Abstract
Recycled aggregate concrete (RAC) is a promising solution to address the challenges raised by concrete production. However, the current lack of pertinent design rules has led to a hesitance to accept structural members made with RAC. It would entail even more difficulties when facing application scenarios where brittle failure is possible (e.g., beam in shear). In this paper, existing major shear design formulae established primarily for conventional concrete beams were assessed for RAC beams. Results showed that when applied to the shear test database compiled for RAC beams, those formulae provided only inaccurate estimations with surprisingly large scatter. To cope with this bias, machine learning (ML) techniques deemed as potential alternative predictors were resorted to. First, a Grey Relational Analysis (GRA) was carried out to rank the importance of the parameters that would affect the shear capacity of RAC beams. Then, two contemporary ML approaches, namely, the artificial neural network (ANN) and the random forest (RF), were leveraged to simulate the beams’ shear strength. It was found that both models produced even better predictions than the evaluated formulae. With this superiority, a parametric study was undertaken to observe the trends of how the parameters played roles in influencing the shear resistance of RAC beams. The findings indicated that, though less influential than the structural parameters such as shear span ratio, the effect of the replacement ratio of recycled aggregate (RA) was still significant. Nevertheless, the value of vc/(fc)1/2 (i.e., the shear contribution from RAC normalized with respect to the square root of its strength) predicted by the ML-based approaches appeared to be insignificantly affected by the replacement level. Given the existing inevitable large experimental scatter, more shear tests are certainly needed and, for safe application of RAC, using partial factors calibrated to consider the uncertainty is feasible when designing the shear strength of RAC beams. Some suggestions for future works are also given at the end of this paper.
Highlights
Mountains of concrete waste are being generated from demolition sites
Another wave of concern is around design and modeling, where the validity of previous code-based models and analytical procedures developed for natural aggregate concrete (NAC) components is questioned for their recycled aggregate concrete (RAC) counterparts; this issue has begun to be systematically addressed [15,16,17]
The results showed that an increased amount of recycled aggregate (RA) may erode the beams’ initial stiffness, but the effect on the shear strength is relatively small; given the same volume of longitudinal reinforcement, the shear capacity of RAC beams is clearly lower than that of NAC beams [25]
Summary
Mountains of concrete waste are being generated from demolition sites. This fact, together with the exceptional recent growth of concrete consumption, puts the construction sector into a dilemma. This should impede the acceptance of RAC-based members, though many laboratory studies have revealed their structural feasibility [8,9,10,11,12,13,14] Another wave of concern is around design and modeling, where the validity of previous code-based models and analytical procedures developed for natural aggregate concrete (NAC) components is questioned for their RAC counterparts; this issue has begun to be systematically addressed [15,16,17]. Limited understanding of the shear failure mechanism per se (even for the case of NAC) adds to the complexity, which encourages further explorations for properly representing the beams’ shear behavior From another angle, it is noticed that machine learning (ML) techniques are being increasingly used for complex material and structural problems [41,42,43]. This study helps to understand the shear problem of RAC beams, and contributes to upscaling the use of RAC in structural applications with confidence
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