Mechanical properties of materials
A tensile test is generally conducted on a standard
specimen to obtain the relationship between the stress and the strain which is
an important characteristic of the material. In the test, the uniaxial load is
applied to the specimen and increased gradually. The corresponding deformations
are recorded throughout the loading. Stress-strain diagrams of materials vary
widely depending upon whether the material is ductile or brittle in nature. If
the material undergoes a large deformation before failure, it is referred to as
ductile material or else brittle material.Stress-strain diagram of a structural
steel, which is a ductile material, is given.
Initial part of the loading indicates a linear
relationship between stress and strain, and the deformation is completely
recoverable in this region for both ductile and brittle materials. This linear
relationship, i.e., stress is directly proportional to strain, is popularly
known as Hooke's law.
s
= Ee
The
co-efficient E is called the modulus of elasticity or Young's modulus.
Most of the engineering structures are designed to
function within their linear elastic region only.After the stress reaches a
critical value, the deformation becomes irrecoverable. The corresponding stress
is called the yield stress or yield strength of the material beyond which the
material is said to start yielding.
In some of the ductile materials like low carbon
steels, as the material reaches the yield strength it starts yielding
continuously even though there is no increment in external load/stress. This
flat curve in stress strain diagram is referred as perfectly plastic region.
The load required to yield the material beyond its
yield strength increases appreciably and this is referred to strain hardening
of the material. In other ductile materials like aluminum alloys, the strain
hardening occurs immediately after the linear elastic region without perfectly
elastic region.
After the stress in the specimen reaches a maximum
value, called ultimate strength, upon further tretching, the diameter of the
specimen starts decreasing fast due to local instability and this p henomenon
is called necking.
The load required for further elongation of the
material in the necking region decreases with decrease in diameter and the
stress value at which the material fails is called the breaking strength. In
case of brittle materials like cast iron and concrete, the material experiences
smaller deformation before rupture and there is no necking.
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