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Engineering Arch Theory
Arches employ the principal that when weight is
uniformly applied to them the forces resolve into axial compressive stresses
and thrust at the base or bearing points instead of into bending moments.
The fundamental feature of arched structures is
that horizontal reactions appear even if the structure is subjected to vertical
loads only.
This phenomenon is known as arch action.
As the height or rise of the arch decreases, the
outward thrust increases and as a result, maintaining the arch action and
preventing the arch from collapsing, internal ties or external bracing must be
employed.
The efficiency of an arch can be demonstrated by
comparing it with a beam of the same span under the same loading conditions.
Fixed arch: statically
indeterminate structures to the third degree, the end points require solid
restraints. These types of arches are the most ridged but are sensitive to
relative settlement at the supports as well as any additional forces created by
changes in temperature.
Two-hinged arch: statically
indeterminate to the first degree and although are not as rigid as fixed
arches, they are somewhat insensitive to relative settlement at the supports.
Three-hinged arch: statically
determinate and are not affected by settlement or the additional forces created
by temperature changes.
Tied-arch: provides
an internal member or tie to resist the outward thrust caused by arch action. A
strong tension member connected between the arch springing points reduces the
amount of any external bracing requirements.
Parabolic arch: because
both the shape of the arch and the shape of the bending moment diagram are
parabolic, when the arch is subjected to a uniform load, the bending moment at
every section of the arch is theoretically zero. The arch will be under pure
axial compression.
Assumptions and Limitations
· The cross-section of the arch is considered
small compared to its length (beam is long and thin)
· Loads act transverse to the longitudinal axis
and pass through the shear centre (any torsion/twist is eliminated).
· Self weight of the arch has been ignored (this
may have to be added).
· The material of the arch is homogenous and
isotropic and has a constant Young's modulus in all directions.
· The young's modulus is considered to be
constant in both compression and tension.
· The resultant moment of the bending stress is
equal to the external moment along the entire length of the beam.
· The centroidal plane (Neutral surface) is
subjected to zero axial stress and does not undergo any change in length.
· Deflections are assumed to be very small
compared to the overall length of the arch.
· The cross-section remains planar and
perpendicular to the longitudinal axis during bending.
· Any deflection of the arch follows a circular
arc with the radius of curvature considered to remain large compared to the
dimension of the cross section.
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