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CHAPTER 6: MECHANICAL PROPERTIES

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Title: CHAPTER 6: MECHANICAL PROPERTIES


1
CHAPTER 6 MECHANICAL PROPERTIES
ISSUES TO ADDRESS...
Stress and strain What are they and why are
they used instead of load and deformation?
Elastic behavior When loads are small, how
much deformation occurs? What materials
deform least?
Plastic behavior At what point do
dislocations cause permanent deformation?
What materials are most resistant to
permanent deformation?
Toughness and ductility What are they and
how do we measure them?
1
2
Chapter 6 Mechanical Properties of Metals6.1
Introduction
  • Why Study the Mechanical Properties of Metals ?
  • It is important for engineers to understand
  • How the various mechanical properties are
    measured, and
  • What these properties represent
  • The role of structural engineers is to determine
    stresses and stress distributions within members
    that are subjected to well-defined loads
  • By experimental testing
  • Theoretical and mathematical stress analysis.
  • Design structures/components using predetermined
    materials such that unacceptable levels of
    deformation and/or failure will not occur.

3
6.2 Concepts of Stress and Strain
  • Static load ? changes relatively slowly with time
  • Applied uniformly over a cross-section or surface
    of a member.
  • Tension
  • Compression
  • Shear
  • Torsion

4
6.2 Concepts of Stress and Strain (Contd.)
  • TENSION TEST
  • Most common mechanical stress-strain test
  • Used to ascertain several mechanical properties
    that are important in design
  • A specimen is deformed, usually to fracture, with
    a gradually increasing tensile load that is
    applied uniaxially along the long axis of the
    specimen.
  • A standard specimen is shown in Figure 6-2.

5
6.2 Concepts of Stress and Strain (Contd.)
  • The specimen is mounted by its ends into the
    holding grips of the testing apparatus (Figure
    6-3).
  • Tensile testing machine
  • To elongate the specimen at a constant rate
  • To continuously and simultaneously measure the
    instantaneous load and the resulting extension
  • Load using load cell
  • Extension using extensometer
  • Takes few minutes and is destructive.

6
6.2 Concepts of Stress and Strain (Contd.)
  • Engineering Stress (s) Instantaneous applied
    load (F) / Original Area (Ao)
  • Unit MPa, GPa, psi
  • Engineering strain (e)
  • li instantaneous length
  • lo original length
  • COMPRESSION TESTS
  • Similar to tensile test, compressive load
  • Sign convention, compressive force is taken
    negative ? stress negative
  • Since lo gt li , negative strain

7
6.2 Concepts of Stress and Strain (Contd.)
  • SHEAR AND TORSIONAL TESTS
  • Shear stress t F / Ao
  • F Load or force imposed parallel to the upper
    and lower faces
  • Ao shear or parallel area
  • Shear strain (g) is defined as the tangent of the
    strain angle q.

8
6.2 Concepts of Stress and Strain (Contd.)
  • GEOMETRIC CONSIDERATIONS OF THE STRESS STATE
  • Stress is a function of orientations of the
    planes

9
ELASTIC DEFORMATION
1. Initial
2. Small load
3. Unload
Elastic means reversible!
2
10
ELASTIC DEFORMATION6.3 Stress-Strain Behavior
  • Elastic deformation
  • Non-permanent, completely reversible,
    conservative
  • Follow same loading and unloading path
  • Linear elastic deformation
  • Hookes Law
  • Modulus of elasticity or Youngs Modulus ?
    stiffness or a materials resistance to elastic
    deformation

11
6.3 Stress-Strain Behavior (Contd.)
12
  • Nonlinear Elastic Behavior
  • Gray cast iron, concrete, many polymers
  • Not possible to determine a modulus of elasticity
  • Either tangent or secant modulus is normally used.

13
6.3 Stress-Strain Behavior (Contd.)
  • On an atomic scale, macroscopic elastic strain is
    manifested as small changes in the interatomic
    spacing and the stretching of interatomic bonds.
  • ? E is a measure of the resistance to separation
    of adjacent atoms
  • Modulus is proportional to the slope of the
    interatomic force-separation curve (Fig 2.8a) at
    equilibrium spacing

14
6.3 Stress-Strain Behavior (Contd.)
  • With increasing temperature, the modulus of
    elasticity diminishes
  • Shear stress and strain are proportional to each
    other
  • Shear modulus or modulus of rigidity ( Table 6.1)

15
6.4 Anelasticity
  • Up to this point, it is assumed that
  • Elastic deformation is time-independent
  • An applied stress produces an instantaneous
    elastic strain
  • Strain remains constant over the period of time
    the stress is maintained
  • Upon release of the load, strain is totally
    recovered (immediately returns to zero)
  • In most engineering materials, there will also
    exist a time-dependent elastic strain component ,
    i.e.
  • elastic deformation will continue after stress
    application
  • Upon load release some finite time is required
    for complete recovery
  • Loading and unloading path are different
  • Anelasticity time-dependent elastic behavior
  • For metals, the anelastic component is normally
    small and neglected.
  • For some polymers, it is significant and known as
    viscoelastic behavior (Sec. 16.7)

16
6.5 Elastic Properties of Materials
  • Poissons ratio
  • E 2G(1 n)
  • Example 6.1
  • Example 6.2

17
PLASTIC DEFORMATION
  • For most metals, elastic deformation persists
    only to strains of about 0.005
  • Plastic deformation
  • Stress not proportional to strain (Hookes law
    cease to be valid)
  • Permanent
  • Nonrecoverable
  • Non-conservative
  • Transition from elastic to plastic deformation
  • Gradual for most metals
  • Some curvature results at the onset of plastic
    deformation

