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PREPARED BY Mr. B. Ramesh kumar
NOTES FOR MEng 2091 Engineering Materials I
UNIT II (MECHANICAL PROPERTIES)
Occurrence of engineering materials/metals
• Materials and metals occur in two forms depending upon their electro positive characteristics.
• Free or native state. A few metals particularly noble metals having least electro positive
characteristics occur in free or in native state are called free/native metals, for example gold,
silver and platinum etc.
• On the other hand the metals fond in combine form which have high electro positive
characteristics are called combined metals most of these types of metals occur in nature in
compound state for example iron, copper and aluminum (as a mineral).
• Mineral. Mineral is defined as it is a compound of ore and gaunge material is called mineral.
• Ore. It is defined as it is a compound/ mixture of metallic and nonmetallic elements is called ore,
for example ferric oxide(Fe2o3), it posses ferrous as a metallic element and oxygen as a non
metallic element.
• Gange. It posses un wanted elements like rocky, dusty and sandy particle
• Classification of ores. There are two classes of ores native and combine state.
• Types of ores. Basically there are so many types of ores but in practical some most important
types of ores are used for engineering purposes in the different industries which are given
below.
• Oxide ores. Those ores which contain some %age of oxygen is called oxide ores.
• Carbonate ores. Those ores which contain carbon in combine is called carbonate ores.
• Sulphide ores. Those which contain sulphur are called sulphide ores.
• Silicous ores. Those which posse’s silicon are called silicous ores.
• Phosphoric ores. Those which posses phosphorous in combine form are called phosphoric ores.
• Note. Actually these all oxygen, carbon, silicon etc are very harm full elements for materials/
metals that is why these impurities should be removed of and purify the engineering materials/
metals for engineering use.
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PROPERTIES OF MATERIALS
• MECHANICAL PROPERTIES: Mechanical properties are the most important requirements of
materials from the engineering part of view in selecting them for design purpose.
• Mechanical properties include the action of external forces. A designer (Engineer) must have a
considerable knowledge of materials and their properties.
• Elasticity: It is the property of the material, which enables to regain its original shape, and size
after removal of load is known as elasticity.
• For each elastic body a certain limit exists beyond which the material will hold a remainingdeformation.
• This limit is called elastic limit.
Plasticity: It is the property of the material, which enables the deformation or permanent
Deformation, under the load. Or in other words that a material cannot regain its original position after
removal of a load is called plasticity.
• Ductility: It is the property of the material which enables it to be drawn out or elongated to an
appreciable extent before repute under the load is called ductility.
• This property is most important of the materials under rolling, forging and extrusion processes.
• Hardness: It is property of the material, which enables to resist easy abrasion indentation,
machining and scratching by harder body is called hardness.
• Brittleness. It is the property of material which break without any deformation under the load
is called brittleness.
Malleability. It is the property of material of getting the desire shape under the compressive load
without any breaking or cracking is called Malleability.
• Strength. It is the capacity or property of material to with stand or sustained the high load
under tension is called strength.
• Toughness. It is the ability of a material which absorb the energy/ impact load without any
fracture is called toughness.
• Creep. It is the ability of a material which resist the slow and continuous deformation under
steady load and some temperature is called creep.
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• Fatigue. It is the ability of a material which resist the deformation under repeated load forlarge number of cycles is called fatigue.
• Wear Resistance: It is the property of material which resist to easy removal of a solid
material by rubbing off the surface is called Wear Resistance.
• PHYSICAL PROPERTIES:
• Physical properties are employed to describe a material under conditions in which external
forces are not concerned. In case of metals some important physical properties are given
below.
• (i) Luster: the ability of the surface of the material to reflect the light is known as luster.
• All metals when polished have luster (accept lead). This property is greatly classifying a
material is metallic or Non metallic.
• For Example: Mild, Steel has some smooth finish with bluish black shine, and cast iron shows
sandy fracture.
