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Failure

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This means that when a load operates on a crack in the manner shown in Figure 9 ... The load is applied as an. impact blow from a. weighted pendulum hammer. ... – PowerPoint PPT presentation

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Title: Failure


1
Failure
  • Chapter 9

2
  • Simple fracture is separation of a body into two
    or more pieces in response to stress at T lower
    than melting point.
  • Our discussion is confined to fractures resulting
    from uniaxial tensile loads.
  • There are two types of fracture for engineering
    materials

cup-cone (ductile) fracture in Al
brittle fracture in a mild steel
In ductile fracture, materials experience
plastic deformation before fracture.
In brittle fracture, materials experience little
or no plastic deformation.
3
  • A typical fracture process has two steps
  • 1)crack formation
  • 2)propagation-this is the step determining the
    mode of the fracture.
  • For example ductile fracture proceeds slowly as
    the crack length is extended. This type of crack
    is called stable. On the other hand, cracks
    spread rapidly with very little accompanying
    plastic deformation. This type of cracks are
    called unstable.

4

Ductile fracture is generally preferred since the
plastic deformation prior to fracture can be
accepted as a warning so that preventive measures
can be taken. Most of the metal alloys are
ductile and they experience ductile frature under
stress. But ceramics are brittle. Polymers
exhibits the two types of fracture. DUCTILE
FRACTURE For extremely soft metals
There is about 100 reduction in area. pure gold
or lead at RT or some metals polymers and
inorganic glasses at high T.
Most common tensile fracture profile
Necking is followed by frature.
5
  • More detailed progress of the fracture is
    illustrated here

This type of fracture is also called cup and cone
fracture since one of the mating surfaces is in
the form of a cup and the other like a cone.
6
  • BRITTLE FRACTURE
  • Propagation of the crack is fast.

The motion of the crack is perpendicular to
applied stress.
7
  • Brittle crystalline materials have successive and
    repeated breaking of
  • atomic bonds along specific crystalline plane and
    fracture cracks pass
  • through grains. The process is called cleavage
    and type of fracture is
  • called transgranular.

8
  • Crack propagation is sometimes along the grain
    boundaries and this fracture is called
    intergranular.

9
  • Fracture Mechanics This research area is about
    the relationships
  • between material properties, stress level, the
    presence of crack
  • producing flaws and crack propagation mechanisms.
  • The measured fracture strengths for brittle
    materials are lower than those predicted by
    theoretical calculations. This difference is
    mainly
  • due to presence of very small microscopic flaws
    or cracks already existing within the material.
    The applied stress is amplified around the flaws
    as shown below

The flaws are sometimes called stress raisers due
to their ability to amplify the applied stress in
their locale.
10
  • If the crack has an elliptical shape and is
    oriented perpendicular to the applied stress,
    then the maximum stress at the crack tip is
    calculated using the equation of

where sm is the maximum stress at the crack tip
s0 is the magnitude of the nominal
applied tensile stress ?t is the radius
of curvature of the crack tip a is the
length of a surface crack or half of the length
of an internal crack
The ratio of sm/ s0 is denoted as the stress
concentration factor Kt
This factor shows the degree to which an external
stress is amplified at the tip of a crack.
11
  • The effect of stress raiser in brittle fracture
    is more significant than in ductile fracture of
    the materials. In ductile material, the plastic
    deformation indicates the point when maximum
    stress exceeds the yield strength. This causes a
    more uniform distribution of stress in the
    vicinity of the stress raiser. But this does not
    occur in brittle materials.
  • The critical stress (sc) required for crack
    propagation in a brittle material can be
    calculated using the equation below

If the magnitude of a tensile stress at the tip
of a flaw exceeds the value of this critical
stress, then acrack forms and then propagates,
which results in fracture
12
  • Fracture Toughness (Kc) is a measure of materials
    resistance to brittle fracture when a crack is
    present.