18
PLASTIC DEFORMATION (METALS)
1. Initial
2. Small load
3. Unload
Plastic means permanent!
3
19
PLASTIC (PERMANENT) DEFORMATION
(at lower temperatures, T lt Tmelt/3)
Simple tension test
14
20
Plastic deformation (Contd.)
  • From as atomic perspective
  • Plastic deformation corresponds to the breaking
    of bonds with original atom neighbors
  • Reforming bonds with new neighbors
  • Large number of atoms and molecules move relative
    to one another
  • Upon removal of stress, they do not return to
    their original position
  • Mechanism of plastic deformation
  • Crystalline Solids
  • accomplished by a process called slip
  • Involves the motion of dislocations (Sec 7.2)
  • Non-crystalline solids (as well liquids)
  • Occurs by a viscous flow mechanism (Sec 13.9)

21
YIELD STRENGTH, sy
Stress at which noticeable plastic deformation
has occurred.
when ep 0.002
15
22
6.6 Tensile Properties
  • YIELDING and YIELD STRESS
  • Typical stress strain behavior (Figure)
  • Proportional Limit (P)
  • Yielding
  • Yield strength
  • In most cases, the position of yield point may
    not be determined precisely.
  • Established convention a straight line is
    constructed parallel to the elastic portion at
    some specified strain offset, usually 0.002
    (0.2) Fig. 6.10a ? corresponding intersection
    point gives yield strength.

23
6.6 Tensile Properties (Contd.)
  • Some steels and other materials exhibit the
    behavior as shown in Fig 6.10b
  • The yield strength is taken as the average stress
    that is associate with the lower yield point.
  • Magnitude of yield strength is a measure of its
    resistance to plastic deformation
  • Range from 35 MPa to 1400 MPa
  • 35 MPa for low-strength aluminum
  • 1400 MPa for high-strength steel

24
6.6 Tensile Properties (Contd.)
  • TENSILE STRENGTH
  • Tensile strength TS (MPa or psi) is the stress at
    the maximum on the engineering stress-strain
    curve
  • All deformation up to this point is uniform.
  • Onset of necking at this stress at some point ?
    all subsequent deformation at this neck.
  • Range 50 - 3000 MPa
  • 50 MPa for aluminum
  • 3000 MPa for high strength steel

25
DUCTILITY, EL
Plastic tensile strain at failure
Adapted from Fig. 6.13, Callister 6e.
Another ductility measure
Note AR and EL are often comparable.
--Reason crystal slip does not change material
volume. --AR gt EL possible if internal
voids form in neck.
19
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27
  • Effect of Temperature
  • As with modulus of elasticity (E), the magnitudes
    of both yield and tensile strengths decline with
    increasing temperature
  • Ductility usually increases with temperature
  • Figure shown stress-strain behavior of iron

28
RESILIENCE
  • Resilience is the capacity of a material to
    absorb energy when it is deformed elastically and
    then, upon unloading, to have this energy
    recovered.
  • Modulus of resilience (Ur)
  • Associated property
  • Area under the engineering stress-strain curve
  • Strain energy per unit volume required to stress
    from an unloaded state to yielding
  • Mathematically,

29
TOUGHNESS
Energy to break a unit volume of material
Approximate by the area under the stress-strain
curve.
20
30
TOUGHNESS
  • A measure of the ability of a material to absorb
    energy up to fracture.
  • Specimen geometry and the manner of load
    application are important in toughness
    determination
  • Notch toughness dynamic (high strain rate)
    loading, specimen with notch (or point of stress
    concentration) (Sec 8.6)
  • Fracture toughness property indicative of a
    materials resistance to fracture when crack is
    present (Sec 8.5)
  • For static (low strain rate) condition, modulus
    of toughness is equal to the total area under the
    stress-strain curve (up to fracture )
  • For Ductile Material For Brittle Material

31
6.7 True Stress and Strain
  • Engineering stress-strain curve beyond maximum
    point (M) seems to indicate that the material is
    becoming weaker.
  • Not true, rather it becomes stronger.
  • Since cross-sectional area is decreasing at the
    neck ? reduces load bearing capacity of the
    material
  • True stress Actual or current or instantaneous
    force divided by the instantaneous
    cross-sectional area.
  • True Strain Change in length per unit
    instantaneous length

32
6.7 True Stress and Strain (Contd.)
  • Relation between two definitions
  • Above equations are valid only to the onset of
    necking beyond this point true stress and strain
    should be computed from actual load, area and
    gauge length.
  • Schematic comparison in Figure 6.16
  • Corrected takes into account complex stress state
    with in neck region.

33
6.7 True Stress and Strain (Contd.)
  • For some metals and alloys, the true
    stress-strain curve is approximated as
  • Parameter n
  • strain-hardening exponent
  • A value less than unity
  • Slope on log-log plot
  • Parameter K
  • Known as strength coefficient
  • True stress at unit true strain

34
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35
6.8 Elastic Recovery During Plastic Deformation
  • Upon release of load, some fraction of total
    strain is recovered as elastic strain
  • During unloading, straight path parallel to
    elastic loading
  • Reloading
  • Yielding at new yield strength

36
  • Solve Examples in Class
  • 6.3
  • 6.4
  • 6.5
  • 6.6
  • Design Example 6.1
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