Applications of Statics, Including Problem-Solving Strategies

Similar documents
Applications of Statics, Including Problem-Solving Strategies

Static Equilibrium; Torque

9 STATICS AND TORQUE. Learning Objectives. Introduction to Statics and Torque

Section 2: Static Equilibrium II- Balancing Torques

Section 2: Static Equilibrium II- Balancing Torques

Consider two students pushing with equal force on opposite sides of a desk. Looking top-down on the desk:

P12 Torque Notes.notebook. March 26, Torques

Torque and Static Equilibrium

Lab 17 Torques/Moments

LECTURE 15 TORQUE AND CENTER OF GRAVITY

Rotational Equilibrium

Unit 1: Equilibrium and Center of Mass

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

Chapter 8. Centripetal Force and The Law of Gravity

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

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

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.

Today we applied our knowledge of vectors to different kinds of problems.

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

Simple Machines. Bởi: OpenStaxCollege

Equilibrium Notes 1 Translational Equilibrium

PHYSICS 149: Lecture 21

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

Physics 1A Lecture 10B

LECTURE 22 EQUILIBRIUM. Instructor: Kazumi Tolich

Static Equilibrium and Torque

Chapter 9 TORQUE & Rotational Kinematics

= o + t = ot + ½ t 2 = o + 2

Problem-Solving Strategies

Static Equilibrium and Elasticity. Luis Anchordoqui

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

SPH 4C Unit 2 Mechanical Systems

Chapter 5: Forces in Equilibrium

Torque. Objectives. Assessment. Assessment. Equations. Physics terms 6/2/14

Equilibrium Notes 1 Translational Equilibrium

UNIT 6 STATICS AND TORQUE. Objectives. to be able to solve problems involving static equilibrium

Torque and Static Equilibrium

Rotational Equilibrium

Chapter 9- Static Equilibrium

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

Science Olympiad. Machines. Roger Demos

Chapter 9. Rotational Dynamics

Torques and Static Equilibrium

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

Models and Anthropometry

Solution Derivations for Capa #12

TEST REPORT. Question file: P Copyright:

Chapter 9 Rotational Dynamics

Chapter 12 Static Equilibrium

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

Lecture Presentation Chapter 8 Equilibrium and Elasticity

Chapter 12 Static Equilibrium; Elasticity and Fracture

PHYSICS 12 NAME: Electrostatics Review

Name Section Number Team Number

Physics 2210 Fall smartphysics Rotational Statics 11/18/2015

Chapter 12. Static Equilibrium and Elasticity

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

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

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

III. Angular Momentum Conservation (Chap. 10) Rotation. We repeat Chap. 2-8 with rotatiing objects. Eqs. of motion. Energy.

Rotational N.2 nd Law

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

The student will be able to: 1 Determine the torque of an applied force and solve related problems.

Rotation. I. Kinematics - Angular analogs

Chapter 4 Dynamics: Newton s Laws of Motion

Rotational N.2 nd Law

Physics 6A Lab Experiment 6

Lecture PowerPoints. Chapter 4 Physics: for Scientists & Engineers, with Modern Physics, 4th edition Giancoli

( )( ) ( )( ) Fall 2017 PHYS 131 Week 9 Recitation: Chapter 9: 5, 10, 12, 13, 31, 34

Physics A - PHY 2048C

HATZIC SECONDARY SCHOOL

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

Unit 4 Statics. Static Equilibrium Translational Forces Torque

Chapter 8. Rotational Equilibrium and Rotational Dynamics

Chapter 4. Forces and Newton s Laws of Motion. continued

Review for 3 rd Midterm

SPH3U Practice Test. True/False Indicate whether the statement is true or false.


The student will be able to: the torque of an applied force and solve related problems.

Rotational Dynamics continued

Solutions to Physics: Principles with Applications, 5/E, Giancoli Chapter 9

Chapter Test A. Teacher Notes and Answers Forces and the Laws of Motion. Assessment

Study Guide. Physics 3104A. Science. Force, Motion and Energy. Adult Basic Education. Prerequisite: Physics 2104B or Physics 2204.

