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Chapter 7: Mechanical Properties

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Title: Chapter 7: Mechanical Properties


1
Chapter 7 Mechanical Properties
Why mechanical properties?
Need to design materials that will withstand
applied load and in-service uses for
Bridges for autos and people
MEMS devices
skyscrapers
Space elevator?
Space exploration
2
Chapter 7 Mechanical Properties
ISSUES TO ADDRESS...
Stress and strain Normalized force and
displacements.
Elastic behavior When loads are small.
Plastic behavior dislocations and permanent
deformation
  • Toughness, ductility, resilience, toughness,
    and hardness
  • Define and how do we measure?
  • Mechanical behavior of the various classes of
    materials.

3
Stress and Strain
Stress Force per unit area arising from
applied load.
Tension, compression, shear, torsion or any
combination.
Stress s force/area
Strain e physical deformation response of
a material to stress, e.g., elongation.
4
Engineering Stress
Tensile stress, s
Shear stress, t
Stress has units N/m2 (or lb/in2 )
5
Pure Tension
Pure Compression
stress
strain
Elastic response
Pure Shear
stress
strain
Elastic response
Pure Torsional Shear
6
Common States of Stress
Simple tension cable
Ski lift (photo courtesy P.M. Anderson)
Simple shear drive shaft
Note t M/AcR here.
7
Common States of Stress
Simple compression
(photo courtesy P.M. Anderson)
Note compressive structural member (s lt 0).
(photo courtesy P.M. Anderson)
8
Common States of Stress
Bi-axial tension
Hydrostatic compression
Pressurized tank
(photo courtesy P.M. Anderson)
(photo courtesy P.M. Anderson)
s lt 0
h
9
Engineering Strain
Tensile strain
Lateral (width) strain
Shear strain
Strain is always dimensionless.
10
Elastic Deformation
Elastic means reversible!
11
Plastic Deformation of Metals
Plastic means permanent!
12
Strain Testing
Tensile test machine
Tensile specimen
Often 12.8 mm x 60 mm
Adapted from Fig. 7.2, Callister Rethwisch 3e.
Other types -compression brittle
materials (e.g., concrete) -torsion
cylindrical tubes, shafts.
13
Linear Elasticity
Units E GPa or psi
Modulus of Elasticity, E (also known as
Young's modulus)
Hooke's Law s E e
14
Example Hookes Law
Hooke's Law s E e (linear elastic
behavior) Copper sample (305 mm long) is pulled
in tension with stress of 276 MPa. If deformation
is elastic, what is elongation?
For Cu (polycrystalline), E 110 GPa.
Hookes law involves axial (parallel to applied
tensile load) elastic deformation.
15
Elastic Deformation
Elastic means reversible!
16
Mechanical Properties
  • Recall Bonding Energy vs distance plots

tension
compression
Adapted from Fig. 2.8 Callister Rethwisch 3e.
17
Mechanical Properties
  • Recall Slope of stress strain plot (proportional
    to the E) depends on bond strength of metal

E larger
E smaller
Adapted from Fig. 7.7, Callister Rethwisch 3e.
18
Elasticity of Ceramics
And Effects of Porosity E E0(1 - 1.9P 0.9 P2)
Elastic Behavior
Neither Glass or Alumina experience plastic
deformation before fracture!
19
Comparison of Elastic Moduli
Silicon (single xtal) 120-190 (depends on
crystallographic direction) Glass (pyrex)
70 SiC (fused or sintered) 207-483 Graphite
(molded) 12 High modulus C-fiber
400 Carbon Nanotubes 1000
Normalize by density, 20x steel wire. strength
normalized by density is 56x wire.
20
Polymers Tangent and Secant Modulus
  • Tangent Modulus is experienced in service.
  • Secant Modulus is effective modulus at 2
    strain.
  • - grey cast iron is also an example
  • Modulus of polymer changes with time and
    strain-rate.
  • - must report strain-rate de/dt for polymers.
  • - must report fracture strain ef before fracture.

