EChem 1 Module 6 - Mechanical Properties of Metals PDF

Summary

This document provides study material on mechanical properties of metals, including various concepts like stress, strain, tension tests, compression tests, and more. The document covers topics from basic definitions to more advanced concepts and applications related to the field of metallurgy and materials science. The text is presented in a lecture note format.

Full Transcript

EChem 1
Module 6

Mechanical
Properties of
Metals
 WHY STUDY The Mechanical
Properties of Metals?
It is incumbent on engineers to
understand how the various mechanical
properties are measured and what these
properties represent; they may be called
upon to design structures/components
using predetermined materials such that
unacceptable levels of deformation and/or
failure will not occur.
▪ It is necessary to know the characteristics
of the material and to design the member
from which it is made such that any
resulting deformation will not be
excessive and fracture will not occur.
▪ The mechanical behavior of a material
reflects the relationship between its
response or deformation to an applied
load or force.
▪ Important mechanical properties are
strength, hardness, ductility, and stiffness.
 Important mechanical properties
▪ Strength
▪ Hardness
▪ Ductility
▪ Stiffness
 CONCEPTS OF STRESS AND
STRAIN
If a load is static or changes relatively
slowly with time and is applied uniformly
over a cross section or surface of a member,
the mechanical behavior may be ascertained
by a simple stress–strain test; these are most
commonly conducted for metals at room
temperature. There are three principal ways
in which a load may be applied: namely,
tension, compression, and shear
 CONCEPTS OF STRESS AND
STRAIN
Three principal ways in which a load
may be applied:
▪ Tension
▪ Compression
▪ Shear
There are three principal ways in which a load may
be applied: namely, tension, compression, and shear
 Tension Tests
One of the most common mechanical stress–strain
tests is performed in tension. The tension test can be
used to ascertain several mechanical properties of
materials that are important in design.

Standard tensile specimen
▪ The tensile testing machine is designed to
elongate the specimen at a constant rate,
and to continuously and simultaneously
measure the instantaneous applied load
(with a load cell) and the resulting
elongations (using an extensometer).

▪ A stress–strain test typically takes several
minutes to perform and is destructive; that
is, the test specimen is permanently
deformed and usually fractured.
▪ Gauge length is used in ductility computations;
the standard value is 50 mm (2.0 in.). The
specimen is mounted by its ends into the holding
grips of the testing apparatus.
 To minimize the geometrical factors,
load and elongation are normalized to the
respective parameters of engineering stress
and engineering strain. Engineering stress is
defined by the relationship
▪ Engineering strain is defined according to
 Compression Tests
Compression stress–strain tests may be conducted
if in-service forces are of this type.A compression test is
conducted in a manner similar to the tensile test,except
that the force is compressive and the specimen contracts
along the direction of the stress. These equations are
utilized to compute compressive stress and strain

Compressive tests are used when a material’s
behavior under large and permanent (i.e., plastic) strains
is desired, as in manufacturing applications, or when the
material is brittle in tension.
 Shear and Torsional Tests
Shear stress is computed according to
 Torsion is a variation of pure shear, wherein a
structural member is twisted; torsional forces produce a
rotational motion about the longitudinal axis of one end
of the member relative to the other end. Examples of
torsion are found for machine axles and drive shafts, and
also for twist drills. Torsional tests are normally
performed on cylindrical solid shafts or tubes.

