Laws; Free Body Diagrams

Springs & Strings.

Examples and Hints for Chapter 5

Chapter 7 Newton’s Third Law

Chapter 5 QuickCheck Questions

Newton’s Second Law The net force on a body is equal to the product of the body’s mass and its acceleration.

Ropes and Pulleys.

Follow the same procedure as other force problems, but keep in mind: 1) Draw a free body diagram for EACH object or for each junction in a rope.

When a car accelerates forward on a level roadway, which force is responsible for this acceleration? State clearly which.

Copyright © 2007, Pearson Education, Inc., Publishing as Pearson Addison-Wesley. Equilibrium Using Newton’s second law Mass, weight, and apparent weight.

Chapter 4: Forces Newton’s Third Law You cannot touch

Kinds of Forces Lecturer: Professor Stephen T. Thornton

Free Body Diagram. Used to show all net forces acting on an object What can an object with a net force of zero be doing?

Chapter 7. Newton’s Third Law

Free-body diagrams Pg. 15 in NB

Forces Contact Forces - those resulting from physical contact between objects –Normal Force –Friction –Tension (spring/rope) –Compression Action at a Distance.

Chapter 4: Newton's Laws of Motion

Problems Chapter 4,5.

I.Newton’s first law. II.Newton’s second law. III.Particular forces: - Gravitational - Gravitational - Weight - Weight - Normal - Normal - Tension - Tension.

What is the normal force for a 500 kg object resting on a horizontal surface if a massless rope with a tension of 150 N is acting at a 45 o angle to the.

Newton’s Laws of Motion

Force and Motion–I Chapter 5 Copyright © 2014 John Wiley & Sons, Inc. All rights reserved.

– coefficient of kinetic friction

21. ConcepTest 4.11On an Incline 21. ConcepTest 4.11 On an Incline 1) case A 2) case B 3) both the same (N = mg) 4) both the same (0 < N < mg) 5) both.

1) 0 N 2) 50 N 3) 100 N 4) 150 N 5) 200 N You tie a rope to a tree and you pull on the rope with a force of 100 N. What is the tension in the rope?

Force Systems accelerate together Combination Systems – connected masses Horizontal Pulley Atwood’s Machine.

1 Some application & Forces of Friction. 2 Example: When two objects of unequal mass are hung vertically over a frictionless pulley of negligible mass,

Newton’s Laws of Motion Sections ) 1,3,4,5,6,8,12)

Chapter 6 Applications of Newton’s Laws What keeps Leo in his seat when the train stops?

Applications & Examples of Newton’s Laws. Forces are VECTORS!! Newton’s 2 nd Law: ∑F = ma ∑F = VECTOR SUM of all forces on mass m  Need VECTOR addition.

Chapter 5 THE LAWS OF MOTION. Force, net force : Force as that which causes an object to accelerate. The net force acting on an object is defined as.

Newton's Laws of Motion Slide 4-19 Newton 0th Law Objects are dumb - They have no memory of the past and cannot predict the future. Objects only know what.

Physics 111 Practice Problem Statements 04 Force and Motion I: The Laws of Motion SJ 8th Ed.: Ch. 5.1 – 5.7 Contents: 5-2E, 5-7P, 5-9E, 5-29P*, 5-31P*,

1) component of the gravity force parallel to the plane increased 2) coeff. of static friction decreased 3) normal force exerted by the board decreased.

Apparent Weight The weight of an object is the force of gravity on that object. Your sensation of weight is due to contact forces supporting you. Let’s.

Chapters 5, 6 Force and Laws of Motion. Newtonian mechanics Describes motion and interaction of objects Applicable for speeds much slower than the speed.

Physics 211 Lecture 5 Today’s Concepts: a) Free Body Diagrams

WEEK 7 PHYSICS. MUST DO Unit 2 Cover Page Write three questions Write a statement of what you already know. Unit 2: Molecules to Cells My Questions: 

University Physics: Mechanics

PHYSICS 11 SOLVING F=MA PROBLEMS USING FREE BODY DIAGRAMS.

Physics 211 Lecture 5 Today’s Concepts: a) Free Body Diagrams b) Force due to strings c) Force due to springs d) Force due to gravity.

Copyright © 2008 Pearson Education, Inc., publishing as Pearson Addison-Wesley. Topics: Interacting Objects Analyzing Interacting Objects Newton’s Third.

Newton’s Third Law If two objects interact, the force exerted by object 1 on object 2 is equal in magnitude and opposite in direction to the force.