initial E
Stress (MPa)
secant E
tangent E
strain
1 2 3 4 5 ..
21
Youngs Modulus, E
Graphite Ceramics Semicond
Metals Alloys
Composites /fibers
Polymers
E(GPa)
Based on data in Table B2, Callister
6e. Composite data based on reinforced epoxy with
60 vol of aligned carbon (CFRE), aramid (AFRE),
or glass (GFRE) fibers.
22
Poisson's ratio, ?
Poisson's ratio, ?
Units n dimensionless
metals ? 0.33ceramics ? 0.25polymers
? 0.40
Why does ? have minus sign?
23
Limits of the Poisson Ratio
  • Poisson Ratio has a range 1 ? 1/2
  • Look at extremes
  • No change in aspect ratio
  • Volume (V AL) remains constant ?V 0.
  • Hence, ?V (L ?AA ?L) 0. So,
  • In terms of width, A w2, then ?A/A 2 w ?w/w2
    2?w/w ?L/L.
  • Hence,

Incompressible solid. Water (almost).
24
Poisson Ratio materials specific
Metals Ir W Ni Cu Al Ag Au
0.26 0.29 0.31 0.34 0.34 0.38 0.42 generic
value 1/3 Solid Argon 0.25 Covalent
Solids Si Ge Al2O3 TiC
0.27 0.28 0.23 0.19 generic value 1/4 Ionic
Solids MgO 0.19 Silica Glass
0.20 Polymers Network (Bakelite) 0.49
Chain (PE) 0.40 generic value Elastomer Hard
Rubber (Ebonite) 0.39 (Natural) 0.49
25
Example Poisson Effect
  • Tensile stress is applied along cylindrical brass
    rod (10 mm diameter). Poisson ratio is ? 0.34
    and E 97 GPa.
  • Determine load needed for 2.5x103 mm change in
    diameter if the deformation is entirely elastic?

Width strain (note reduction in
diameter) ex ?d/d (2.5x103 mm)/(10 mm)
2.5x104 Axial strain Given Poisson
ratio ez ex/? (2.5x104)/0.34
7.35x104 Axial Stress sz Eez (97x103
MPa)(7.35x104) 71.3 MPa. Required Load F
szA0 (71.3 MPa) p(5 mm)2 5600 N.
26
Other Elastic Properties
Elastic Shear modulus, G
simple Torsion test
t G?
Elastic Bulk modulus, K
Pressure test Init. vol Vo. Vol chg. ?V
Special relations for isotropic materials
So, only 2 independent elastic constants for
isotropic media
27
Useful Linear Elastic Relationships
Simple tension
Material, geometric, and loading parameters all
contribute to deflection. Larger elastic moduli
minimize elastic deflection.
28
Complex States of Stress in 3D
  • There are 3 principal components of stress and
    (small) strain.
  • For linear elastic, isotropic case, use linear
    superposition.
  • Strain to load by Hookes Law eisi/E,
    i1,2,3 (maybe x,y,z).
  • Strain e to load governed by Poisson effect
    ewidth ?eaxial.

Total Strain in x in y in z
In x-direction, total linear strain is
29
Complex State of Stress and Strain in 3-D Solid
  • Hookes Law and Poisson effect gives total
    linear strain
  • For uniaxial tension test s1 s2 0, so e3
    s3/E and e1e2 ?e3.
  • Hydrostatic Pressure
  • For volume (Vl1l2l3) strain, ?V/V e1 e2 e3
    (1-2?)s3/E

Bulk Modulus, B or K P K ?V/V so K
E/3(1-2?) (sec. 7.5)
30
Plastic (Permanent) Deformation
(at lower temperatures, i.e. T lt Tmelt/3)
Simple tension test
engineering stress, s
Elastic
initially
engineering strain, e
Adapted from Fig. 7.10 (a), Callister Rethwisch
3e.
31
Yield Stress, sY
Stress where noticeable plastic deformation
occurs.
When ep 0.002
For metals agreed upon 0.2
  • P is the proportional limit where deviation from
    linear behavior occurs.

sY
  • Strain off-set method for Yield Stress
  • Start at 0.2 strain (for most metals).
  • Draw line parallel to elastic curve (slope of E).
  • sY is value of stress where dotted line crosses
    stress-strain curve (dashed line).

