Chapter 4 Macromechanical Analysis of a Laminate Objectives and Laminate Code Dr. Autar Kaw Department of Mechanical Engineering University of South Florida,

Slides:

Advertisements

Similar presentations

Structural scales and types of analysis in composite materials

Advertisements

Macromechanics of a Laminate

Aerospace Structures and Materials Lecture 22: Laminate Design.

Mechanics of Composite Materials

Laminated plates.

Chapter 4 Macromechanical Analysis of a Laminate Dr. Autar Kaw Department of Mechanical Engineering University of South Florida, Tampa, FL Courtesy.

Hygrothermal behavior of composite laminates

CHAPTER 4 MACROMECHANICAL ANALYSIS OF LAMINATES

Composites Design and Analysis Stress-Strain Relationship Prof Zaffar M. Khan Institute of Space Technology Islamabad.

Micromechanics Macromechanics Fibers Lamina Laminate Structure Matrix.

Chapter 5 Design and Analysis of a Laminate The Drive Shaft Problem Dr. Autar Kaw Department of Mechanical Engineering University of South Florida, Tampa,

M. A. Farjoo.  The stiffness can be defined by appropriate stress – strain relations.  The components of any engineering constant can be expressed in.

Mechanics of Materials – MAE 243 (Section 002) Spring 2008 Dr. Konstantinos A. Sierros.

Assist.Prof.Dr. Ahmet Erklig

Classical Laminated Plate Theory

MACROMECHANICS Ahmet Erkliğ.

CE 579: STRUCTRAL STABILITY AND DESIGN

MACROMECHANICS (Part 2)

PROBLEM-1 State of stress at a point is represented by the element shown. Determine the state of stress at the point on another element orientated 30

Ken Youssefi Mechanical Engineering Department 1 Normal & Shear components of stress Normal stress is perpendicular to the cross section,  (sigma). Shear.

1 THERMAL STRESSES Temperature change causes thermal strain Constraints cause thermal stresses Thermo-elastic stress-strain relationship (a) at T = T.

Chapter 4 Macromechanical Analysis of a Laminate Hygrothermal Loads Dr. Autar Kaw Department of Mechanical Engineering University of South Florida, Tampa,

Chapter 4 Macromechanical Analysis of a Laminate Laminate Analysis: Example Dr. Autar Kaw Department of Mechanical Engineering University of South Florida,

EML 4230 Introduction to Composite Materials

Civil Engineering Materials – CIVE 2110

ME 520 Fundamentals of Finite Element Analysis

Chapter 3 Micromechanical Analysis of a Lamina Ultimate Strengths of a Unidirectional Lamina Dr. Autar Kaw Department of Mechanical Engineering University.

Chapter 3 Micromechanical Analysis of a Lamina Elastic Moduli Dr. Autar Kaw Department of Mechanical Engineering University of South Florida, Tampa, FL.

Chapter 3 Micromechanical Analysis of a Lamina Coefficients of Thermal Expansion Dr. Autar Kaw Department of Mechanical Engineering University of South.

CTC / MTC 322 Strength of Materials

Chapter 5 Design and Analysis of a Laminate The Drive Shaft Problem Dr. Autar Kaw Department of Mechanical Engineering University of South Florida, Tampa,

Strength of Materials Outline Overview AXIALLY LOADED MEMBERS THIN-WALLED CYLINDER GENERAL STATE OF STRESS PLANE STRESS + MOHR’S CIRCLE PLANE STRAIN +

EML 4230 Introduction to Composite Materials

EML 4230 Introduction to Composite Materials

Mechanics of Materials – MAE 243 (Section 002) Spring 2008

Chapter 2 Macromechanical Analysis of a Lamina 2D Stiffness and Compliance Matrix for Unidirectional Lamina Dr. Autar Kaw Department of Mechanical Engineering.