Force Problems. A car is traveling at constant velocity with a frictional force of 2000 N acting opposite the motion of the car. The force acting on the.

Physics 218 Lecture 8: Dynamics Alexei Safonov.

Review for Forces Test. Describe an objects velocity and acceleration when the net force is zero? Describe an objects velocity and acceleration.

Solving problems when  F = ma

Force and Motion–I Chapter 5. Newton's First and Second Laws A force: o Is a “push or pull” acting on an object o Causes acceleration We will focus on.

Consider a person standing in an elevator that is moving upward at constant speed. The magnitude of the upward normal force,

Free-body diagrams Pg. 17 in NB. Identify normal forces. Draw a free-body diagram with forces in vertical and/or horizontal directions. Calculate the.

Physics 218 Lecture 6: Dynamics Alexei Safonov.

AP Physics Review Ch 4 – Forces and Newton’s Laws of Motion

It does not draw each object separately.

This is the same as both situations above Springs and Hooke’s Law k is the “force constant”

Aim: How can we apply Newton’s Second Law?

Q5.1 A car engine is suspended from a chain linked at O to two other chains. Which of the following forces should be included in the free-body diagram.

Forces Third Law First Law and Equilibrium Second Law and Acceleration.

SPH4U1 “Free Body Diagrams”

Two blocks, mass

Force Problems.

Presentation transcript:

Free Body Diagrams For any complicated situation, Isolate each object; Draw all forces acting on it; Use for each object.

Free Body Diagrams 3) Use for each object.

Friction forces: Contact friction: (Note that it doesn’t depend on the area.) Drag:

A. Both (1) and (2) are correct; Three massless pulleys of identical radius R=0.05 m are connected with inextensible cords, as shown in the figure. Pulleys 1 and 3 are attached to a vertical wall and pulley 2 is hanging from a cord that is held by pulleys 1 and 3 and weights of masses m1=m3=5 kg. Weight 2 of mass m2=15 kg is hanging from pulley 2. Consider the following equations that involve the given masses, the tensions shown in the figure, and the acceleration of weight 1, a. (1) ; (2) ; Which one is correct? A. Both (1) and (2) are correct; B. Only (1) is correct, (2) is incorrect; C. Only (2) is correct, (1) is incorrect; D. Both (1) and (2) are incorrect.

A. Both (1) and (2) are correct; Three massless pulleys of identical radius R=0.05 m are connected with inextensible cords, as shown in the figure. Pulleys 1 and 3 are attached to a vertical wall and pulley 2 is hanging from a cord that is held by pulleys 1 and 3 and weights of masses m1=m3=5 kg. Weight 2 of mass m2=15 kg is hanging from pulley 2. Consider the following equations that involve the given masses, the tensions shown in the figure, and the acceleration of weight 1, a. (1) ; (2) ; Which one is correct? A. Both (1) and (2) are correct; B. Only (1) is correct, (2) is incorrect; C. Only (2) is correct, (1) is incorrect; D. Both (1) and (2) are incorrect.

The magnitude of the net force on the wall is: Smaller than ; Three massless pulleys of identical radius R=0.05 m are connected with inextensible cords, as shown in the figure. Pulleys 1 and 3 are attached to a vertical wall and pulley 2 is hanging from a cord that is held by pulleys 1 and 3 and weights of masses m1=m3=5 kg. Weight 2 of mass m2=15 kg is hanging from pulley 2. The magnitude of the net force on the wall is: Smaller than ; B. Equal to ; C. Larger than ; D. Not enough information to answer this question.

The magnitude of the net force on the wall is: Smaller than ; Three massless pulleys of identical radius R=0.05 m are connected with inextensible cords, as shown in the figure. Pulleys 1 and 3 are attached to a vertical wall and pulley 2 is hanging from a cord that is held by pulleys 1 and 3 and weights of masses m1=m3=5 kg. Weight 2 of mass m2=15 kg is hanging from pulley 2. The magnitude of the net force on the wall is: Smaller than ; B. Equal to ; C. Larger than ; D. Not enough information to answer this question.

The net torque on pulley 2 is in the following direction: Three massless pulleys of identical radius R=0.05 m are connected with inextensible cords, as shown in the figure. Pulleys 1 and 3 are attached to a vertical wall and pulley 2 is hanging from a cord that is held by pulleys 1 and 3 and weights of masses m1=m3=5 kg. Weight 2 of mass m2=15 kg is hanging from pulley 2. The net torque on pulley 2 is in the following direction: A. Into the page; B. Out of the page; C. It is zero; D. Not enough information to answer this question.