• (ii) Color: This is the property of a material displaying a particular appearance in a normal
daylight is called color.
• For Example: Aluminum has white, when the Cu has yellowish, red and iron has grayish in
color and soon.
• (iii) Density: The density is defined as the wt: per unit volume of mat: is known as its density.
Different materials posse’s different density it is the very help full property of material that
we can justify either the metal is light or heavy. According to periodic table the density of the
element shows that density increase regularly with increasing the automatic number.
• For Example: Al has 2.7, Cu has 8.7 etc.
• (iv). Melting Point: the temperature at which the solid substances (Metals) changes into the
liquid or molten state is called the melting point.
• For Example: Al has 660 0C, Cu has 1083 0C and iron has 1535 0C.
• (v). Porosity: A material is said to be porous if it absorb lubricants/liquid easily is called
porosity.
• (vi).Thermal expansion: It is the property of material when the material increases in
dimensions on application of heat are called thermal expansion.
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• Chemical properties.
• Corrosion: It is the property of a material by which it deteriorate by chemical reaction with
its environment is known as corrosion, it degrades material properties and reduces economic
value of the material.
Technical properties of materials:
• (i). Machine ability: It is the property of the material, which enables it to be machined easily
in the desire shape by cutting tools is called machine ability. It signifies how much force and
power are required to removes stock from the material. In another sense machine ability has
been used to signify how well a material takes place a good finish.
• Simply it is to say that machine ability is the ease by which metal can be removed in various
machining operations.
• (ii) Cast ability: it is the ability of a material which can be cast into to the desire
form/component is known as cast ability.
• The metals which cannot be easily machined they can cast easily.
• For example cast iron can not easily machined.
• (iii) Weld ability: it is the property of a material which can be easily welded is called weld
ability.
• Why are alloys so popular?
Because the addition of alloy provides the mechanical properties needed for strength, corrosion
resistance and ductility
• How do Plasticity and Ductility differ?
Plasticity is the ability to be formed by force, ductility is a measure of how much the shape can
change.
5% or less elongation is considered brittle, greater than 5% is considered ductile.
• List some products made with Refractory metals. How are the metals made?
Light bulb filaments, electrodes, gas turbines, crucibles. These metals are pure elements.
• Explain how the AISI numbering system is used in classifying steels.
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The first two letters of the 4 digit number are the type of steel and the last two are the percent of carbon.
Tensile Strength Testing
• “Tensile” is a test in which a prepared sample is pulled until the sample breaks.
• Test Measurements are recorded in PSI (Pounds per Square Inch) E7018 = 70,000 PSI Tensile
• Test samples called “Tensile Bolts” can reveal a welds Tensile strength, Elastic limit, Yield point,
and Ductility.
• The Elastic Limit of metal is the stress (load) it can withstand and still return to the original
length after the load is released.
• Yield Strength occurs when the test sample stretches however will not return to its original
length.
• Ductility is the ability of a metal to stretch or elongate before it breaks.
Izod test Brinell TEST MACHINE UNIVERSAL TESTING MACHINE
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Impact Testing
• An Impact tester uses a heavy pendulum that is able to measure the amount of force required
to shear or fracture a test sample taken from welds “Heat Affected Zone” (HAZ)
• Impact testing may be performed using either the Izod or Charpy method. (Both methods are
similar)
• A Charpy or Izod test measures the welds ability to withstand an Impact force.
• Low Charpy test readings indicate brittle weld metal
• Higher Charpy readings indicate the samples toughness.
Hardness testing
• Hardness may be defined as the resistance to permanent indentation.
• Three common hardness measuring tests are
– Rockwell test
– Scleroscope test
– Brinell
– Microhardness test
• The Rockwell testing machine operates somewhat like a press, using a indenter to penetrate the
surface of the test sample.
• The depth of the indentation determines the materials hardness on a scale of 0-100
Rockwell test Machine
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• The Sceleroscpoe testing machine measures the amount “bounce” that a diamond tip hammer
rebounds off the test sample after being dropped.
