Static Equilibrium; Elasticity & Fracture

Similar documents
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.

Chapter 12 Static Equilibrium; Elasticity and Fracture

Chapter 12. Static Equilibrium and Elasticity

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

Chapter 26 Elastic Properties of Materials

2/28/2006 Statics ( F.Robilliard) 1

4/14/11. Chapter 12 Static equilibrium and Elasticity Lecture 2. Condition for static equilibrium. Stability An object is in equilibrium:

Static Equilibrium and Elasticity. Luis Anchordoqui

Equilibrium. the linear momentum,, of the center of mass is constant

1 (a) On the axes of Fig. 7.1, sketch a stress against strain graph for a typical ductile material. stress. strain. Fig. 7.1 [2]

Objectives: After completion of this module, you should be able to:

Stress Strain Elasticity Modulus Young s Modulus Shear Modulus Bulk Modulus. Case study

PHYS 1441 Section 002 Lecture #23

Lecture Presentation Chapter 8 Equilibrium and Elasticity

MECHANICAL PROPERTIES OF SOLIDS

Linear Elasticity ( ) Objectives. Equipment. Introduction. ε is then

EQUILIBRIUM and ELASTICITY

Rutgers University Department of Physics & Astronomy. 01:750:271 Honors Physics I Fall Lecture 19. Home Page. Title Page. Page 1 of 36.

MECE 3321 MECHANICS OF SOLIDS CHAPTER 3

UNIVERSITY PHYSICS I. Professor Meade Brooks, Collin College. Chapter 12: STATIC EQUILIBRIUM AND ELASTICITY

Chapter Two: Mechanical Properties of materials

Chapter 13 ELASTIC PROPERTIES OF MATERIALS

Chapter 5: Forces in Equilibrium

9 MECHANICAL PROPERTIES OF SOLIDS

Equilibrium & Elasticity

Chapter 10 Lecture Outline. Copyright The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

[5] Stress and Strain

Contents. Concept Map

INTRODUCTION TO STRAIN

Announcements. Suppose your scores are 12, 16, 15. (16/20)*20 + (15/20)*15 + (12/20)*15 = out of a possible

Chapter 3. Inertia. Force. Free Body Diagram. Net Force. Mass. quantity of matter composing a body represented by m. units are kg

Chapter 12 Static Equilibrium

Mechanics of Solids. Mechanics Of Solids. Suraj kr. Ray Department of Civil Engineering

Simple Harmonic Motion and Elasticity continued

Elastic Properties of Solid Materials. Notes based on those by James Irvine at

Elasticity. A PowerPoint Presentation by Paul E. Tippens, Professor of Physics Southern Polytechnic State University Modified by M.

X has a higher value of the Young modulus. Y has a lower maximum tensile stress than X

NORMAL STRESS. The simplest form of stress is normal stress/direct stress, which is the stress perpendicular to the surface on which it acts.

Lecture 18. In other words, if you double the stress, you double the resulting strain.

Chapter 9 TORQUE & Rotational Kinematics

ME 243. Mechanics of Solids

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.


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

Class XI Chapter 9 Mechanical Properties of Solids Physics

Be on time Switch off mobile phones. Put away laptops. Being present = Participating actively

Chapter 6: Mechanical Properties of Metals. Dr. Feras Fraige

Class XI Physics. Ch. 9: Mechanical Properties of solids. NCERT Solutions

Introduction to Engineering Materials ENGR2000. Dr. Coates

Physics 141 Rotational Motion 2 Page 1. Rotational Motion 2

Chapter 9 Rotational Dynamics

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.

cos(θ)sin(θ) Alternative Exercise Correct Correct θ = 0 skiladæmi 10 Part A Part B Part C Due: 11:59pm on Wednesday, November 11, 2015

Chapter 12 Vibrations and Waves Simple Harmonic Motion page

Practice. Newton s 3 Laws of Motion. Recall. Forces a push or pull acting on an object; a vector quantity measured in Newtons (kg m/s²)

Which expression gives the elastic energy stored in the stretched wire?

