Abstract
Geopolymer concrete is an inorganic concrete that uses industrial or agro by-product ashes as the main binder instead of ordinary Portland cement; this leads to the geopolymer concrete being an eco-efficient and environmentally friendly construction material. A variety of ashes used as the binder in geopolymer concrete such as fly ash, ground granulated blast furnace slag, rice husk ash, metakaolin ash, and Palm oil fuel ash, fly ash was commonly consumed to prepare geopolymer concrete composites. The most important mechanical property for all types of concrete composites, including geopolymer concrete, is the compressive strength. However, in the structural design and construction field, the compressive strength of the concrete at 28 days is essential. Therefore, achieving an authoritative model for predicting the compressive strength of geopolymer concrete is necessary regarding saving time, energy, and cost-effectiveness. It gives guidance regarding scheduling the construction process and removal of formworks. In this study, Linear (LR), Non-Linear (NLR), and Multi-logistic (MLR) regression models were used to develop the predictive models for estimating the compressive strength of fly ash-based geopolymer concrete (FA-GPC). In this regard, a comprehensive dataset consists of 510 samples were collected in several academic research studies and analyzed to develop the models. In the modeling process, for the first time, twelve effective variable parameters on the compressive strength of the FA-GPC, including SiO2/Al2O3 (Si/Al) of fly ash binder, alkaline liquid to binder ratio (l/b), fly ash (FA) content, fine aggregate (F) content, coarse aggregate (C) content, sodium hydroxide (SH)content, sodium silicate (SS) content, (SS/SH), molarity (M), curing temperature (T), curing duration inside ovens (CD) and specimen ages (A) were considered as the modeling input parameters. Various statistical assessments such as Root Mean Squared Error (RMSE), Mean Absolute Error (MAE), Scatter Index (SI), OBJ value, and the Coefficient of determination (R2) were used to evaluate the efficiency of the developed models. The results indicated that the NLR model performed better for predicting the compressive strength of FA-GPC mixtures compared to the other models. Moreover, the sensitivity analysis demonstrated that the curing temperature, alkaline liquid to binder ratio, and sodium silicate content are the most affecting parameter for estimating the compressive strength of the FA-GPC.
Highlights
It is commonly known that the production of Portland cement (PC) needs a considerable amount of energy as well as participates in about 7% of the total volume of carbon dioxide in the atmosphere
The polymerization process is rapidly increased with the increment of curing temperature which makes the geopolymer concrete (GC) gain up to 70% of its final strength when the specimens cured inside an oven at 65 ̊C for 24 hr. beyond which there is a peripheral enhance in the compressive strength after 28 days of maturity [36,37]
The input dataset consists of the Si/Al range from 0.4– 7.7, l/b range from 0.25–0.92, fly ash (FA) range from 254–670 kg/m3, F range from 318–1196 kg/m3, C range from 394–1591 kg/m3, sodium hydroxide (SH) range from 25–135 kg/m3, sodium silicate (SS) range from 48–342 kg/m3, SS/ SH range from 0.4–8.8, M range from 3–20, T range from 23–120 ̊C, curing duration inside ovens (CD) range from 8–168 hr, and A range from 3–112 days
Summary
It is commonly known that the production of Portland cement (PC) needs a considerable amount of energy as well as participates in about 7% of the total volume of carbon dioxide in the atmosphere. The compressive strength of FA-GPC is affected by more than one parameter; in this study, for the first time, in a single developed model, influences of twelve parameters, such as SiO2/Al2O3 (Si/Al) of fly ash, alkaline liquid/binder (l/b), fly ash (FA) content, fine aggregate (F) content, coarse aggregate (C) content, sodium hydroxide (SH) content, sodium silicate (SS) content, (SS/SH) ratio, molarity (M), curing temperature (T), curing duration inside ovens (CD) and specimens ages (A) were investigated and quantified on the compressive strength of FA-GPC by using different model techniques, namely Linear Regression (LR), Nonlinear regression (NLR) and Multi-logistic Regression (MLR) They were used as predictive models for predicting the compressive strength of eco-efficient FA-GPC by using 510 samples from the literature studies
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