• The Brinell method presses the “indenter” into a sample for a given period of time.
• The ability for the sample to resist indentation determines hardness.
• Microhardness testers allow you to measure a materials hardness while leaving the least
amount of damage possible on the metals surface.
• After the indenter is used a powerful microscope is used to determine the the amount of
indentation into the components surface.
• Chemical analysis is used in metallurgical laboratories to determine the metals grain and
crystalline structures.
• Samples are then place under a high power microscope to view the results.
• This is referred to as “Metalography
• Pressure testing or leak testing can be performed with either gasses or liquids.
• When this pressure exceeds the limitations of the structures design it will rupture under force.
• This rupture will allow engineers to understand the welds weakest areas.
TENSION TEST ON MILD STEEL
AIM:
To conduct tension test on the given mild steel rod for determining the yield stress, ultimate stress,
breaking stress, percentage of reduction in area, percentage of elongation over a gauge length and young’s
modulus.
APPARATUS REQUIRED:
1. Venire caliper.
2. Scale.
THEORY:
The tensile test is most applied one, of all mechanical tests. In this test ends of test piece and fixed into
grips connected to a straining device and to a load measuring device. If the applied load is small enough,
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the deformation of any solid body is entirely elastic. An entirely deformed solid will return to its original
form as soon as load is removed. However, if the load is too large, the material can be deformed
permanently. The initial part of the tension curve, which is recoverable immediately after unloading ,is
termed as elastic and the rest of the curve, which represents the manner in solid undergoes plastic
deformation is termed as plastic. The stress below which the deformation is essentially entirely elastic is
known as the yield strength of material. In some materials the onset of plastic deformation is denoted by a
sudden drop in load indication both an upper and a lower yield point. However, some materials do not
exhibit a sharp yield point. During plastic deformation, at larger extensions strain hardening cannot
compensate for the decrease in section and thus the load passes through the maximum and then begins to
decrease. At this stage the “ultimate strengths”, which is defined as the ratio of the load on the specimen
to the original cross sectional are, reaches the maximum value. Further loading will eventually cause neck
formation and rupture.
Usually a tension testis conducted at room temperature and the tensile load is applied slowly. During this
test either round of flat specimens may be used. The round specimens may have smooth, shouldered or
threaded ends. The load on the specimen is applied mechanically or hydraulically depending on the type
of testing machine
GRAPH : Draw a graph between Elongations (X-axis) and load (Y-axis).
PROCEDURE:
1. Measure the diameter of the rod using Vernier caliper.
2. Measure the original length of the rod.
3. Select the proper jaw inserts and complete the upper and lower chuck assemblies.
4. Apply some graphite grease to the tapered surface of the grip surface for the smooth motion.
5. Operate the upper cross head grip operation handle and grip fully the upper end of the test piece.
6. The left valve in UTM is kept in fully closed position and the right valve in normal open position.
7. Open the right valve and close it after the lower table is slightly lifted.
8. Adjust the load to zero by using large push button (This is necessary to remove the dead
weight of the lower table, upper cross head and other connecting parts of the load).
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9. Operate the lower grip operation handle and lift the lower cross head up and grip fully the
lower part of the specimen. Then lock the jaws in this position by operating the jaw locking
handle.
10. Turn the right control valve slowly to open position (anticlockwise) until we get a desired
loadings rate.
11. After that we will find that the specimen is under load and then unclamp the locking handle.
12. Now the jaws will not slide down due to their own weight. Then go on increasing the load.
13. At a particular stage there will be a pause in the increase of load. The load at this point is
noted as yield point load.
14. Apply the load continuously, when the load reaches the maximum value. This is noted as
ultimate load.
15. Note down the load when the test piece breaks, the load is said to be a breaking load.
16. When the test piece is broken close the right control valve, take out the broken
Pieces of the test piece. Then taper the left control valve to take the piston down.