▪ Shear stress is a
function of the
applied torque T
▪ Shear strain is related
to the angle of twist
 Geometric Considerations of the
Stress State
Stresses that are computed from the
tensile, compressive, shear, and torsional
force states act either parallel or
perpendicular to planar faces of the bodies
represented in these illustrations. The stress
state is a function of the orientations of the
planes upon which the stresses are taken to
act.
 Stresses that are computed from the tensile, compressive,
shear, and torsional force states act either parallel or
perpendicular to planar faces of the bodies represented in these
illustrations.
 STRESS–STRAIN BEHAVIOR
The degree to which a structure deforms or strains
depends on the magnitude of an imposed stress. For
most metals that are stressed in tension and at
relatively low levels, stress and strain are
proportional to each other through the relationship
known as Hooke’s Law, and the constant of
proportionality E (GPa or psi) is the modulus of
elasticity, or Young’s modulus.
Modulus of elasticity values for several metals
at room temperature
Elastic Deformation - deformation in which
stress and strain are proportional; a plot of
stress (ordinate) versus strain (abscissa) results
in a linear relationship.
▪ The slope of this linear segment corresponds
to the modulus of elasticity E.
▪ This modulus may be thought of as stiffness,
or a material’s resistance to elastic
deformation.
▪ The greater the modulus, the stiffer the
material, or the smaller the elastic strain that
results from the application of a given stress.
▪ The modulus is an important design
parameter used for computing elastic
deflections.
▪ Elastic deformation is nonpermanent, which
means that when the applied load is released,
the piece returns to its original shape.
There are some materials (e.g., gray cast iron, concrete, and many
polymers) for which this elastic portion of the stress–strain curve is not
linear; hence, it is not possible to determine a modulus of elasticity. For
this nonlinear behavior, either tangent or secant modulus is normally
used. Tangent modulus is taken as the slope of the stress–strain curve
at some specified level of stress, while secant modulus represents the
slope of a secant drawn from the origin to some given point of the
curve.
On an atomic scale, macroscopic elastic strain is
manifested as small changes in the interatomic
spacing and the stretching of interatomic bonds. As
a consequence, the magnitude of the modulus of
elasticity is a measure of the resistance to separation
of adjacent atoms, that is, the interatomic bonding
forces. Furthermore,this modulus is proportional to
the slope of the interatomic force–separation curve at
the equilibrium spacing:
Figure shows the force–separation curves
for materials having both strong and weak
interatomic bonds; the slope at is indicated
for each.
Values of the modulus of elasticity for ceramic materials are
about the same as for metals; for polymers they are lower. These
differences are a direct consequence of the different types of
atomic bonding in the three materials types. Furthermore, with
increasing temperature, the modulus of elasticity diminishes, as
is shown for several metals in Figure.
 The imposition of compressive, shear, or
torsional stresses also evokes elastic behavior.
The stress–strain characteristics at low stress
levels are virtually the same for both tensile
and compressive situations, to include the
magnitude of the modulus of elasticity. Shear
stress and strain are proportional to each other
through the expression

where G is the shear modulus, the slope of the
linear elastic region of the shear stress–strain
curve
 ANELASTICITY
▪ Time-dependent elastic behavior and it is
due to time-dependent microscopic and
atomistic processes that are attendant to the
deformation.
▪ Elastic deformation will continue after the
stress application, and upon load release
some finite time is required for complete
recovery.
▪ For metals the anelastic component is
normally small and is often neglected.
However, for some polymeric materials its
magnitude is significant; in this case it is
termed viscoelastic behavior.
ELASTIC PROPERTIES OF
MATERIALS
 For isotropic materials, shear and
elastic moduli are related to each other and
to Poisson’s ratio according to

In most metals G is about 0.4E; thus, if the
value of one modulus is known, the other may
be approximated.

