Presentation is loading. Please wait.

Presentation is loading. Please wait.

Tensile Strength of Continuous Fiber-Reinforced Lamina

Published bySteven Logan Modified over 8 years ago

Similar presentations

Presentation on theme: "Tensile Strength of Continuous Fiber-Reinforced Lamina"— Presentation transcript:

1 Tensile Strength of Continuous Fiber-Reinforced Lamina
M.E – Lecture 6 Dr. B.J. Sullivan

2 Strength of a Continuous Fiber Reinforced Lamina
For the orthotropic lamina under simple uniaxial or shear stress, there are 5 strengths: = Longitudinal tensile strength = Longitudinal compressive strength = Transverse tensile strength = Transverse compressive strength = Shear strength (See Fig. 4.1)

3 Longitudinal Uniaxial Loading
Stress-strain curves for uniaxial and shear loading showing lamina strengths and ultimate strains. Longitudinal Uniaxial Loading Tension Compression

4 Transverse Uniaxial Loading
Stress-strain curves for uniaxial and shear loading showing lamina strengths and ultimate strains. Transverse Uniaxial Loading Tension Compression

5 Stress-strain curves for uniaxial and shear loading showing lamina strengths and ultimate strains.

6 Assuming linear elastic behavior up to failure:
(4.1) where are the corresponding ultimate strains.

7 Transverse tensile strength ST(+) is low because of stress concentration in matrix at fiber/matrix interfaces. Fibers are, in effect, “holes” in matrix under transverse or shear loading.

8 Material SL(+) ksi(MPa) SL(-) ksi(Mpa) ST(+) ksi(Mpa) ST(-) ksi(Mpa)
Typical values of lamina strengths for several composites Material SL(+) ksi(MPa) SL(-) ksi(Mpa) ST(+) ksi(Mpa) ST(-) ksi(Mpa) SLT ksi(Mpa) Boron/5505 boron/epoxy vf = 0.5 (*) 230 (1586) 360 (2482) 9.1 (62.7) 35.0 (241) 12.0 (82.7) AS/3501 graphite/epoxy vf = 0.6 (*) 210 (1448) 170 (1172) 7.0 (48.3) 36.0 (248) 9.0 (62.1) T300/5208 graphite/epoxy vf = 0.6 (*) 6.5 (44.8) Kevlar 49/epoxy aramid/epoxy vf = 0.6 (*) 200 (1379) 40 (276) 4.0 (27.6) 9.4 (64.8) 8.7 (60.0) Scotchply E-glass/epoxy vf = 0.45 (*) 160 (1103) 90 (621) 20.0 (138) E-glass/ E-glass/vinylester vf = 0.30 (*) 85 (584) 116 (803) 6.2 (43) 27.1 (187) 9.3 (64.0)

9 Micromechanics Models for Strength
Strength more sensitive to material and geometric nonhomogeneity than stiffness, so statistical variability of strength is usually greater than that of stiffness. Different failure modes for tension and compression require different micro -mechanical models.

10 Statistical distribution of tensile strength for boron filaments
Statistical distribution of tensile strength for boron filaments. (From Weeton, J.W., Peters, D.M., and Thomas, K.L., eds Engineers’ Guide to Composite Materials. ASM International, Materials Park, OH. Reprinted by permission of ASM International.)

11 Tensile Failure of Lamina Under Longitudinal Stress
Representative stress-strain curves for typical fiber, matrix and composite materials (matrix failure strain greater than fiber failure strain) Stress (a) Fiber Failure Mode Fiber Typical of polymer matrix composites Composite Matrix Composite Strain

12 Tensile Failure of Lamina Under Longitudinal Stress
Representative stress-strain curves for typical fiber, matrix and composite materials (fiber failure strain greater than matrix failure strain) Stress Fiber (a) Matrix Failure Mode Typical of ceramic matrix composites Composite Matrix Strain

13 Longitudinal Tensile Strength
Fiber failure mode (ef1(+)<em1(+)); polymer matrices Rule of mixtures for longitudinal stress: when (3.22) (4.22) (only valid if vf is large enough)