Equilibrium. Today: Center of Gravity Static Equilibrium. Sign convention for torques: (-) CW torque (+) CCW torque

Chapter 5 The Force Vector

Physics 1A Lecture 4B. "Fig Newton: The force required to accelerate a fig inches per second. --J. Hart

Semester 1 Revision. Last modified: 05/06/2018

Lecture 7: More on Newton s Laws

Chapter 9. Rotational Dynamics

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

Concept of Force Challenge Problem Solutions

τ net l = r p L = Iω = d L dt = I α ΔL Angular momentum (one) Angular momentum (system, fixed axis) Newton s second law (system)

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.

Newton s First Law and IRFs

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.

4.1 Forces. Chapter 4 The Laws of Motion

Phys 1401: General Physics I

θ Beam Pivot F r Figure 1. Figure 2. STATICS (Force Vectors, Tension & Torque) MBL-32 (Ver. 3/20/2006) Name: Lab Partner: Lab Partner:

Physics 2210 Homework 18 Spring 2015

The net force on a moving object is suddenly reduced to zero. As a consequence, the object

Transcription:

Applications of Statics, Including Problem-Solving Strategies Bởi: OpenStaxCollege Statics can be applied to a variety of situations, ranging from raising a drawbridge to bad posture and back strain. We begin with a discussion of problem-solving strategies specifically used for statics. Since statics is a special case of Newton s laws, both the general problem-solving strategies and the special strategies for Newton s laws, discussed in Problem-Solving Strategies, still apply. Problem-Solving Strategy: Static Equilibrium Situations 1. The first step is to determine whether or not the system is in static equilibrium. This condition is always the case when the acceleration of the system is zero and accelerated rotation does not occur. 2. It is particularly important to draw a free body diagram for the system of interest. Carefully label all forces, and note their relative magnitudes, directions, and points of application whenever these are known. 3. Solve the problem by applying either or both of the conditions for equilibrium (represented by the equations net F 0 and net τ 0, depending on the list of known and unknown factors. If the second condition is involved, choose the pivot point to simplify the solution. Any pivot point can be chosen, but the most useful ones cause torques by unknown forces to be zero. (Torque is zero if the force is applied at the pivot (then r 0), or along a line through the pivot point (then θ 0)). Always choose a convenient coordinate system for projecting forces. 4. Check the solution to see if it is reasonable by examining the magnitude, direction, and units of the answer. The importance of this last step never diminishes, although in unfamiliar applications, it is usually more difficult to judge reasonableness. These judgments become progressively easier with experience. 1/6

Now let us apply this problem-solving strategy for the pole vaulter shown in the three figures below. The pole is uniform and has a mass of 5.00 kg. In [link], the pole s cg lies halfway between the vaulter s hands. It seems reasonable that the force exerted by each hand is equal to half the weight of the pole, or 24.5 N. This obviously satisfies the first condition for equilibrium (net F 0). The second condition (net 1 children in msub 0) is also satisfied, as we can see by choosing the cg to be the pivot point. The weight exerts no torque about a pivot point located at the cg, since it is applied at that point and its lever arm is zero. The equal forces exerted by the hands are equidistant from the chosen pivot, and so they exert equal and opposite torques. Similar arguments hold for other systems where supporting forces are exerted symmetrically about the cg. For example, the four legs of a uniform table each support one-fourth of its weight. In [link], a pole vaulter holding a pole with its cg halfway between his hands is shown. Each hand exerts a force equal to half the weight of the pole, F R F L w / 2. (b) The pole vaulter moves the pole to his left, and the forces that the hands exert are no longer equal. See [link]. If the pole is held with its cg to the left of the person, then he must push down with his right hand and up with his left. The forces he exerts are larger here because they are in opposite directions and the cg is at a long distance from either hand. Similar observations can be made using a meter stick held at different locations along its length. A pole vaulter holds a pole horizontally with both hands. 2/6

