dc.description.abstract |
The experimental investigation has been carried out by testing near
. prototype size ferrocement box girders. Two box girders were tested under
uniformly distributed load (ud!) over the entire top flange and two other under
udl over half flange width and full span. Two box girders were joined at
the. level of top flange. The combined box girder was loaded and unloaded
under various load combinations in the uncracked stage. The girder was
later subjected to monotonically increasing sustained loads of short durations.
One composi te box girder made of bottom flange and side webs of ferrocement
and top flange of reinforced concrete was cast and tested under udl over the
entire top flange. After unloading it was again subjected to sustained loads
of short durations upto the penultimate load and for ten and half. months
at maximum applied load.
For the elastic analysis of ttreedimensional ferrocement structures such
as folded plates and shells of various shapes, beam theory, membrane theory,
membrane-bending theory and finite element method rove been used by variOUS
researchers. The analysis in the cracked range has been reported only in
the case of folded plates using beam theory to predict deflections, first crack
Ferrocement has been used in a variety of applications such as boats,
tanks, silos and roofs. For roofing purposes, its behaviour has .been investigated
by many researchers in the form of channel sections, ribbed slabs, folded
plates and shells of various shapes. Only channel sections and ribbed slabs
provide a flat top surface. Due to their small flexural rigidities, these elements
undergo large deflections and cracking at service loads. To reduce del!ection
and cracking and also to have a flat top surface, a new type of roofing/flooring
element in the form of box girder shape has been investigated experimentally
and analyticaUy in tre present study. load and ultimate load. Even the elastic analysis of folded plates using beam
theory is an approximate one because it does not take into account the distortion
and warping of the cross-section. The analysis in the cracked range
is even more approximate as it does not take into account the changing rigidity
of the material at different sections, material anisotropy and yielding of
the reinforcement leading to local redistribution of stresses.
To overcome above deficiencies, finite element method has been used
to predict the behaviour of ferrocement box girders through the elastic, cracked
and ultimate stages. Further to economize the finite element solution, the
conventional layered approach has been suitably modified for thin ferrocement
plated structures. Instead of considering the element to be consisting of.
suitable number of layers of mortar and reinforcement, the element is assumed
to be consisting of single mortar layer in the uncracked stage, uncracked and
cracked mortar layers in the cracked stage and smeared layers of wire mesh
and skeletal steel. In the cracked stage, the depth of cracked/yielded/crushed
mortar is determined. The stiffness of the element in the cracked stage
is obtained by adding the contributions due touncracked mortar layer, cracked/ .
yielded mortar layer and unyielded layers of wire mesh and skeletal steel.
The finite element analysis has been carried out under dead loads and
monotonically increasing live loads. A rectangular flat shell element capable
of representing membrane action, bending action and the interaction between
membrane and bending. action is adopted. Only. material nonlinearity due
to cracking of mortar, tension stiffening effect of mortar between the cracks
and the nonlinear stress-strain relationships for the mortar, wire mesh and
skeletal steel is considered. Since the box section provides large flexural
and torsional rigidity, the deflections in the cracked range are found to be
small and hence, geometrical nonlinearity is not considered. Also not considered in the analysis are bond slip between the reinforcement and mortar, time
dependent and thermal effects.
An incremen tal itera ti ve procedure capable of taking advantage of
both thc tangent and constant stiffncss approach has bcen used for the nonlinear
analysis. A general computer program has been developed to facilitate corilputer
aided analysis.
The validation of the proposed analytical formulation has been checked
by comparing the predicted results with the reported experimental/analytical
results of typical test problems taken from the literature as weli as with
the experimental results of the present investigation.
The predicted values from the proposcd analytical method ilrc gcnerilily
in good agreement with the experimental values except neilr the ultimate
. failure load where predicted values are on the flexible side.
The experimental .investigation shows that the limit state of serviceability
for ferrocement box girders is governed by the maximum crack width. At
the recommended crack width of 0.1 mm, the span/deflection ratio is much
above the value of 250 as permitted by 1.5. Code. At a span/deflection
ratio of 250, the load taken by the girders is .close to the yielding of the
reinforcemen t.
The double cel! box girder under various combinations of symmetric
and unsymmetric loads in the uncracked stage has behaved as one single unit
by undergoing downward deflections along the entire length and width. This
demonstrates the large load distribution capability of the box section.
Replacing the top ferrocement flange by a reinforced concrete one
results into the lowering of the first crack load and ultimate load. The failure of the girders is characterized by well distributed flexural
..
5.0 to 6.0 ti mes' the
The ulti rna te load was found
The instantaneous deflection of' the girder is reduced due
The sustained loading also leads to an increase in the width of cracks and
the region of cracks formation. However, the ultimate load of the girder IS
The increase In deflections or strains due to monotonically increasing
method is the prediction of cracks on .the bottom surface of the top flange
with the experimental crack-patterns. The added advantage of the analytical
,
The predicted crack-patterns of the bottom flange and the side webs
to be 2.0 to 3.0 times the first crack load.
sustained loads of short duration is maximum in the ini tial portion of the
to the sustained loading at lower load levels as compared to the instantaneous
deflection that would have occurred under monotonically increasing loads.
(being inside the box) at ultimate or near ultimate loads.
cracked range.
not affected by monotonically increasing sustained loads of short duration. |
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