Note for 2 in. sample e 0.002 ?z/z ?z
0.004 in
32
Yield Points and sYS
Yield-point phenomenon occurs when elastic
plastic transition is abrupt.
No offset method required.
  • In steels, this effect is seen when dislocations
    start to move and unbind for interstitial solute.
  • Lower yield point taken as sY.
  • Jagged curve at lower yield point occurs when
    solute binds dislocation and dislocation
    unbinding again, until work-hardening begins to
    occur.

33
Stress-Strain in Polymers
3 different types of behavior
  • For plastic polymers
  • YS at maximum stress just after elastic region.
  • TS is stress at fracture!

Brittle
plastic
Highly elastic
  • Highly elastic polymers
  • Elongate to as much as 1000 (e.g. silly putty).
  • 7 MPa lt E lt 4 GPa 3 order of magnitude!
  • TS(max) 100 MPa some metal alloys up to
    4 GPa

34
Compare Yield Stress, sYS
Room T values
Based on data in Table B4, Callister 6e. a
annealed hr hot rolled ag aged cd cold
drawn cw cold worked qt quenched tempered
35
(Ultimate) Tensile Strength, sTS
Maximum possible engineering stress in tension.
Metals occurs when necking starts.
Ceramics occurs when crack propagation starts.
Polymers occurs when polymer backbones are
aligned and about to break.
36
Metals Tensile Strength, vTS
For Metals max. stress in tension when
necking starts, which is the metals
work-hardening tendencies vis-à-vis those that
initiate instabilities.
Maximum eng. Stress (at necking)
Fractional Increase in Flow stress
fractional decrease in load-bearing area
decreased force due to decrease in gage diameter
Increased force due to increase in applied stress
At the point where these two competing changes in
force equal, there is permanent neck. Determined
by slope of true stress - true strain curve
37
Compare Tensile Strength, sTS
Room T values
Based on data in Table B4, Callister Rethwisch
3e.
38
Example for Metals Determine E, YS, and TS
Stress-Strain for Brass
  • Youngs Modulus, E (bond stretch)
  • 0ffset Yield-Stress, YS (plastic deformation)
  • Max. Load from Tensile Strength TS
  • Gage is 250 mm (10 in) in length and 12.8 mm
    (0.505 in) in diameter.
  • Subject to tensile stress of 345 MPa (50 ksi)
  • Change in length at Point A, ?l el0

39
Temperature matters (see Failure)
Most metals are ductile at RT and above, but can
become brittle at low T
bcc Fe
cup-and-cone fracture in Al
brittle fracture in mild steel
40
Ductility (EL and RA)
Plastic tensile strain at failure
Adapted from Fig. 7.13, Callister Rethwisch 3e.
Another ductility measure
Note RA and EL are often comparable.
- Reason crystal slip does not change
material volume. - RA gt EL possible
if internal voids form in neck.
41
Toughness
Energy to break a unit volume of material,
or absorb energy to fracture. Approximate
as area under the stress-strain curve.
Brittle fracture elastic energyDuctile
fracture elastic plastic energy
42
Resilience, Ur
Resilience is capacity to absorb energy when
deformed elastically and recover all energy
when unloaded (s2YS/2E). Approximate as area
under the elastic stress-strain curve.
Area up to 0.2 strain
If linear elastic
43
Elastic Strain Recovery
  • Unloading in step 2 allows elastic strain to
    be recovered from bonds.
  • Reloading leads to higher YS, due to
    work-hardening already done.

44
Ceramics Mechanical Properties
  • Ceramic materials are more brittle than metals.
    Why?
  • Consider mechanism of deformation
  • In crystalline materials, by dislocation motion
  • In highly ionic solids, dislocation motion is
    difficult
  • due to too few slip systems
  • Not 111lt110gt as in fcc metal!
  • Why is it 110lt110gt (or100 lt110gt )?
  • resistance to motion of ions of
  • like charge (e.g., anions)
  • past one another.

45
Strength of Ceramics - Elastic Modulus
  • RT behavior is usually elastic with brittle
    failure.
  • 3-point bend test employed (tensile test not
    best for brittle materials).