Chapter 3 Micromechanical Analysis of a Lamina Volume Fractions, Weight Fractions, Density, and Void Content Dr. Autar Kaw Department of Mechanical Engineering.

EXPLORATION GEOPHYSICS THE EXPLORATION TASK PLAN EXPLORATION APPROACH FOR A MATURE TREND GATHER DATA FOR A MATURE TREND DEVELOP PLAY PROSPECT FRAMEWORK.

Mechanics of Materials

Copyright Kaplan AEC Education, 2005 Mechanics of Materials Outline Overview AXIALLY LOADED MEMBERS, p. 262 Modulus of Elasticity Poisson’s Ratio Thermal.

Stress and Strain ( , 3.14) MAE 316 – Strength of Mechanical Components NC State University Department of Mechanical & Aerospace Engineering Stress.

EML 4230 Introduction to Composite Materials

☻ 1.0 Axial Forces 2.0 Bending of Beams M M

Testing Methods for Composites

EML 4230 Introduction to Composite Materials

Chapter 2 Macromechanical Analysis of a Lamina Tsai-Hill Failure Theory Dr. Autar Kaw Department of Mechanical Engineering University of South Florida,

Mechanics of Materials Inter - Bayamon Review 1 FE Review Mechanics of Materials Professor: Dr. Omar E. Meza Castillo

Chapter 2 Macromechanical Analysis of a Lamina Review of Definitions Dr. Autar Kaw Department of Mechanical Engineering University of South Florida, Tampa,

Chapter 2 Macromechanical Analysis of a Lamina Maximum Stress Failure Theory Dr. Autar Kaw Department of Mechanical Engineering University of South Florida,

Principal Stresses and Strain and Theories of Failure

Mechanics of Materials Instructor: Dr. Botao Lin & Dr. Wei Liu Page 1 Chapter 10 Strain Transformation 2015 Mechanics of Materials Foil gauge LVDT.

Pendahuluan Material Komposit

Pendahuluan Material Komposit

Pendahuluan Material Komposit

Pendahuluan Material Komposit

Pendahuluan Material Komposit

EML 4230 Introduction to Composite Materials

EML 4230 Introduction to Composite Materials

EML 4230 Introduction to Composite Materials

CLASSIC LAMINATION THEORY Zdeněk Padovec

CTC / MTC 222 Strength of Materials

CLASSIC LAMINATION THEORY Zdeněk Padovec

EML 4230 Introduction to Composite Materials

Laminates of Orthotropic plies

EML 4230 Introduction to Composite Materials

EML 4230 Introduction to Composite Materials

EML 4230 Introduction to Composite Materials

EML 4230 Introduction to Composite Materials

EML 4230 Introduction to Composite Materials

Presentation transcript:

Chapter 4 Macromechanical Analysis of a Laminate Objectives and Laminate Code Dr. Autar Kaw Department of Mechanical Engineering University of South Florida, Tampa, FL Courtesy of the Textbook Mechanics of Composite Materials by Kaw

 Understand the code for laminate stacking sequence  Develop relationships of mechanical and hygrothermal loads applied to a laminate to strains and stresses in each lamina  Find the elastic stiffnesses of laminate based on the elastic moduli of individual laminas and the stacking sequence  Find the coefficients of thermal and moisture expansion of a laminate based on elastic moduli, coefficients of thermal and moisture expansion of individual laminas, and stacking sequence

Graphite/Epoxy 0 Boron/Epoxy 45 Boron/Epoxy -45 Boron/Epoxy -45 Boron/Epoxy 45 Graphite/Epoxy 0

elastic moduli the stacking position thickness angles of orientation coefficients of thermal expansion coefficients of moisture expansion

(4.1)

N x = normal force resultant in the x direction (per unit length) N y = normal force resultant in the y direction (per unit length) N xy = shear force resultant (per unit length)

M x = bending moment resultant in the yz plane (per unit length) M y = bending moment resultant in the xz plane (per unit length) M xy = twisting moment resultant (per unit length)