Experimental and analytical investigations on corroded reinforced concrete slab
Reinforced concrete (RC) flat slabs are indispensable members within RC structures because they maintain structural integrity. Under monotonic or seismic loadings, the flat slab represents the most vulnerable region. If it were to fail during punching shear, the structural system would be affe...
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| Format: | Thesis-Doctor of Philosophy |
| Language: | English |
| Published: |
Nanyang Technological University
2023
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| Online Access: | https://hdl.handle.net/10356/164946 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | Reinforced concrete (RC) flat slabs are indispensable members within RC structures
because they maintain structural integrity. Under monotonic or seismic loadings, the
flat slab represents the most vulnerable region. If it were to fail during punching
shear, the structural system would be affected, and it would lead to the rapid
collapse of the structure. More seriously, corrosion of reinforcements causes the
load capacity and durability of RC slab to deteriorate and increases the probability
of shear failure. There has therefore been a pressing concern to assess the security
of existing corroded RC flat slabs and to decide the appropriate time to repair or to
strengthen them according to their residual capacity at that particular time.
In this research, experimental studies on RC slabs under punching shear loading
were conducted. A total of 8 corroded and un-corroded specimens were tested to
investigate their strengths and failure modes. Punching shear strength, stiffness,
crack pattern, energy dissipation and failure mode, amongst other factors, were
examined. The punching shear strength of the corroded RC slabs was drastically
reduced, according to experimental data. Additionally, it was shown that specimen
failure modes changed with increasing corrosion, moving from punching shear
failure to flexural failure.
Numerical work was done to better estimate and investigates the punching shear
mechanisms in the corroded RC slabs. A calibrated and validated 3-dimensional
(3D) non-linear FE model was proposed considering the material deterioration and
bond degradation. This can be utilized to estimate the ultimate shear strength of
corroded RC slabs with various corrosion levels, reinforcement ratios, compressive
concrete strengths, and slab thicknesses efficiently. A thorough parametric analysis
was conducted to look into any additional factors that might have an impact on
punching shear strength. Empirical equations for forecasting the punching shear
strength of corroded RC slabs were suggested and validated based on the analytical
studies of the parametric study. Additionally, using the newly developed Critical
Shear Crack Theory, the behaviour of corroded RC slabs was examined (CSCT). A
deteriorated bond mechanism and material properties owing to the corrosion of reinforcements were incorporated into the CSCT model. The potential suggested
model showed good agreement with and the experimentally determined punching
shear strength as well as failure mode. A parametric study was also proposed on the
basis of the CSCT so as to study its impact on the failure mode and residual strength
of the corroded RC slabs. The results indicated that an increase in corrosion level,
decrease in reinforcement ratio and reduction in slab thickness would result in the
failure mode of the corroded RC slabs being converted from fail in punching shear
to fail in flexure.
Apart from the study of corroded slab under monotonic loading, further
investigation on the seismic behaviour of corroded slab-column joints was
conducted. A FE model of slab-column joint was utilized by considering the effect
of corrosion on mechanical properties of rebar as well as concrete deterioration.
Owing to the limitations of the experimental data, the numerical results were
verified by several un-corroded slab-column joints subjected to cyclic loading in the
literature. A parametric study was conducted so as to observe the effect of some
crucial factors that might affect seismic behaviour of the corroded RC slab. After
that, empirical formulas were proposed to estimate the ultimate moment capacity of
interior and exterior corroded slabs on the basis of the multivariable regression
analysis of the parametric study. |
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