46
Strength of Ceramics - Flexural Strength
  • 3-point bend test employed for RT Flexural
    strength.

Rectangular cross-section
Typical values
Circular cross-section
L length between load pts b width d
height or diameter
Data from Table 7.2, Callister Rethwisch 3e.
47
Stress-Strain in Polymers
Fracture strengths of polymers 10 of those
for metals.
Deformation strains for polymers gt 1000.
for most metals, deformation strains lt 10.
48
Influence of T and Strain Rate on Thermoplastics
s
(MPa)
Decreasing T... -- increases E --
increases TS -- decreases EL Increasing
strain rate... -- same effects
as decreasing T.
Plots for
4C
semicrystalline
PMMA (Plexiglas)
20C
40C
to 1.3
60C
0
e
0
0.1
0.2
0.3
Adapted from Fig. 7.24, Callister Rethwisch 3e.
(Fig. 7.24 is from T.S. Carswell and J.K. Nason,
'Effect of Environmental Conditions on the
Mechanical Properties of Organic Plastics",
Symposium on Plastics, American Society for
Testing and Materials, Philadelphia, PA, 1944.)
49
Stress-Strain in Polymers
Necking appears along entire sample after YS!
Mechanism unlike metals, necking due to
alignment of crystallites.
Load vertical
  • Align crystalline sections by straightening
    chains in the amorphous sections
  • After YS, necking proceeds by unraveling hence,
    neck propagates, unlike in metals!

See Chpt 8
50
Time-dependent deformation in Polymers
Stress relaxation test
  • strain in tension to eo
  • and hold.
  • - observe decrease in
  • stress with time.

51
True Stress and Strain
Relation before necking
Engineering stress
Initial area always
True stress
instantaneous area
True strain
Relative change
Necking 3D state of stress!
52
Why use True Strain?
  • Up to YS, there is volume change due to Poisson
    Effect!
  • In a metal, from YS and TS, there is plastic
    deformation, as dislocations move atoms by slip,
    but ?V0 (volume is constant).

Test length Eng. Eng. 0-1-2-3 0-3
0 2.00 1 2.20 0.1 2 2.42 0.1 3 2.662 0.1 0.662/2
.0 TOTAL 0.3 0.331
Eng. Strain
Sum of incremental strain does NOT equal total
strain!
True Strain
Sum of incremental strain does equal total
strain.
53
Hardening (true stress-strain)
An increase in sy due to plastic deformation.
Curve fit to the stress-strain response after
YS
54
Using Work-Hardening
Influence of cold working on low-carbon steel.
2nd drawn
1st drawn
Undrawn wire
  • Processing Forging, Rolling, Extrusion,
    Drawing,
  • Each draw of the wire decreases ductility,
    increases YS.
  • Use drawing to strengthen and thin aluminum
    soda can.

55
Hardness
Resistance to permanently indenting the
surface. Large hardness means
--resistance to plastic deformation or cracking
in compression. --better wear properties.
Adapted from Fig. 7.18.
56
Hardness Measurement
  • Rockwell
  • No major sample damage
  • Each scale runs to 130 (useful in range 20-100).
  • Minor load 10 kg
  • Major load 60 (A), 100 (B) 150 (C) kg
  • A diamond, B 1/16 in. ball, C diamond
  • HB Brinell Hardness
  • TS (psia) 500 x HB
  • TS (MPa) 3.45 x HB

57
Hardness Measurement
58
Account for Variability in Material Properties
  • Elastic modulus is material property
  • Critical properties depend largely on sample
    flaws (defects, etc.). Large sample to sample
    variability.
  • Statistics
  • Mean
  • Standard Deviation

where n is the number of data points
59
Design Safety Factors
Design uncertainties mean we do not push the
limit. Factor of safety, N (often given as S)
Often N is between 1.2 and 4
Ex Calculate diameter, d, to ensure that no
yielding occurs in the 1045 carbon steel rod.
Use safety factor of 5.
5
d 0.067 m 6.7 cm
60
Summary
Stress and strain These are
size-independent measures of load and
displacement, respectively.
Elastic behavior This reversible behavior
often shows a linear relation between
stress and strain. To minimize deformation,
select a material with a large elastic
modulus (E or G).
Plastic behavior This permanent deformation
behavior occurs when the tensile (or
compressive) uniaxial stress reaches sy.
Toughness The energy needed to break a unit
volume of material.
Ductility The plastic strain at failure.
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