Objectives Students will be able to label a stress-strain diagram correctly indicating. Ultimate stress, yield stress and proportional limit. Students.

Slides:

Advertisements

Similar presentations

Stress, strain and more on peak broadening

Advertisements

2E4: SOLIDS & STRUCTURES Lecture 9

MECHANICAL PROPERTIES OF MATERIALS

Professor Joe Greene CSU, CHICO

Solid Materials.

LECTURER 2 Engineering and True Stress-Strain Diagrams

Normal Strain and Stress

Chapter 3 Mechanical Properties of Materials

MECHANICAL PROPERTIES OF MATERIALS

The various engineering and true stress-strain properties obtainable from a tension test are summarized by the categorized listing of Table 1.1. Note that.

EXPERIMENT # 3 Instructor: M.Yaqub

Mechanics of Materials II

Mechanics of Materials II

ENGR 225 Section

MECHANICAL PROPERTIES OF MATERIALS

Mechanics of Elastic Materials

Lecture # 6 Mechanical Properties of Metals Intended learning Outcomes: After the end of this lecture the student should be able to: Define stress –strain.

Mechanics of Materials Goal:Load Deformation Factors that affect deformation of a structure P PPP Stress: intensity of internal force.

Elastic Stress-Strain Relationships

CHAPTER OBJECTIVES Show relationship of stress and strain using experimental methods to determine stress-strain diagram of a specific material Discuss.

Mechanical Properties

Hooke’s Law and Modulus of Elasticity ( )

FYI: All three types of stress are measured in newtons / meter2 but all have different effects on solids. Materials Solids are often placed under stress.

CHE 333 Class 11 Mechanical Behavior of Materials.

Class #1.2 Civil Engineering Materials – CIVE 2110

STRENGTH OF MATERIALS John Parkinson ©.

Unit V Lecturer11 LECTURE-I  Introduction  Some important definitions  Stress-strain relation for different engineering materials.

STRUCTURES Outcome 3 Gary Plimer 2008 MUSSELBURGH GRAMMAR SCHOOL.

Mechanicial Properties of Materials

Mechanics of Materials, 5e Chapter 1 Tension, Compression, and Shear.

Manufacturing Processes

4 Mechanical Properties of Biomaterials CHAPTER 4.1 Introduction

Poisson's ratio, n • Poisson's ratio, n: Units:

ME Manufacturing Systems Introduction To Manufacturing Systems by Ed Red Introduction To Manufacturing Systems by Ed Red.

Mechanical Properties of Materials

1.To understand the keywords associated with the deformation of different types of solids 2.To be able to calculate stress, strain and hence Young’s modulus.

1.To understand the keywords associated with the deformation of different types of solids 2.To be able to calculate stress, strain and hence Young’s modulus.

 2005 Pearson Education South Asia Pte Ltd 3. Mechanical Properties of Materials 1 CHAPTER OBJECTIVES Show relationship of stress and strain using experimental.

1.To understand that once the elastic limit has been exceeded, the force-extension graphs for loading and unloading are unequal 2.To know that such curves.

Haseeb Ullah Khan Jatoi Department of Chemical Engineering UET Lahore.

Group 2 presentation Q : stress and strain curve presentation.

Mechanical & Aerospace Engineering West Virginia University Elastic Properties of Materials, Tensile Test Xingbo Liu.

SIMPLE STRESS & STRAIN ► EN NO GUIDED BY EN NO PROF. V.R.SHARMA GEC PALANPUR APPLIED MECHANICS DEPARTMENT.

PROPERTIES OF MATERIALS ENF 150 Chapter 10: Properties of Materials.

The various engineering and true stress-strain properties obtainable from a tension test are summarized by the categorized listing of Table 1.1. Note that.

DEPARTMENT OF MECHANICAL AND MANUFACTURING ENGINEERING

CHAPTER OBJECTIVES Show relationship of stress and strain using experimental methods to determine stress-strain diagram of a specific material Discuss.

Mechanics of Materials

Chapter 3 – Mechanical Properties of Material

Mechanics of Materials Dr. Konstantinos A. Sierros

Chapter 7 Deforming Solids.

Chapter 3 Mechanical Properties of Materials

Manufacturing Systems

Poisons Ratio Poisons ratio = . w0 w Usually poisons ratio ranges from

Experiment #1 Tension Test

Eng. Ahmed Al-Afeefy Eng. Ibrahim Aljaish

Tensile Testing The following MATERIAL PROPERTIES can be evaluated / determined by TENSILE TESTING: STRENGTH DUCTILITY ELASTICITY STIFFNESS.

Mechanical Properties: 1

Applied Technology High School (ATHS)

LECTURER 9 Engineering and True Stress-Strain Diagrams

Elastic & Plastic behavior of Materials

Mechanical properties of metals Stress and Strain in metals

PDT 153 Materials Structure And Properties

LECTURER 2 Engineering and True Stress-Strain Diagrams

Describing deformation

CHAPTER OBJECTIVES Show relationship of stress and strain using experimental methods to determine stress-strain diagram of a specific material Discuss.

Mechanical Properties Of Metals - I

Mechanical Property 기계적 성질

Presentation transcript:

Objectives Students will be able to label a stress-strain diagram correctly indicating. Ultimate stress, yield stress and proportional limit. Students will be able to calculate yield stress using the offset method. Students will be able to calculate true stress.

FIG. 1-10 Stress-strain diagram for a typical structural steel in tension (not to scale) A- proportional limit; B – Yield stress; D – Ultimate stress; E – Fracture stress; E’ – True Fracture Stress

In reality samples will often ”neck” In reality samples will often ”neck”. This necking leads to a reduction in cross sectional area and thus a localized increase in the stress in the necked region. True stress is therefore F/Ameasured

Stress-strain diagram for a typical structural steel in tension (drawn to scale) For plastic materials such as steels the yielding, strain hardening and necking regions can be very large compared to the elastic region.

Sometimes stress-strain curves are drawn with two scales so that the elastic properties can be easily read. Figure: 03-06

Typical stress-strain diagram for an aluminum alloy. Aluminum and aluminum alloys often do not have a well defined yield stress.

Arbitrary yield stress determined by the offset method For materials such as aluminum the off-set method is often used to assign a value for the yield stress by drawing a line parallel to the elastic curve at an offset of 0.002 (0.2%). The point of intersection is then the yield stress.

Stress-strain curves for two kinds of rubber in tension Rubber is a non-linear elastic material. The difference in stiffness of two rubbers is evident due to a difference in the slope of the curves.

Typical stress-strain diagram for a brittle material showing the proportional limit (point A) and fracture stress (point B) No yielding, or necking is evident. For brittle materials that fail the pieces still fit together e.g. glass or ceramics.

Stress-strain diagram for copper in compression For materials such as aluminum the off-set method is often used to assign a value for the yield stress by drawing a line parallel to the elastic curve at an offset of 0.002 (0.2%). The point of intersection is then the yield stress.

Problems A tension test was performed on a steel specimen having an original diameter of 0.503 in and gauge length of 2.00 in. Using the data listed in the table calculate and plot the stress strain diagram.

The stress-strain diagram for a steel alloy having an original diameter 0f 0.5 in and gauge length 2.0in is given in the figure. Determine the load on the sample that will cause yielding and the ultimate tensile load that the specimen will support. Figure: 03-20-04P3.5-07