sc is the critical stress for crack propagation a
is the crack length Y is a dimensionless
parameter and its value depends on both crack
adn specimen sizes and geometries, and load
application.
Y1
Y1.1
13
  • For relatively thin specimens, the value of Kc
    depends on the thickness. However, if the
    thickness is much greater than the crack
    dimensions, Kc becomes independent of thickness
    and under these conditions plain strain
    condition exists.
  • This means that when a load operates on a crack
    in the manner shown in Figure 9-11a (previous
    slight) , there is no strain component
    perpendicular to the front and back faces.
  • Plain strain fracture toughness is calculated by

The subscript of K denotes the plain strain
fracture toughness for mode I crack displacement.
Plain strain fracture toughness is lower for
brittle materials while it is higher for ductile
materials.
KIC is a fundamental material property depending
on many factors, such as, T, strain rate, and
microstructure.
14
  • The magnitude of KIC decreases with increasing
    strain rate and decreasing T.
  • KIC decreases as yield strength is improved by
    solid solution or dispersion additions or by
    strain hardening.
  • KIC increases with reduction in grain size.
  • DESIGN USING FRACTURE MECHANICS
  • There are three variables that must be considered
    for fracture of a component
  • The fracture toughness (KC) or plain strain
    fracture toughness (KIC)
  • The imposed stress (s)
  • The flaw size (a)
  • When designing a component first decide which of
    these variables are
  • constrained and which are subject to design
    control.

15
  • Once a combination of two factors is fixed, then
    the third factor is automatically fixed.
  • If KIC and a are fixed, then

If stress level and plain strain fracture
toughness are fixed, then the maximum allowable
flaw size is
Sizes of the flaws are measured by nondestructive
tests (NDT).
16
Impact Fracture Testing
  • There are two standardized tests Charpy and Izod
  • The tests are used to measure the impact energy,
    which is also called notch toughness.
  • For both of the tests, the specimen is in the
    shape of a bar with square X-section and a
    V-notch is machined.

17
The main difference b/w Izod and Charpy is
the manner of specimen support as shown here.
The load is applied as an impact blow from a
weighted pendulum hammer. It is released from a
fixed height (h). Pendulum strikes and fractures
the specimen at the notch. The
pendulum continues its swing rising to maximum
height h. The energy absorption, computed from
the difference between h and h is a measure of
the impact energy.
18
  • Fracture properties of the materials are defined
    by plane strain fracture toughness and impact
    energy. The later is easier to measure than
    former and there is no correlation between them.
  • Ductile to Brittle Transition
  • One of the most commonly used areas of Charpy and
    Izod tests is determination of ductile-to-brittle
    transition that a material experiences with
    decreasing temperature.

19
  • Appearance of the fracture surface is also
    indicative of the transition.

ductile (fibrous)
brittle (shiny)
Transition has both types of surfaces and
corresponds to a temperature range. Metal alloys
with FCC structures (Al and Cu) remain ductile
even at extremely low T. BCC and HCP alloys
experience this transition. The grain size and
microstructure of the materials controls
transition T. Decreasing the grain size lowers
the transition T and increasing C content raises
the CVN transition of the steels.
20
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21
  • Fatigue
  • It is a form of failure occurred when the
    structures are exposed to dynamic and fluctuating
    stresses. Failure as a result of fatigue can
    occur at a stress level lower than the tensile or
    yield strength.
  • 90 of the fractures in metallic materials is due
    to fatigue.
  • Cyclic stresses Applied stress may be axial
    (tension or compression), flexural (bending) or
    torsional (twisting).
  • There are three modes of stress-time
  • Regular sinusoidal time dependence and amplitude
    is symmetrical about a mean zero stress level,
    alternating from max. tensile stress to max.
    compressive stress.

22
  • 2) Repeated stress cycle maxima and minima are
    asymmetrical relative to zero stress level.