A pole vaulter is holding a pole horizontally with both hands. The center of gravity is near his right hand. A pole vaulter is holding a pole horizontally with both hands. The center of gravity is to the left side of the vaulter. If the pole vaulter holds the pole as shown in [link], the situation is not as simple. The total force he exerts is still equal to the weight of the pole, but it is not evenly divided between his hands. (If F L F R, then the torques about the cg would not be equal since the lever arms are different.) Logically, the right hand should support more weight, since it is closer to the cg. In fact, if the right hand is moved directly under the cg, it will support all the weight. This situation is exactly analogous to two people carrying a load; the one closer to the cg carries more of its weight. Finding the forces F L and F R is straightforward, as the next example shows. If the pole vaulter holds the pole from near the end of the pole ([link]), the direction of the force applied by the right hand of the vaulter reverses its direction. What Force Is Needed to Support a Weight Held Near Its CG? For the situation shown in [link], calculate: (a) F R, the force exerted by the right hand, and (b) F L, the force exerted by the left hand. The hands are 0.900 m apart, and the cg of the pole is 0.600 m from the left hand. 3/6

Strategy [link] includes a free body diagram for the pole, the system of interest. There is not enough information to use the first condition for equilibrium (net F 0), since two of the three forces are unknown and the hand forces cannot be assumed to be equal in this case. There is enough information to use the second condition for equilibrium (net τ 0) if the pivot point is chosen to be at either hand, thereby making the torque from that hand zero. We choose to locate the pivot at the left hand in this part of the problem, to eliminate the torque from the left hand. Solution for (a) There are now only two nonzero torques, those from the gravitational force (τ w ) and from the push or pull of the right hand (τ R ). Stating the second condition in terms of clockwise and counterclockwise torques, net τ cw net τ ccw. or the algebraic sum of the torques is zero. Here this is τ R τ w since the weight of the pole creates a counterclockwise torque and the right hand counters with a clockwise toque. Using the definition of torque, τ rf sin θ, noting that θ 90º, and substituting known values, we obtain (0.900 m)(f R) (0.600 m)(mg). Thus, F R (0.667)(5.00 kg)(9.80 m/s 2 ) 32.7 N. Solution for (b) The first condition for equilibrium is based on the free body diagram in the figure. This implies that by Newton s second law: F L + F R mg 0 4/6

From this we can conclude: F L + F R w mg Solving for F L, we obtain F L mg F R mg 32.7 N (5.00 kg)(9.80 m/s 2 ) 32.7 N 16.3 N Discussion F L is seen to be exactly half of F R, as we might have guessed, since F L is applied twice as far from the cg as F R. If the pole vaulter holds the pole as he might at the start of a run, shown in [link], the forces change again. Both are considerably greater, and one force reverses direction. Take-Home Experiment This is an experiment to perform while standing in a bus or a train. Stand facing sideways. How do you move your body to readjust the distribution of your mass as the bus accelerates and decelerates? Now stand facing forward. How do you move your body to readjust the distribution of your mass as the bus accelerates and decelerates? Why is it easier and safer to stand facing sideways rather than forward? Note: For your safety (and those around you), make sure you are holding onto something while you carry out this activity! PhET Explorations: Balancing Act Play with objects on a teeter totter to learn about balance. Test what you've learned by trying the Balance Challenge game. Balancing Act 5/6

Summary Statics can be applied to a variety of situations, ranging from raising a drawbridge to bad posture and back strain. We have discussed the problemsolving strategies specifically useful for statics. Statics is a special case of Newton s laws, both the general problem-solving strategies and the special strategies for Newton s laws, discussed in Problem-Solving Strategies, still apply. Conceptual Questions When visiting some countries, you may see a person balancing a load on the head. Explain why the center of mass of the load needs to be directly above the person s neck vertebrae. Problems & Exercises To get up on the roof, a person (mass 70.0 kg) places a 6.00-m aluminum ladder (mass 10.0 kg) against the house on a concrete pad with the base of the ladder 2.00 m from the house. The ladder rests against a plastic rain gutter, which we can assume to be frictionless. The center of mass of the ladder is 2 m from the bottom. The person is standing 3 m from the bottom. What are the magnitudes of the forces on the ladder at the top and bottom? In [link], the cg of the pole held by the pole vaulter is 2.00 m from the left hand, and the hands are 0.700 m apart. Calculate the force exerted by (a) his right hand and (b) his left hand. (c) If each hand supports half the weight of the pole in [link], show that the second condition for equilibrium (net 1 children in msub 0) is satisfied for a pivot other than the one located at the center of gravity of the pole. Explicitly show how you follow the steps in the Problem-Solving Strategy for static equilibrium described above. 6/6

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