14 Longitudinal Tensile Strength
Critical fiber volume fraction, vfcrit when (4.23) Once fibers fail, when vf <vfcrit (4.24)

15 Longitudinal Tensile Strength
This defines (4.25) In most of the cases, vfcrit is very small, so (4.22)

16 Variation of composite longitudinal tensile strength with fiber volume fraction for composites having matrix failure strain greater than fiber failure strain Strength Equation (4.22) Equation (4.24) 1.0 Fiber Volume Fraction

17 Variation of composite longitudinal tensile strength with fiber volume fraction for composites having fiber failure strain greater than matrix failure strain Strength Equation (4.27) Equation (4.26) Fiber Volume Fraction

18 Longitudinal Tensile Strength
(b) Matrix Failure Mode; ceramic matrices (4.26) Fibers can withstand ef1(+)>em1(+) and remaining area of fibers is such that (4.27) which applies for practical vf (see Fig – previous two slides)

Download ppt "Tensile Strength of Continuous Fiber-Reinforced Lamina"

Similar presentations

Structural scales and types of analysis in composite materials

Structural scales and types of analysis in composite materials
Mechanics of Composite Materials

Mechanics of Composite Materials
Chap.8 Mechanical Behavior of Composite

Chap.8 Mechanical Behavior of Composite
Composites Design and Analysis Stress-Strain Relationship Prof Zaffar M. Khan Institute of Space Technology Islamabad.

Composites Design and Analysis Stress-Strain Relationship Prof Zaffar M. Khan Institute of Space Technology Islamabad.
Professor Joe Greene CSU, CHICO

Professor Joe Greene CSU, CHICO
Chapter 11 Mechanical Properties of Materials

Chapter 11 Mechanical Properties of Materials
Micromechanics Macromechanics Fibers Lamina Laminate Structure Matrix.

Micromechanics Macromechanics Fibers Lamina Laminate Structure Matrix.
Normal Strain and Stress

Normal Strain and Stress
Micromechanics Macromechanics Fibers Lamina Laminate Structure Matrix.

Micromechanics Macromechanics Fibers Lamina Laminate Structure Matrix.
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.

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.
Modeling of CNT based composites: Numerical Issues

Modeling of CNT based composites: Numerical Issues
Shear - Tensile - Compression Stresses Slip Ted 126 Spring 2007.

Shear - Tensile - Compression Stresses Slip Ted 126 Spring 2007.
M. A. Farjoo.  The stiffness can be defined by appropriate stress – strain relations.  The components of any engineering constant can be expressed in.

M. A. Farjoo.  The stiffness can be defined by appropriate stress – strain relations.  The components of any engineering constant can be expressed in.
CHAPTER 7: MECHANICAL PROPERTIES

CHAPTER 7: MECHANICAL PROPERTIES
Mechanics of Materials II UET, Taxila Lecture No. (3)

Mechanics of Materials II UET, Taxila Lecture No. (3)
Assist.Prof.Dr. Ahmet Erklig

Assist.Prof.Dr. Ahmet Erklig
CH3 MICROMECHANICS Assist.Prof.Dr. Ahmet Erklig. Ultimate Strengths of a Unidirectional Lamina.

CH3 MICROMECHANICS Assist.Prof.Dr. Ahmet Erklig. Ultimate Strengths of a Unidirectional Lamina.
Chapter 12 Equilibrium and Elasticity Key contents Conditions for mechanical equilibrium Indeterminate structure Stress, strain, modulus of elasticity.

Chapter 12 Equilibrium and Elasticity Key contents Conditions for mechanical equilibrium Indeterminate structure Stress, strain, modulus of elasticity.
Lecture 26: Mechanical Properties I: Metals & Ceramics

Lecture 26: Mechanical Properties I: Metals & Ceramics
Composite Strength and Failure Criteria

Composite Strength and Failure Criteria

Similar presentations

Ads by Google