Many materials are elastically anisotropic;
that is, the elastic behavior (e.g.,the magnitude
of E) varies with crystallographic direction.
 Plastic Deformation
For most metallic materials, elastic
deformation persists only to strains of about
0.005. As the material is deformed beyond
this point, the stress is no longer
proportional to strain (Hooke’s law,
Equation 6.5, ceases to be valid), and
permanent, nonrecoverable, or plastic
deformation occurs.
 Figure 6.10a plots schematically the tensile
stress–strain behavior into the plastic region for a
typical metal. The transition from elastic to plastic is
a gradual one for most metals; some curvature
results at the onset of plastic deformation, which
increases more rapidly with rising stress.
▪ From an atomic perspective, plastic deformation
corresponds to the breaking of bonds with original
atom neighbors and then reforming bonds with
new neighbors as large numbers of atoms or
molecules move relative to one another; upon
removal of the stress they do not return to their
original positions.
▪ The mechanism of this deformation is different for
crystalline and amorphous materials.
▪ For crystalline solids, deformation is
accomplished by means of a process called slip,
which involves the motion of dislocations.
▪ Plastic deformation in noncrystalline solids (as
well as liquids) occurs by a viscous flow
mechanism.
 TENSILE PROPERTIES
▪ Yielding and Yield Strength
▪ It is desirable to know the stress level at
which plastic deformation begins, or where
the phenomenon of yielding occurs. For
metals that experience this gradual elastic–
plastic transition, the point of yielding may
be determined as the initial departure from
linearity of the stress–strain curve; this is
sometimes called the proportional limit, as
indicated by point P in Figure 6.10a.
▪ The stress corresponding to the intersection
of this line and the stress–strain curve as it
bends over in the plastic region is defined as
the yield strength
▪ The units of yield strength are MPa or psi
▪ Some steels and other materials exhibit the
tensile stress–strain behavior as shown in
Figure 6.10b. The elastic–plastic transition is
very well defined and occurs abruptly in
what is termed a yield point phenomenon. At
the upper yield point, plastic deformation is
initiated with an actual decrease in stress.
▪ The magnitude of the yield strength for a
metal is a measure of its resistance to
plastic deformation. Yield strengths may
range from 35 MPa (5000 psi) for a low
strength aluminum to over 1400 MPa
(200,000 psi) for high-strength steels.
 Tensile Strength
▪ The tensile strength TS (MPa or psi) is the
stress at the maximum on the engineering
stress–strain curve.
▪ After yielding, the stress necessary to
continue plastic deformation in metals
increases to a maximum, point M in
Figure
 Tensile Strength
▪ This corresponds to the maximum stress that can
be sustained by a structure in tension; if this stress
is applied and maintained, fracture will result.
▪ However, at this maximum stress, a small
constriction or neck begins to form at some point,
and all subsequent deformation is confined at this
neck.
▪ This phenomenon is termed “necking,” and
fracture ultimately occurs at the neck. The fracture
strength corresponds to the stress at fracture.
 Ductility
▪ Ductility is another important mechanical
property. It is a measure of the degree of
plastic deformation that has been
sustained at fracture.
▪ A material that experiences very little or
no plastic deformation upon fracture is
termed brittle.
▪ The tensile stress–strain behaviors for both
ductile and brittle materials are
schematically illustrated in Figure.
 Ductility may be expressed quantitatively
as either percent elongation or percent
reduction in area. The percent elongation %EL
is the percentage of plastic strain at fracture, or
Percent reduction in area %RA is defined as
 A knowledge of the ductility of
materials is important for at least two
reasons.
▪ First, it indicates to a designer the
degree to which a structure will deform
plastically before fracture.
▪ Second, it specifies the degree of
allowable deformation during
fabrication operations.
Several important mechanical properties of
metals may be determined from tensile stress–
strain tests.
▪ Resilience is the capacity of a material to
absorb energy when it is deformed elastically
and then, upon unloading, to have this
energy recovered. The associated property is
the modulus of resilience, which is the strain
energy per unit volume required to stress a
material from an unloaded state up to the
point of yielding.
▪ Computationally, the modulus of resilience
for a specimen subjected to a uniaxial tension
test is just the area under the engineering
stress–strain curve taken to yielding
Assuming a linear elastic region,

Incorporation of the equations, yields
▪ Toughness is a mechanical term that is
used in several contexts; loosely speaking,
it is a measure of the ability of a material
to absorb energy up to fracture.
 TRUE STRESS AND STRAIN
▪ True stress is defined as the load F divided
by the instantaneous cross-sectional area
over which deformation is occurring