3) Random stress cycle
Mean stress Range of stress Amplitude Stress
ratio
23
  • The S-N Curve
  • For testing fatigue, a rotating bending test is
    employed.

The compression and tensile stresses are imposed
on the specimen by bending and rotating
simultaneously. A series of tests is made by
subjecting the specimen to the stress cycles
(cycle between max. and min. stress) and number
of cycles until the failure is counted. Based on
the data obtained S-N curve is plotted.
24
  • Important observations are made using S-N curves.

The higher the magnitude of the stress, the
smaller the number of cycles before the failure.
For some ferrous and titanium alloys, the S-N
curve becomes horizontal at higher N values and
this is called as fatigue or endurance limit.
Below this limit fatigue failure does not occur.
For many steels, the fatigue limit is between
35 to 60 of the tensile strength. For most
nonferrous alloys, there is no fatigue limit and
there is a continuous decrease in strength for
increasing number of cycles.
25
  • There is a significant scatter in fatigue data
    leading to significant design
  • uncertainities. This is why fatigue data are
    shown on constant
  • probability curves. The P value of the curve is
    the probability of failure.

At a stress of 200 MPa, 1 of the specimens to
fail at about 106 cycles and 50 to fail at
about 2x107 cycles. There are two domains in
fatigue behavior. For the short fatigue lives
with high loads, not only elastic but plastic
deformation of the material is observed also.
This domain is called low-cycle fatigue
(N104-105). For long-cycle fatigue, deformations
are totally elastic and longer lives result.
26
  • Factors Affecting Fatigue Life
  • 1)mean stress S-N plot shows the dependence of
    fatigue life to stress amplitude. However mean
    stress also affects the fatigue life.
  • As seen, increasing the mean stress level
    decreases the fatigue life.

27
  • 2) Surface effects In general, the maximum
    stress within a component occurs at the surface
    of the material. Therefore, most cracks originate
    at the surface.
  • Fatigue life has been found to be sensitive to
    surface conditions. Many factors influence
    fatigue resistance including design criteria and
    surface treatments.
  • Design factors Any notch or geometrical
    discontinuity acts as a stress raiser and fatigue
    crack initiation site. The probability of
    fatigue failure can be reduced by avoiding
    structural irregularities in the design.

Surface treatments Surface markings during
machining can increase the probability of
fatigue failure. The surface finish by polishing
improves fatigue life significantly. One of the
techniques is imposing residual compressive
stresses within a thin outer surface layer to
nullify the syrface tensile stress. Case
hardening is a technique increasing the hardness
and fatigue life of steel alloys. this is
accomplished by carburizing and nitriding process.
28
Creep Materials exposed to static mechanical
stresses and high temperatures deform, which is
specifically called as creep. Creep limits the
lifetime of a part and undesirable. It is
observed in all of the materials. For metals, it
becomes important at T greater than about 0.4Tm.
29
  • A typical creep test consists of subjecting a
    specimen to a constant load or stress while
    maintaining the temperature constant.
  • Typical constant load creep behavior of metals

Instantenous deformation is usually elastic.
After this deformation, there are three
stages Primary or transient creep creep rate
diminishes with time. Material resistance to
creep increases and this is same strain
hardening. Secondary or steady state creep rate
of creep is constant. Tertiary creep
acceleration in rate and ultimate failure.
30
  • The slope of the secondary portion of the creep
    curve is an important parameter. It is called as
    minimum or steady state creep rate (es).
  • Time to rupture is also anothe rdesign parameter
    used.
  • Stress and Temperature Effects on Creep
  • With increasing stress or temperature
  • instantenous strain at the time of stress
    application increases
  • steady state creep rate is increased
  • the rupture lifetime is diminished.

31
Creep characteristics of the metals are affected
by melting T, elastic modulus, and grain size.
The higher the melting temperature, the greater
the elastic modulus and the larger the grain
size, the better is a materials resistance to
creep. Smaller grains permit more grain boundary
sliding.
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