Abstract
Waste glass (WG) is unsustainable due to its nonbiodegradable property. However, its main ingredient is silicon dioxide, which can be utilised as a supplementary cementitious material. Before reusing WG, the flexural strength (FS) and alkali–silica reaction (ASR) expansion of WG concrete are two essential properties that must be investigated. This study produced mortar containing activated glass powder using mechanical, chemical, and mechanical–chemical (combined) approaches. The results showed that mortar containing 30% WG powder using the combined method was optimal for improving the FS and mitigating the ASR expansion. The microstructure analysis was implemented to explore the activation effect on the glass powder and mortar. Moreover, a random forest (RF) model was proposed with hyperparameters tuned by beetle antennae search (BAS), aiming at predicting FS and ASR expansion precisely. A large database was established from the experimental results based on 549 samples prepared for the FS test and 183 samples produced for the expansion test. The BAS-RF model presented high correlation coefficients for both FS (0.9545) and ASR (0.9416) data sets, showing much higher accuracy than multiple linear regression and logistic regression. Finally, a sensitivity analysis was conducted to rank the variables based on importance. Apart from the curing time, the particle granularity and content of WG were demonstrated to be the most sensitive variable for FS and expansion, respectively.
Highlights
Lower flexural strength (FS) was observed in specimens containing 300 μm waste glass powder (WGP), which agrees with previous findings that coarse glass adversely affected mechanical characteristics [1,57]
The FS of the sample containing 30% 75 μm WGP was 7.6 MPa/s and the flexural strength (MPa), which almost reached the same strength level as the ordinary mortar sample. This is mainly attributed to the bonding strength arising from WGP’s pozzolanic reaction [11,58,59]
It is effective to increase the FS of WGP mortars by applying a mechanical approach
Summary
Sustainable construction involves the creation of a resource-efficient and eco-friendly environment. Construction waste reduction and waste recycling are two essential principles of this practice. Waste glass (WG) is a common urban solid waste, which is hazardous to the environment because of its inert and biodegradable properties. WG treatment is expansive, and its reuse is still at the initial stage. 11,530 kilotons of WG were generated in the United States in 2010, with only 30% recycled, and approximately
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