PROPERTIES OF ENGINEERING MATERIALS.docx

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PROPERTIES OF ENGINEERING MATERIALS

1. **PHYSICAL PROPERTIES**- observable and measurable values describes
the state of physical System.

EXAMPLES

**MASS DENSITY**- material's mass per unit of volume

**WEIGHT DENSITY**- materials weight per unit volume

**DIELECTRIC STRENGHT**- maximum electric field that a pure material can
withstand without breaking down

**ELECTRICAL RESISTIVITY**- measures how strongly a material can resist
electric current

**MELTING POINT**- temperature which it changes state from solid to
liquid

**HEAT DISTORTION TEMPERATURE**- temperature at which a polymer plastic
deforms under specific loads

**REFRACTIVE INDEX**- dimensionless number that indicates light bending
ability of that medium.

**SPECIFIC GRAVITY**- ratio of the density of a substance to that of a
standard substance

**THERMAL CONDUCTIVITY-** ability of a material to conduct heat

**COEFFICIENT OF EXPANSION-** tendency of a material to change its
shape, area, volume in response to change in temperature.

**SPECIFIC HEAT-** quantity of heat required to raise the temperature of
one gram of a substance by one Celsius degree

2. **CHEMICAL PROPERTIES- changing its chemical identity through
chemical reactions**

EXAMPLES

**CORROSION-** deterioration of a metal as a result of reaction between
in and the environment

**CAUSTIC BRITTLEMENT-** material of a boiler which are under stress
becomes brittle due to accumulation of caustic substance.

3. **MECHANICAL PROPERTIES- behaviour of materials under the action of
external forces called loads**

**STRESSES-** measure of a force acting on a unit area of an
imaginary section through a body

**FORCE-** an influence that causes the object to undergo a certain
change

**LOADS-** external forces acting on a rigid body

**STRAIN-** deformation of solid due to stress

**TENSION-** two sections of material on either side of a plane tend to
be pulled apart

**TENSILE STRESS-** force which point away from its point

**TENSILE STRAIN-** measures the deformation of an object under tensile
stress

**COMPRESSION-** applies a load that squeezes the ends of a cylindrical
specimen

**COMPRESSICE STRESS-** force which points towards its point of
application

**COMPRESSIVE STRAIN-** change in length per original length due to
compressive force

**SHEARING-** applying a load parallel to a plane which caused the
material on one side want to slide across the other side

**BENDING-** applying load in manner that causes the material to curve.

**TORSION-** application of a force that causes twisting in a material.

**Elastic limit** is the greatest stress the material can withstand
without any measurable permanent strain remaining on the complete
release of load.

**Yield strength** is the stress required to produce a small-specified
amount of plastic deformation.

**Proportional limit** is the highest stress at which stress is linearly
proportional to strain.

**Ultimate tensile strength** is an engineering value calculated by
dividing the maximum load on a material experienced during a tensile
test by the initial cross section of the test sample.

**True fracture strength** is the load at fracture divided by the cross
sectional area of the sample

**DUCTILITY-** ability of a material to be stretched into wires
permanently without fracture

**MALLEABILITY-** ability of metal to be hammered, rolled, or pressed
into various shapes without fracture

**BRITTLENESS-** tendency of a material to fracture without any plastic
or little deformation

**STIFFNESS-** tendency of an element to return to its original form
after being subjected to a force

**STRENGHT-** measures how much stress can be applied to an element
before it deforms permanently

**HARDNESS-** measures a materials resistance to surface

**CREEP-** slow and continuous deformation that occur in the dimensions
of the material under a constant stress, usually at high temp.

**FRACTURE-** breakage of a material into separate parts under stress

**FATIGUE-** changes in the mechanical properties of the material under
the action of repeated stress

**ELASTICITY-** property of a material to return exactly to its original
shape on removal of straining force

**PLASTICITY-** ability of a material to not return to its original
shape when it deforms

**HOOKE'S LAW-** stress is linearly proportional to strain

**MODULUS OF ELASTICITY-** resistance to elastic deformation

**YOUNG'S MODULUS-** ratio of uniaxial stress over uniaxial strain

**SHEAR MODULUS-** ratio of shear stress over shear strain

**BULK MODULUS-** ratio of normal stress over volumetric strain

**OTHER PROPRTIES AND CHARACTERISTICS OF MATERIALS**

**THERMAL PROPERTIES-** response of a material to application of heat

**HEAT CAPACITY-** amount of energy required to produce a unit temp rise

**THERMAL EXPANSION-** increase in length, are, volume in response to
increase in temp.

**THERMAL CONDUCTION-** transport of thermal energy from high to low
temp regions of a material

Solid materials, heat is transported by vibrational lattice waves or
phonos

Ceramics and polymers- poor thermal conductors because free electron
concentrations are low and phonon conduction predominates

**THERMAL STRESSES-** induced in a body as a result of changes in temp

**THERMAL SHOCK RESISTANCE-** capacity of material to withstand plastic
deformation under thermal stress

**BIMETAL STRIP-** two metals bonded together with different coefficient
of expansion

**MAGNETISM-** phenomenon where materials exert an attractive or
repulsive force or influence on other materials

**MAGNETIC SUSCEPTABILITY-** measures the response of electrons to a
magnetic field

**MAGNETIC DIPOLES-** generated by moving electrically charged
particles, imaginary line of force that indicate the direction of force

**MAGNETIC FIELD VECTORS-** externally applied magnetic field

**MAGNETIC INDUCTION-** magnitude of the internal field strength within
a substance that is subjected to a magnetic field

**PERMEABILITY-** property of the specific medium through which the
magnetic field passes and in which magnetic induction is measured

**MAGNETIZATION OF A MATERIAL-** dependent on susceptibility and
magnetic fie;d strength

**FERROMAGNETIC-** certain materials strongly attract each other

**ANTIFERROMAGNETIC-** magnetic moments of each atom are arranged in
such way that every second moment is in the opposite direction to the
first. Alternate

**FERRIMAGNETIC-** magnetic moments have opposing moments