Question 9.1: Answer. Length of the steel wire, L 1 = 4.7 m. Area of cross-section of the steel wire, A 1 = m 2

Equilibrium Notes 1 Translational Equilibrium

Unit Workbook 1 Level 4 ENG U8 Mechanical Principles 2018 UniCourse Ltd. All Rights Reserved. Sample

22 Which of the following correctly defines the terms stress, strain and Young modulus? stress strain Young modulus

Question Figure shows the strain-stress curve for a given material. What are (a) Young s modulus and (b) approximate yield strength for this material?

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

Oscillations. Oscillations and Simple Harmonic Motion

Page 2. What is the main purpose of the steel core? To force more current into the outer sheath.

High Tech High Top Hat Technicians. An Introduction to Solid Mechanics. Is that supposed to bend there?

SOLUTION a. Since the applied force is equal to the person s weight, the spring constant is 670 N m ( )( )

P12 Torque Notes.notebook. March 26, Torques

Forces. Name and Surname: Class: L E A R N I N G O U T C O M E S. What is a force? How are forces measured? What do forces do?

Recap. Transitions from one state into another are initiated by heating/cooling the material. Density is mass per volume: Pressure is force per area:

1. A force acts on a particle and displaces it through. The value of x for zero work is 1) 0.5 2) 2 4) 6

EDEXCEL NATIONAL CERTIFICATE/DIPLOMA SCIENCE FOR TECHNICIANS OUTCOME 1 - STATIC AND DYNAMIC FORCES TUTORIAL 3 STRESS AND STRAIN

The Young modulus is defined as the ratio of tensile stress to tensile strain. Explain what is meant by each of the terms in italics.

Advanced Structural Analysis EGF Section Properties and Bending

Work done by multiple forces. WEST VIRGINIA UNIVERSITY Physics

Energy Considerations

Mechanical properties 1 Elastic behaviour of materials

M-3: Statics & M-10 Elasticity

Chapter 8. Rotational Equilibrium and Rotational Dynamics. 1. Torque. 2. Torque and Equilibrium. 3. Center of Mass and Center of Gravity

Science 7 Unit B: Structures and Forces. Topic 4. Forces, Loads, & Stresses. pp WORKBOOK. Name:

Fluid Mechanics. If deformation is small, the stress in a body is proportional to the corresponding

Course: US01CPHY01 UNIT 1 ELASTICITY I Introduction:

MATERIALS. Why do things break? Why are some materials stronger than others? Why is steel tough? Why is glass brittle?

STRESS, STRAIN AND DEFORMATION OF SOLIDS

Chapter 5 The Force Vector

BTECH MECHANICAL PRINCIPLES AND APPLICATIONS. Level 3 Unit 5

Tensile stress strain curves for different materials. Shows in figure below

How materials work. Compression Tension Bending Torsion

The... of a particle is defined as its change in position in some time interval.

What is a Force? Free-Body diagrams. Contact vs. At-a-Distance 11/28/2016. Forces and Newton s Laws of Motion

Section 2: Static Equilibrium II- Balancing Torques

Physics 8 Monday, October 28, 2013

Members Subjected to Torsional Loads

Johns Hopkins University What is Engineering? M. Karweit MATERIALS

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.

Name Date Period PROBLEM SET: ROTATIONAL DYNAMICS

Chapter 8 - Rotational Dynamics and Equilibrium REVIEW

Samantha Ramirez, MSE. Stress. The intensity of the internal force acting on a specific plane (area) passing through a point. F 2

, causing the length to increase to l 1 R U M. L Q P l 2 l 1

Physics 211 Sample Questions for Exam IV Spring 2013

OCR Physics Specification A - H156/H556

Transcription:

Static Equilibrium; Elasticity & Fracture

The Conditions for Equilibrium Statics is concerned with the calculation of the forces acting on and within structures that are in equilibrium. An object with forces acting on it that is not moving, is said to be in equilibrium.!! The first condition for equilibrium is that the forces along each coordinate axis add to zero.!! The second condition of equilibrium is that there be no torque around any axis; the choice of axis is arbitrary.! F = 0 "! = 0