▪ True strain defined by
Schematic comparison of engineering and
true stress–strain behaviors
For some metals and alloys the region of the
true stress–strain curve from the onset of
plastic deformation to the point at which
necking begins may be approximated by
 ELASTIC RECOVERY AFTER
PLASTIC DEFORMATION
Upon release of the load during the
course of a stress–strain test, some fraction
of the total deformation is recovered as
elastic strain. This behavior is demonstrated
in Figure 6.17, a schematic engineering
stress–strain plot.
 COMPRESSIVE, SHEAR, AND
TORSIONAL DEFORMATION
▪ For compression, there will be no
maximum, since necking does not occur;
furthermore, the mode of fracture will be
different from that for tension.
▪ HARDNESS which is a measure of a
material’s resistance to localized plastic
deformation (e.g., a small dent or a
scratch).
 Hardness tests are performed more
frequently than any other mechanical test for
several reasons:
1) They are simple and inexpensive—ordinarily
no special specimen need be prepared, and
the testing apparatus is relatively
inexpensive.
2) The test is nondestructive—the specimen is
neither fractured nor excessively deformed; a
small indentation is the only deformation.
3) Other mechanical properties often may be
estimated from hardness data, such as tensile
strength
 Rockwell Hardness Test
The Rockwell tests constitute the most
common method used to measure hardness
because they are so simple to perform and
require no special skills. Several different scales
may be utilized from possible combinations of
various indenters and different loads, which
permit the testing of virtually all metal alloys
(as well as some polymers).
 Brinell Hardness Tests
In Brinell tests, as in Rockwell
measurements, a hard, spherical indenter is
forced into the surface of the metal to be
tested. The diameter of the hardened steel
(or tungsten carbide) indenter is 10.00 mm
(0.394 in.). Standard loads range between
500 and 3000 kg in 500-kg increments;
during a test, the load is maintained
constant for a specified time (between 10
and 30 s).
 Knoop and Vickers
Microindentation Hardness Tests15
Two other hardness-testing techniques
are Knoop (pronounced ) and Vickers
(sometimes also called diamond pyramid). For
each test a very small diamond indenter having
pyramidal geometry is forced into the surface
of the specimen.Applied loads are much
smaller than for Rockwell and Brinell,ranging
between 1 and 1000 g.The resulting impression
is observed under a microscope and
measured;this measurement is then converted
into a hardness number
 Hardness Conversion
The facility to convert the hardness measured
on one scale to that of another is most desirable.
However, since hardness is not a well-defined
material property, and because of the experimental
dissimilarities among the various techniques, a
comprehensive conversion scheme has not been
devised. Hardness conversion data have been
determined experimentally and found to be
dependent on material type and characteristics. The
most reliable conversion data exist for steels, some of
which are presented in Figure 6.18 for Knoop,
Brinell, and two Rockwell scales; the Mohs scale is
also included.
Correlation Between Hardness and
Tensile Strength
Both tensile strength and hardness are indicators
of a metal’s resistance to plastic deformation.
Consequently, they are roughly proportional for tensile
strength as a function of the HB for cast iron, steel, and
brass. The same proportionality relationship does not
hold for all metalsAs a rule of thumb for most steels, the
HB and the tensile strength are related according to
1. A cylindrical specimen of a nickel alloy having an elastic
modulus of 207 Gpa (30 x 106 psi) and an original diameter of
10.2 mm (0.40 in.) will experience only elastic deformation
when a tensile load of 8900 N (2000 lbf) is applied. Compute
the maximum length of the specimen before deformation if
the maximum allowable elongation is 0.25 mm 90.010 in)

2. A cylindrical rod of steel (E = 207 Gpa, 30 x 106 psi) having a
yield strenght of 310 MPa (45,000 psi) is to be subjected to a
load of 11,100 N (2500 lbf). If the length of the rod is 500 mm
(20.0 in.), what must be the diameter to allow an elongation
of 0.38 mm (0.015 in.)?
3. A cylindrical specimen of a hypothetical
metal alloy is stressed in compression. If
its original and final diameters are 30.00
and 30.04 mm, respectively, and its final
length is 105.20 mm, compute its original
length if the deformation is totally elastic.
The elastic and shear moduli for this alloy
are 65.5 and 25.4 GPa, respectively.
4. A cylindrical metal specimen having an
original diameter of 12.8 mm (0.505 in.) and
gauge length of 50.80 mm (2.000 in.) is pulled
in tension until fracture occurs.The diameter
at the point of fracture is 8.13 mm (0.320 in.),
and the fractured gauge length is 74.17 mm
(2.920 in.). Calculate the ductility in terms
of percent reduction in area and percent
elongation.

Reference:
Materials Science and Engineering: An
Introduction by William Calister, Jr.