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Chapter 9 - 1

ISSUES TO ADDRESS...

• How do cracks that lead to failure form?

• How is fracture resistance quantified? How do the fracture resistances of the different material classes compare?

• How do we estimate the stress to fracture?

• How do loading rate, loading history, and temperatureaffect the failure behavior of materials?

Chapter 9: Mechanical Failure

Chapter 9 - 3

Fracture mechanisms

An oil tanker fractured in a brittle manner by crack propagation around its girth(cyclic loading from waves).

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Chapter 9 - 4

Ductile failure:•Significant plastic deformation •Often one piece

Example: Pipe Failures

Brittle failure:

• Little or no plastic deformation

• Catastrophic

• Often many pieces

• Ductility is a function of temperature, strain rate and stress state.

Chapter 9 - 5

Ductile vs Brittle Failure

Large Moderate%AR or %EL Small

• Ductile fracture is

usually more desirable

than brittle fracture!

• Classification:

Ductile:

• Warning before fracture

•Needs more strain energy

Brittle:

•No warning

• Pure gold and lead at room

temperature

• Other metals, polymers, and

glasses at high temperatures

Very Ductile

ModeratelyDuctile

BrittleFracturebehavior:

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Chapter 9 - 7

• Evolution to failure:

10 mm

Moderately Ductile Failure

neckingvoid growth and linkage

Cup-and-cone fracture

void nucleation

shearing at surface

fracture

• A steel fracture surfaces

Particles/defects serve as voidnucleation sites

Chapter 9 - 9

Ductile vs. Brittle Failure

Cup-and-cone fracture Brittle fracture

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Chapter 9 - 10

Ductile Failure

Chapter 9 - 12

Brittle Fracture Surfaces

Intergranular Intragranular

Difference?

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Chapter 9 - 13

Brittle Fracture Surfaces

• Intergranular (between grains)

A transgranular fracture surface: SEM

fractograph of ductile cast iron

• For most brittle crystalline materials

Crack propagation = Cleavage: successive and repeated breaking

of atomic bonds along specific crystallographic planes

Chapter 9 - 15

Brittle Fracture Surfaces

• Intragranular (within grains)

• Occurrence of processes that weaken or embrittle grain

boundary regions.

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Chapter 9 - 17

• Stress-strain behavior (Room Temp.)

Ideal vs Real Materials

σ

ε0.1

perfect materials- no flaws

carefully produced glass fiber

typical ceramic typical strengthened metaltypical polymer

• Presence of very small, microscopic flaws or cracks at the

surface and within the interior of a body of material.

TS << TSengineeringmaterials

perfectmaterials

Chapter 9 - 18

Ideal vs Real Materials

Reprinted w/

permission from R.W.

Hertzberg,

"Deformation and

Fracture Mechanics

of Engineering

Materials", (4th ed.)

Fig. 7.4. John Wiley

and Sons, Inc., 1996.

• DaVinci (500 yrs ago!) observed...- the longer the wire,

the smaller the load for failure.

• Reasons:• Flaws cause premature failure

• An applied stress may be amplified or concentrated at the tip of the flaws

• Larger samples contain more flaws!

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Chapter 9 - 19

• Flaws:

�reduce cross section area

�are stress concentrators!

(stress raiser)

Chapter 9 - 20

ρt

Concentration of Stress at Crack Tip

where•σo = applied stress•σm = stress at crack tip•a = length of a surface crack or half of the length of an internal crack.

•ρt = radius of curvature

•Kt= stress concentration factor

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Chapter 9 - 21

Engineering Fracture Design

r/h

sharper fillet radius

increasing w/h

0 0.5 1.01.0

1.5

2.0

2.5

Kt

�Avoid sharp corners!�Avoid sudden change in dimensions!

σ

r , fillet

radius

w

h

o

σmax