Basics of Structural Analysis
Structural analysis is an
important subject of civil engineering that evaluates the different loads on
structures, and their effects. It is an accurate method to ascertain the
capability of the structures to withstand the expected loads, and assist in designing
the structures accordingly.
What Is Structural Analysis
Structural analysis is a
comprehensive assessment to ensure that the deformations ina structure will be adequately lower than the
permissible limits, and failure of structural will not occur. The aim of
structural analysis is to design a structure that has the proper strength,
rigidity, and safety. Deformations in a structure can be either elastic that is
totally recoverable, or inelastic that is permanent. Structural analysis
assists in the design of structures that meet their functional requirements, are
economical and attractive. Structural analysis integrates the disciplines of
mechanics, dynamics, and failure theories to compute the internal forces and
stresses on the structures to be designed.
Modes Of Structural Analysis
Structural analysis is carried
out by an examination of the real structure, on a model of the structure
created on some scale, and by the utilization of mathematical models. Tests are
conducted on the real structure when production is required of similar
structures in large quantities, like frames of a particular car, or when the
test expenses are acceptable due to the significance of the task. When elements
of the main structures are to be examined, then models are used for the
estimation of the different loads to be endured. Most structural analyses are
conducted on the mathematical models, in which the model could be elastic or
inelastic, forces may be static or dynamic, and the model of the structure
might be two dimensional or three dimensional.
Strength Of Materials
There are several methods to
determine the stresses in different structural members, such as columns and
beams that may cause failure under loading. To conduct an accurate structural analysis,
complete data concerning the structural loads, properties of materials, and
stresses involved is essential. The approach related to the strength of
materials is utilized for simple structural elements subjected to plain loads, such as shafts subjected to torsion, and
axial loading of bars. The strength of a material is dependent upon its
microstructure that can be changed by the application of various engineering
techniques on the material, such as work hardening and grain boundary
hardening. However, various mechanical characteristics of a material may
deteriorate in an effort to increase the strength, such as when the grain size
is decreased, the yield strength is increased but the material becomes brittle.
Estimation Of Loads
One important element of the
structural analysis is the accurate analysis of the estimation of structural
loads to be endured. Structural loads are the forces on a part of a structure,
or on the complete structure, and evaluation of their consequences is conducted
by structural analysis. Overload loading may result into failure of structures,
and such conditions should be considered during the design of the structures.
For buildings and bridges, the main vertical loads are gravity loads, including
the structure weight and the permanent accessories, known as dead loads. The
live loads are the concentrated loads, or distributed loads over large areas
such as floors. The horizontal loading on buildings is due to wind and inertial
forces caused by earthquakes.