The net torque on pulley 2 is in the following direction: Three massless pulleys of identical radius R=0.05 m are connected with inextensible cords, as shown in the figure. Pulleys 1 and 3 are attached to a vertical wall and pulley 2 is hanging from a cord that is held by pulleys 1 and 3 and weights of masses m1=m3=5 kg. Weight 2 of mass m2=15 kg is hanging from pulley 2. The net torque on pulley 2 is in the following direction: A. Into the page; B. Out of the page; C. It is zero; D. Not enough information to answer this question.

A box B sits in the back of a truck T as the truck slows down for a stop (the box remains motionless relative to the truck). What is the appropriate symbol for the horizontal force that the contact interaction between the box and the truck exerts on the truck? FNB(T) FNT(B) FSFB(T) FSFT(B) FKFB(T)

A box B sits in the back of a truck T as the truck slows down for a stop (the box remains motionless relative to the truck). What is the appropriate symbol for the horizontal force that the contact interaction between the box and the truck exerts on the truck? FNB(T) FNT(B) FSFB(T) FSFT(B) FKFB(T)

N7T.4 A child C pulls on a wagon W, using a string S; the wagon moves forward at a constant speed as a result. The third-law partner to the forward force exerted on the wagon is which of the following forces? (R=road) FST(W) FWT(S) FWT(C) FCT(W) FWKF(R) None of the above.

N7T.4 A child C pulls on a wagon W, using a string S; the wagon moves forward at a constant speed as a result. The third-law partner to the forward force exerted on the wagon is which of the following forces? (R=road) FST(W) FWT(S) FWT(C) FCT(W) FWKF(R) None of the above.

N7T.5 A small car pushes on a disabled truck, accelerating it slowly forward. Each exerts a force on the other as a result of their contact interaction. Which vehicle exerts the greater force on the other? The car. The truck. Both forces have the same magnitude. The truck doesn’t exert any force on the car. There is not enough information for a meaningful answer.

N7T.5 A small car pushes on a disabled truck, accelerating it slowly forward. Each exerts a force on the other as a result of their contact interaction. Which vehicle exerts the greater force on the other? The car. The truck. Both forces have the same magnitude. The truck doesn’t exert any force on the car. There is not enough information for a meaningful answer.

N7T.6 A physicist and a chemist are playing tug-of-war. For a certain length of time during the game, the participants are essentially at rest. During this time, each person pulls on the rope (which can be treated as an ideal string) with a force of 350N. What is the tension on the rope? 700N 350N 175N None of the above

N7T.6 A physicist and a chemist are playing tug-of-war. For a certain length of time during the game, the participants are essentially at rest. During this time, each person pulls on the rope (which can be treated as an ideal string) with a force of 350N. What is the tension on the rope? 700N 350N 175N None of the above

N7T.7 Object A (mA=1.0kg) hangs at rest from an ideal string A connected to the ceiling. Object B (mB=2.0kg) hangs at rest from an ideal string B connected to object A. The tension on string A is: Twice the tension on string B 3/2 times the tension on string B. Equal to the tension on string B 2/3 the tension of string B None of the above

N7T.7 Object A (mA=1.0kg) hangs at rest from an ideal string A connected to the ceiling. Object B (mB=2.0kg) hangs at rest from an ideal string B connected to object A. The tension on string A is: Twice the tension on string B 3/2 times the tension on string B. Equal to the tension on string B 2/3 the tension of string B None of the above

N7T.8 Two people are attempting to break a rope, which will break if the tension on the rope exceeds 360N. If each person can exert a pull of 200N, They can break the rope if they each take an end and pull. They can break the rope if they tie one end to the wall and both pull on the other. They can break the rope if they use either of the strategies above. They cannot break the rope.

N7T.8 Two people are attempting to break a rope, which will break if the tension on the rope exceeds 360N. If each person can exert a pull of 200N, They can break the rope if they each take an end and pull. They can break the rope if they tie one end to the wall and both pull on the other. They can break the rope if they use either of the strategies above. They cannot break the rope.

A spring scale typically indicates the magnitude of the tension force exerted on its bottom hook. What will the scale read in each of the cases shown in the diagram? (Hint: Construct a free-body or a free-particle diagram for the scale in each case.) 49N 98N 186N None of the above

A spring scale typically indicates the magnitude of the tension force exerted on its bottom hook. What will the scale read in each of the cases shown in the diagram? (Hint: Construct a free-body or a free-particle diagram for the scale in each case.) 49N 98N 186N None of the above