ROCK WELL HARDNESS TEST
AIM:
To determine the Rockwell hardness number of the given specimen.
APPARATUS REQUIRED:
1. Emery paper
2. Penetrator
THOERY:
In Rock well hardness test consists in touching an indenter of standard cone or ball into the
surface of a test piece in two operations and measuring the permanent increase of depth of
indentation of this indenter under specified condition. From it Rockwell hardness is deduced.
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The ball (B) is used for soft materials (e.g. mild steel, cast iron, Aluminum, brass. Etc.) And the
cone (C) for hard ones (High carbon steel. etc.)
HRB means Rockwell hardness measured on B scale
HRC means Rock well hardness measured on C scale
PROCEDURE:
1. Clean the surface of the specimen with an emery sheet.
2. Place the specimen on the testing platform.
3. Raise the platform until the longer needle comes to rest
4. Release the load.
5. Apply the load and maintain until the longer needle comes to rest
6. After releasing the load, note down the dial reading.
7. The dial reading gives the Rockwell hardness number of the specimen.
8. Repeat the same procedure three times with specimen.
9. Find the average. This gives the Rockwell hardness number of the given specime
ROCK WELL HARDNESS TEST Machine
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BRINELL HARDNESS TEST
AIM:
To find the Brinell Hardness number for the given metal specimen.
EQUIPMENTS REQUIRED:
1. Brinell Hardness Testing Machine
2. Metal Specimens
3. Brinell Microscope.
FORMULAE:
Brinell Hardness Number (BHN) = 2P / {D [D - (D 2 – d 2) ] }
Where,
P = Load applied in Kgf.
D = Diameter of the indenter in mm.
d = Diameter of the indentation in mm.
DESCRIPTION:
It consists of pressing a hardened steel ball into a test specimen. In this usually a steel ball of
Diameter D under a load „P‟ is forced in to the test piece and the mean diameter „d‟ of the
indentation left in the surface after removal of load is measured. According to ASTM
specifications a 10 mm diameter ball is used for the purpose. Lower loads are used for measuring
hardness of soft materials and vice versa. The Brinell hardness is obtained by dividing the test
load „P‟ by curved surface area of indentation. This curved surface is assumed to be portion of
the sphere of diameter „D‟.
TEST REQUIREMENTS:
1. Usual ball size is 10 mm + 0.0045 mm. Some times 5 mm steel ball is also used. It shall be
hardened and tempered with a hardness of at least 850 VPN. (Vickers Pyramid Number). It shall
be polished and free from surface defects.
2. Specimen should be smooth and free from oxide film. Thickness of the piece to be tested shall
not be less than 8 times from the depth of indentation.
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3. Diameter of the indentation will be measured n two directions normal to each other with an
accuracy of + 0.25% of diameter of ball under microscope provided with cross tables and
calibrated measuring screws.
PRECAUTIONS:
1. Brinell test should be performed on smooth, flat specimens from which dirt and scale have
been cleaned.
2. The test should not be made on specimens so thin that the impression shows throu gh the
metal, nor should impressions be made too close to the edge of the specimen.
PROCEDURE:
1. Specimen is placed on the anvil. The hand wheel is rotated so that the specimen along with the
anvil moves up and contact with the ball.
2. The desired load is applied mechanically (by gear driven screw) and the ball presses into the
specimen.
3. The diameter of the indentation made in the specimen by the pressed ball is measured by the
use of a micrometer microscope, having transparent engraved scale in the field of view.
4. The indentation diameter is measured at two places at right angles to each other, and the
average of two readings is taken.
5. The Brinell Hardness Number (BHN) which is the pressure per unit surface area of the
indentation is noted down.
RESULT:
Thus the Brinell hardness of the Given Specimen is
1. Mild Steel = ---------- BHN
2. EN 8 = ---------- BHN
3. EN 20 = ---------- BHN