Solving Statics Problems!! Choose one object at a time, and make a free-body diagram showing all the forces on it and where they act!! Choose a convenient coordinate system, and resolve the forces into their components.!! Write down the equilibrium equations for the forces!! Write down the torque equilibrium equation. Choose any axis perpendicular to the xy plane that might make the calculation easier. Pay careful attention to determining the lever arm for each force correctly. Give each torque a + or! sign to indicate torque direction.!! Solve these equations for the unknowns.

Problem(1) A board of mass M = 4.0 kg serves as a seesaw for two children. Child A has a mass of 30 kg and sits 2.5 m from the pivot point, P (his center of gravity is 2.5 m from the pivot). At what distance x from the pivot must child B, of mass 25 kg, place herself to balance the seesaw? Assume the board is uniform and centered over the pivot.

Stability and Balance An object in static equilibrium, if left undisturbed, will undergo no translational or rotational acceleration since the sum of all the forces and the sum of all the torques acting on it are zero. However, if the object is displaced slightly, three outcomes are possible: (1)! the object returns to its original position: stable equilibrium (2)! the object moves even farther from its original position: unstable equilibrium (3)! the object remains in its new position: neutral equilibrium.

Examples of Stability and Balance Stable : the object returns to its original position Balance: the object readjusts its center of gravity Unstable: the object moves even farther from its original position

Problem (2) A 1 kg ball is hung at the end of a 1 m long uniform rod. If the system balances at a point on the rod 0.25 m from the end holding the mass, what is the mass of the rod? a)! 1/4 kg b)! 1/2 kg c)! 1 kg d)! 2 kg e)! 4 kg 11kg same distance 1m X CM of rod m rod = 1 kg

Elasticity; Stress and Strain A model of a common physical system on which the force varies with position is a spring. If the spring is either stretched or compressed a small distance, "#, from its unstretched (equilibrium) configuration, the force exerted on the spring can be written as: F = k!l This equation is called Hooke's law after Robert Hooke. The Hooke s law is found to be valid for almost any solid material from iron to bone but it is valid only up to a point. If the force is too large, the object stretches excessively and eventually breaks.

Elasticity; Stress and Strain The stiffness of a rod (its ability to resist stretching) is also directly proportional to its cross-sectional area. Stress is defined to be the total force applied to an object divided by the cross-sectional area of the object. Stress = force area = F A!! Tensile stress: when sample is under tension (is being stretched)!! Compressive stress: when a sample is under compression (is being squeezed)!! Sheer stress: when a pair of parallel forces with opposite directions are applied to the surface of the object (It is the kind of stress applied by a pair of shears when it is cutting) The strain is the changes in length, "#, of a sample per unit of undistorted length, #, of the sample, change in length Strain = original length =!l l 0

Elasticity; Stress and Strain If we compare rods made of the same material but of different lengths and cross-sectional areas, it is found that for the same applied force, the change in length is proportional to the original length and inversely proportional to the cross-sectional area. So for a given force, the longer the object, the more it elongates and the thicker it is, the less it elongates.!l " F A l 0 or # $#!l = 1 E F A l 0 E is a constant of proportionality known as the elastic modulus, or Young's modulus; its value depends only on the material. The value of Young's modulus for various materials. Young modulus! Elastic modulus = Stress Strain = F A "l l 0 # $# Y = E = F A l 0 "l

Fracture The ultimate strengths of materials under tensile stress, compressional stress, and shear stress have been measured. If the stress is too great, the object will fracture. When designing a structure, it is a good idea to keep anticipated stresses less than 1/3 to 1/10 of the ultimate strength.

Problem (3) A 1.60-m-long steel piano wire has a diameter of 0.20 cm. How great is the tension in the wire if it stretches 0.25 cm when tightened? Young s modulus for steel is 200 x 10 9 (N/m 2 ).

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